 STRUCTURE OF DIVISION TABLE DIVISION BY NARROW BAND TIME FOR NARROW BAND COMMUNICATIONS
专利摘要:
there is a need to support narrowband tdd frame structure for narrowband communications. the present disclosure provides a solution supporting one or more frame narrow band tdd structures for narrow band communications. in one aspect of the disclosure, a method, a computer-readable medium and an apparatus are provided. the apparatus can receive information associated with a narrowband tdd frame structure for narrowband communications. the apparatus may transmit a first group of symbols from a first narrowband physical random access channel preamble (nprach) to a base station. in one aspect, a first length of the first group of symbols can be associated with the narrow band tdd frame structure. 公开号:BR112019017797A2 申请号:R112019017797-3 申请日:2018-02-22 公开日:2020-03-31 发明作者:Bhattad Kapil;Feng Wang Xiao;Rico Alvarino Alberto;Xu Hao 申请人:Qualcomm Incorporated; IPC主号:
专利说明:
STRUCTURE OF DIVISION TABLE DIVISION BY NARROWBAND TIME FOR NARROWBAND COMMUNICATIONS CROSS REFERENCE TO RELATED ORDER [0001] This order claims the benefit of Order Serial Number I.N. 201741007075, entitled NARROWBAND TIME-DIVISION DUPLEX FRAME STRUCTURE FOR narrowband communications and filed on February 28, 2017, and US Patent Application No. 15 / 710,748, entitled NARROWBAND TIME-DIVISION DUPLEX FRAME STRUCTURE FOR narrowband communications and deposited on September 20, 2017, which are expressly incorporated in this document as a reference in their entirety. BACKGROUND Field [0002] The present disclosure relates, in general, to communication systems and, more particularly, to a narrowband time division duplexing (TDD) frame structure for narrowband communications. Background [0003] Wireless communication systems are widely deployed to provide various telecommunication services, such as telephony, video, data, message transmission and broadcasts. Typical wireless communication systems can employ multiple access technologies capable of supporting communication with multiple users by sharing available system resources. Examples of such multiple access technologies include multiple division access systems Petition 870190083603, of 08/27/2019, p. 7/215 2/144 code (CDMA), time division multiple access systems (TDMA), frequency division multiple access systems (FDMA), orthogonal frequency division multiple access systems (OFDMA), multiple access systems by single carrier frequency division (SCFDMA) and multiple access system by time division synchronous code division (TD-SCDMA). [0004] These multiple access technologies have been adopted in several telecommunication standards to provide a common protocol that allows different wireless devices to communicate at a municipal, national, regional and even global level. An example of a telecommunications standard is Nova Rádio 5G (NR). NR 5G is part of a continuous evolution of mobile broadband promulgated by the Third Generation Partnership Project (3GPP) in order to meet new requirements associated with latency, reliability, security, scalability (for example, with Internet of Things (IoT )) and other requirements. Some aspects of the NR 5G may be based on the 4G Long Term Evolution (LTE) standard. There is a need for further improvements in NR 5G technology. These enhancements can also be applicable to other multi-access technologies and to the telecommunication standards that employ these technologies. [0005] Narrowband communications involve communication with a limited frequency bandwidth compared to the frequency bandwidth used for LTE communications. An example of narrowband communication is narrowband IoT (NB) communication (NB-IoT), which is limited to a single resource block Petition 870190083603, of 08/27/2019, p. 8/215 3/144 (RB) of system bandwidth, for example, 180 kHz. Another example in Communication band narrow is communication type enhanced machine (eMTC), which is limited to six RBs width band of system, per example, 1.08 MHz • [0006] THE Communication NB-IoT and eMTC can reduce device complexity, enable battery life for multiple years, and provide greater coverage in order to reach challenging locations inside buildings. There is a need to support narrowband TDD frame structure for narrowband communications. SUMMARY [0007] The following is a simplified summary of one or more aspects in order to provide a basic understanding of those aspects. This summary is not an extensive overview of all aspects covered and is not intended to identify key or crucial elements of all aspects, nor is it intended to outline the scope of any or all aspects. The sole purpose is to present some concepts of one or more aspects in a simplified form as a prelude to the more detailed description that is presented later. [0008] Narrowband communications involve communication with a limited frequency bandwidth compared to the frequency bandwidth used for LTE communications. An example of narrowband communication is NB-IoT communication, which is limited to an RB of the system's bandwidth, for example, 180 kHz. Another example of narrowband communication is eMTC, which Petition 870190083603, of 08/27/2019, p. 9/215 4/144 is limited to six RBs of system bandwidth, for example, 1.08 MHz. [0009] NB-IoT and eMTC communication can reduce the complexity of the device, enable battery life for multiple years and provide greater coverage in order to reach challenging locations inside buildings. However, due to the fact that coverage provided by narrowband communications may include reaching challenging locations (for example, a smart gas meter located in the basement of a building), there is a greater chance that one or more transmissions will not be received properly . Consequently, narrowband communications can include a predetermined number of repeated transmissions in order to increase the chance that the transmission will be decoded properly. There is a need to support narrowband TDD frame structure for narrowband communications. [0010] The present disclosure provides a solution supporting one or more narrowband frame TDD structures for narrowband communications. In one aspect of the disclosure, a method, a computer-readable medium and an apparatus are provided. The apparatus can determine a narrowband TDD frame structure for narrowband communications. The apparatus can also determine a PUSCH format from a group of PUSCH formats to allocate at least one resource unit (RU) to a UE for a narrowband physical uplink control (NPUCCH) channel. In addition, the device can allocate at least one RU to the UE using the channel format Petition 870190083603, of 08/27/2019, p. 10/215 5/144 shared physical uplink (PUSCH) determined, and the RU includes multiple subcarriers in each of one or more intervals. [0011] In addition, the apparatus can determine a narrowband TDD frame structure that includes at least a predetermined number of contiguous uplink subframes. The apparatus can also determine a first number of symbols in each of a second number of intervals to use in allocating at least one RU for a user device (UE) to a narrowband PUSCH (NPUSCH). In one aspect, the first number of symbols and the second number of intervals can be based on the predetermined number of contiguous uplink subframes. The device can allocate at least one RU to the UE. [0012] In an additional aspect, the device can receive information associated with a narrowband TDD frame structure that has a first set of contiguous uplink subframes. In one aspect, the first set of contiguous uplink subframes can include a first number of intervals. The apparatus may also transmit a first portion of an uplink transmission using at least a portion of the first number of slots in the first set of contiguous uplink subframes, wherein the uplink transmission has a longer duration than the first set of contiguous uplink subframes. [0013] In one aspect, the device can receive information associated with a TDD frame structure of Petition 870190083603, of 08/27/2019, p. 11/215 6/144 narrow band. The apparatus may also carry out an uplink transmission a predetermined number of times with the use of a first encryption sequence. In one aspect, the first encryption sequence may include a first number of less significant bits (LSBs) associated with a first radio frame. In another aspect, the first number of LSBs can be greater than a second number of LSBs used in a second encryption sequence associated with a narrowband frequency division duplexing (FDD) transmission. [0014] In an additional aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. In addition, the apparatus may determine to repeat an uplink transmission on a first set of radio frames and a second set of radio frames. The device can determine not to monitor downlink subframes in the first set of radio frames and the second set of radio frames. The apparatus may also perform one or more of a timing estimate or a frequency estimate using at least one downlink subframe in one or more of the first set of radio frames or the second set of radio frames. [0015] In another aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. In addition, the device can transmit a narrowband audible reference signal (NB-SRS) to a station Petition 870190083603, of 08/27/2019, p. 12/215 7/144 base using the narrowband TDD frame structure. [0016] In one aspect, the apparatus can receive information associated with a narrowband TDD frame structure for narrowband communications, the narrowband TDD frame structure includes a set of contiguous uplink subframes. The apparatus can also determine an orthogonal sequence length associated with a reference signal (RS) based on at least one of a number of uplink subframes or a number of intervals in the set of contiguous uplink subframes. In addition, the device can transmit an RS using the specified orthogonal sequence length. [0017] In an additional aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. The apparatus may also determine a sequence hop pattern associated with an RS based on at least one of a number of uplink subframes, a number of intervals in the set of contiguous uplink subframes or a radio frame number. In addition, the device can transmit the RS using the specified sequence jump pattern. [0018] In another aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. The apparatus can transmit a first group of symbols from a first narrowband physical random access channel (NPRACH) preamble to a base station. On a Petition 870190083603, of 08/27/2019, p. 13/215 8/144 aspect, a first length of the first group of symbols can be associated with the narrowband TDD frame structure. [0019] In one aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. In another aspect, the apparatus can determine a maximum number of symbol groups in a plurality of symbol groups associated with an NPRACH preamble that are suitable for an uplink occasion in the narrowband TDD frame structure. In a further aspect, the apparatus can transmit a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first uplink occasion in the narrowband TDD frame structure and a second subset of the plurality of associated symbol groups to the preamble of NPRACH on a second occasion of uplink in the narrowband TDD frame structure. In one aspect, the first subset can include the maximum number of groups of symbols. In another aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. [0020] In another aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. The apparatus can also determine a first number of groups of symbols from an NPRACH preamble to be transmitted on a first uplink occasion in the narrowband TDD frame structure. On a Petition 870190083603, of 08/27/2019, p. 14/215 9/144 aspect, the first number of symbol groups can include either two groups of symbols or three groups of symbols. [0021] In an additional aspect, the device can receive information associated with a narrowband TDD frame structure for narrowband communications. In addition, the device can determine a hop pattern associated with two pairs of symbol groups from an NPRACH transmitted on one or more uplink occasions using the narrowband TDD frame structure. [0022] In order to achieve the aforementioned and related purposes, the one or more aspects comprise the resources now fully described and highlighted particularly in the claims. The following description and the accompanying drawings present in detail certain illustrative features of the one or more aspects. However, these resources are indicative of only a few of the various ways in which the principles of the various aspects can be employed, and the present description is intended to include all of these aspects and their equivalents. BRIEF DESCRIPTION OF THE DRAWINGS [0023] Figure 1 is a diagram that illustrates an example of a wireless communications system and an access network. [0024] Figures 2A, 2B, 2C and 2D are diagrams that illustrate LTE examples of a DL frame structure, DL channels within the DL frame structure, a UL frame structure and UL channels within the Petition 870190083603, of 08/27/2019, p. 15/215 10/144 UL frame structure, respectively. [0025] The figure 3 is a diagram that illustrates a example of a node E evolved (eNB ) and user equipment (UE) in a network access. [0026] The figure 4A is a diagram that illustrates the structures of picture in Narrow band TDD exemplary in accordance with certain aspects of revelation. [0027] The figure 4B is a diagram that illustrates the exemplary narrowband PUSCH formats in accordance with certain aspects of the disclosure. [0028] Figure 4C is a diagram illustrating the example narrowband subcarrier frequency spacing in accordance with certain aspects of the disclosure. [0029] Figure 5A illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0030] Figure 5B illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0031] Figure 6 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can Petition 870190083603, of 08/27/2019, p. 16/215 11/144 support narrowband communications with the use of structures narrow band TDD frame in compliance with certain aspects of the disclosure.[0032] Figure 7 illustrates a data flow for one narrowband communication system (or systems narrowband communication) that can support narrowband communications with the use of structures narrow band TDD frame in compliance with certain aspects of the disclosure. [0033] Figure 8 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0034] Figure 9A illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0035] Figure 9B illustrates a comb type structure that can be used to transmit SRS and / or NB-SRS in accordance with certain aspects of the disclosure. [0036] Figure 10A illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. Petition 870190083603, of 08/27/2019, p. 17/215 12/144 [0037] Figure 10B illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0038] Figure 11 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0039] Figure 12 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0040] Figure 13 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. [0041] Figure 14 illustrates a data stream for a narrowband communication system (or narrowband communication systems) that can support narrowband communications using narrowband TDD frame structures in accordance with certain aspects of the disclosure. Petition 870190083603, of 08/27/2019, p. 18/215 13/144 [0042] A Figure 15 is a flow chart in one method of communication wireless •[0043] A Figure 16 is a flow chart in one method of communication wireless •[0044] A Figure 17 is a flow diagram in Dice conceptual that illustrates thedata flow in between different media / components in an exemplary device. [0045] Figure 18 is a conceptual diagram that illustrates an example of a hardware deployment for a device that employs a processing system. [0046] A Figure 19A is one flowchart in one method of communication wireless. [0047] A Figure 19B is one flowchart in one method of communication wireless. [0048] A Figure 20 is one flowchart in one method of communication wireless. [0049] A Figure 21 is one flowchart in one method of communication wireless. [0050] A Figure 22 is one flowchart in one method of communication wireless. [0051] A Figure 23 is one flowchart in one method of communication wireless. [0052] A Figure 24 is one flowchart in one method of communication wireless. [0053] A Figure 25 is one flowchart in one method of communication wireless. [0054] A Figure 26 is one flowchart in one method of communication wireless. [0055] A Figure 27 is one flowchart in one Petition 870190083603, of 08/27/2019, p. 19/215 14/144 wireless communication method. [0056] Figure 28 is a flow chart of a wireless communication method. [0057] Figure 29 is a conceptual data flow diagram that illustrates the data flow between different media / components in an exemplary device. [0058] Figure 30 is a conceptual diagram that illustrates an example of a hardware deployment for a device that employs a processing system. [0059] Figure 31 is a conceptual data flow diagram that illustrates the data flow between different media / components in an exemplary device. [0060] Figure 32 is a conceptual diagram that illustrates an example of a hardware deployment for a device that employs a processing system. [0061] Figure 33 is a conceptual data flow diagram that illustrates the data flow between different media / components in an exemplary device. [0062] Figure 34 is a conceptual diagram that illustrates an example of a hardware deployment for a device that employs a processing system. [0063] Figure 35 is a conceptual data flow diagram that illustrates the data flow between different media / components in an exemplary device. [0064] Figure 36 is a conceptual diagram that illustrates an example of a hardware deployment for Petition 870190083603, of 08/27/2019, p. 20/215 15/144 a device that employs a processing system. DETAILED DESCRIPTION [0065] The detailed description presented below in connection with the accompanying drawings is intended to serve as a description of various configurations and is not intended to represent the only configurations in which the concepts described in this document can be practiced. The detailed description includes specific details in order to provide a thorough understanding of various concepts. However, it will be evident to people skilled in the art that these concepts can be practiced without these specific details. In some examples, well-known structures and components are shown in the form of a block diagram in order to avoid incompressibility of such concepts. [0066] Several aspects of telecommunication systems will be presented with reference to various devices and methods. These devices and methods will be described in the following detailed description and illustrated in the accompanying drawings by various blocks, components, circuits, processes, algorithms, etc. (collectively called elements). These elements can be implemented using electronic hardware, computer software or any combination of them. The possibility of such elements being implemented as hardware or software depends on the particular application and the model limitations imposed on the general system. [0067] [0026] As an example, an element or any portion of an element or any combination of elements can be implanted as a system of Petition 870190083603, of 08/27/2019, p. 21/215 16/144 processing that includes one or more processors. Examples of processors include microprocessors, microcontrollers, graphics processing units (GPUs), central processing units (CPUs), application processors, digital signal processors (DSPs), reduced instruction set switching processors (RISC), systems on a chip (SoC), baseband processors, field programmable port arrangements (FPGAs), programmable logic devices (PLDs), state machines, port logic, discrete hardware circuits and other suitable hardware configured for perform the various features described throughout this disclosure. One or more processors in the processing system can run software. Software should be interpreted broadly to mean instructions, instruction sets, code, code segments, program code, programs, subprograms, software components, applications, software applications, software packages, routines, subroutines, objects, products executables, execution threads, procedures, functions, etc., be referred to as software, firmware, middleware, microcode, hardware description language or otherwise. [0068] Consequently, in one or more exemplary modalities, the functions described can be implemented in hardware, software or any combination thereof. If implemented in software, functions can be stored or encoded as one or more instructions or codes on computer-readable media. Computer-readable media includes Petition 870190083603, of 08/27/2019, p. 22/215 17/144 computer storage. Storage media can be any available media that can be accessed by a computer. For example, and not by way of limitation, such computer-readable media may comprise a random access memory (RAM), a read-only memory (ROM), an electrically erasable programmable ROM (EEPROM), optical disk storage, storage on magnetic disk, other magnetic storage devices, combinations of the types mentioned above for computer-readable media or any other media that can be used to store computer-executable code in the form of instructions or data structures that can be accessed by a computer. [0069] Figure 1 is a diagram illustrating an example of a wireless communications system and an access network 100. The wireless communications system (also called wireless wide area network (WWAN)) includes base stations 102 , UEs 104 and an Evolved Packet Core (EPC) 160. Base stations 102 can include macrocells (high power cell base station) and / or small cells (lower power cell base station). The macrocells include base stations. Small cells include femtocells, picocells and microcells. [0070] Base stations 102 (collectively referred to as the terrestrial radio access network interface of the evolved universal mobile telecommunications system (UMTS) (E-UTRAN)) with EPC 160 through backhaul links 132 (for example, interface Sl). In addition to other functions, base stations 102 can perform one or more Petition 870190083603, of 08/27/2019, p. 2/23 18/144 among the following functions: user data transfer, radio channel encryption and decryption, integrity protection, header compression, mobility control functions (eg automatic switching, dual connectivity), interface coordination between cells, connection preparation and release, load balancing, distribution for non-access layer (NAS) messages, NAS node selection, synchronization, radio access network (RAN) sharing, multicast / multicast service (MBMS), subscriber and equipment tracking, RAN information management (RIM), paging, positioning and delivery of warning messages. Base stations 102 can communicate directly or indirectly (for example, through EPC 160) with each other over backhaul links 134 (for example, interface X2). Backhaul links 134 can be wired or wireless. [0071] Base stations 102 can communicate wirelessly with UEs 104. Each of base stations 102 can provide communication coverage for a respective geographic coverage area 110. There may be overlapping geographical coverage areas 110. For example, small cell 102 'may have a coverage area 110' that overlaps coverage area 110 of one or more base stations 102. A network that includes both small cells and macrocells may be known as a network heterogeneous. A heterogeneous network may also include Domestic Evolved B Nodes (eNBs) (HeNBs), which can provide service to a limited group known as a closed group of subscribers (CSG). The links of Petition 870190083603, of 08/27/2019, p. 24/215 Communication 120 between base stations 102 and UEs 104 may include uplink (UL) transmissions (also called reverse link) from a UE 104 to a base station 102 and / or downlink (DL) transmissions. ) (also called a routing link) from a base station 102 to a UE 104. Communication links 120 may use multiple input and multiple output antenna technology (MIMO), including spatial multiplexing, beam formation and / or transmission diversity. The communication links can be through one or more carriers. Base stations 102 / UEs 104 can use a spectrum with a bandwidth up to Y MHz (for example, 5, 10, 15, 20, 100 MHz) per carrier allocated in a carrier aggregation of up to a total of Yx MHz (x component carriers) used for transmission in each direction. The carriers may or may not be adjacent to each other. The allocation of carriers can be asymmetric with respect to DL and UL (for example, they can be allocated to more or less DL carriers than for UL). Component carriers may include a primary component carrier and one or more secondary component carriers. A primary component carrier can be called a primary cell (PCell) and a secondary component carrier can be called a secondary cell (SCell). [0072] Certain UEs 104 can communicate with each other using the device-to-device (D2D) 192 communication link. The D2D 192 communication link can use the DL / UL WWAN spectrum. The D2D communication link 192 may use one or more side link channels, such as a physical side link diffusion channel (PSBCH), Petition 870190083603, of 08/27/2019, p. 25/215 20/144 a side link discovery physical channel (PSDCH), a side link shared physical channel (PSSCH) and a side link control physical channel (PSCCH). D2D communication can take place through a variety of wireless D2D communication systems, such as, for example, FlashLinQ, WiMedia, Bluetooth, ZigBee, Wi-Fi based on the IEEE 802.11 standard, LTE or NR. [0073] The wireless communications system may additionally include a Wi-Fi access point (AP) 150 in communication with Wi-Fi stations (STAs) 152 via communication links 154 in an unlicensed frequency spectrum of 5 GHz. During communication over an unlicensed frequency spectrum, STAs 152 / AP 150 can perform a clean channel assessment (CCA) before communicating to determine if the channel is available. [0074] Small cell 102 'can operate on a licensed / unlicensed frequency spectrum. During operation and an unlicensed frequency spectrum, small cell 102 'can employ NR and use the same unlicensed 5 GHz frequency spectrum as used by Wi-Fi AP 150. Small cell 102', which employs NR in an unlicensed frequency spectrum, it can intensify coverage up to the access network and / or increase its capacity. [0075] gNodeB (gNB) 180 can operate at millimeter wave frequencies (mmW) and / or frequencies almost mmW in communication with UE 104. When gNB 180 operates at frequencies of mmW or almost mmW, gNB 180 can be called an mmW base station. A frequency Petition 870190083603, of 08/27/2019, p. 26/215 Extremely high 21/144 (EHF) is part of the RE in the electromagnetic spectrum. The EHF has a range of 30 GHz to 300 GHz and a wavelength between 1 millimeter and 10 millimeters. The radio waves in the band can be called the millimeter wave. Almost mmW can extend up to a frequency of 3 GHz with a wavelength of 100 mm. The superhigh frequency band (SHE) extends between 3 GHz and 30 GHz, also called centimeter wave. Communications using the mmW / almost mmW radio frequency band have extremely high loss of path and a short range. The mmW 180 base station can use beamform 184 with UE 104 to compensate for extremely high path loss and short range. [0076] 0 EPC 160 can include an Entity in Management of Mobility (MME) 162, other MMEs 164, an Communications Port Server 166, a door in Communications from Service Multimedia From Broadcast / Broadcast Selective (MBMS) ) 168, a Center for Service in Broadcast / Broadcast Selective (BM-SC) 170 and a door in Packet Data Network (PDN) Communications 172. MME 162 may be in communication with a Domestic Subscriber Server (HSS) 174. MME 162 is the control node that processes signaling between UEs 104 and EPC 160 Generally speaking, MME 162 provides bearer and connection management. All user internet protocol (IP) packets are transferred through Server Communication Port 166 which, by itself, is connected to PDN Communications Port 172. PDN Communications Port 172 provides IP address allocation as well as other functions. PDN Communications Port 172 and BM-SC 170 Petition 870190083603, of 08/27/2019, p. 27/215 22/144 are connected to IP Services 176. IP Services 176 may include the Internet, an intranet, an IP Multimedia Subsystem (IMS), a PS Stream Service and / or other IP services. The BM-SC 170 can provide functions for providing and delivering MBMS user service. The BM-SC 17 0 can serve as an entry point for transmitting MBMS from a content provider, can be used to authorize and start MBMS Bearer Services within a mobile public land network (PLMN) and can be used to schedule MBMS transmissions. MBMS Communications Port 168 can be used to distribute MBMS traffic to base stations 102 that belong to a Multicast / Broadcast Single Frequency Network Area (MBSFN) that broadcasts a particular service and may be responsible for session management (start stopped) and to collect loading information related to eMBMS. [0077] The base station can also be called gNB, Node B, an eNB, an access point, a transceiver base station, a radio base station, a radio transceiver, a transceiver function, a set basic services (BSS), a set of extended services (ESS) or some other suitable terminology. Base station 102 provides an access point to EPC 160 for a UE 104. Examples of UEs 104 include a cell phone, a smart phone, a session initiation protocol (SIP) phone, a laptop computer, a personal digital assistant (PDA), a satellite radio, a global positioning system, a multimedia device, a video playback device, a Petition 870190083603, of 08/27/2019, p. 28/215 23/144 digital audio player (for example, MP3 player), a camera, an electronic game console, a tablet-type device, a smart device, a device that can be worn close to the body, a vehicle, an electric meter, a gas pump, large or small kitchen appliance, health care device, implant, viewfinder or other similarly functioning device. Some of the UEs 104 can be called loT devices (for example, parking meters, gas pump, toaster, cardiac monitor vehicles, etc.). UE 104 can also be called a station, mobile station, a subscriber station, a mobile unit, a subscriber unit, a wireless unit, a remote unit, a mobile device, a wireless device, a wireless communications device, a remote device, a mobile subscriber station, an access terminal, a mobile terminal, a wireless terminal, a remote terminal, a handset, a user agent, a mobile client, a client or some other suitable terminology. [0078] Again with reference to Figure 1, in certain aspects, the base station 102 / UE 104 can be configured to support one or more frame narrowband TDD structures for narrowband communications (198), for example, as described below with reference to any of Figures 4A to 36. [0079] Figure 2A is a diagram 200 illustrating an example of a DL frame structure in LTE. Figure 2B is a diagram 230 that illustrates an example of channels within the DL frame structure at LTE. Figure 2C is a diagram 250 that illustrates an example of a Petition 870190083603, of 08/27/2019, p. 2/29 24/144 UL frame structure at LTE. Figure 2D is a diagram 280 that illustrates an example of channels within the UL frame structure at LTE. Other wireless communication technologies may have a different frame structure and / or different channels. In LTE, a frame (10 ms) can be divided into 10 subframes of equal size. Each subframe can include two consecutive time slots. A resource grid can be used to represent the two time slots, each time slot including one or more competing time resource blocks (RBs) (also called physical RBs (PRBs)). The resource grid is divided into multiple resource elements (REs). In LTE, for a normal cyclic prefix, an RB contains 12 consecutive subcarriers in the frequency domain and 7 consecutive symbols (for DL, OFDM symbols; for UL, SC-FDMA symbols) in the time domain for a total of 84 REs . For an extended cyclic prefix, a RB contains 12 consecutive subcarriers in the frequency domain and 6 consecutive symbols in the time domain, for a total of 72 REs. The number of bits carried by each RE depends on the modulation scheme. [0080] As illustrated in Figure 2A, some of the REs carry DL (pilot) reference signals (DL-RS) for channel estimation in the UE. DL-RS can include cell-specific reference signals (CRS) (sometimes referred to as common RS), EU-specific reference signals (UE-RS) and Information reference signals in Channel State (CSI-RS). THE Figure 2A illustrates CRS for at antenna ports 0, 1, 2 and 3 (indicated like R o , Ri, r 2 and R 3 , respectively) , the UE-RS to the antenna port 5 Petition 870190083603, of 08/27/2019, p. 2/30 25/144 (indicated as R 5 ) and CSI-RS for antenna port 15 (indicated as R). Figure 2B illustrates an example of several channels within a DL subframe of a frame. The physical control format indicator (PCFICH) channel is within the 0 symbol of the 0 range and carries a control format indicator (CFI) indicating whether the physical downlink control channel (PDCCH) occupies 1, 2 or 3 symbols (Figure 2B illustrates a PDCCH that occupies 3 symbols). The PDCCH carries downlink control information (DCI) within one or more control channel elements (CCEs), with each CCE including new groups of RE (REGs), each REG includes four consecutive REs in an OFDM symbol . A UE can be configured with an EU-specific enhanced PDCCH (ePDCCH) which also carries DCI. The ePDCCH can have 2, 4 or 8 pairs of RB (Figure 2B shows two pairs of RB, each subset includes a pair of RB). The hybrid auto-repeat request (ARQ) physical indicator (PHICH) channel (HARQ) is also within the 0 symbol in the 0 range and carries the HARQ (HI) indicator that indicates negative ACK / ACK feedback ( NACK) based on the physical uplink shared channel (PUSCH). The primary synchronization channel (PSCH) is within symbol 6 of the interval 0 within subframes 0 and 5 of a frame and carries a PSS that is used by a UE to determine subframe timing and a physical layer identity. The secondary synchronization channel (SSCH) is within the interval 5 symbol 5 within subframes 0 and 5 of a frame and carries an SSS that is used by a UE to determine a Petition 870190083603, of 08/27/2019, p. 2/31/15 26/144 physical layer cell identity group number. Based on the physical layer identity and the physical layer cell identity group number, the UE can determine a physical cell identifier (PCI). Based on the PCI, the UE can determine the DL-RS locations mentioned above. The physical diffusion channel (PBCH) is within the symbols 0, 1, 2, 3 of interval 1 of subframe 0 of a frame and carries a master information block (MIB). The MIB provides several RBs in the DL system bandwidth, a PHICH configuration and a system frame number (SEN). The downlink shared physical channel (PDSCH) carries user data, broadcast system information not transmitted through the PBCH, such as system information blocks (STBs) and paging messages. [0081] As illustrated in Figure 2C, some of the REs carry demodulation reference signals (DM-RS) for channel estimation in eNB. The UE can additionally transmit audible reference signals (SRS) on the last symbol of a subframe. The SRS can have a comb type structure, and a UE can transmit SRS on one of the combs. The SRS can be used by an eNB to estimate channel quality to enable frequency-dependent programming at UL. Figure 2D illustrates an example of several channels within a frame's UL subframe. A physical random access channel (PRACH) can be within one or more subframes within a frame based on the PRACH configuration. PRACH can include six consecutive RB pairs within a subframe. PRACH allows the UE to perform access to Petition 870190083603, of 08/27/2019, p. 32/215 27/144 initial system and achieve UL synchronization. A physical uplink control channel (PUCCH) can be located at the edges of the UL system bandwidth. The PUCCH carries uplink control (UCI) information, such as programming requests, a channel quality indicator (CQI), a pre-coding matrix indicator (PMI), a Classification Indicator (RI) and a ACK / NACK feedback from HARQ. The PUSCH carries data and can be used additionally to carry a temporary storage status report (BSR), a power space report (PHR) and / or UCI. [ 0082] The figure 3 it is a diagram in blocks in an eNB 310 in Communication with one EU 350 en i a network in access. At the DL, the packages in IP EPC 160 can to be provided to a 375 controller / processor. The 375 controller / processor implements layer 3 and layer 2 functionality. Layer 3 includes a radio resource control layer (RRC), and layer 2 includes a convergence protocol layer of packet data (PDCP), a radio link control layer (RLC) and a medium access control layer (MAC). The 375 controller / processor provides RRC layer functionality associated with a diffusion of system information (for example, MIB, SIBs), RRC connection control (for example, RRC connection paging, RRC connection establishment, modification of RRC connection and RRC connection release), mobility of inter-radio access technology (RAT) and measurement configuration for UE measurement reporting; functionality of Petition 870190083603, of 08/27/2019, p. 33/215 28/144 PDCP layer associated with header decompression compression, security (encryption, decryption, integrity protection, integrity checking) and automatic switch support functions; RLC layer functionality associated with the transfer of upper layer packet data units (PDUs), error correction through ARQ, concatenation, segmentation and reassembly of RLC service data units (SDUs), new segmentation of PDUs from RLC data and RLC data PDU reordering; and MAC layer functionality associated with mapping between logical channels and transport channels, multiplexing MAC SDUs into transport blocks (TBs), demultiplexing MAC SDUs from TBs, programming information reporting, error correction through HARQ, manipulation priorities and logical channel prioritization. [0083] The transmission processor (TX) 316 and the receiving processor (RX) 370 implement layer 1 functionality associated with various signal processing functions. Layer 1, which includes a physical layer (PHY), can include error detection on transport channels, error correction of forwarding (FEC) encoding / decoding of transport channels, interleaving, rate matching, mapping on physical channels, modulation / demodulation of physical channels and MIMO antenna processing. The TX 316 processor manipulates the mapping to signal constellations based on various modulation schemes (for example, binary phase shift modulation (BPSK), quadrature phase shift modulation (QPSK), M phase shift modulation ( M-PSK), amplitude modulation by Petition 870190083603, of 08/27/2019, p. 34/215 29/144 square M (M-QAM)). The coded and modulated symbols can then be separated into parallel streams. Each flow can then be mapped to an OFDM subcarrier, multiplexed with a reference signal (for example, pilot) in the time and / or frequency domain, and then combined with the use of a Fast Transform of Inverse Fourier (IFFT) to produce a physical channel that carries a time domain OFDM symbol stream. The OFDM stream is spatially precoded to produce multiple spatial streams. Channel estimates of channel estimator 374 can be used to determine the coding modulation scheme, as well as for spatial processing. The channel estimate can be derived from a reference signal and / or channel condition feedback transmitted via the UE 350. Each spatial flow can then be supplied to a different antenna 320 via a separate transmitter 318TX. Each 318TX transmitter can modulate an RF carrier with a respective spatial flow for transmission. [0084] On the UE 350, each 354RX receiver receives a signal through its respective antenna 352. Each 354RX receiver retrieves modulated information on an RF carrier and provides the information to the receiving (RX) 356 processor. The TX 368 processor and the RX 356 processor implements layer 1 functionality associated with various signal processing functions. The RX 356 processor can perform spatial processing on the information to retrieve any spatial streams destined for the UE 350. If multiple spatial streams Petition 870190083603, of 08/27/2019, p. 35/215 30/144 are intended for the UE 350, these can be combined by the RX 356 processor into a single OFDM symbol stream. The RX 356 processor then converts the OFDM symbol stream from the time domain to the frequency domain using a Fast Fourier Transform (FFT). The frequency domain signal comprises a separate OFDM symbol stream for each sub-carrier of the OFDM signal. The symbols on each subcarrier and the reference signal are retrieved and demodulated by determining the most likely signal constellation points transmitted by the eNB 310. These discrete decisions can be based on channel estimates by channel estimator 358. Then, discrete decisions are decoded and deinterleaved to retrieve the data and control signals that were originally transmitted by eNB 310 on the physical channel. Then, the data and control signals are supplied to the 359 controller / processor, which implements layer 3 and layer 2 functionality. [0085] The controller / processor 359 can be associated with a 360 memory that stores codes and program data. 360 memory can be called computer-readable media. At UL, the 359 controller / processor provides demultiplexing between transport and logical channels, packet reassembly, decryption, header decompression and control signal processing to retrieve IP packets from the EPC 160. The 359 controller / processor is also responsible for error detection using an ACK and / or NACK protocol to support HARQ operations. [0086] Similar to functionality Petition 870190083603, of 08/27/2019, p. 36/215 31/144 described in the connection to the DL transmission by eNB 310, the 359 controller / processor provides RRC layer functionality associated with obtaining system information (for example, MIB, SIBs), RRC connection and measurement reporting; PDCP layer functionality associated with header compression / decompression and security (encryption, decryption, integrity protection, integrity verification); RLC layer functionality associated with the transfer of top layer PDUs, error correction by means of ARQ, concatenation, segmentation and reassembly of RLC SDUs, new segmentation of RLC data PDUs and rearrangement of RLC data PDUs; and MAC layer functionality associated with mapping between logical channels and transport channels, multiplexing of MAC SDUs in TBs, demultiplexing of MAC SDUs of TBs, scheduling information reporting, error correction through HARQ, priority handling and prioritization logical channel. [0087] Channel estimates derived by a channel estimator 358 from a reference or feedback signal transmitted by eNB 310 can be used by the TX 368 processor to select the appropriate coding and modulation schemes and to facilitate spatial processing. The spatial streams generated by the TX 368 processor can be supplied to different antennas 352 by means of separate transmissions 354TX. Each 354TX transmitter can modulate an RF carrier with a respective spatial flow for transmission. [0088] The UL transmission is processed in eNB 310 similar to that described in combination with the Petition 870190083603, of 08/27/2019, p. 37/215 32/144 receiver function in UE 350. Each 318RX receiver receives a signal through its respective antenna 320. Each 318RX receiver retrieves the modulated information in an RE carrier and supplies the information to an RX 370 processor. [0089] The 375 controller / processor can be associated with a 376 memory that stores program codes and data. The memory 376 can be called computer-readable media. At UL, the 375 controller / processor provides demultiplexing between transport and logical channels, packet reassembly, decryption, header decompression, control signal processing to retrieve IP packets from the UE 350. The 375 controller / processor IP packets can be supplied to EPC 160. The 375 controller / processor is also responsible for error detection using an ACK and / or NACK protocol to support HARQ operations. [0090] Narrowband communications involve communication with a limited frequency bandwidth compared to the frequency bandwidth used for LTE communications. An example of narrowband communication is NB-IoT communication, which is limited to an RB of the system's bandwidth, for example, 180 kHz. Another example of narrowband communication is eMTC, which is limited to six RBs of the system's bandwidth. [0091] NB-IoT and eMTC communication can reduce the complexity of the device, enable battery life for multiple years and provide greater coverage in order to reach challenging locations inside buildings. However, due to the fact that coverage Petition 870190083603, of 08/27/2019, p. 38/215 33/144 provided by narrowband communications may include reaching challenging locations (for example, a smart gas meter located in the basement of a building), there is a greater chance that one or more transmissions will not be received properly. Consequently, narrowband communications can include a predetermined number of repeated transmissions in order to increase the chance that the transmission will be decoded properly. There is a need to support narrowband TDD frame structure for narrowband communications. [0092] The present disclosure provides a solution providing support for NPDCCH, NPDSCH, NPUCCH and / or NPUSCH transmissions using a narrow band TDD frame structure. [0093] Figure 4A is a diagram illustrating a narrowband TDD frame structure 400 that can be used for narrowband communications in accordance with certain aspects of the disclosure. In one aspect, the narrowband TDD frame structure 400 can be determined from the group of narrowband TDD frame structures (for example, configuration 0 - configuration o) listed in table 410. For example, a station -based can determine the narrowband TDD frame structure based on upper layer signaling (for example, transmission of RRC messages) received from the network. Additionally and / or alternatively, the base station can determine the narrowband TDD frame structure based on the channel conditions. [0094] In one aspect, the narrowband TDD frame structure 400 may include a frame split Petition 870190083603, of 08/27/2019, p. 39/215 34/144 of 10 ms in two frames, each lasting 5 ms. The half frames can be divided into five subframes, each 1 ms long. The narrowband TDD frame structure 400 can include any of the narrowband configurations listed in table 410. [0095] Switching periodicity refers to the time that a UE may need to switch between monitoring a downlink subframe (for example, downlink transmissions from a base station) and sending a transmission using a subframe uplink, or vice versa. Depending on the determined narrowband TDD frame structure 400, the switching periodicity can be 5 ms, 10 ms, or more than 10 ms (for example, 20 ms). For narrowband TDD frame structures 412 with a switching period of 5 ms, a special subframe (SSF) can exist in both halves of the narrowband TDD frame structure 400. for TDD frame structures of narrow band 414 with a switching period of 10 ms, the special subframe may exist in the first half frame, but not in the second half frame. For narrowband TDD frame structures 416 with a switching period greater than 10 ms, special subframes may only be present during switching from DL to UL and therefore may not be present in all frames. In narrowband TDD frame structures 412, 414 that include a special subframe (for example, configurations 0, 1, 2, 3, 4, 5, and 6), subframes 0 and 5 as well as the Pilot Time Range Link Petition 870190083603, of 08/27/2019, p. 40/215 35/144 Descending (DwPTS) in the special subframe can be reserved for downlink transmissions. In addition and / or alternatively, on narrowband TDD frame structures 412, 414 that include a special subframe, the Uplink Pilot Time Range (UpPTS) in the special subframe and in the subframe immediately after the special subframe can be reserved for uplink transmission. [0096] During operation in band input mode and / or band protection mode, the narrow band TDD frame structure 400 can reuse certain LTE TDD frame structures (for example, see settings 0, 1, 2, 3, 4, 5, 6 in Figure 4A). Additionally and / or alternatively, some subframes in the narrowband TDD frame structure 400 can be marked as flexible subframes (for example, see configuration 1 and in Figure 4A) and can be used either as a downlink subframe or an uplink subframe by a UE depending on the current lease received from the base station. [0097] In certain respects, a subset of the narrowband TDD configurations striped in table 410 in Figure 4A can be used to support narrowband communications. For example, setting 0 may not be suitable for narrowband communications due to the fact that setting 0 has only two downlink subframes. In one configuration, narrowband communications using a narrowband TDD frame structure can be supported only in the bandwidth and / or mode Petition 870190083603, of 08/27/2019, p. 41/215 36/144 bandwidth protection (for example, but not in standalone mode). In another configuration, narrowband communications using a narrowband TDD frame structure can support the bandwidth input mode, the bandwidth protection mode and the standalone mode. [0098] In addition, multiple narrowband downlink carriers and multiple narrowband uplink carriers can be used to enhance narrowband communication between the base station and a UE. Among the carriers, a narrowband docking carrier can be used to provide synchronization, system information, paging, data and control for UEs enabled by multiple carriers. In this way, the overhead of narrowband system information can be reduced. For example, synchronization and paging for a given cell may not be provided on all narrowband carriers. Narrowband carriers that do not provide synchronization and / or paging can be called narrowband non-anchoring carriers. Coordination between base stations to select anchor carriers that mitigate interference and to transmit power control to non-anchor carriers provides additional network performance advantages. [0099] Figure 4B is a diagram illustrating a radio frame 430 that can be used for narrowband communications in accordance with certain aspects of the disclosure. [0100] Figure 4C is a diagram that illustrates a 10 ms frame with a subcarrier spacing of 15 Petition 870190083603, of 08/27/2019, p. 42/215 37/144 kHz 480, a 20 ms frame with 7.5 kHz 47 0 subcarrier spacing and a 40 ms frame with 3.75 kHz 460 spacing in accordance with certain aspects of the disclosure. [0101] Referring to Figures 4B and 4C, radio frame 430 may include a 10 ms frame, a 20 ms frame or a 40 ms frame depending on the subcarrier spacing. For example, a 10 ms frame can have a 15 kHz subcarrier spacing (for example, see item 480 in Figure 4C). In addition, a 20 ms frame can have a subcarrier spacing of 7.5 kHz (see item 470 in Figure 4C). In addition, a 40 ms frame can have a spacing of 3.7 5 kHz (see item 460 in Figure 4C). [0102] In certain configurations, the radio frame 430 can be divided into 10 subframes that are made, each, by up to 2 intervals. Each of the intervals can be x / 20 ms in length depending on whether the frame is a 10 ms frame, a 20 ms frame or a 40 ms frame. In one respect, x can be equal to the frame length (for example, 10 ms, 20 ms or 40 ms). In other words, each interval in a 10 ms frame (for example, 15 kHz subcarrier spacing) can be 0.5 ms in length, each interval in a 20 ms frame (for example, 7.5 subcarrier spacing) kHz) can be 1 ms long and each interval in a 40 ms frame (for example, 3.75 kHz subcarrier spacing) can be 2 ms long. [0103] Referring to Figure 4B, each slot can be divided into a number N s subcarriers Petition 870190083603, of 08/27/2019, p. 43/215 38/144 that each have the same subcarrier spacing (for example, 3.75 kHz, 7.5 kHz, or 15 kHz) and N symb orthogonal frequency division multiplexing (OFDM) symbols (for example, 7 OFDM symbols). [0104] Various NPUSCH formats can be used by a base station to allocate resources for one or more uplink transmissions from a UE. For example, a base station can use the NPUSCH 1 format to allocate resources for uplink data transmissions (for example, NPUSCH). When resources for an acknowledgment (for example, NPUCCH or ACK / NACK) to a downlink transmission are allocated to a UE, the NPUSCH 2 format can be used. For example, when a base station transmits an NPDCCH, the NPUSCH 2 format can be used to allocate resources for an ACK / NACK response from a UE. The smallest unit that a base station can use to map a transport block (TB) or to an NPUSCH, NPUCCH and / or ACK / NACK can be a resource unit (RU). [0105] For legacy NPUSCH 2 format (for example, in FDD NB-IoT systems), the RU can be composed of a single subcarrier with a length of 4 intervals. Consequently, for the subcarrier spacing of 3.75 kHz, the RU has a duration of 8 ms and for subcarrier spacing of 15 kHz the RU has a duration of 2 ms. An example of an NPUSCH 2 format inherited with a RU allocated to a single subcarrier is illustrated in the gap structure 440 in Figure 4B. [0106] Certain narrowband TDD frame structures may include only a few Petition 870190083603, of 08/27/2019, p. 44/215 39/144 uplink subframes (for example, see configuration 5 in Figure 4A which have only one uplink subframe). When configuration 5 is used for the narrowband TDD frame structure, a UE can send the uplink transmission in an uplink subframe (for example, 2 intervals) in a first radio frame and in another subframe uplink (for example, 2 intervals) in a second radio frame even in a good signal-to-noise (SNR) situation. Uplink transmissions that are transmitted over different radio frames may change in channel conditions, and the base station may not properly decode an uplink transmission sent through different radio frames. In addition, sending uplink broadcasts through different radio frames can also introduce a long delay in decoding the channel. There is a need to modify the legacy NPUSCH 2 format so that an uplink transmission received through different radio frames in a narrowband TDD frame structure can be decoded appropriately by a base station. [0107] In order to increase the chances of proper decoding at the base station, the present disclosure provides a modified NPUSCH 2 format structure that can be used to allocate an RU across multiple subcarriers over multiple intervals, as illustrated in the structure 450 in Figure 4B. Although 4 subcarriers are illustrated in Figure 4B as being allocated to the UK, any number of 2 or more Petition 870190083603, of 08/27/2019, p. 45/215 40/144 subcarriers can be used to allocate the UK without departing from the scope of the present disclosure. [0108] Increasing the number of carriers that are used to allocate a UK, the base station may have a better chance of decoding an uplink transmission sent through different radio frames due to the fact that more resource elements in each interval they can be used to carry the uplink transmission and / or due to the fact that the RU can be allocated in one or two intervals due to the increased number of resource elements allocated by multiple subcarriers and then, in some cases , avoid splitting the uplink transmission into discontinued parts (for example, expanding multiple radio frames). Resource Units [0109] Figure 5A illustrates a data stream 500 for base station 502 allocating one or more RUs for UE 504 for an uplink transmission (for example, NPUCCH and / or ACK / NACK) accordingly with certain aspects of the disclosure. Base station 502 can correspond, for example, to base station 102, 180, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702 / 1702 '. UE 504 may correspond, for example, to UE 104, 350, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 502 and UE 504 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 504 can be an NB-IoT device and / or an eMTC device. Petition 870190083603, of 08/27/2019, p. 46/215 41/144 [0110] In one aspect, base station 502 can determine 501 a narrowband TDD frame structure for narrowband communications. For example, base station 502 can determine 501 that the narrowband TDD frame structure has one of the configurations 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0111] In addition, base station 502 can determine 503 a PUSCH format (for example, NPUSCH 2 format or modified PUSCH 2 format) to allocate at least one RU for UE 504 to an NPUCCH (for example, ACK / NACK ). For example, base station 502 may require that the modified NPUSCH 2 format be used (for example, see 450 in Figure 4B) to allocate one or more RUs for UE 504 to an NPUCCH across one or more subcarriers in one or more intervals. In certain configurations, the determination of the PUSCH format may be based on a number of uplink subframes in the narrowband TDD frame structure. In certain other configurations, a number within one or more subcarriers in each of one or more intervals may correspond to a number of uplink subframes in the narrowband TDD frame structure. In certain other configurations, a number within one or more subcarriers in each of one or more intervals may correspond to a maximum transmission delay or round trip timeline. In certain other configurations, a number within one or more subcarriers in each of one or more ranges may correspond to an RU number used for Petition 870190083603, of 08/27/2019, p. 47/215 42/144 transmitting the PUSCH format determined at a predetermined number of intervals. [0112] In another aspect, the base station 502 can allocate 505 to at least one RU for the UE 504 using the determined PUSCH format. In one aspect, the UK may include one or more subcarriers in each of one or more ranges. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 5 kHz, 7.5 kHz or 15 kHz. For example, base station 502 can allocate one or more subcarriers in one or more intervals (for example, four intervals) for UE 504 for an NPUCCH. If the subcarrier spacing of the narrowband TDD frame structure is 3.75 kHz, the base station 502 can allocate one or more RUs either in a single interval or in two intervals. In certain configurations, the associated subcarrier frequency spacing may correspond to an interval duration. [0113] In addition, base station 502 can transmit information 507 indicating the format of NPUSCH and the RUs allocated for UE 504 to NPUCCH. For example, information 507 can indicate whether the NPUSCH 2 format or modified PUSCH 2 format is used to allocate the RU (or RUs). The information can indicate how many subcarriers the RU (or RUs) occupy when the NPUSCH 2 format is the determined PUSCH format. In one aspect, 507 information can be sent in the DCI. [0114] Figure 5B illustrates a data stream 550 to base station 502 to allocate one or more RUs to UE 504 for an uplink transmission. Petition 870190083603, of 08/27/2019, p. 48/215 43/144 (for example, NPUSCH) in accordance with certain aspects of the disclosure. Base station 502 can correspond, for example, to base station 102, 180, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702 / 1702 '. UE 504 may correspond, for example, to UE 104, 350, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 502 and UE 504 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 504 can be an NB-IoT device and / or an eMTC device. [0115] In one aspect, base station 502 can determine 509 a narrowband TDD frame structure including at least a predetermined number of contiguous uplink subframes. In one aspect, the predetermined number of subframes can include three contiguous uplink subframes, each 1 ms long (for example, 15 kHz subcarrier spacing). For example, base station 502 can determine 509 that the narrowband TDD frame structure has one of the 0 or 6 configuration of table 410 in Figure 4A when the predetermined number of contiguous uplink subframes is three link subframes contiguous ascending. In another aspect, the predetermined number of contiguous uplink subframes can include two contiguous uplink subframes or more than three contiguous uplink subframes. [0116] In another aspect, base station 502 can determine 511 a first number of symbols in each Petition 870190083603, of 08/27/2019, p. 49/215 44/144 one of a second number of intervals to be used in allocating at least one RU to the UE 504 to an NPUSCH. In one aspect, the first number of symbols and the second number of intervals can be based on the predetermined number of contiguous uplink subframes. In another aspect, each interval in the second number of intervals can have an associated subcarrier frequency spacing of 3.75 kHz, 5 kHz, 7.5 kHz or 15 kHz. In an additional aspect, the subcarrier frequency spacing can be a function of the configuration used for the narrowband TDD subframe structure. In certain configurations, the second number of intervals can include 6 intervals. In certain other configurations, the second number of intervals can include 10 intervals. [0117] The allocation of inherited RUs can be in units of 2 ranges (for example, an uplink subframe), 4 intervals (two uplink subframes), 8 intervals (for example, four uplink subframes) and / or 16 intervals (for example, eight uplink subframes). Each range can have 7 OFDM symbols. When a RU is allocated in a narrowband TDD frame structure over 3 contiguous uplink subframes (eg 6 intervals) lasting 3 ms (eg 15 kHz subcarrier spacing), the Use of legacy RU allocation units may result in resources not being used. For example, an inherited RU allocation of 4 intervals can be used for a TDD configuration with the duration of 6 contiguous UL intervals. The allocation of 4 Petition 870190083603, of 08/27/2019, p. 50/215 45/144 intervals for a UK with a duration of 6 resource intervals can prevent resources in the fifth and sixth intervals of the available UL intervals from being used. [0118] In a first configuration, when settings 0 or 3 are used as the narrowband TDD frame structure, 3 contiguous uplink subframes with a duration of 3 ms are located in each radio frame. In other words, 6 uplink intervals may be available on each radio frame for uplink transmission (or uplink transmissions). In this way, the RU allocation can include 6 intervals (for example, each with 7 OFDM symbols) that can use the uplink resources available on each radio frame more efficiently than with the use of the allocation units of Inherited UK. [0119] In a second configuration, when configuration 6 is used as the narrowband TDD frame structure, 3 contiguous subframes (for example, 6 intervals) are located in the first half frame of a radio frame and 2 subframes of contiguous uplink (eg 4 intervals) are located in the second half frame of the radio frame. In other words, 10 uplink intervals may be available on each radio frame for uplink transmission (or uplink transmissions). In this way, the RU allocation can include 10 intervals (for example, each with 7 OFDM symbols) that can use the uplink features available on each radio frame more efficiently than using the units of Petition 870190083603, of 08/27/2019, p. 51/215 46/144 allocation of inherited RUs. [0120] In a third configuration, when uplink subframes with a 3.75 kHz subcarrier spacing are used for RU allocation, RU allocation units can include more or less than 16 intervals (for example, each one with 7 OFDM symbols). An RU allocation of more or less than 16 intervals can use the uplink resources available on each radio frame more efficiently than using legacy RU allocation units. [0121] In an additional aspect, base station 502 can allocate 513 to at least one RU for UE 504. In one aspect, the RU can include a single subcarrier or multiple subcarriers in each of one or more intervals. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 5 kHz, 7.5 kHz or 15 kHz. For example, base station 502 can allocate two or more subcarriers at six intervals for the UE 504 to an NPUSCH. [0122] In addition, base station 502 can transmit information 515 indicating the RUs allocated to UE 504 to NPUSCH. For example, information 515 can be sent to DCI. Uplink Transmissions [0123] Figure 6 illustrates a data stream 600 from an uplink transmission sent from an UE 604 to a base station 602 in accordance with certain aspects of the disclosure. Base station 602 can correspond, for example, to base station 102, 180, 502, Petition 870190083603, of 08/27/2019, p. 52/215 47/144 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to apparatus 1702/1702 '. UE 604 may correspond, for example, to UE 104, 350, 504, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 602 and UE 604 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 604 can be an NB-IoT device and / or an eMTC device. [0124] In one aspect, UE 604 can receive information 601 associated with a narrowband TDD frame structure that has a first set of contiguous uplink subframes with a first number of intervals. For example, the narrowband TDD frame structure may have one of the 0, 1, 3, 4 or 6 configuration of table 410 in Figure 4A which each includes contiguous uplink subframes. In one aspect, the narrowband TDD frame structure can include a first set of contiguous uplink subframes and a second set of contiguous uplink subframes. For example, narrowband TDD frame structures that include a first and second sets of contiguous uplink subframes may have the configuration 0, 1, and / or 6 of table 410 in Figure 4A. In another aspect, the narrowband TDD frame structure can include a single set of contiguous uplink subframes. For example, narrowband TDD frame structures that include a single set of contiguous uplink subframes can have configuration 3 and / or 4 from table 410 Petition 870190083603, of 08/27/2019, p. 53/215 48/144 in Figure 4A. Such TDD configurations are defined for the 10 ms frame, the 15 kHz subcarrier spacing in which each sub frame is 1 ms long. In a system that employs multiple subcarrier spacing, the TDD configuration can be thought of as specifying a duration of uplink transmissions and downlink transmissions. [0125] When using a narrowband TDD frame structure, an uplink transmission can be sent over a plurality of intervals. An interval, if defined as 7 OFDM symbols, is 0.5 ms long for 15 kHz subcarrier spacing, 1 ms long for 7.5 kHz subcarrier spacing and 2 ms long for 3 subcarrier spacing , 75 kHz. The transmission of UL within a range comprises both pilots and data and is intended to be self-decoding. Since pilots within the range are used to decode the data, it is desirable to have all symbols in the range transmitted together or very close together. The transmission of an interval, for example, for two discontinuous UL durations can cause a loss of performance. In a first configuration, the UE 604 can transmit a first portion of the uplink transmission using a maximum number of complete intervals that suit a first contiguous uplink transmission duration and transmit a remaining portion of the link transmission upstream using at least a portion of the next contiguous uplink transmission duration. In a second Petition 870190083603, of 08/27/2019, p. 54/215 49/144 configuration, the UE 604 can transmit a first portion of the uplink transmission with the use of at least a partial interval in a first contiguous uplink transmission duration and the remaining portion of the uplink transmission with the use of at least a partial interval in the next contiguous uplink transmission duration. In a third configuration, new interval formats can be defined with fewer symbols per interval as the subcarrier spacing decreases so that the duration that is the time for an interval is equal for all supported subcarrier spacing. [0126] In the first configuration, the UE 604 can transmit the first portion of the uplink transmission 605 using all the complete intervals in the first set of contiguous uplink transmission durations. In other words, the UE 604 can determine the number of intervals that can be transmitted completely in the first contiguous UL transmission duration and transmit the first portion of the uplink transmission 605 using all available symbols in the number of determined intervals in the first contiguous uplink transmission duration, and then move to the next uplink transmission duration in order to transmit a second portion (e.g., remaining portion) of the uplink transmission 607 using intervals that fit the next contiguous uplink transmission duration. In a first example, it is assumed that the 601 information received by the UE Petition 870190083603, of 08/27/2019, p. 55/215 50/144 604 indicates that configuration 1 is used for the narrowband TDD frame structure and that the duration of the uplink transmission is eight intervals (e.g., four subframes) where each interval is 0.5 ms in length. The first contiguous uplink transmission duration in configuration 1 can be 2 ms long (for example, subframes 2 and 3), and the second set of contiguous uplink transmission durations in configuration 1 can be 2 ms long ( for example, subframes 7 and 8). Therefore, in accordance with the first configuration, UE 604 can transmit the first portion of the uplink transmission 605 which comprises 4 intervals in the first contiguous uplink transmission duration in a radio frame. UE 604 can transmit the second portion of the uplink transmission 607 which comprises the remaining 4 intervals using the second contiguous uplink transmission duration in the first radio frame. However, if the duration of the uplink transmission is 6 intervals, then the UE 604 can transmit the first portion of the uplink transmission 605 with the first four intervals of the first contiguous uplink transmission duration, and the remaining portion of the uplink transmission with the last two intervals of the second contiguous uplink transmission duration and can potentially transmit nothing in the remaining portion. [0127] In one second example, it is supposed what at 601 information received by EU 604 indicate what The setting 6 is used for the structure of picture of TDD in Petition 870190083603, of 08/27/2019, p. 56/215 51/144 narrowband and that the duration of the uplink transmission is 4 ms and that each interval has a duration of 2 ms (for example, subcarrier spacing and 3.75 kHz). For an uplink transmission that begins with the radio frame, the first contiguous uplink duration in configuration 6 is 3 ms long and the second uplink duration in configuration 6 is 2 ms long (without considering the special subframe ). Therefore, only a complete uplink interval will fit the first contiguous uplink transmission duration. In accordance with the first configuration, the UE 604 can transmit the first interval in the first contiguous uplink duration and transmit the second interval in the next contiguous uplink duration. In accordance with the second configuration, the UE 604 can transmit the first portion of the uplink transmission 605 using all symbols corresponding to the first interval and a portion of the symbols (for example, partial interval / less than 7 OFDM symbols ) of the second interval. The UE 604 can transmit the second portion of the uplink transmission 607 using a portion of the symbols (e.g., remaining portion of the partial range / less than 7 OFDM symbols) in the next uplink duration, or the UE 604 you can drill the rest of the previous partial interval (for example, do not transmit the perforated intervals) and start transmitting a new interval at the next uplink duration. Unused portions of the second uplink transmission duration may be perforated. It is observed that the first Petition 870190083603, of 08/27/2019, p. 57/215 52/144 and second uplink transmission durations are related to when UE 604 initiates an uplink transmission. If the UE 604 initiates the uplink transmission in the second half of the radio frame for the TDD 6 configuration, which corresponds to that transmission, the first uplink duration is 2 ms and the second uplink duration is 3 ms. [0128] In a first aspect of the second configuration, UE 604 can match rate 603 for a first portion of an uplink transmission in the first uplink transmission duration based on a total number of symbols in the first uplink transmission duration. contiguous uplink. In a second aspect of the second configuration, UE 604 can match fee 603 for the first portion of uplink transmission 605 in the first contiguous uplink transmission duration based on a total number of symbols (for example, 7 OFDM symbols ) in the first range and the first subset of symbols in the second range. In one aspect, the first portion of the uplink transmission 605 can be transmitted using a pilot pattern based on all symbols (for example, 7 OFDM symbols) in the first range and the first subset of symbols (for example , less than 7 OFDM symbols) in the second interval. Either in the first aspect or the second aspect of the second configuration, the UE 604 can transmit the first portion of the uplink transmission 605 using all symbols in a first slot in the first number of slots and a first subset of symbols in a second break in Petition 870190083603, of 08/27/2019, p. 58/215 53/144 first number of intervals. In certain configurations, the UE 604 can perform rate matching assuming that the entire interval is transmitted and then perforate symbols that are not, in fact, transmitted. In certain other configurations, the UE 604 can perform rate matching assuming the number of symbols reduced due to the partial interval. In certain respects, a new pilot pattern can be defined for the new partial interval structure. Alternatively, the pilot pattern corresponding to the full range can be used with drilling. That is, if the partial interval has N symbols, the pilot symbols outside the N symbols are perforated. [0129] In addition, UE 604 can transmit a second portion of uplink transmission 607 using a second subset of symbols in a third slot located in a second contiguous uplink transmission duration. In one aspect, the first subset of symbols and the second subset of symbols can be the same as all symbols in an uplink subframe. In another aspect, the second subset of symbols can be associated with a second contiguous uplink transmission duration. Encryption / Repetitions [0130] Data encryption can be used to transpose and / or reverse signals or otherwise encode an uplink transmission (for example, NPUCCH and / or NPUSCH) with a predetermined encryption sequence. The encryption string may be unintelligible for a device (for example, station Petition 870190083603, of 08/27/2019, p. 59/215 54/144 base and / or UE) not equipped with an appropriately configured encryption and, therefore, only a device intended can properly decode the uplink transmission. Encryption also helps to randomly interfere with other devices. [0131] With the use of a narrowband FDD frame structure, the encryption sequence for the uplink transmission can remain the same for a predetermined number of repeated transmissions over a set of uplink subframes. The use of the same encryption over the repetitions can simplify the implantation of the receiver since the same encryption over the repetitions can combine different repetitions before encryption and demodulation. In order to increase the chance of properly decoding the uplink transmission, a base station can combine the uplink transmission over each of the repeated transmissions before encryption and demodulation as long as the channel does not vary over the repeated transmissions. . The UE can combine post-demodulation to obtain the benefits of repetitions potentially at the expense of greater complexity. [0132] The inherited FDD encryption sequence may depend on the LSB associated with the frame number. For example, inherited FDD encryption strings can be defined as c init = n RNTI -2 14 + nf mod 2 · 2 13 + [ns / 2] · 2 9 + N ^ el1 , where nf is the number of radio frame, Urnti is the temporary radio network identifier that is used to identify a connected mode UE located in a cell, n s is the range number and N ^ D cel1 is the Petition 870190083603, of 08/27/2019, p. 60/215 55/144 cell identification. [0133] Due to the fact that an uplink transmission sent using a narrowband TDD frame structure can expand multiple radio frames (for example, discussed above in relation to 5), a base station can not being able to combine a repeated broadcast that uses the same sequence of encryptions over different radio frames due to changes in channel conditions. [0134] There is a need to update a sequence of encryptions for a repeated uplink transmission using a narrowband TDD frame structure. [0135] Figure 7 illustrates a data stream 700 of repeated uplink transmissions with different encryption strings sent from an UE 704 to a base station 702 in accordance with certain aspects of the disclosure. Base station 702 can correspond, for example, to base station 102, 180, 502, 602, 802, 902, 1002, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702 / 1702 '. UE 704 may correspond, for example, to UE 104, 350, 504, 604, 804, 904, 1004, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 702 and UE 704 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 704 can be an NB-IoT device and / or an eMTC device. [0136] In one aspect, UE 704 can receive 701 information associated with a TDD frame structure Petition 870190083603, of 08/27/2019, p. 61/215 56/144 narrow band. For example, the narrowband TDD frame structure can have one of the configurations 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0137] In another aspect, UE 704 can transmit an uplink transmission 703 a predetermined number of times with the use of a first encryption sequence. For example, each uplink transmission can be repeated M times with the same encryption sequence. Repeating U-link transmission M times may assist in combining uplink transmission by base station 702 before decryption, but it may have the cost of not randomizing interference. In one aspect, the first sequence of encryptions may include a first number of LSBs associated with a first radio frame. In one aspect, the first number of LSBs can be greater than a second number of LSBs used in a second encryption sequence associated with a narrowband FDD uplink transmission. [0138] Since an uplink transmission can expand multiple radio frames while using a narrowband TDD frame structure, the UE 704 can update the encryption sequence to use more n f LSBs (for example, the radio frame number) in order to avoid repeating the encryption sequence since a smaller number of uplink intervals (eg uplink subframes) is available on each radio frame compared to a frame structure narrowband FDD. For example, UE 704 can use n f mod 10 instead of n f mod 2 in Petition 870190083603, of 08/27/2019, p. 62/215 57/144 sequence of encryptions. As mentioned above, due to the fact that the repetitions of an uplink transmission can occur on different radio frames, the base station 702 may not be able to combine the repetitions before demodulation. [0139] In one aspect, the M number of repetitions can be a function of the narrowband TDD frame structure so that different encryption sequences are used for repetitions that occur on different radio frames. Additionally and / or alternatively, the encryption sequence can be redefined over different sets of uplink subframes within the same radio frame. For example, uplink transmission 703 can be sent M times with the same encryption sequence, and then the next M repetition numbers 705 can be transmitted with a different encryption sequence. M can be a function of the number of contiguous or non-contiguous uplink subframes in a single radio frame. In addition, identical repetitions cannot be sent (for example, M = 1). In other words, each repetition of the uplink transmission 703 can be transmitted since using a unique encryption sequence. [0140] Using different encryption sequences for repetitions, the base station 702 of the present disclosure can randomize interference across different cells to improve system performance and also to combine repetitions and have an increased chance of decoding the uplink transmission. Petition 870190083603, of 08/27/2019, p. 63/215 58/144 Space Between Uplink Transmission [0141] When an uplink transmission is repeated using a narrowband FDD frame structure, a space of a predetermined length (for example, 40 ms) can be located after a predetermined number of radio frames (for example, 256) that are used to repeat an uplink transmission. A UE can use the space to estimate timing and / or frequency before continuing to repeat the uplink transmission on the next set of radio frames. However, due to the fact that the UE may need to stop sending the uplink transmission to perform the timing and / or frequency estimate during space, an increased latency associated with uplink transmission decoding at the base station may occur. [0142] There is a need to reduce latency associated with the decoding of an uplink transmission that can be caused by performing the timing and / or frequency estimate by the UE. [0143] Figure 8 is a diagram illustrating a flow diagram 800 for performing timing and / or frequency estimation by an UE 804 in accordance with certain aspects of the disclosure. Base station 802 may correspond, for example, to base station 102, 180, 502, 602, 702, 902, 1002, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702/1702 ' . UE 804 can correspond, for example, to UE 104, 350, 504, 604, 704, 904, 1004, 1104, 1204, 1304, 1404, to the apparatus Petition 870190083603, of 08/27/2019, p. 64/215 59/144 2902/2902 ’, 3102/3102’, 3302/3302 ’, 3502/3502’. In addition, base station 802 and UE 804 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 804 can be an NB-IoT device and / or an eMTC device. [0144] In one aspect, UE 804 can receive 801 information associated with a narrowband TDD frame structure. For example, the narrowband TDD frame structure can have one of the configurations 0, 1, 2, 3, 4, 5, 6, I or that of table 410 in Figure 4A. [0145] In another aspect, UE 804 can determine 803 to repeat an uplink transmission in a first set of radio frames and in a second set of radio frames. In certain configurations, the first set of radio frames and the second set of radio frames can each include 256 radio frames. In certain other configurations, the first set of radio frames and the second set of radio frames can include more or less than 256 radio frames. The first set of radio frames and the second radio frames can include the same number of radio frames or a different number of radio frames. Uplink transmissions may include, for example, a narrowband physical random access channel preamble (NPRACH). [0146] In an additional aspect, UE 804 can determine 805 not to monitor downlink subframes in the first set of radio frames and in the second set of radio frames. In one aspect, the UE 804 can receive signaling (for example, not shown in the Petition 870190083603, of 08/27/2019, p. 65/215 60/144 Figure 8) of base station 802 indicating not to monitor at least a portion of the downlink subframes in one or more of the first set of radio frames and / or the second set of radio frames. [0147] In addition, UE 804 can perform 807 one or more of a timing estimate or a frequency estimate with the use of at least one downlink subframe in one or more of the first set of radio frames or the second set of radio frames. By not monitoring at least a portion of the downlink subframes in the first radio frame and / or the second radio frame, the UE 804 can use the duration of the downlink subframes to perform the timing and / or estimate the frequency estimate. Timing estimation and / or frequency estimation can be used to synchronize (for example, subframe synchronization) with 802 base station. Due to the fact that timing estimation and / or frequency estimation is performed over subframe durations downlink, there may be no time between the first set of radio frames and the second set of radio frames. In other words, the timing estimate and / or the frequency estimate can be performed without using a space between a first set of radio frames and a second set of radio frames. NB-SRS [0148] Figure 9A is a diagram illustrating a flow diagram 900 for sending narrowband SRS (NB-SRS) from UE 904 to base station 902 at Petition 870190083603, of 08/27/2019, p. 66/215 61/144 compliance with certain aspects of the disclosure. Legacy SRS transmitted by a UE can have a comb-like structure, and a UE can transmit SRS in one of the tones in the comb-like structure. The NB-SRS can be transmitted by the UE using tones that are not used in the comb type structure. The NB-SRS can be used by the base station 902 to estimate channel quality in order to enable frequency-dependent scheduling of the uplink transmission. [0149] Base station 902 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 1002, 1102, 1202, 1302, 1402, 2950, eNB 310, device 1702/1702 ', 3102/3102'. UE 904 can correspond, for example, to UE 104, 350, 504, 604, 704, 804, 1004, 1104, 1204, 1304, 1404, 1750, to apparatus 2902/2902 ', 3302/3302'. In addition, base station 902 and UE 904 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 904 can be an NB-IoT device and / or an eMTC device. [0150] In one aspect, UE 904 can receive 901 information associated with a narrowband TDD frame structure. For example, the narrowband TDD frame structure can have one of the configurations 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0151] In another aspect, UE 904 can transmit an NB-SRS 903 to base station 902 using the narrowband TDD frame structure. In one aspect, the NB-SRS 903 comprises a single-tone SRS. In another aspect, the NB-SRS 903 can be transmitted as a Petition 870190083603, of 08/27/2019, p. 67/215 62/144 series of uplink transmissions that use frequency hopping to cover a system bandwidth associated with narrowband communications. In yet another aspect, the NB-SRS 903 can be transmitted over an uplink portion of a special subframe. In addition, the NB-SRS 903 can be multiplexed with an inherited SRS in the uplink portion of the special subframe. [0152] Figure 9B is a diagram illustrating the comb type structure 915 with NB-SRS 925 multiplexed with inherited SRS 935. In certain configurations, certain tones 945 in the comb type structure may be unused. Reference Signal [0153] Using a narrowband FDD frame structure, narrowband reference signal sequence (NRS) orthogonality can be obtained in 16 intervals (for example, the length of the sequence is defined in 16 intervals). For example, a UE can transmit an NRS in 16 intervals using the orthogonal 16 string length. Due to the fact that an uplink transmission sent using a narrowband TDD frame structure can span multiple frames radio (for example, discussed above in relation to 5), a base station may not be able to combine an NRS with an orthogonal sequence length 16 due to changes in channel condition. [0154] There is a need to update an orthogonal sequence length from NRS to a transmitted NRS using a narrow band TDD frame structure. Petition 870190083603, of 08/27/2019, p. 68/215 63/144 [0155] Figure 10A is a diagram illustrating a flow diagram 1000 for sending an NRS from an UE 1004 to a base station 1002 in accordance with certain aspects of the disclosure. The NRS can be a narrowband DM-RS (NB-DM-RS) that can be used by the base station 1002 to enable coherent signal demodulation. In a second configuration, the NRS can be NB-SRS as discussed above with respect to Figure 9. [0156] Base station 1002 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, apparatus 1702/1702 '. UE 1004 can correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 1002 and UE 1004 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1004 can be an NBloT device and / or an eMTC device. [0157] In one aspect, UE 1004 can receive information 1001 associated with a narrowband TDD frame structure. For example, UE 1004 can receive information 1001 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. In one aspect, information 1001 may indicate a narrowband TDD frame structure that includes a set of contiguous uplink subframes. When information 1001 indicates that the narrowband TDD frame structure includes a set of uplink subframes Petition 870190083603, of 08/27/2019, p. 69/215 64/144 contiguous, the narrowband TDD frame structure can be one of the 0, 1, 3, 4 or 6 configuration of table 410 in Figure 4A. Each of the 0, 1, 3, 4, or 6 configurations includes at least two additional contiguous uplink subframes. [0158] In another aspect, UE 1004 can determine 1003 an orthogonal sequence length associated with an NRS based on at least one of a number of uplink subframes or a number of intervals in the set of contiguous uplink subframes. For example, supposing that information 1001 received by UE 1004 indicates that configuration 1 is used as the narrowband TDD frame structure. As seen in Figure 4A, configuration 1 has a set of 2 contiguous uplink subframes (for example, subframes 2 and 3). The set of 2 contiguous uplink subframes has 4 intervals. Therefore, UE 1004 can determine 1003 that the orthogonal sequence length associated with NRS is length 4. Alternatively, when the narrowband TDD frame structure has a single uplink subframe (eg configuration 5), the orthogonal sequence length of the NRS can be length 2 based on the number of intervals in the single uplink subframe (for example, 2 intervals). [0159] In an additional aspect, UE 1004 can transmit NRS 1005 using the specified orthogonal sequence length. For example, NRS 1005 can be transmitted using an NPUCCH 1 format pilot structure. In one aspect, NRS 1005 can be transmitted Petition 870190083603, of 08/27/2019, p. 70/215 65/144 transmitted using a modified NPUSCH 1 format pilot structure that includes an increased pilot density per interval over the pilot density used in the legacy NPUSCH 1 format. For example, the modified NPUSCH 1 format can include two pilots per interval instead of one pilot per interval, as in an inherited NPUSCH 1 format. Sequence Group Jump [0160] The sequence group jump pattern in a narrowband FDD frame structure can change from interval to interval in a pseudo-random manner, while the offset deviation can be fixed at all intervals . In other words, the sequence group jump pattern can be a function of interval number. Due to the fact that the uplink subframes can be separated into a narrowband TDD frame structure, a sequence group hop pattern that is just a function of interval number can be repeated in different radio frames and therefore it can limit diversity. [0161] There is a need for a sequence group jump pattern that may not limit diversity when a narrowband TDD frame structure is used for narrowband communications. [0162] Figure 10B is a diagram illustrating a flow diagram 1050 for sending an NRS using a sequence group hop pattern from an UE 1004 to a base station 1002 in accordance with certain aspects of the disclosure. The NRS can be an NB-DM-RS that can be used by the base station 1002 to enable Petition 870190083603, of 08/27/2019, p. 71/215 66/144 signal demodulation and / or coherent channel estimation. In a second configuration, the NRS can be NB-SRS as discussed above with respect to Figure 9. [0163] Base station 1002 may correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1102, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, apparatus 1702/1702 '. UE 1004 can correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1104, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 1002 and UE 1004 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1004 can be an NBloT device and / or an eMTC device. [0164] In one aspect, UE 1004 can receive information 1001 associated with a narrowband TDD frame structure. For example, UE 1004 can receive information 1001 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0165] In another aspect, UE 1004 can determine 1007 a sequence jump pattern associated with an NRS based on at least one of a number of uplink subframes, a number of intervals in the set of contiguous uplink subframes or a radio frame number. For example, the sequence skip pattern may be a function of one or more LSBs associated with a radio frame number. Using a sequence hop pattern that is based on at least one of a number of uplink subframes, one Petition 870190083603, of 08/27/2019, p. 72/215 67/144 number of intervals in a set of contiguous uplink subframes or a radio frame number, diversity can be increased compared to using a sequence hop pattern that is just a function of the interval number. [0166] In an additional aspect, the UE 1004 can transmit the NRS 1009 using the determined sequence hop pattern. NPRACH - Symbol Group Size [0167] Figure 11 is a diagram illustrating a flow diagram 1100 for sending an NPRACH from an UE 1104 to a base station 1102 in accordance with certain aspects of the disclosure. Base station 1102 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1002, 1202, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702 / 1702 '. UE 1104 may correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1004, 1204, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 1102 and UE 1104 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1104 can be an NB-IoT device and / or an eMTC device. [0168] In one aspect, UE 1104 can receive information 1101 associated with a narrowband TDD frame structure. For example, UE 1104 can receive information 1101 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0169] In another aspect, EU 1104 can Petition 870190083603, of 08/27/2019, p. 73/215 68/144 transmitting a first group of symbols 1103 from a first NPRACH preamble to base station 1102. In one aspect, a first length of the first group of symbols can be associated with the narrowband TDD frame structure. [0170] In a first configuration, the first length of the first group of symbols can be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure . In one aspect, the first length can be reduced so that the uplink transmission repetitions suit a narrow band TDD frame structure. For example, if the first length is reduced from 1.4 ms / 1.6 ms (for example, the lengths used for the narrowband FDD frame structure) to 1 ms, the UE 1104 can accommodate 2 groups of symbols on a 2 ms uplink occasion (for example, a single uplink subframe or a set of contiguous uplink subframes) and 3 groups of symbols on a 3 ms uplink occasion. A special subframe can be located before certain uplink occasions, and the timing uncertainty associated with NPRACH can be accommodated by the special subframe located before the uplink occasion. Reducing the length of the NPRACH preamble can also enable 1 group of symbols to fit 1 uplink subframe, which can be useful when configuration 2 is used for narrowband TDD frame structure. Petition 870190083603, of 08/27/2019, p. 74/215 69/144 [0171] In a second configuration, the first length of the first group of symbols can be longer than the second length of a second group of symbols of a second preamble of NPRACH transmitted using an FDD frame structure narrow band. In one aspect, the first length can be increased so that the uplink transmission repetitions suit a narrowband TDD frame structure. For example, UE 1104 can increase the size of the symbol group by 2 ms and accommodate 1 group of uplink symbols on a 2 ms uplink occasion. Transmission of the same size symbol group on a 2 ms uplink occasion using the size of the symbol group associated with the narrowband FDD frame structure can cause a 0.6 ms / 0.4 waste ms of the 2 ms uplink occasion since the group length of symbols in the narrowband FDD frame structure is 1.4 ms / 1.6 ms. [0172] In a third configuration, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. [0173] In a fourth configuration, the first length of the first group of symbols can * be associated with one or more uplink occasions in the narrowband TDD frame structure. For example, the first length of the first group of symbols may be a function of the configuration used for the structure of Petition 870190083603, of 08/27/2019, p. 75/215 70/144 narrow band TDD frame. NPRACH - Preamble [0174] An NPRACH preamble in a narrowband FDD frame structure can include a predetermined number of repetitions (for example, 4 repetitions) of the group of symbols discussed above with respect to Figure 10B. However, the predetermined number of repetitions used in the narrowband FDD frame structure may not be well suited for narrowband TDD frame structures due to the limited number of uplink subframes in each coherent radio frame. [0175] There is a need for an NPRACH preamble that is configured for a narrow band TDD frame structure. [0176] Figure 12 is a diagram illustrating a flow diagram 1200 for sending repetitions of an NPRACH preamble from a UE 1204 to a base station 1202 in accordance with certain aspects of the disclosure. Base station 1202 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1302, 1402, 3150, 3350, 3550, eNB 310, to device 1702 / 1702 '. UE 1204 may correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1304, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502 '. In addition, base station 1202 and UE 1204 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1204 can be an NB-IoT device and / or an eMTC device. [0177] In one aspect, the UE 1204 can receive Petition 870190083603, of 08/27/2019, p. 76/215 71/144 information 1201 associated with a narrowband TDD frame structure. For example, UE 1204 can receive information 1201 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0178] In another aspect, UE 1204 can determine 1203 a maximum number of symbol groups in a plurality of symbol groups associated with an NPRACH preamble that suits an uplink occasion in the band TDD frame structure narrow. [0179] In a first configuration, the NPRACH preamble for a narrowband TDD frame structure can include a fixed number of repetitions for the symbol group, and the UE 1204 can suit the symbol group repetitions over of different occasions of uplink in series, adapting to the maximum possible repetitions in each occasion of uplink. [0180] In a second configuration, the number of repetitions for the symbol group and the sequence jump pattern of the NPRACH preamble can be equal to the number of repetitions and the sequence jump pattern used for an FDD frame structure. narrow band. [0181] In a third configuration, the number of repetitions of the symbol group can be a function of the configuration used for the narrowband TDD frame structure. [0182] In an additional aspect, UE 1204 can transmit a first subset of the plurality of groups of symbols 1205 associated with the preamble of NPRACH in one Petition 870190083603, of 08/27/2019, p. 77/215 72/144 first uplink occasion in the narrowband TDD frame structure and a second subset among the plurality of symbol groups 1205 associated with the NPRACH preamble on a second uplink occasion in the narrowband TDD frame structure . In a first aspect, the first subset can include the maximum number of groups of symbols. In a second aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. In one aspect, a distance between tones used to transmit each group of symbols in the plurality of symbol groups can be associated with the narrowband TDD frame structure. [0183] Figure 13 is a diagram illustrating a flow diagram 1300 for sending repetitions of an NPRACH preamble from an UE 1304 to a base station 1302 in accordance with certain aspects of the disclosure. In one aspect, the NPRACH preamble can be a predefined sequence of mini preambles (for example, the number of symbol groups, type of jump, pitch position (X)). Additionally and / or alternatively, the NPRACH preamble can be a function of the configuration used for the narrowband TDD frame structure and / or the number of special subframes in the narrowband TDD frame structure. [0184] Base station 1302 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1402, 3150, 3350, 3550, eNB 310, apparatus 1702/1702 '. UE 1304 can correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1004, Petition 870190083603, of 08/27/2019, p. 78/215 73/144 1104, 1204, 1404, to apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'. In addition, base station 1302 and UE 1304 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1304 can be an NBloT device and / or an eMTC device. [0185] In one aspect, UE 1304 can receive information 1301 associated with a narrowband TDD frame structure. For example, UE 1304 can receive information 1301 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0186] In another aspect, UE 1304 can determine 1303 a first number of groups of symbols in an NPRACH preamble to be transmitted on a first uplink occasion in the narrowband TDD frame structure. The first number of symbol groups can include either two symbol groups or three symbol groups. [0187] In a first configuration, the first number of symbol groups can include two groups of symbols. In the first configuration, UE 1304 can transmit a first group of symbols 1305 in a first tone on the first uplink occasion and a second group of symbols 1305 in a second tone on the first uplink occasion. [0188] In a first aspect of the first configuration, a distance between the first tone and the second tone can be a tone (for example, an OFDM symbol). For example, the first group of symbols can be Petition 870190083603, of 08/27/2019, p. 79/215 74/144 transmitted in tone X and the second group of symbols can be transmitted in tone X + 1. [0189] In a second aspect of the first configuration, a distance between the first tone and the second tone can be six tones (for example, six OFDM symbols). For example, the first group of symbols can be transmitted in tone X and the second group of symbols can be transmitted in tone X + 6. [0190] In a second configuration, the first number of symbol groups can include three groups of symbols. In the second configuration, UE 1304 can transmit a first group of symbols 1307 out of the three groups of symbols in a first tone of the first uplink occasion, a second group of symbols out of the three groups of symbols 1307 in a second tone of the first uplink occasion and a third group of symbols 1307 out of the three groups of symbols in a third tone of the first uplink occasion. [0191] In a first aspect of the second configuration, a first distance between the first tone and the second tone can be a tone and a second distance between the second tone and the third tone can be a tone. For example, the first group of symbols can be transmitted in tone X, the second group of symbols can be transmitted in tone X + louX-1, and the third group of symbols can be transmitted in tone X. The use of X + 1 or X - 1 for the second group of symbols can be based on whether X is even or odd. [0192] In a second aspect of the second configuration, a first distance between the first tone and Petition 870190083603, of 08/27/2019, p. 80/215 75/144 the second tone can be six tones and a second distance between the second tone and the third tone can be six tones. For example, the first group of symbols can be transmitted in tone X, the second group of symbols can be transmitted in tone X + 6orX-6 and the third group of symbols can be transmitted in tone X. For the second group of symbols, it is made a selection between X + 6 or X - 6 to ensure that the tone is in the same resource block. [0193] In a third aspect of the second configuration, a first distance between the first tone and the second tone can be one tone and a second distance between the second tone and the third tone can be six tones. In addition, UE 1304 can transmit a fourth group of symbols 1309 in a fourth tone on a second uplink occasion subsequent to the first uplink occasion. In one aspect, a third distance between the third tone and the fourth tone can be a tone. [0194] For example, the first group of symbols can be transmitted in tone X on the first occasion of uplink, the second group of symbols can be transmitted in tone X + 1 on the first occasion of uplink, the third group of symbols can be transmitted on the X + 6 symbol on the first uplink occasion and the fourth group of symbols can be transmitted on the X or X + 7 tone on the second uplink occasion NPRACH - Frequency Hopping [0195] The frequency hopping of an NPRACH preamble in a narrowband FDD frame structure can be used by a base station to perform Petition 870190083603, of 08/27/2019, p. 81/215 76/144 and accurate estimation of course and timing. For example, a first pair of symbol groups can be separated by a subcarrier on a first uplink occasion and used for timing course estimation. A second pair of symbol groups can be separated by five to seven subcarriers on a second uplink occasion and used for accurate timing estimation. If the frequency hop pattern is used for a narrowband TDD frame structure, the base station may have to depend on preambles that are separated in time over different uplink occasions and therefore do not provide accurate timing and course estimation due to the fact that channel conditions can change between uplink occasions. [0196] There is a need for an NPRACH frequency hopping pattern in a narrowband TDD frame structure that supports accurate stroke and timing estimation. [0197] Figure 14 is a diagram illustrating a flow diagram 1400 for an NPRACH frequency hop pattern sent from an UE 1404 to a base station 1402 in accordance with certain aspects of the disclosure. Base station 1402 can correspond, for example, to base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 3150, 3350, 3550, eNB 310, apparatus 1702 / 1702 '. UE 1404 may correspond, for example, to UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, to apparatus 2902/2902 ’, 3102/3102’, 3302/3302 ', 3502/3502'. In addition, base station 1402 and the Petition 870190083603, of 08/27/2019, p. 82/215 77/144 UE 1404 can be configured to communicate using narrowband communications (for example, NB-IoT and / or eMTC). For example, UE 1404 can be an NBloT device and / or an eMTC device. [0198] In one aspect, UE 1404 can receive 1401 information associated with a narrowband TDD frame structure. For example, UE 1404 can receive information 1401 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0199] In another aspect, UE 1404 can determine 1403 a hop pattern associated with two pairs of groups of symbols from an NPRACH transmitted on one or more uplink occasions using the narrowband TDD frame structure. [0200] In a first configuration, the hop pattern associated with the two pairs of groups of symbols can occur on a single uplink occasion. For example, one group of symbols in a first pair of symbol groups may be located in subcarrier Z on an uplink occasion and the other group of symbols in the first pair of symbol groups may be located in subcarrier Z + 1 at that time. uplink. The first pair of symbol groups can be used by base station 1402 to estimate course delay. In addition, one group of symbols in a second pair of symbol groups may be located in subcarrier Z at the time of uplink and the other group of symbols in the second pair of symbol groups may be located in subcarrier Z + 6 at the time of uplink. O Petition 870190083603, of 08/27/2019, p. 83/215 78/144 second pair of symbol groups can be used by base station 1402 for accurate timing estimation. [0201] In a second configuration, the hop pattern associated with one of the two pairs of symbol groups can occur on a first uplink occasion and the jump pattern associated with the other between the two pairs of symbol groups can occur at a time of different upward link. For example, one group of symbols in a first pair of symbol groups may be located in subcarrier Z on a first uplink occasion, and the other group of symbols in the first pair of symbol groups may be located in subcarrier Z + 1 on first occasion of upward link. The first pair of symbol groups can be used by base station 1402 to estimate course delay. In addition, a group of symbols in a second pair of symbol groups can be located on subcarrier Z on a second uplink occasion (for example, next uplink occasion after the first uplink occasion) and the other group of uplink. symbols in the second pair of symbol groups can be located on the Z + 6 subcarrier on the second uplink occasion. The second pair of symbol groups can be used by base station 1402 for accurate timing estimation. [0202] In an additional aspect, UE 1404 can transmit the first pair of symbol groups 1405 and the second pair of symbol groups 1405 on the same uplink occasion or on adjacent uplink occasions in the TDD frame structure narrow band. Petition 870190083603, of 08/27/2019, p. 84/215 79/144 [0203] Figure 15 is a 1500 flow chart of a wireless communication method. The method can be performed by a base station (for example, the base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3150, 3350, 3550, eNB 310, apparatus 1702/1702 '). In Figure 15, operations with dashed lines indicate optional operations. [0204] In 1502, the base station can determine a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 5A, base station 502 can determine 501 a narrowband TDD frame structure for narrowband communications. For example, base station 502 can determine 501 that the narrowband TDD frame structure has one of the configurations 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0205] In 1504, the base station can determine a physical uplink shared channel (PUSCH) format from a group of PUSCH formats to allocate at least one RU for a UE to an NPUCCH. For example, with reference to Figure 5A, base station 502 can determine 503 a group PUSCH format (for example, NPUSCH 1 format, NPUSCH 2 format or modified PUSCH 2 format) to allocate at least one RU for UE 504 for an NPUCCH. For example, base station 502 may require that the modified NPUSCH 2 format be used (for example, see 450 in Figure 4B) in order to allocate one or more RUs for UE 504 to an NPUCCH. [0206] In 1506, the base station can allocate at least one RU to the UE using the PUSCH format Petition 870190083603, of 08/27/2019, p. 85/215 80/144 determined. In one aspect, the UK can include multiple subcarriers in each of the one or more ranges. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. For example, with reference to Figure 5A, base station 502 can allocate 505 to at least one RU for UE 504 using the given PUSCH format. In one aspect, the UK can include multiple subcarriers in each of the one or more ranges. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. For example, base station 502 can allocate two or more subcarriers at one or more intervals (for example, four intervals) for UE 504 for an NPUCCH. If the subcarrier spacing of the narrowband TDD frame structure is 3.75 kHz, base station 502 can allocate one or more RUs either in a single interval or in two intervals. [0207] In 1508, the base station can transmit information associated with at least one of the UK or PUSCH format. For example, with reference to Figure 5A, base station 502 can transmit information 507 indicating the format of NPUSCH and the RUs allocated for UE 504 to NPUCCH. [0208] Figure 16 is a 1600 flow chart of a wireless communication method. The method can be performed by a base station (for example, the base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3150, 3350, 3550, eNB 310, the device Petition 870190083603, of 08/27/2019, p. 86/215 81/144 1702/1702 '). In Figure 16, operations with dashed lines indicate optional operations. [0209] In 1602, the base station can determine a narrowband TDD frame structure that includes at least a predetermined number of contiguous uplink subframes. For example, with reference to Figure 5B, base station 502 can determine 509 a narrowband TDD frame structure that includes at least a predetermined number of contiguous uplink subframes. In one aspect, the predetermined number of subframes can include three contiguous uplink subframes, each 1 ms long (for example, 15 kHz subcarrier spacing). In another aspect, the predetermined number of contiguous uplink subframes can include two contiguous uplink subframes or more than three contiguous uplink subframes. For example, base station 502 can determine 509 that the narrowband TDD frame structure has one of the 0 or 6 configuration of table 410 in Figure 4A when the predetermined number of contiguous uplink subframes is three link subframes contiguous ascending. [0210] In 1604, the base station can determine a first number of symbols in each of a second number of intervals to be used in allocating at least one RU to a UE to an NPUSCH. In one aspect, the first number of symbols and the second number of intervals can be based on the predetermined number of contiguous uplink subframes. For example, with reference to Figure 5B, base station 502 can determine Petition 870190083603, of 08/27/2019, p. 87/215 82/144 511 a first number of symbols in each of the second number of intervals to be used in allocating at least one RU to the UE 504 to an NPUSCH. In one aspect, the first number of symbols and the second number of intervals can be based on the predetermined number of contiguous uplink subframes. In another aspect, each interval in the second number of intervals can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. In an additional aspect, each interval in the second number of intervals may have a different associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz and is a function of the configuration used for the TDD subframe structure of narrow band. Legacy RU allocation units can be units of 2 slots (for example, one uplink subframe), 4 slots (two uplink subframes), 8 intervals (for example, four uplink subframes) and / or 16 intervals (for example, eight uplink subframes). Each range can have 7 OFDM symbols. In a first configuration, when settings 0 or 3 are used as the narrowband TDD frame structure, 3 contiguous uplink subframes with a duration of 3 ms are located in each radio frame. In other words, 6 uplink intervals may be available on each radio frame for uplink transmission (or uplink transmissions). Thus, the RU allocation can include 6 ranges (for example, each with 7 OFDM symbols) that can use the uplink features Petition 870190083603, of 08/27/2019, p. 88/215 83/144 available on each radio frame more efficiently than using legacy UK allocation units. In a second configuration, when configuration 6 is used as the narrowband TDD frame structure, 3 contiguous subframes (for example, 6 intervals) are located in the first half frame of a radio frame and 2 contiguous uplink subframes (for example, 4 intervals) are located in the second half frame of the radio frame. In other words, 10 uplink intervals may be available on each radio frame for uplink transmission (or uplink transmissions). In this way, the RU allocation can include 10 intervals (for example, each with 7 OFDM symbols) that can use the uplink features available on each radio frame more efficiently than with the use of the allocation units of Inherited UK. In a third configuration, when uplink subframes with a 3.75 kHz subcarrier spacing are used for RU allocation, the RU allocation units can include more or less than 16 intervals (for example, each with 7 OFDM symbols). An RU allocation of more or less than 16 intervals can use the uplink resources available on each radio frame more efficiently than using legacy RU allocation units. [0211] In 1606, the base station can allocate at least one RU to the UE. For example, with reference to Figure 5B, base station 502 can allocate 513 to at least one RU for UE 504. In one aspect, the RU can include a single subcarrier or multiple subcarriers in each Petition 870190083603, of 08/27/2019, p. 89/215 84/144 between one or more intervals. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. For example, base station 502 can allocate two or more subcarriers at six intervals for the UE 504 to an NPUSCH. [0212] In 1608, the base station can transmit information associated with at least one RU allocated to the UE. For example, referring to Figure 5B, base station 502 can transmit information 515 indicating the RUs allocated for UE 504 to NPUSCH. [0213] Figure 17 is a conceptual data flow diagram 1700 that illustrates the data flow between different media / components in an example apparatus 1702. The apparatus may be a base station (for example, the base station 102, 180, 502 , 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3150, 3350, 3550, eNB 310, apparatus 1702 ', 3102/3102') in communication with a UE 1750 (for example for example, UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404 apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0214] The apparatus may include a receiving component 1704, frame structure component 1706, RU allocation component 1708, transmission component 1710 and / or a PUSCH format component 1712. [0215] In certain configurations, frame structure component 1706 can be configured to determine a narrowband TDD frame structure for narrowband communications. The component Petition 870190083603, of 08/27/2019, p. 90/215 Frame structure 85/144 1706 can be configured to send a signal associated with the narrowband TDD frame structure to the 1710 transmission component. [0216] In certain configurations, the PUSCH 1712 format component can be configured to determine a PUSCH format from a group of PUSCH formats to allocate at least one RU for the UE 1750 to an NPUCCH. The PUSCH 1712 component can be configured to send a signal associated with the PUSCH format to the 1710 transmission component and / to the RU 1708 allocation component. [0217] In certain configurations, the allocation component of RU 1708 can be configured to allocate at least one RU to the UE using the determined PUSCH format. In one aspect, the UK can include multiple subcarriers in each of the one or more ranges. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. The allocation component of RU 1708 can be configured to send a signal associated with the allocated RU which is based on the PUSCH format determined to the 1710 transmission component. [0218] In certain configurations, the 1710 transmission component can be configured to transmit information associated with at least one within the UK or the PUSCH format to the UE 1750. [0219] In certain configurations, the receiving components 1704 can be configured to receive one or more from one or NPUCCH and / or an NPUSCH from the UE Petition 870190083603, of 08/27/2019, p. 91/215 86/144 1750. [0220] The device can include additional components that perform each of the algorithm blocks in the flow chart mentioned above in Figure 15. Thus, each block in the flow charts mentioned above in Figure 15 can be made by a component, and the device can include a or more among these components. The components can be one or more hardware components configured specifically to carry out the declared processes / algorithms, deployed by a processor configured to carry out the declared processes / algorithm, stored within a computer-readable medium for deployment by a processor or some combination of the themselves. [0221] Figure 18 is a diagram 1800 that illustrates an example of a hardware deployment for a 1702 'appliance employing an 1814 processing system. The 1814 processing system can be deployed with a bus architecture, represented in general via the 1824 bus. The 1824 bus can include any number of bus and interconnect bridges depending on the specific application of the 1814 processing system and general model limitations. The 1824 bus connects several circuits including one or more processors and / or hardware component, represented by the 1804 processor, the 1704, 1706, 1708, 1710, 1712 components and the 1806 computer / memory readable media. The 1824 bus can also connect various other circuits, such as timing sources, peripherals, voltage regulators and power management circuits, which are well known in the art and therefore not Petition 870190083603, of 08/27/2019, p. 92/215 87/144 will be further described. [0222] The 1814 processing system can be coupled to an 1810 transceiver. The 1810 transceiver is coupled to one or more 1820 antennas. The 1810 transceiver provides a means of communicating with various other devices via a transmission medium. The transceiver 1810 receives a signal from one or more antennas 1820, extracts information from the received signal and supplies the extracted information to the processing system 1814, specifically the receiving component 1704. In addition, the transceiver 1810 receives information from the processing system 1814, specifically the transmission component 1710, and based on the information received it generates a signal to be applied to one or more antennas 1820. The processing system 1814 includes a processor 1804 coupled to a computer-readable media / memory 1806. The processor 1804 is responsible for general processing, including executing software stored on 1806 computer-readable media / memory. The software, when executed by the 1804 processor, causes the 1814 processing system to perform the various functions described above for any particular device. 1806 computer-readable media / memory can also be used to store data that is handled by the 1804 processor while the software is running. The processing system 1814 additionally includes at least one of the components 1704, 1706, 1708, 1710, 1712. The components can be software components that run on the 1804 processor, remain / are stored on 1806 computer-readable media / memory, one or more Petition 870190083603, of 08/27/2019, p. 93/215 88/144 hardware components attached to the 1804 processor some combination thereof. The processing system 1814 can be a component of the eNB 310 and can include memory 376 and / or at least one among the TX processor 316, the RX processor 370 and the controller / processor 375. [0223] In one configuration, apparatus 1702/1702 'for wireless communication may include means for determining the narrowband TDD frame structure for narrowband communications. In another configuration, apparatus 1702/1702 'for wireless communication may include means for determining a PUSCH format from a group of PUSCH formats to allocate at least one RU to a UE for a bandwidth physical uplink control channel. narrow NPUCCH. In an additional configuration, the apparatus 1702/1702 'for wireless communication may * include means to allocate at least one RU to the UE using the given PUSCH format. In one aspect, the UK can include multiple subcarriers in each of the one or more ranges. In another aspect, each of the multiple subcarriers can have an associated subcarrier frequency spacing of 3.75 kHz, 7.5 kHz or 15 kHz. In an additional configuration, the device 1702/1702 'for wireless communication may include means for transmitting information associated with at least one within the UK or the PUSCH format to the UE. The means mentioned above can be one or more of the components mentioned above of the apparatus 1702 and / or the processing system 1814 of the apparatus 1702 'configured to perform the functions recited by the means mentioned above. As described Petition 870190083603, of 08/27/2019, p. 94/215 89/144 above, the processing system 1814 may include the TX 316 processor, the RX 370 processor and the 375 controller / processor. Thus, in one configuration, the means mentioned above may be the TX 316 processor, the processor RX 370 and controller / processor 375 configured to perform the functions recited by the means mentioned above. [0224] Figures 19A and 19B are a 1900 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). In Figure 19, operations with dashed lines indicate optional operations. [0225] In Figure 19A, in 1902, the UE can receive information associated with a narrowband TDD frame structure that has a first set of contiguous uplink subframes. In one aspect, the first set of contiguous uplink subframes can include a first number of intervals. For example, with reference to Figure 6, UE 604 can receive information 601 associated with a narrowband TDD frame structure that has a first set of contiguous uplink subframes with a first number of intervals. For example, the narrowband TDD frame structure may have one of the 0, 1, 3, 4 or 6 configuration of table 410 in Figure 4A which each includes contiguous uplink subframes. In one aspect, the narrowband TDD frame structure can include a first set of Petition 870190083603, of 08/27/2019, p. 95/215 90/144 contiguous uplink subframes and a second set of contiguous uplink subframes. For example, narrowband TDD frame structures that include a first and second sets of contiguous uplink subframes may have the configuration 0, 1, and / or 6 of table 410 in Figure 4A. In another aspect, the narrowband TDD frame structure can include a single set of contiguous uplink subframes. For example, narrowband TDD frame structures that include a single set of contiguous uplink subframes can have the configuration 3 and / or 4 of table 410 in Figure 4A. [0226] In Figure 19A, in 1904, the UE can match the first uplink transmission portion in rate in the first set of contiguous uplink subframes based on a total number of symbols in the first set of contiguous uplink subframes. . In one aspect, any symbols in the first set of contiguous uplink subframes not used to transmit the first portion of the uplink transmission can be perforated. In another aspect, the first portion of the uplink transmission can be transmitted using a pilot pattern based on the total number of symbols in the first slot and the second slot with the unused symbols in the second slot perforated. For example, with reference to Figure 6, UE 604 may match fee 603 for a first portion of an uplink transmission in the first set of contiguous uplink subframes based on a total number of Petition 870190083603, of 08/27/2019, p. 96/215 91/144 symbols in the first set of contiguous uplink subframes. It is assumed that the information 601 received by the UE 604 indicates that configuration 1 is used for the narrowband TDD frame structure and that the uplink transmission duration is 3 ms and that each interval has a duration of 2 ms (for example, subcarrier spacing and 3.75 kHz). The first set of contiguous subframes in configuration 1 can be subframes 2 and 3, and the total duration of subframes 2 and 3 is 4 ms. Therefore, the uplink transmission with a duration of 3 ms will not occupy all symbols in both subframe 2 and subframe 3 due to the fact that the duration of subframes 2 and 3 (for example, 4 ms) is longer than the duration uplink transmission. In accordance with the second configuration, UE 604 can transmit the first portion of the uplink transmission 605 using all symbols in subframe 2 and a portion of the symbols (for example, 0.5 ms / less than 7 symbols of OFDM) in subframe 3. UE 604 can transmit the second portion of the uplink transmission 607 using a portion of the symbols (for example, 0.5 ms / less than 7 OFDM symbols) in subframe 7. Any symbols not used in subframe 7 can be drilled. [0227] In Figure 19A, in 1906, the UE can match the first portion of the uplink transmission in the first set of contiguous subframes based on a total number of symbols in the first interval and the first subset of symbols in the second interval. . In one respect, the first subset of Petition 870190083603, of 08/27/2019, p. 97/215 92/144 symbols in the second range can correspond to the symbols available for uplink transmissions. In another aspect, the first portion of the uplink transmission can be transmitted using a pilot pattern based on all symbols in the first slot and the subset of symbols in the second slot. For example, with reference to Figure 6, UE 604 can match fee 603 the first portion of uplink transmission 605 in the first set of contiguous uplink subframes based on a total number of symbols (for example, 7 symbols of OFDM) in the first range and in the first subset of symbols in the second range. It is assumed that the information 601 received by the UE 604 indicates that configuration 1 is used for the narrowband TDD frame structure and that the uplink transmission duration is 3 ms and that each interval has a duration of 2 ms (for example, subcarrier spacing and 3.75 kHz). The first set of contiguous subframes in configuration 1 can be subframes 2 and 3, and the total duration of subframes 2 and 3 is 4 ms. Therefore, the uplink transmission with a duration of 3 ms will not occupy all symbols in both subframe 2 and subframe 3 due to the fact that the duration of subframes 2 and 3 (for example, 4 ms) is longer than the duration uplink transmission. In accordance with the second configuration, UE 604 can transmit the first portion of the uplink transmission 605 using all symbols in subframe 2 and a portion of the symbols (for example, 0.5 ms / less than 7 symbols of OFDM) in subframe 3. The UE 604 can Petition 870190083603, of 08/27/2019, p. 98/215 93/144 transmitting the second portion of the uplink transmission 607 using a portion of the symbols (e.g., 0.5 ms / less than 7 OFDM symbols) in subframe 7. [0228] In Figure 19A, in 1908, the UE can transmit a first portion of an uplink transmission using at least a portion of the first number of slots in the first set of contiguous uplink subframes. In one aspect, the uplink transmission can have a longer duration than the first set of contiguous uplink subframes. For example, with reference to Figure 6, UE 604 can transmit a first portion of uplink transmission 605 using a maximum number of complete intervals in a first set of contiguous uplink subframes (for example, using of all symbols in the first set of contiguous uplink subframes) and can transmit a remaining portion of uplink transmission 607 using at least one portion of one or more ; breaks in one next set of subframes in uplink contiguous. [0229] In Figure 19A, in 1910, the UE can transmitting a first portion of an uplink transmission using at least a portion of the first number of slots in the first set of contiguous uplink subframes transmitting the first portion of the uplink transmission using all symbols in a first interval in the first number of intervals and a first subset of symbols in a Petition 870190083603, of 08/27/2019, p. 99/215 94/144 second interval in the first number of intervals. In a further aspect, the first portion of the uplink transmission can be transmitted using all the intervals in the first set of contiguous uplink subframes. In yet another aspect, the first set of contiguous uplink subframes and a second set of contiguous uplink subframes can be located on the same radio frame. In an additional aspect, the first set of contiguous uplink subframes and the second set of contiguous uplink subframes are located on different radio frames. For example, with reference to Figure 6, UE 604 can transmit the first portion of the uplink transmission 605 using all the symbols available in the intervals of the first set of contiguous subframes and then move the next set of subframes uplink transmission in order to transmit a second portion (e.g., remaining portion) of uplink transmission 607 using the intervals available in the next set of uplink subframes. In a first example, it is assumed that the information 601 received by the UE 604 indicates that configuration 1 is used for the narrowband TDD frame structure and that the duration of the uplink transmission is eight intervals (for example, four subframes). The first set of contiguous subframes in configuration 1 can be subframes 2 and 3, and the second set of contiguous subframes in configuration 1 can be subframes 7 and 8. Therefore, according to the first configuration, the UE 604 Petition 870190083603, of 08/27/2019, p. 100/215 95/144 can transmit the first portion of the uplink transmission 605 using all symbols (for example, 7 OFDM symbols in each interval or 14 OFDM symbols in total) in both intervals in subframe 2 and in both the intervals in subframe 3 on a radio frame. UE 604 can transmit the second portion of uplink transmission 607 using all symbols (for example, 7 OFDM symbols in each interval or 14 OFDM symbols in total) in both intervals in subframe 7 and both intervals in subframe 8 in the first radio frame. However, if the duration of the uplink subframe is 6 intervals, then the UE 604 can transmit the first portion of the uplink transmission 605 using all symbols in both intervals in subframe 2 and in both intervals in subframe 3, and the remaining portion of the uplink transmission using the two slots in subframe 7 and may not transmit anything in subframe 8. [0230] In Figure 19B, in 1912, the UE can transmit a second portion of the uplink transmission using a second subset of symbols in a third slot in a second number of slots. In one aspect, the first subset of symbols and the second subset of symbols can be the same as all symbols in a uplink subframe, and the second subset of symbols can be associated with a second set of contiguous uplink subframes. For example, with reference to Figure 6, UE 604 can transmit a second portion of uplink transmission 607 using a Petition 870190083603, of 08/27/2019, p. 101/215 96/144 second subset of symbols in a third interval located in a second number of intervals (for example, located in a second set of contiguous uplink subframes). In one aspect, the first subset of symbols and the second subset of symbols can be the same as all symbols in an uplink subframe. In another aspect, the second subset of symbols can be associated with a second set of contiguous uplink subframes. [0231] In Figure 19B, in 1914, the UE can * transmit a second portion of the uplink transmission using all symbols in a third slot in a second number of slots. In one aspect, any symbols not used in the third interval are perforated. For example, with reference to Figure 6, it is assumed that information 601 received by UE 604 indicates that configuration 1 is used for the narrowband TDD frame structure and that the uplink transmission duration is 3 ms and that each interval has a duration of 2 ms (for example, subcarrier spacing and 3.75 kHz). The first set of contiguous subframes in configuration 1 can be subframes 2 and 3, and the total duration of subframes 2 and 3 is 4 ms. Therefore, the uplink transmission with a duration of 3 ms will not occupy all symbols in both subframe 2 and subframe 3 due to the fact that the duration of subframes 2 and 3 (for example, 4 ms) is longer than the duration uplink transmission. In accordance with the second configuration, the UE 604 can transmit the first portion of the link transmission Petition 870190083603, of 08/27/2019, p. 102/215 Ascending 97/144 605 using all symbols in subframe 2 and a portion of the symbols (for example, 0.5 ms / less than 7 OFDM symbols) in subframe 3. UE 604 can transmit the second portion of the transmission uplink 607 using a portion of the symbols (for example, 0.5 ms / less than 7 OFDM symbols) in subframe 7. Any unused symbols in subframe 7 can be perforated. [0232] Figure 20 is a 2000 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). In Figure 20, operations with dashed lines indicate optional operations. [0233] In 2002, the UE can receive information associated with a narrowband TDD framework structure. For example, with reference to Figure 7, UE 704 can receive information 701 associated with a narrowband TDD frame structure. For example, the structure of picture TDD in narrow band can have one of setting 0, 1, 2, 3, 4, 5, 6 , 1 or the table 410 at Figure 4A.[0234 ] In 2004, the EU can transmit an transmission of link upward a number predetermined of times with O US the one first sequence in encryptions. In one aspect, the first sequence in encryptions can include a first number of LSBs associated with a first radio frame. In one respect, the first number of LSBs can be greater than a second Petition 870190083603, of 08/27/2019, p. 103/215 98/144 number of LSBs used in a second encryption sequence associated with a narrowband FDD uplink transmission. For example, with reference to Figure 7, UE 704 can transmit an uplink transmission 703 to a predetermined number of teams using a first encryption sequence. For example, each uplink transmission can be repeated M times with the same encryption sequence. Repeating U-link transmission M times may assist in combining uplink transmission by base station 702 before decryption, but it may have the cost of not randomizing interference. In one aspect, the first sequence of encryptions may include a first number of LSBs associated with a first radio frame. In one aspect, the first number of LSBs can be greater than a second number of LSBs used in a second encryption sequence associated with a narrowband FDD uplink transmission. [0235] In 2006 UE can perform uplink transmission using the first encryption sequence by performing the uplink transmission once using the first encryption sequence. For example, with reference to Figure 7, UE 704 may not send identical repetitions (for example, M = 1). In other words, the uplink transmission 703 can be transmitted once using a unique encryption sequence. [0236] In 2008 UE can perform uplink transmission using the first Petition 870190083603, of 08/27/2019, p. 104/215 99/144 encryption sequence by repeating the uplink transmission multiple times using the first encryption sequence. In one aspect, a number of times that the uplink transmission can be repeated using the first encryption sequence is associated with the narrowband TDD frame structure or a number of consecutive uplink subframes. For example, with reference to Figure 7, the uplink transmission 703 can be sent M times with an equal encryption sequence, and then the next M repetition numbers 705 can be transmitted with a different encryption sequence. M can be a function of the number of contiguous or non-contiguous uplink subframes in a single radio frame. [0237] In 2010, the UE can repeat the uplink transmission. In one aspect, a different encryption sequence can be used for each repetition of the uplink transmission. For example, with reference to Figure 7, each of the 705 repetitions of the uplink transmission can be sent with a different encryption sequence. [0238] Figure 21 is a 2100 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0239] In 2102, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, Petition 870190083603, of 08/27/2019, p. 105/215 100/144 with reference to Figure 8, UE 804 can receive information 801 associated with a narrowband TDD frame structure. For example, the narrowband TDD frame structure can have one of the configurations 0, 1, 2, 3, 4, 5, 6, I or that of table 410 in Figure 4A. [0240] In 2104, the UE may determine to repeat an uplink transmission on a first set of radio frames and a second set of radio frames. In one aspect, the first set of radio frames and the second set of radio frames can include the same number of radio frames. In another aspect, the radio frames can be associated with the narrowband TDD frame structure. In an additional aspect, the uplink transmission includes an NPRACH preamble. For example, with reference to Figure 8, UE 804 can determine 803 to repeat an uplink transmission on a first set of radio frames and a second set of radio frames. In certain configurations, the first set of radio frames and the second set of radio frames can each include 256 radio frames. In certain other configurations, the first set of radio frames and the second set of radio frames can include more or less than 256 radio frames. The first set of radio frames and the second radio frames can include the same number of radio frames or a different number of radio frames. Uplink transmissions can include, for example, an NPRACH preamble. [0241] In 2106, the UE may determine not to Petition 870190083603, of 08/27/2019, p. 106/215 101/144 monitor downlink subframes in the first set of radio frames and the second set of radio frames. For example, with reference to Figure 8, UE 804 can determine 805 not to monitor downlink subframes in the first set of radio frames and the second set of radio frames. In one aspect, UE 804 can receive signaling (for example, not shown in Figure 8) from base station 802 indicating not to monitor at least a portion of the downlink subframes in one or more of the first set of radio frames and / or the second set of radio frames. [0242] In 2108, the UE may perform one or more of a timing estimate or a frequency estimate using at least one downlink subframe in one or more of the first set of radio frames or the second set radio frames. In one aspect, there can be no time lag between the first set of radio frames and the second set of radio frames and one or more of the timing estimate or frequency estimate is performed without using space information. For example, with reference to Figure 8, UE 804 can perform 807 one or more of a timing estimate or a frequency estimate with the use of at least one downlink subframe in one or more of the first set of data frames. radio or the second set of radio frames. By not monitoring at least a portion of the downlink subframes in the first radio frame and / or the second radio frame, the UE 804 can use the duration of the link subframes Petition 870190083603, of 08/27/2019, p. 107/215 102/144 downward to perform the timing estimate and / or the frequency estimate. Timing estimation and / or frequency estimation can be used to synchronize (for example, subframe synchronization) with 802 base station. Due to the fact that timing estimation and / or frequency estimation is performed over subframe durations downlink, there may be no time between the first set of radio frames and the second set of radio frames. In other words, the timing estimate and / or the frequency estimate can be performed without using a space between a first set of radio frames and a second set of radio frames. [0243] Figure 22 is a 2200 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0244] In 2202, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 9A, UE 904 can receive information 901 associated with a narrowband TDD frame structure. For example, the narrowband TDD frame structure can have one of the configurations 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0245] In 2204, the UE can transmit an NB-SRS to a base station using the narrowband TDD frame structure. In one aspect, the NB-SRS can include a single-tone SRS. In another aspect, the NB-SRS can be Petition 870190083603, of 08/27/2019, p. 108/215 103/144 transmitted as a series of uplink transmissions that use frequency hopping to cover a system bandwidth associated with narrowband communications. In an additional aspect, the NB-SRS can be transmitted on an uplink portion of a special subframe. In yet another aspect, the NB-SRS can be multiplexed with an inherited SRS in the uplink portion of the special subframe. For example, with reference to Figure 9A, UE 904 can transmit an NB-SRS 903 to base station 902 using the narrowband TDD frame structure. In one aspect, the NB-SRS 903 comprises a single-tone SRS. In another aspect, the NB-SRS 903 can be transmitted as a series of uplink transmissions that use frequency hopping to cover a system bandwidth associated with narrowband communications. In yet another aspect, the NB-SRS 903 can be transmitted over an uplink portion of a special subframe. Additionally, the NB-SRS 903 can be multiplexed with an inherited SRS in the uplink portion of the special subframe, as discussed above with reference to Figure 9B. [0246] Figure 23 is a 2300 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0247] In 2302, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. In one respect, the narrowband TDD frame structure Petition 870190083603, of 08/27/2019, p. 109/215 104/144 can include a set of contiguous uplink subframes. For example, with reference to Figure 10A, UE 1004 can receive information 1001 associated with a narrowband TDD frame structure. For example, UE 1004 can receive information 1001 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, I or that of table 410 in Figure 4A. In one aspect, information 1001 may indicate a narrowband TDD frame structure that includes a set of contiguous uplink subframes. When information 1001 indicates that the narrowband TDD frame structure includes a set of contiguous uplink subframes, the narrowband TDD frame structure can be one of the configuration 0, 1, 3, 4 or 6 of table 410 in Figure 4A. Each of the 0, 1, 3, 4, or 6 configurations includes at least two additional contiguous uplink subframes. [0248] In 2304, the UE may determine an orthogonal sequence length associated with an RS based on at least one of a number of uplink subframes or a number of intervals in the set of contiguous uplink subframes. For example, with reference to Figure 10A, UE 1004 can determine 1003 an orthogonal sequence length associated with an NRS based on at least one of a number of uplink subframes or a number of intervals in the set of uplink subframes contiguous. For example, assuming that information 1001 received by UE 1004 indicates that configuration 1 is used as the Petition 870190083603, of 08/27/2019, p. 110/215 105/144 narrow band TDD frame. As noted in Figure 4A, configuration 1 has a set of 2 contiguous uplink subframes (for example, subframes 2 and 3). The set of 2 contiguous uplink subframes has 4 intervals. Therefore, UE 1004 can determine 1003 that the orthogonal sequence length associated with NRS is length 4. Alternatively, when the narrowband TDD frame structure has a single uplink subframe (eg configuration 5), the orthogonal sequence length of the NRS can be length 2 based on the number of intervals in the single uplink subframe (for example, 2 intervals). [0249] In 2306, the UE can transmit the RS using the specified orthogonal sequence length. For example, with reference to Figure 10A, UE 1004 can transmit NRS 1005 using the given orthogonal sequence length. For example, NRS 1005 can be transmitted using a NPUCCH 1 format pilot structure. In one aspect, NRS 1005 can be transmitted using a modified NPUCCH 1 format pilot structure that includes a density of pilot by increased interval in relation to the pilot density used in the legacy NPUCCH 1 format. For example, the modified NPUCCH 1 format can include two pilots per interval instead of one pilot per interval, as in an inherited NPUCCH 1 format. [0250] Figure 24 is a 2400 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, the 2902/2902 'apparatus, Petition 870190083603, of 08/27/2019, p. 111/215 106/144 3102/3102 ’, 3302/3302’, 3502/3502 ’). [0251] In 2402, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 10B, UE 1004 can receive information 1001 associated with a narrowband TDD frame structure. For example, UE 1004 can receive information 1001 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, I or that of table 410 in Figure 4A. [0252] In 2404, the UE may determine a sequence hop pattern associated with an RS based on at least one of a number of uplink subframes, a number of intervals in the set of contiguous uplink subframes or a number radio frame icon. For example, with reference to Figure 10B, UE 1004 can determine 1007 a sequence jump pattern associated with an NRS based on at least one of a number of uplink subframes, a number of intervals in the set of link subframes contiguous ascending or a radio frame number. For example, the sequence skip pattern may be a function of one or more LSBs associated with a radio frame number. Using a sequence hop pattern that is based on at least one of a number of uplink subframes, a number of intervals in a set of contiguous uplink subframes, or a radio frame number, diversity can be increased compared to using a sequence jump pattern that is just a function of the interval number. Petition 870190083603, of 08/27/2019, p. 112/215 107/144 [0253] In 2406, the UE can transmit the RS using the determined sequence jump pattern. For example, with reference to Figure 10B, UE 1004 can transmit NRS 1009 using the given sequence jump pattern. [0254] Figure 25 is a 2500 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0255] In 2502, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 11, UE 1104 can receive information 1101 associated with a narrowband TDD frame structure. For example, UE 1104 can receive information 1101 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0256] In 2504, the UE can transmit a first group of symbols from a first preamble of NPRACH to a base station. In one aspect, a first length of the first group of symbols can be associated with the narrowband TDD frame structure. In one aspect, the first length of the first group of symbols may be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In another respect, the first length of the first group of symbols is longer than Petition 870190083603, of 08/27/2019, p. 113/215 108/144 a second length of a second group of symbols from a second NPRACH preamble transmitted using a narrowband FDD frame structure. In a further aspect, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. In yet another aspect, the first length of the first group of symbols can be associated with one or more uplink durations of the narrowband TDD frame structure. In certain aspects, the first length of the first group of symbols can be selected so that N groups of symbols can be transmitted in N subframes, as described below. [0257] For example, with reference to Figure 11, UE 1104 can transmit a first group of symbols 1103 from a first preamble of NPRACH to base station 1102. In one aspect, a first length of the first group of symbols can be associated to the narrowband TDD frame structure. In a first configuration, the first length of the first group of symbols may be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In one aspect, the first length can be reduced so that the uplink transmission repetitions suit a narrow band TDD frame structure. For example, if the first length is reduced by 1.4 ms / 1.6 ms (for example, the lengths Petition 870190083603, of 08/27/2019, p. 114/215 109/144 used for the narrowband FDD frame structure) for 1 ms, the UE 1104 can accommodate 2 groups of symbols on a 2 ms uplink occasion (for example, a single uplink subframe or a set contiguous uplink subframes) and 3 groups of symbols on a 3 ms uplink occasion. A special subframe can be located before certain uplink occasions, and the timing uncertainty associated with NPRACH can be accommodated by the special subframe located before the uplink occasion. Reducing the length of the NPRACH preamble can also enable 1 group of symbols to fit 1 uplink subframe, which can be useful when configuration 2 is used for narrowband TDD frame structure. In a second configuration, the first length of the first group of symbols can be longer than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In one aspect, the first length can be increased so that the uplink transmission repetitions suit a narrowband TDD frame structure. For example, UE 1104 can increase the size of the symbol group by 2 ms and accommodate 1 group of uplink symbols on a 2 ms uplink occasion. Transmission of the same size symbol group on a 2 ms uplink occasion using the size of the symbol group associated with the narrowband FDD frame structure can cause a 0.6 ms / 0.4 waste ms of the 2 ms uplink occasion Petition 870190083603, of 08/27/2019, p. 115/215 110/144 since the symbol group length in the narrowband FDD frame structure is 1.4 ms / 1.6 ms. In a third configuration, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. In a fourth configuration, the first length of the first group of symbols can * be associated with one or more uplink occasions in the narrowband TDD frame structure. For example, the first length of the first group of symbols may be a function of the configuration used for the narrowband TDD frame structure. [0258] Figure 26 is a 2600 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0259] In 2602, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 12, UE 1204 can receive information 1201 associated with a narrowband TDD frame structure. For example, UE 1204 can receive information 1201 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0260] In 2604, UE 1204 can determine a maximum number of groups of symbols in a plurality of groups of symbols associated with an NPRACH preamble that Petition 870190083603, of 08/27/2019, p. 116/215 111/144 is suitable for an uplink occasion in the narrowband TDD frame structure. In one aspect, the plurality of symbol groups can include a symbol frame. In another aspect, a length of a group of symbols can be a function of the narrowband TDD frame structure. For example, with reference to Figure 12, UE 12 04 can determine a maximum number of symbol groups in a plurality of symbol groups associated with an NPRACH preamble that suits an uplink occasion in the TDD frame structure. narrow band. In a first configuration, the NPRACH preamble for a narrowband TDD frame structure can include a fixed number of repetitions for the symbol group, and the UE 1204 can suit the symbol group repetitions on different occasions uplink in series, adapting to the maximum possible repetitions in each occasion of uplink. In a second configuration, the number of repetitions for the symbol group and the sequence jump pattern of the NPRACH preamble can be equal to the number of repetitions and the sequence jump pattern used for a narrowband FDD frame structure. . In a third configuration, the number of repetitions of the symbol group can be a function of the configuration used for the narrowband TDD frame structure. [0261] In 2606, the transmission component UE 2912 may transmit a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first uplink occasion in the narrowband TDD frame structure and a second subset of the Petition 870190083603, of 08/27/2019, p. 117/215 112/144 plurality of groups of symbols associated with the preamble of NPRACH on a second occasion of uplink in the narrowband TDD frame structure. In one aspect, the first subset can include the maximum number of groups of symbols. In another aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. For example, with reference to Figure 12, UE 1204 can transmit a first subset of the plurality of symbol groups 1205 associated with the NPRACH preamble on a first uplink occasion in the narrowband TDD frame structure and a second subset among the plurality of groups of symbols 1205 associated with the NPRACH preamble on a second uplink occasion in the narrowband TDD frame structure. In a first aspect, the first subset can include the maximum number of groups of symbols. In a second aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. In one aspect, a distance between tones used to transmit each group of symbols in the plurality of symbol groups can be associated with the narrowband TDD frame structure. [0262] Figure 27 is a 2700 flow chart of a wireless communication method. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). In Figure 27, operations with dashed lines indicate operations Petition 870190083603, of 08/27/2019, p. 118/215 113/144 optional. [0263] In 2702, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 13, UE 1304 can receive information 1301 associated with a narrowband TDD frame structure. For example, UE 1304 can receive information 1301 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [02 64] At 27 04, the UE can determine a first number of groups of symbols in an NPRACH preamble to be transmitted on a first uplink occasion in the narrowband TDD frame structure. In one aspect, the first number of symbol groups can include either two groups of symbols or three groups of symbols. For example, with reference to Figure 13, UE 1304 can determine 1303 a first number of groups of symbols from an NPRACH preamble to be transmitted on a first uplink occasion in the narrowband TDD frame structure. [0265] When the first number of groups of symbols includes two groups of symbols, in 2706, the UE can transmit a first group of symbols between the two groups of symbols in a first tone on the first occasion of uplink and a second group of symbols between the two groups of symbols in a second tone on the first occasion of uplink. In one aspect, a distance between the first tone and the second tone can be either one tone or six tones. For example, with reference to Figure 13, the Petition 870190083603, of 08/27/2019, p. 119/215 114/144 the first number of symbol groups can include two symbol groups in a first configuration. In the first configuration, UE 1304 can transmit a first group of symbols 1305 in a first tone on the first uplink occasion and a second group of symbols 1305 in a second tone on the first uplink occasion. In a first aspect of the first configuration, a distance between the first tone and the second tone can be a tone (for example, an OFDM symbol). For example, the first group of symbols can be transmitted in tone X and the second group of symbols can be transmitted in tone X + 1. In a second aspect of the first configuration, a distance between the first tone and the second tone can be six tones (for example, six OFDM symbols). For example, the first group of symbols can be transmitted in tone X and the second group of symbols can be transmitted in tone X + 6. [0266] When the first number of groups of symbols includes three groups of symbols, in 2708, the UE can transmit a first group of symbols among the three groups of symbols in a first tone of the first occasion of uplink, a second group of symbols among the three groups of symbols in a second tone of the first occasion of uplink and a third group of symbols among the three groups of symbols in a third tone of the first occasion of uplink. In one aspect, a first distance between tones used by at least one pair of symbol groups can be one tone, and a second distance between tones used for another pair of symbol groups can be six tones. For example, with Petition 870190083603, of 08/27/2019, p. 120/215 115/144 reference to Figure 13, UE 1304 can transmit a first group of symbols 1307 among the three groups of symbols in a first tone of the first occasion of uplink, a second group of symbols among the three groups of symbols 1307 in a second tone of the first uplink occasion and a third group of symbols 1307 out of the three groups of symbols in a third tone of the first uplink occasion. In one aspect, the first group of symbols can be transmitted at the tone X on the first occasion link upward, O secondgroup of symbols Can be transmitted at the tone X + 1 on the first occasion link upward and the third group of symbols Can be transmitted at the symbol X + 6 on the first occasion link ascending.[0267 ] In 2710 , the UE can transmit a bedroom group of symbols in a fourth tone on a second uplink occasion subsequent to the first uplink occasion. In one aspect, a third distance between the third tone and the fourth tone can be a tone. For example, with reference to Figure 13, UE 1304 can transmit a fourth group of symbols 1309 in a fourth tone on a second uplink occasion subsequent to the first uplink occasion. In one respect, a third distance between the third tone and the fourth tone can be a tone. 0 first group of symbols can to be transmitted at the tone X at first occasion link upward, O secondgroup of symbols can to be transmitted at the tone X + 1 on the first occasion link upward, O thirdgroup of symbols can to be Petition 870190083603, of 08/27/2019, p. 121/215 116/144 transmitted on the X + 6 symbol on the first uplink occasion and the fourth group of symbols can be transmitted on the X or X + 7 tone on the second uplink occasion [0268] Figure 28 is a 2800 flow chart of a method wireless communication. The method can be carried out by a UE (e.g. UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502/3502'). [0269] In 2802, the UE can receive information associated with a narrowband TDD frame structure for narrowband communications. For example, with reference to Figure 14, UE 1404 can receive information 1401 associated with a narrowband TDD frame structure. For example, UE 1404 can receive information 1401 indicating that the narrowband TDD frame structure is one of the configuration 0, 1, 2, 3, 4, 5, 6, 1 or that of table 410 in Figure 4A. [0270] In 2804, the UE can determine a hop pattern associated with two pairs of symbol groups from an NPRACH transmitted on one or more uplink occasions using the narrowband TDD frame structure. For example, with reference to Figure 14, UE 1404 can determine 1403 a hop pattern associated with two pairs of symbol groups from an NPRACH transmitted on one or more uplink occasions using the band TDD frame structure narrow. In a first configuration, the hop pattern associated with the two pairs of groups of symbols can occur on a single occasion of uplink. For example, a group of Petition 870190083603, of 08/27/2019, p. 122/215 117/144 symbols in a first pair of symbol groups can be located in subcarrier Z on an uplink occasion and the other symbol group in the first pair of symbol groups can be located in subcarrier Z + 1 on an uplink occasion . The first pair of symbol groups can be used by base station 1402 to estimate travel timing. In addition, one group of symbols in a second pair of symbol groups may be located in subcarrier Z at the time of uplink and the other group of symbols in the second pair of symbol groups may be located in subcarrier Z + 6 at the time of uplink. The second pair of symbol groups can be used by base station 1402 for accurate timing estimation. In a second configuration, the hop pattern associated with one of the two pairs of symbol groups can occur on a first uplink occasion and the jump pattern associated with the other between the two pairs of symbol groups can occur on one occasion different uplink. For example, one group of symbols in a first pair of symbol groups may be located in subcarrier Z on a first uplink occasion, and the other group of symbols in the first pair of symbol groups may be located in subcarrier Z + 1 on first occasion of upward link. The first pair of symbol groups can be used by base station 1402 to estimate course delay. In addition, a group of symbols in a second pair of symbol groups can be located in subcarrier Z on a second uplink occasion (for example, next occasion Petition 870190083603, of 08/27/2019, p. 123/215 118/144 uplink after the first uplink occasion) and the other group of symbols in the second pair of symbol groups can be located on sub-carrier Z + 6 on the second uplink occasion. The second pair of symbol groups can be used by base station 1402 for accurate timing estimation. [0271] In 2806, the UE can transmit a first pair of symbol groups and a second pair of symbol groups on the same uplink occasion or on adjacent uplink occasions in the narrowband TDD frame structure. In one aspect, a first subcarrier spacing associated with the first pair of symbol groups can be a single subcarrier. In another aspect, a second subcarrier spacing associated with the second pair of symbol groups can be six subcarriers. For example, with reference to Figure 14, UE 1404 can transmit the first pair of symbol groups 1405 and the second pair of symbol groups 1405 on the same uplink occasion or on adjacent uplink occasions in the frame structure. Narrow band TDD. [0272] Figure 29 is a conceptual data flow diagram 2900 that illustrates the data flow between different media / components in an example apparatus 2902. The apparatus may be a UE (for example, UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902 ', 3102/3102', 3302/3302 ', 3502/3502') in narrowband communication (for example, NBloT or eMTC) with the 2950 base station (e.g., a 102, 180, 502, 602, 702, 802, 902, 1002, 1102, base station, Petition 870190083603, of 08/27/2019, p. 124/215 119/144 1202, 1302, 1402, 2350, 3150, 3350, 3550, eNB 310, ο apparatus 1702/1702 '). The apparatus may include a receiving component 2904, a preamble component of NPRACH 2906, a frame structure component 2908, a symbol group length component 2 910 and a transmission component 2912. [0273] In certain configurations, the receiving component 2904 can be configured to receive information associated with a narrowband TDD frame structure for narrowband communications. The receiving component 2904 can be configured to send a signal associated with the narrowband TDD frame structure to the frame structure component 2908. [0274] In certain configurations, the frame structure component 2908 can be configured to determine a narrow band TDD frame structure. The frame structure component 2908 can be configured to send a signal associated with the narrowband TDD frame structure determined to the symbol group length component 2910 and / or the transmission component 2912. [0275] In certain configurations, the NPRACH preamble component 2906 can be configured to generate an NPRACH preamble for transmission to the 2950 base station. The NPRACH 2906 preamble component can be configured to send a signal associated with the NPRACH preamble. the symbol group length component 2910 and / or the transmission component 2912. [0276] In certain configurations, the 2910 symbol group length component can Petition 870190083603, of 08/27/2019, p. 125/215 120/144 to be configured to determine a first symbol group length from a first NPRACH preamble. In one aspect, a first length of the first group of symbols can be associated with the narrowband TDD frame structure. In one aspect, the first length of the first group of symbols may be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In certain aspects, the first length of the first group of symbols can be selected so that N groups of symbols can be transmitted in N subframes. In another aspect, the first length of the first group of symbols is longer than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In a further aspect, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. In yet another aspect, the first length of the first group of symbols can be associated with one or more uplink durations of the narrowband TDD frame structure. The symbol group length component 2910 can be configured to send a signal associated with a symbol group length and / or the NPRACH preamble to the 2912 transmission component. [0277] In certain configurations, the Petition 870190083603, of 08/27/2019, p. 126/215 121/144 transmission component 2912 can be configured to transmit a first group of symbols from a first NPRACH preamble to the base station 2950. In one aspect, a first length of the first group of symbols can be associated with the TDD frame structure narrow band. In one aspect, the first length of the first group of symbols may be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In another aspect, the first length of the first group of symbols is longer than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In a further aspect, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. In yet another aspect, the first length of the first group of symbols can be associated with one or more uplink durations of the narrowband TDD frame structure. [0278] The apparatus may include additional components that perform each of the algorithm blocks in the flowchart mentioned above in Figure 25. Thus, each block in the flowchart mentioned above in Figure 25 may be made by a component, and the apparatus may include a or more among these components. The components can be one or more hardware components configured specifically to carry out the processes / algorithms Petition 870190083603, of 08/27/2019, p. 127/215 122/144 declared, implanted by a processor configured to carry out the declared processes / algorithm, stored within a computer-readable medium for implantation by a processor or some combination thereof. [0279] Figure 30 is a diagram 3000 illustrating an example of a hardware deployment for a 2902 'device employing a 3014 processing system. The 3014 processing system can be deployed with a bus architecture, represented in general via the 3024 bus. The 3024 bus can include any number of bus and interconnect bridges depending on the specific application of the 3014 processing system and general model limitations. The 3024 bus connects several circuits including one or more processors and / or hardware component, represented by the 3004 processor, the 2904, 2906, 2908, 2910, 2912 components and the 3006 computer / memory readable media. The 3024 bus can also connect several other circuits, such as timing sources, peripherals, voltage regulators and power management circuits, which are well known in the art and therefore will not be described further. [0280] The 3014 processing system can be coupled to a 3010 transceiver. The 3010 transceiver is coupled to one or more 3020 antennas. The 3010 transceiver provides a means of communicating with various other devices via a transmission medium. The transceiver 3010 receives a signal from one or more antennas 3020, extracts information from the received signal and supplies the extracted information to the processing system 3014, Petition 870190083603, of 08/27/2019, p. 128/215 123/144 specifically the receiving component 2904. In addition, the transceiver 3010 receives information from the processing system 3014, specifically the transmitting component 2912, and based on the received information generates a signal to be applied to one or more antennas 3020. The processing system 3014 includes a processor 3004 coupled to a computer-readable media / memory 3006. The processor 3004 is responsible for general processing, including running software stored on the computer-readable media / memory 3006. The software, when run by processor 3004, makes the processing system 3014 perform the various functions described above for any particular device. The computer-readable media / memory 3006 can also be used to store data that is handled by the 3004 processor while the software is running. The processing system 3014 additionally includes at least one among the components 2904, 2906, 2908, 2910, 2912. The components can be software components that run on the processor 3004, remain / are stored in the computer-readable media / memory 3006, one or more hardware components coupled to the 3004 processor some combination thereof. The processing system 3014 can be a component of the UE 350 and can include memory 360 and / or at least one among the TX processor 368, the RX processor 356 and the controller / processor 359. [0281] In certain configurations, the 2902/2902 'device for wireless communication may include means for receiving information associated with a structure Petition 870190083603, of 08/27/2019, p. 129/215 124/144 of narrowband TDD frame for narrowband communications. In an additional configuration, the apparatus 2902/2902 'for wireless communication may include means for transmitting a first group of symbols from a first NPRACH preamble to a base station. In one aspect, a first length of the first group of symbols can be associated with the narrowband TDD frame structure. In one aspect, the first length of the first group of symbols may be shorter than the second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In another aspect, the first length of the first group of symbols is longer than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a narrowband FDD frame structure. In a further aspect, a first preamble format associated with the first NPRACH preamble can be different from a second preamble format associated with a second NPRACH preamble transmitted using a narrowband FDD frame structure. In certain aspects, the first length of the first group of symbols can be selected so that N groups of symbols can be transmitted in N subframes. In yet another aspect, the first length of the first group of symbols can be associated with one or more uplink durations of the narrowband TDD frame structure. The means mentioned above can be one or more of the above mentioned components of the 2902 apparatus and / or the 3014 processing system of the 2902 'apparatus configured Petition 870190083603, of 08/27/2019, p. 130/215 125/144 to perform the functions recited by the means mentioned above. As described above, the processing system 3014 may include the TX 368 processor, the RX 356 processor and the 359 controller / processor. Thus, in one configuration, the means mentioned above may be the TX 368 processor, the processor RX 356 and the controller / processor 359 configured to perform the functions recited by the means mentioned above. [0282] Figure 31 is a conceptual data flow diagram 3100 that illustrates the data flow between different media / components in an example apparatus 3102. The apparatus may be a UE (for example, UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102', 3302/3302 ', 3502/3502') in narrowband communication (for example, NB communication -IoT or eMTC) with base station 3150 (for example, base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3350, 3550 , eNB 310, apparatus 1702/1702 '). The apparatus may include a receiving component 3104, a preamble component of NPRACH 3106, a frame structure component 3108, a symbol group component 3110 and a transmission component 3112. [0283] In certain configurations, the receiving component 3104 can be configured to receive information associated with a narrowband TDD frame structure for narrowband communications. The receiving component 3104 can be configured to send a signal associated with the narrowband TDD frame structure to the frame structure component 3108. Petition 870190083603, of 08/27/2019, p. 131/215 126/144 [0284] In certain configurations, the frame structure component 3108 can be configured to determine a narrow band TDD frame structure. The frame structure component 3108 can be configured to send a signal associated with the determined narrowband TDD frame structure to the symbol group component 3110 and / or the transmission component 3112. [0285] In certain configurations, the preamble component of NPRACH 3106 can be configured to generate an NPRACH preamble for transmission to the base station 3150. The preamble component of NPRACH 3106 can be configured to send a signal associated with the NPRACH preamble. to the 3110 symbol group component and / or to the 3112 transmission component. [0286] In certain configurations, the symbol group component 3110 can be configured to determine a maximum number of symbol groups in a plurality of symbol groups associated with an NPRACH preamble that suits an adjacent bonding occasion in the structure narrow band TDD frame. In one aspect, the plurality of symbol groups can include a symbol frame. In another aspect, a length of a group of symbols can be a function of the narrowband TDD frame structure. The symbol group component 3110 can be configured to send a signal associated with the maximum number of symbol groups in a plurality of symbol groups associated with the NPRACH preamble that suits an adjacent link occasion in the TDD frame structure of narrow band Petition 870190083603, of 08/27/2019, p. 132/215 127/144 to the 3112 transmission component. [0287] In certain configurations, the transmission component 3112 can be configured to transmit a first subset among the plurality of symbol groups associated with the NPRACH preamble on a first occasion of adjacent link in the narrowband TDD frame structure and a second subset among the plurality of groups of symbols associated with the preamble of NPRACH on a second occasion of adjacent link in the narrowband TDD frame structure. In one aspect, the first subset can include the maximum number of groups of symbols. In another aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. [0288] The apparatus may include additional components that perform each of the algorithm blocks in the flowchart mentioned above in Figure 26. Thus, each block in the flowchart mentioned above in Figure 26 may be made by a component, and the apparatus may include a or more among these components. The components can be one or more hardware components configured specifically to carry out the declared processes / algorithms, deployed by a processor configured to carry out the declared processes / algorithm, stored within a computer-readable medium for deployment by a processor or some combination of the themselves. [0289] Figure 32 is a 3200 diagram illustrating an example of a hardware deployment for a 3102 'device that employs a processing system Petition 870190083603, of 08/27/2019, p. 133/215 128/144 3214. The 3214 processing system can be deployed with a bus architecture, generally represented by the 3224 bus. The 3224 bus can include any number of bus and interconnecting bridges depending on the specific application of the 3214 processing system and general limitations of the model. The 3224 bus connects several circuits including one or more processors and / or hardware components, represented by the 3204 processor, the 3104, 3106, 3108, 3110, 3112 components, and the 3206 computer / memory readable media. The 3224 bus can also connecting various other circuits, such as timing sources, peripherals, voltage regulators and power management circuits, which are well known in the art and therefore will not be described further. [0290] The 3214 processing system can be coupled to a 3210 transceiver. The 3210 transceiver is coupled to one or more 3220 antennas. The 3210 transceiver provides a means of communicating with various other devices via a transmission medium. The 3210 transceiver receives a signal from one or more 3220 antennas, extracts information from the received signal and supplies the extracted information to the 3214 processing system, specifically the receiving component 3104. In addition, the 3210 transceiver receives information from the 3214 processing system, specifically the 3112 transmission component, and based on the information received it generates a signal to be applied to one or more 3220 antennas. The 3214 processing system includes a processor 3204 coupled to a computer-readable media / memory 3206. The Petition 870190083603, of 08/27/2019, p. 134/215 129/144 processor 3204 is responsible for general processing, including running software stored on computer-readable media / memory 3206. The software, when run by processor 3204, causes the 3214 processing system to perform the various functions described above for any particular device. Computer-readable media / memory 3206 can also be used to store data that is handled by the 3204 processor during software execution. The processing system 3214 additionally includes at least one among the components 3104, 3106, 3108, 3110, 3112. The components can be software components that run on processor 3204, remain / are stored in computer readable media / memory 3206, one or more hardware components coupled to the 3204 processor some combination thereof. The 3214 processing system can be a component of the UE 350 and can include the 360 memory and / or at least one of the TX 368 processor, the RX 356 processor and the 359 controller / processor. [0291] In certain configurations, the 3102/3102 'apparatus for wireless communication may include means for receiving information associated with a narrowband TDD frame structure for narrowband communications. In certain other configurations, the apparatus 3102/3102 'for wireless communication may include means for determining a maximum number of symbol groups in a plurality of symbol groups associated with an NPRACH preamble that is suitable for an uplink occasion on the TDD frame structure Petition 870190083603, of 08/27/2019, p. 135/215 130/144 narrow band. In one aspect, the plurality of symbol groups can include a symbol frame. In another aspect, a length of a group of symbols can be a function of the narrowband TDD frame structure. In certain other configurations, the apparatus 3102/3102 'for wireless communication may include means for transmitting a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first uplink occasion in the narrowband TDD frame structure and a second subset of the plurality of symbol groups associated with the NPRACH preamble on a second uplink occasion in the narrowband TDD frame structure. In one aspect, the first subset can include the maximum number of groups of symbols. In another aspect, the second subset can include any remaining symbol groups in the plurality of symbol groups or the maximum number of symbol groups. The means mentioned above can be one or more of the components mentioned above of the apparatus 3102 and / or the processing system 3214 of the apparatus 3102 'configured to perform the functions recited by the means mentioned above. As described above, the processing system 3214 can include the TX processor 368, the RX processor 356 and the controller / processor 359. Thus, in one configuration, the means mentioned above may be the TX processor 368, the processor RX 356 and the controller / processor 359 configured to perform the functions recited by the means mentioned above. [0292] Figure 33 is a conceptual 3300 data flow diagram that illustrates the data flow between Petition 870190083603, of 08/27/2019, p. 136/215 131/144 different media / components in an exemplary apparatus 3302. The apparatus may be a UE (for example, UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, the apparatus 2902/2902 ', 3102/3102', 3302 ', 3502/3502') in narrowband communication (for example, NBloT or eMTC communication) with 3350 base station (for example, base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3150, 3550, eNB 310, apparatus 1702/1702 '). The apparatus may include a receiving component 3304, a preamble component of NPRACH 3306, a frame structure component 3308, a symbol group component 3310 and a transmission component 3312. [0293] In certain configurations, the receiving component 3304 can be configured to receive information associated with a narrowband TDD frame structure for narrowband communications. The receiving component 3304 can be configured to send a signal associated with the narrowband TDD frame structure to the frame structure component 3308. [0294] In certain configurations, the frame structure component 3308 can be configured to determine a narrowband TDD frame structure. The frame structure component 3308 can be configured to send a signal associated with the determined narrowband TDD frame structure to the symbol group component 3310 and / or the transmission component 3312. [0295] In certain configurations, the preamble component of NPRACH 3306 can be configured to generate an NPRACH preamble for transmission to the Petition 870190083603, of 08/27/2019, p. 137/215 132/144 base station 3350. The preamble component of NPRACH 3306 can be configured to send a signal associated with the preamble of NPRACH to the symbol group component 3310 and / or the transmission component 3312. [0296] In certain configurations, the 3310 symbol group component can be configured to determine a first number of symbol groups from an NPRACH preamble to be transmitted on a first adjacent link occasion in the narrowband TDD frame structure . In one aspect, the first number of symbol groups can include either two groups of symbols or three groups of symbols. The 3310 symbol group component can be configured to send a signal associated with the first number of symbol groups in the NPRACH preamble to be transmitted on a first adjacent link occasion in the narrowband TDD frame structure to the 3312 transmission component . [0297] When the first number of symbol groups includes two symbol groups, the 3312 transmission component can be configured to transmit a first symbol group among the two symbol groups in a first tone on the first adjacent link occasion and a second group of symbols between the two groups of symbols in a second tone on the first occasion of adjacent link. In one respect, a distance between the first tone and the second tone can be or a tone or six tones. [0298] When the first number groups of symbols includes three groups of symbols, the component of transmission 3321 can be configured to transmit a Petition 870190083603, of 08/27/2019, p. 138/215 133/144 first group of symbols among the three groups of symbols in a first tone of the first occasion of uplink, a second group of symbols among the three groups of symbols in a second tone of the first occasion of uplink and a third group of symbols among the three groups of symbols in a third tone of the first occasion of uplink. In one aspect, a first distance between tones used by at least one pair of symbol groups can be one tone, and a second distance between tones used for another pair of symbol groups can be six tones. [0299] In certain configurations, the transmission component 3312 can be configured to transmit a fourth group of symbols in a fourth tone on a second adjacent link occasion subsequent to the first adjacent link occasion. In one aspect, a third distance between the third tone and the fourth tone can be a tone. [0300] The device can include additional components that perform each of the algorithm blocks in the flowchart mentioned above in Figure 27. Thus, each block in the flowchart mentioned above in Figure 27 can be made by a component, and the device can include a or more among these components. The components can be one or more hardware components configured specifically to carry out the declared processes / algorithms, deployed by a processor configured to carry out the declared processes / algorithm, stored within a computer-readable medium for deployment by a processor or some combination of the themselves. Petition 870190083603, of 08/27/2019, p. 139/215 134/144 [0301] Figure 34 is a diagram 3400 that illustrates an example of a hardware deployment for a 3302 'appliance employing a 3414 processing system. The 3414 processing system can be deployed with a bus architecture, represented generally via the 3424 bus. The 3424 bus can include any number of bus and interconnect bridges depending on the specific application of the 3414 processing system and general model limitations. The 3424 bus connects several circuits including one or more processors and / or hardware component, represented by the 3404 processor, the 3304, 3306, 3308, 3310, 3312 components, and the 3406 computer / memory readable media. The 3424 bus can also connecting various other circuits, such as timing sources, peripherals, voltage regulators and power management circuits, which are well known in the art and therefore will not be described further. [0302] The 3414 processing system can be coupled to a 3410 transceiver. The 3410 transceiver is coupled to one or more 3420 antennas. The 3410 transceiver provides a means of communicating with various other devices via a transmission medium. The 3410 transceiver receives a signal from one or more 3420 antennas, extracts information from the received signal and provides the extracted information to the 3414 processing system, specifically the receiving component 3304. In addition, the 3410 transceiver receives information from the 3414 processing system, specifically the 3312 transmission component, and based on the information received it generates Petition 870190083603, of 08/27/2019, p. 140/215 135/144 a signal to be applied to one or more 3420 antennas. The 3414 processing system includes a 3404 processor coupled to a computer-readable media / memory 3406. The 3404 processor is responsible for general processing, including running stored software on computer-readable media / memory 3406. The software, when run by the 3404 processor, causes the 3414 processing system to perform the various functions described above for any particular device. The 3406 computer-readable media / memory can also be used to store data that is handled by the 3404 processor while the software is running. The 3414 processing system additionally includes at least one of the components 3304, 3306, 3308, 3310, 3312. The components can be software components that run on the 3404 processor, remain / are stored on computer-readable media / memory 3406, one or more hardware components coupled to the 3404 processor some combination thereof. The processing system 3414 can be a component of the UE 350 and can include memory 360 and / or at least one among the TX processor 368, the RX processor 356 and the controller / processor 359. [0303] In certain configurations, apparatus 3302/3302 'for wireless communication may include means for receiving information associated with a narrowband TDD frame structure for narrowband communications. In certain other configurations, the wireless communication device 3302/3302 'may include means for determining a first number of groups of Petition 870190083603, of 08/27/2019, p. 141/215 136/144 symbols of an NPRACH preamble to be transmitted on a first uplink occasion in the narrowband TDD frame structure. In one aspect, the first number of symbol groups can include either two groups of symbols or three groups of symbols. In certain other configurations, the apparatus 3302/3302 'for wireless communication may include means for transmitting a first group of symbols between the two groups of symbols in a first tone on the first occasion of adjacent link and a second group of symbols between the two groups of symbols in a second tone on the first occasion of adjacent link when the first number of groups of symbols includes two groups of symbols. In one aspect, a distance between the first tone and the second tone can be either one tone or six tones. In certain other configurations, the apparatus 3302/3302 'for wireless communication may include means for transmitting a first group of symbols from the three groups of symbols in a first tone of the first adjacent link occasion, a second group of symbols from the three groups of symbols in a second tone of the first occasion of adjacent link, and a third group of symbols of the three groups of symbols in a third tone of the first occasion of adjacent link when the first number of groups of symbols includes three groups of symbols. In one aspect, a first distance between tones used by at least one pair of symbol groups can be one tone, and a second distance between tones used for another pair of symbol groups can be six tones. In certain other configurations, the 3302/3302 'wireless device may include means for transmitting a fourth group of symbols in a Petition 870190083603, of 08/27/2019, p. 142/215 137/144 fourth tone on a second uplink occasion subsequent to the first uplink occasion. In one aspect, a third distance between the third tone and the fourth tone can be a tone. The means mentioned above can be one or more of the above mentioned components of the apparatus 3302 and / or the processing system 3414 of the apparatus 3302 'configured to perform the functions recited by the means mentioned above. As described above, processing system 3414 may include the TX 368 processor, the RX 356 processor and the 359 controller / processor. Thus, in one configuration, the means mentioned above may be the TX 368 processor, the processor RX 356 and the controller / processor 359 configured to perform the functions recited by the means mentioned above. [0304] Figure 35 is a conceptual 3500 data flow diagram that illustrates the data flow between different media / components in an example 3502 apparatus. The apparatus may be a UE (for example, UE 104, 350, 504, 604, 704, 804, 904, 1004, 1104, 1204, 1304, 1404, apparatus 2902/2902 ', 3102/3102', 3302/3302 ', 3502') in narrowband communication (for example, NBloT or eMTC) with 3550 base station (e.g. base station 102, 180, 502, 602, 702, 802, 902, 1002, 1102, 1202, 1302, 1402, 2350, 2950, 3150, 3350, eNB 310, apparatus 1702/1702 '). The apparatus may include a receiving component 3504, a symbol group component of NPRACH 3506, a frame structure component 3508, a frequency hop pattern component 3510 and a transmission component 3512. Petition 870190083603, of 08/27/2019, p. 143/215 138/144 [0305] In certain configurations, the receiving component 3504 can be configured to receive information associated with a narrowband TDD frame structure for narrowband communications. The receiving component 3504 can be configured to send a signal associated with the narrowband TDD frame structure to the frame structure component 3508. [0306] In certain configurations, the frame structure component 3508 can be configured to determine a narrow band TDD frame structure. The frame structure component 3508 can be configured to send a signal associated with the narrowband TDD frame structure determined to the frequency hop pattern component 3510 and / or the transmission component 3512. [0307] In certain configurations, the NPRACH 350 symbol group component 6 can be configured to generate at least one NPRACH symbol group for transmission to the 3550 base station. The NPRACH 3506 symbol group component can be configured to send a signal associated with at least one group of NPRACH symbols to the frequency hop pattern component 3510 and / or the transmission component 3512. [0308] In certain configurations, the 3510 frequency hop pattern component can be configured to determine a hop pattern associated with two parts of symbol groups of an NPRACH transmitted on one or more uplink occasions using the structure narrow band TDD frame. The 3510 frequency hop pattern component can be configured Petition 870190083603, of 08/27/2019, p. 144/215 139/144 to send a signal associated with the hop pattern associated with two pairs of groups of NPRACH symbols transmitted on one or more uplink occasions using the narrowband TDD frame structure to the 3512 transmission component. [0309] In certain configurations, the 3512 transmission component can be configured to transmit a first pair of symbol groups and a second pair of symbol groups on the same adjacent link occasion or on adjacent uplink occasions in the frame structure narrow band TDD. In one aspect, a first subcarrier spacing associated with the first pair of symbol groups can be a single subcarrier. In another aspect, a second subcarrier spacing associated with the second pair of symbol groups can be six subcarriers. [0310] The apparatus may include additional components that perform each of the algorithm blocks in the flowchart mentioned above in Figure 28. Thus, each block in the flowchart mentioned above in Figure 28 may be made by a component, and the apparatus may include a or more among these components. The components can be one or more hardware components configured specifically to carry out the declared processes / algorithms, deployed by a processor configured to carry out the declared processes / algorithm, stored within a computer-readable medium for deployment by a processor or some combination of the themselves. [0311] Figure 36 is a 3600 diagram that illustrates an example of a hardware deployment for a Petition 870190083603, of 08/27/2019, p. 145/215 140/144 apparatus 3502 'employing a 3614 processing system. The 3614 processing system can be deployed with a bus architecture, represented generally by the 3624 bus. The 3624 bus can include any number of bus and interconnecting bridges depending the specific application of the 3614 processing system and general limitations of the model. The 3624 bus connects multiple circuits including one or more processors and / or hardware components, represented by the 3604 processor, the 3504, 3506, 3508, 3510, 3512 components, and the 3606 computer / human readable media. The 3624 bus can also connecting various other circuits, such as timing sources, peripherals, voltage regulators and power management circuits, which are well known in the art and therefore will not be described further. [0312] The processing system 3614 can be coupled to a 3610 transceiver. The 3610 transceiver is coupled to one or more 3620 antennas. The 3610 transceiver provides a means of communicating with various other devices via a transmission medium. Transceiver 3610 receives a signal from one or more antennas 3620, extracts information from the received signal and supplies the extracted information to processing system 3614, specifically the receiving component 3504. In addition, transceiver 3610 receives information from processing system 3614, specifically the 3512 transmission component, and based on the information received it generates a signal to be applied to one or more 3620 antennas. The 3614 processing system includes a 3604 processor Petition 870190083603, of 08/27/2019, p. 146/215 141/144 coupled to a computer-readable media / 3606 memory. The 3604 processor is responsible for general processing, including running software stored on the 3606 computer-readable media / memory. The software, when run by the 3604 processor, causes the 3614 processing system performs the various functions described above for any particular device. 3606 computer-readable media / memory can also be used to store data that is handled by the 3604 processor during software execution. The processing system 3614 additionally includes at least one of the components 3504, 3506, 3508, 3510, 3512. The components can be software components that run on the 3604 processor, remain / are stored on the computer-readable media / memory 3606, one or more hardware components coupled to the 3604 processor some combination thereof. The processing system 3614 can be a component of the UE 350 and can include memory 360 and / or at least one among the TX processor 368, the RX processor 356 and the controller / processor 359. [0313] In certain configurations, the 3502/3502 'apparatus for wireless communication may include means for receiving information associated with a narrowband TDD frame structure for narrowband communications. In certain other configurations, the device 3502/3502 'for wireless communication may include means to determine a hop pattern associated with two pairs of groups of symbols of an NPRACH transmitted on one or more uplink occasions using the Petition 870190083603, of 08/27/2019, p. 147/215 142/144 narrowband TDD frame structure. In certain other configurations, the device 3502/3502 'for wireless communication may include means for transmitting a first pair of symbol groups and a second pair of symbol groups on the same uplink occasion or on adjacent uplink occasions on the narrow band TDD frame structure. In one aspect, a first subcarrier spacing associated with the first pair of symbol groups can be a single subcarrier. In another aspect, a second subcarrier spacing associated with the second pair of symbol groups can be six subcarriers. The means mentioned above can be one or more of the components mentioned above of the apparatus 3502 and / or the processing system 3614 of the apparatus 3502 'configured to perform the functions recited by the means mentioned above. As described above, the processing system 3614 may include the TX processor 368, the RX processor 356 and the controller / processor 359. Thus, in one configuration, the means mentioned above may be the TX processor 368, the processor RX 356 and the controller / processor 359 configured to perform the functions recited by the means mentioned above. [0314] It is understood that the specific order or hierarchy of blocks in the revealed processes / flowcharts is an illustration of exemplary approaches. Based on the model preferences, it is understood that the specific order or hierarchy of blocks in the processes / flowcharts can be redistributed. In addition, some blocks can be combined or omitted. The attached claims of the method Petition 870190083603, of 08/27/2019, p. 148/215 143/144 present elements of the various blocks in a sample order and should not be limited to the specific order or hierarchy presented. [0315] The previous description is provided to enable anyone skilled in the art to practice the various aspects described in this document. Various changes to these aspects will become readily apparent to persons skilled in the art and the generic principles defined in this document can be applied to other aspects. Thus, the claims should not be limited to the aspects shown in this document, however, they must be in accordance with the complete scope consistent with the language of the claims, in which the reference to an element in the singular must not mean one (a) and only one, unless specifically stated in this way, but preferably one or more. The word exemplificative (a) is used in this document to serve as an example, occurrence or illustration. Any aspect described in this document as an example (a) should not necessarily be interpreted as preferential or advantageous over other aspects. Unless specifically stated otherwise, the term does not refer to one or more. Combinations, such as at least one of A, B, or C, one or more of A, B, or C, at least one of A, B, and C, one or more of A, B, and C and A, B, C, or any combination thereof, include any combination of A, B and / or C and may include multiples of A, multiples of B, or multiples of C. Specifically, Petition 870190083603, of 08/27/2019, p. 149/215 144/144 combinations, such as at least one of A, B, or C, one or more of A, B, or C, at least one of A, B and C, one or more of A, B, and C and A, B, C or any combination thereof may be A only, B only, C only, A and B, A and C, B and C, or A and B and C, where any such combinations may contain one or more members among A, B or C. All structural and functional equivalents to the elements of the various aspects described throughout the present disclosure that are known or later become known to persons skilled in the art are expressly incorporated into this document as a reference and should be covered by the claims. Furthermore, none of what has been revealed in this document should be dedicated to the public regardless of whether such disclosure is explicitly recited in the claims. The words module, mechanism, element, device and the like may not be a substitute for the word medium. In this way, no claiming element should be interpreted as a more functional means, except when the element is expressly recited using the phrase means for.
权利要求:
Claims (19) [1] 1. Method for wireless communication to a user equipment (UE) comprising: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and transmitting a first group of symbols from a first narrowband physical access channel (NPRACH) preamble to a base station, the first length of the first group of symbols being associated with the narrowband TDD frame structure . [2] A method according to claim 1, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame structure of narrowband frequency division (FDD) duplexing. [3] A method according to claim 2, wherein the first length of the first symbol group is selected so that N symbol groups can be transmitted in N subframes. [4] Method according to claim 1, wherein the first length of the first group of symbols is longer than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame structure of narrowband frequency division (FDD) duplexing. [5] 5. Method according to claim 1, wherein a first preamble format associated with the first NPRACH preamble is different from a second preamble format Petition 870190083603, of 08/27/2019, p. 151/215 2/19 preamble associated The one second preamble in NPRACH transmitted as use in a structure of frame in duplexing division per frequency (FDD) in band narrow.6 . Method, in according to claim 1, in that the first length of the first group of symbols is associated with one or more uplink durations of the narrowband TDD frame structure. 7. Method for wireless communication to a user equipment (UE) comprising: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; determining a maximum number of symbol groups in a plurality of symbol groups associated with a narrowband physical access channel (NPRACH) preamble that suit an adjacent link occasion in the narrowband TDD frame structure; and transmitting a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first adjacent link occasion in the narrowband TDD frame structure and a second subset among the plurality of symbol groups associated with the NPRACH preamble in one second adjacent link occasion in the narrowband TDD frame structure, where the first subset includes the maximum number of symbol groups, and the second subset includes any remaining symbol groups in the plurality of symbol groups or the maximum number of groups of symbols. Petition 870190083603, of 08/27/2019, p. 152/215 3/19 8. Method according to claim 7, characterized in that the plurality of groups of symbols includes four groups of symbols. A method according to claim 7, wherein a length of a group of symbols is a function of the narrowband TDD frame structure. 10. Method for wireless communication to a user equipment (UE) comprising: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determining a first number of symbol groups of a narrowband physical access channel (NPRACH) preamble to transmit on a first adjacent link occasion in the narrowband TDD frame structure, the first number of groups of symbols includes either two groups of symbols or three groups of symbols. 11. The method of claim 10, wherein the first number of symbol groups includes the two symbol groups, the method further comprising: transmitting a first group of symbols between the two groups of symbols in a first tone on the first occasion of adjacent link and a second group of symbols between the two groups of symbols in a second tone on the first occasion of adjacent link, in which a distance between the first tone and the second tone is either one or six tones. 12. Method according to claim 10, in Petition 870190083603, of 08/27/2019, p. 153/215 4/19 that the first number of symbol groups includes the three symbol groups, the method further comprising: transmitting a first group of symbols among the three groups of symbols in a first tone of the first occasion of adjacent link, a second group of symbols among the three groups of symbols in a second tone of the first occasion of adjacent link and a third group of symbols among the three groups of symbols in a third tone of the first occasion of adjacent link, in which a first distance between the tones used for at least one pair of the symbol groups is one tone and a second distance between the tones used for another pair of the symbol groups is six tones. A method according to claim 12, which further comprises: transmitting a fourth group of symbols in a fourth tone on a second adjacent link occasion subsequent to the first adjacent link occasion, with a third distance between the third tone and the fourth tone being one tone. 14. Method for wireless communication to a user equipment (UE) comprising: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determine a hop pattern associated with two pairs of groups of symbols from a narrowband physical random access channel (NPRACH) transmitted on one or more uplink occasions using the structure Petition 870190083603, of 08/27/2019, p. 154/215 5/19 narrow band TDD frame. A method according to claim 14, which further comprises: transmitting a first pair of symbol groups and a second pair of symbol groups on the same adjacent link occasion or on adjacent uplink occasions in the narrowband TDD frame structure, where a first subcarrier spacing associated with the first pair of symbol groups is a single subcarrier, and a second subcarrier spacing associated with the second pair of symbol groups is six subcarriers. 16. Wireless communication device for user equipment (UE) comprising: means for receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and means for transmitting a first group of symbols from a first narrowband physical access channel (NPRACH) preamble to a base station, the first length of the first group of symbols being associated with the TDD frame structure of narrow band. An apparatus according to claim 16, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame structure of narrowband frequency division (FDD) duplexing. Petition 870190083603, of 08/27/2019, p. 155/215 [6] 6/19 Apparatus according to claim 17, wherein the first length of the first symbol group is selected so that N symbol groups can be transmitted in N subframes. 19. The method of claim 16, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame structure of narrowband frequency division (FDD) duplexing. An apparatus according to claim 16, wherein a first preamble format associated with the first NPRACH preamble is different from a second preamble format associated with a second NPRACH preamble transmitted using a duplex frame structure narrowband frequency division (FDD). An apparatus according to claim 16, wherein the first length of the first group of symbols is associated with one or more uplink durations of the narrowband TDD frame structure. 22. Wireless communication device for user equipment (UE) comprising: means for receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; means for determining a maximum number of symbol groups in a plurality of symbol groups associated with a physical access channel preamble Petition 870190083603, of 08/27/2019, p. 156/215 [7] 7/19 (NPRACH) narrowband that suit an occasion of adjacent link in the narrowband TDD frame structure; and means for transmitting a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first adjacent link occasion in the narrowband TDD frame structure and a second subset among the plurality of symbol groups associated with the NPRACH preamble on a second occasion of link adjente at structure of frame TDD in band narrow, on what O first subset includes O number maximum of groups in symbols, and in the second subset includes any groups of symbols remaining in the plurality of symbol groups or the maximum number of symbol groups. An apparatus according to claim 22, wherein the plurality of groups of symbols includes four groups of symbols. Apparatus according to claim 22, wherein a length of a group of symbols is a function of the narrowband TDD frame structure. 25. Wireless communication device for user equipment (UE) comprising: means for receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and means for determining a first number of groups of symbols in an access channel preamble Petition 870190083603, of 08/27/2019, p. 157/215 [8] 8/19 narrowband physical (NPRACH) to transmit on a first occasion of adjacent link in the narrowband TDD frame structure, the first number of symbol groups including either two symbol groups or three symbol groups. 26. Apparatus according to claim 25, wherein the first number of symbol groups includes the two symbol groups, the method further comprising: means for transmitting a first group of symbols between the two groups of symbols in a first tone on the first occasion of the adjacent link and a second group of symbols between the two groups of symbols in a second tone on the first occasion of the adjacent link, wherein one The distance between the first tone and the second tone is either one or six tones. 27. Apparatus according to claim 25, wherein the first number of symbol groups includes the three symbol groups, the method further comprising: means for transmitting a first group of symbols among the three groups of symbols in a first tone of the first occasion of adjacent link, a second group of symbols among the three groups of symbols in a second tone of the first occasion of adjacent link and a third group of symbols among the three groups of symbols in a third tone of the first occasion of adjacent link, in which a first distance between the tones used for at least one pair of the symbol groups is one tone and a second distance between the tones used for Petition 870190083603, of 08/27/2019, p. 158/215 [9] 9/19 another pair of groups of symbols is six tones. 28. Apparatus according to claim 27, which further comprises: means for transmitting a fourth group of symbols in a fourth tone on a second adjacent link occasion subsequent to the first adjacent link occasion, with a third distance between the third tone and the fourth tone being one tone. 29. Wireless communication device for user equipment (UE) comprising: means for receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and means for determining a hop pattern associated with two pairs of groups of symbols from a narrowband physical random access channel (NPRACH) transmitted on one or more uplink occasions using the narrowband TDD frame structure . 30. Apparatus according to claim 29, further comprising: means for transmitting a first pair of symbol groups and a second pair of symbol groups on the same adjacent link occasion or on adjacent uplink occasions in the narrowband TDD frame structure, where an associated first subcarrier spacing to the first pair of symbol groups is a single subcarrier, and where a second subcarrier spacing Petition 870190083603, of 08/27/2019, p. 159/215 [10] 10/19 associated with the second pair of symbol groups are six subcarriers. 31. Wireless communication device for user equipment (UE) comprising: a memory; and at least one processor attached to the memory and configured to: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and transmitting a first group of symbols from a first narrowband physical access channel (NPRACH) preamble to a base station, the first length of the first group of symbols being associated with the narrowband TDD frame structure . An apparatus according to claim 31, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame structure of narrowband frequency division (FDD) duplexing. Apparatus according to claim 32, wherein the first length of the first group of symbols is selected so that N symbol groups can be transmitted in N subframes. 34. The method of claim 31, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame frame structure. duplexing Petition 870190083603, of 08/27/2019, p. 160/215 [11] 11/19 narrowband frequency division (FDD). 35. The apparatus of claim 31, wherein a first preamble format associated with the first NPRACH preamble is different from a second preamble format associated with a second NPRACH preamble transmitted using a duplex frame structure narrowband frequency division (FDD). 36. An apparatus according to claim 31, wherein the first length of the first group of symbols is associated with one or more uplink durations of the narrowband TDD frame structure. 37. Wireless communication device for user equipment (UE) comprising: a memory; and at least one processor attached to the memory and configured to: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; determining a maximum number of symbol groups in a plurality of symbol groups associated with a narrowband physical access channel (NPRACH) preamble that suit an adjacent link occasion in the narrowband TDD frame structure; and transmitting a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first adjacent link occasion in the narrowband TDD frame structure and a second subset among the plurality of symbol groups associated with the Petition 870190083603, of 08/27/2019, p. 161/215 [12] 12/19 NPRACH preamble on a second occasion of adjacent link in the narrowband TDD frame structure, where the first subset includes the maximum number of symbol groups, and the second subset includes any remaining groups of symbols in the plurality of symbol groups or the maximum number of symbol groups. 38. The apparatus of claim 37, wherein the plurality of symbol groups includes four groups of symbols. 39. The apparatus of claim 37, wherein a length of a group of symbols is a function of the narrowband TDD frame structure. 40. Wireless communication device for user equipment (UE) comprising: a memory; and at least one processor attached to the memory and configured to: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determining a first number of symbol groups of a narrowband physical access channel (NPRACH) preamble to transmit on a first adjacent link occasion in the narrowband TDD frame structure, the first number of groups of symbols includes either two groups of symbols or three groups of symbols. 41. Apparatus according to claim 40, characterized by the fact that the first number of groups Petition 870190083603, of 08/27/2019, p. 162/215 [13] Symbol 13/19 includes both groups of symbols, the least processor being additionally configured for: transmitting a first group of symbols between the two groups of symbols in a first tone on the first occasion of adjacent link and a second group of symbols between the two groups of symbols in a second tone on the first occasion of adjacent link, in which a distance between the first tone and the second tone is either one or six tones. 42. Apparatus according to claim 40, characterized by the fact that the first number of symbol groups includes the three symbol groups, the at least processor being additionally configured for: transmitting a first group of symbols among the three groups of symbols in a first tone of the first occasion of adjacent link, a second group of symbols among the three groups of symbols in a second tone of the first occasion of adjacent link and a third group of symbols among the three groups of symbols in a third tone of the first occasion of adjacent link, in which a first distance between the tones used for at least one pair of the symbol groups is one tone and a second distance between the tones used for another pair of the symbol groups is six tones. 43. Apparatus according to claim 42, wherein the at least one processor is additionally configured to: transmit a fourth group of symbols in a fourth tone on a second occasion of adjacent link subsequent to the first occasion of adjacent link, being Petition 870190083603, of 08/27/2019, p. 163/215 [14] 14/19 that a third distance between the third tone and the fourth tone is one tone. 44. Wireless communication device for user equipment (UE) comprising: a memory; and at least one processor attached to the memory and configured to: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determining a hop pattern associated with two pairs of symbol groups from a narrowband physical random access channel (NPRACH) transmitted on one or more uplink occasions using the narrowband TDD frame structure. 45. Apparatus according to claim 44, wherein the at least one processor is additionally configured to: transmitting a first pair of symbol groups and a second pair of symbol groups on the same adjacent link occasion or on adjacent uplink occasions in the narrowband TDD frame structure, where a first subcarrier spacing associated with the first pair of symbol groups is a single subcarrier, and a second subcarrier spacing associated with the second pair of symbol groups is six subcarriers. 46. Computer-readable media that stores computer-executable code for computer equipment Petition 870190083603, of 08/27/2019, p. 164/215 [15] 15/19 user (EU) who understands code for: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and transmitting a first group of symbols from a first narrowband physical access channel (NPRACH) preamble to a base station, the first length of the first group of symbols being associated with the narrowband TDD frame structure . 47. Computer-readable media according to claim 46, wherein the first length of the first group of symbols is shorter than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame narrowband frequency division (FDD) duplexing frame. 48. Computer-readable media according to claim 47, wherein the first length of the first group of symbols is selected so that N groups of symbols can be transmitted in N subframes. 49. Computer-readable media according to claim 46, wherein the first length of the first group of symbols is longer than a second length of a second group of symbols of a second preamble of NPRACH transmitted using a frame narrowband frequency division (FDD) duplexing frame. 50. Computer-readable media according to claim 46, wherein a first preamble format associated with the first NPRACH preamble is different from a Petition 870190083603, of 08/27/2019, p. 165/215 [16] 16/19 second preamble format associated with a second NPRACH preamble transmitted using a narrowband frequency division duplexing (FDD) frame structure. 51. Computer-readable media according to claim 46, wherein the first length of the first group of symbols is associated with one or more uplink durations of the narrowband TDD frame structure. 52. Computer-readable media that stores computer-executable code for user equipment (UE) that comprises code for: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; determining a maximum number of symbol groups in a plurality of symbol groups associated with a narrowband physical access channel (NPRACH) preamble that suit an adjacent link occasion in the narrowband TDD frame structure; and transmitting a first subset of the plurality of symbol groups associated with the NPRACH preamble on a first adjacent link occasion in the narrowband TDD frame structure and a second subset among the plurality of symbol groups associated with the NPRACH preamble in one second occasion of adjacent link in the narrowband TDD frame structure, where the first subset includes the maximum number of symbol groups, and the second subset includes any groups Petition 870190083603, of 08/27/2019, p. 166/215 [17] 17/19 of symbols remaining in the plurality of symbol groups or the maximum number of symbol groups. 53. Computer-readable media according to claim 52, wherein the plurality of symbol groups includes four symbol groups. 54. Computer-readable media according to claim 52, wherein a length of a group of symbols is a function of the narrowband TDD frame structure. 55. Computer-readable media that stores computer-executable code for user equipment (UE) that comprises code for: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determining a first number of symbol groups of a narrowband physical access channel (NPRACH) preamble to transmit on a first adjacent link occasion in the narrowband TDD frame structure, the first number of groups of symbols includes either two groups of symbols or three groups of symbols. 56. Computer-readable media according to claim 55, characterized by the fact that the first number of symbol groups includes the two symbol groups, and in which the code is further configured to: transmit a first group of symbols between the two groups of symbols in a first tone on the first occasion of adjacent link and a second group of symbols Petition 870190083603, of 08/27/2019, p. 167/215 [18] 18/19 between the two groups of symbols in a second tone on the first occasion of an adjacent link, where a distance between the first tone and the second tone is either one or six tones. 57. Computer-readable media according to claim 55, characterized by the fact that the first number of symbol groups includes the three symbol groups, in which the code is further configured to: transmitting a first group of symbols among the three groups of symbols in a first tone of the first occasion of adjacent link, a second group of symbols among the three groups of symbols in a second tone of the first occasion of adjacent link and a third group of symbols among the three groups of symbols in a third tone of the first occasion of adjacent link, in which a first distance between the tones used for at least one pair of the symbol groups is one tone and a second distance between the tones used for another pair of the symbol groups is six tones. 58. Computer-readable media according to claim 57, in which the code is additionally configured to: transmitting a fourth group of symbols in a fourth tone on a second adjacent link occasion subsequent to the first adjacent link occasion, with a third distance between the third tone and the fourth tone being one tone. 59. Computer-readable media that stores computer-executable code for computer equipment Petition 870190083603, of 08/27/2019, p. 168/215 [19] 19/19 user (EU) who understands code for: receiving information associated with a narrowband time division duplexing (TDD) frame structure for narrowband communications; and determining a hop pattern associated with two pairs of symbol groups from a narrowband physical random access channel (NPRACH) transmitted on one or more uplink occasions using the narrowband TDD frame structure. 60. Computer-readable media according to claim 59, wherein the code is additionally configured to: transmitting a first pair of symbol groups and a second pair of symbol groups on the same adjacent link occasion or on adjacent uplink occasions in the narrowband TDD frame structure, where a first subcarrier spacing associated with the first pair of symbol groups is a single subcarrier, and a second subcarrier spacing associated with the second pair of symbol groups is six subcarriers.
类似技术:
公开号 | 公开日 | 专利标题 BR112019017797A2|2020-03-31|STRUCTURE OF DIVISION TABLE DIVISION BY NARROW BAND TIME FOR NARROW BAND COMMUNICATIONS ES2843520T3|2021-07-19|Scheduling enhancements for contention-based shared frequency spectrum employing uplink cross-carrier scheduling ES2883629T3|2021-12-09|Narrow-band time division duplexing frame structure for narrow-band communications BR112019019321A2|2020-04-14|scheduling request for one or more uplink transmissions using narrowband communications BR112019016677A2|2020-04-14|narrowband time division duplexing frame structure for narrowband communications
同族专利:
公开号 | 公开日 CN111884784A|2020-11-03| CN110326250B|2021-11-09| KR20200092432A|2020-08-03| SG11201906541PA|2019-09-27| JP6744503B2|2020-08-19| JP6955049B2|2021-10-27| KR102285182B1|2021-08-03| SG11201906546TA|2019-09-27| SG11201906549SA|2019-09-27| CN111786762A|2020-10-16| CN112312409A|2021-02-02| CN110326250A|2019-10-11| JP2020515119A|2020-05-21| TW201836313A|2018-10-01| US11115175B2|2021-09-07| CN111884783A|2020-11-03| KR20190118159A|2019-10-17| JP6841930B2|2021-03-10| JP2020511064A|2020-04-09| US10454658B2|2019-10-22| US20180248672A1|2018-08-30| BR112019017790A2|2020-03-31| US20180248674A1|2018-08-30| KR20210034696A|2021-03-30| US20180248671A1|2018-08-30| KR20200031698A|2020-03-24| SG11201906542YA|2019-09-27| KR20190118161A|2019-10-17| EP3590292A2|2020-01-08| CN110326348A|2019-10-11| WO2018160365A2|2018-09-07| TWI729271B|2021-06-01| KR102227338B1|2021-03-12| CN111884785A|2020-11-03| CN110326350A|2019-10-11| US20180248673A1|2018-08-30| EP3720220A1|2020-10-07| EP3590291A1|2020-01-08| BR112019017800A2|2020-03-31| TW201838458A|2018-10-16| JP2020174399A|2020-10-22| US20190394013A1|2019-12-26| TWI687082B|2020-03-01| EP3590221A1|2020-01-08| BR112019017811A2|2020-03-31| CN110326249B|2020-11-03| KR102148129B1|2020-08-27| CN110326350B|2021-05-04| TWI701962B|2020-08-11| US20190394014A1|2019-12-26| WO2018160432A1|2018-09-07| JP2020515121A|2020-05-21| JP2020515118A|2020-05-21| JP2020509696A|2020-03-26| KR20190116984A|2019-10-15| KR20190118160A|2019-10-17| US10819495B2|2020-10-27| US10454659B2|2019-10-22| US10721052B2|2020-07-21| CA3050548C|2021-12-28| US10454657B2|2019-10-22| US11101971B2|2021-08-24| KR102349241B1|2022-01-07| KR102077981B1|2020-02-17| WO2018160428A1|2018-09-07| TW201838459A|2018-10-16| CA3050548A1|2018-09-07| US10764021B2|2020-09-01| TW201836317A|2018-10-01| JP6743309B2|2020-08-19| EP3590293A1|2020-01-08| CN110326347B|2021-05-04| CN110326249A|2019-10-11| KR102345373B1|2021-12-29| JP2020123976A|2020-08-13| BR112019017821A2|2020-03-31| CN110326347A|2019-10-11| WO2018160365A3|2018-10-11| TW201838371A|2018-10-16| JP6674589B1|2020-04-01| EP3590217A1|2020-01-08| WO2018160433A1|2018-09-07| WO2018160430A1|2018-09-07| KR102233794B1|2021-03-29| US20190349183A1|2019-11-14| JP6840259B2|2021-03-10| KR20190116985A|2019-10-15| US20180248675A1|2018-08-30|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 IT1253698B|1990-05-31|1995-08-23|Sisas Spa|PROCEDURE FOR THE RECOVERY OF MALEIC ANHYDRIDE FROM REACTION MIXTURES| US7068631B2|2001-08-06|2006-06-27|Telefonaktiebolaget Lm Ericsson |Training sequence hopping in a radio communication system| JP4624475B2|2007-06-18|2011-02-02|パナソニック株式会社|Transmitting apparatus and reference signal generation method| US8457032B2|2007-11-02|2013-06-04|China Academy Of Telecommunications Technology|Method and apparatus for data transmission in a time division duplexing system| KR101530806B1|2007-11-20|2015-06-24|인터디지탈 패튼 홀딩스, 인크|Method and apparatus of signaling and procedure for sequence hopping pattern change during handover| KR101597573B1|2008-08-11|2016-02-25|엘지전자 주식회사|Method for uplink transmitting a control information| JP5383819B2|2008-12-05|2014-01-08|テレフオンアクチーボラゲットエルエムエリクソン(パブル)|Method and apparatus in communication network system| JP5377516B2|2008-12-22|2013-12-25|株式会社日立製作所|Signal arrangement method and communication apparatus| US8780784B2|2009-05-29|2014-07-15|Lg Electronics Inc.|Method and apparatus for transmitting control information from relay node on backhaul uplink| US8868091B2|2010-01-18|2014-10-21|Qualcomm Incorporated|Methods and apparatus for facilitating inter-cell interference coordination via over the air load indicator and relative narrowband transmit power| KR101824902B1|2010-02-22|2018-02-02|삼성전자 주식회사|Application of sequence hopping and orthogonal covering codes to uplink reference signals| CN102202409A|2010-03-26|2011-09-28|北京三星通信技术研究有限公司|Method for determining reference symbol| CN102325377B|2011-05-24|2014-08-06|电信科学技术研究院|Resource scheduling indication method and device| US9398122B2|2011-07-27|2016-07-19|Lg Electronics Inc.|Sequence mapping method and apparatus in wireless communication system| WO2013129884A1|2012-02-29|2013-09-06|엘지전자 주식회사|Method and apparatus for transmitting downlink data| US9622230B2|2012-05-17|2017-04-11|Qualcomm Incorporated|Narrow band partitioning and efficient resource allocation for low cost user equipments| EP2901599A1|2012-09-26|2015-08-05|Interdigital Patent Holdings, Inc.|Methods for dynamic tdd uplink/downlink configuration| US10314015B2|2012-10-26|2019-06-04|Intel Corporation|Reporting of user plan congestion| US9210670B2|2013-03-18|2015-12-08|Samsung Electronics Co., Ltd.|Uplink power control in adaptively configured TDD communication systems| JP2016149583A|2013-06-06|2016-08-18|シャープ株式会社|Terminal, base station device, wireless communication system and communication method| CN105519216B|2013-09-05|2019-01-29|Lg 电子株式会社|The method and device thereof of resource allocation for D2D communication| US9516541B2|2013-09-17|2016-12-06|Intel IP Corporation|Congestion measurement and reporting for real-time delay-sensitive applications| US9467261B2|2013-09-25|2016-10-11|Samsung Electronics Co., Ltd.|System and method for resource mapping for coverage enhancements of broadcast channels| US9749144B2|2014-01-30|2017-08-29|Qualcomm Incorporated|MBSFN and RS considerations in bundled transmission design| US10708015B2|2014-02-10|2020-07-07|Lg Electronics Inc.|Signal transmitting method for device-to-device communication in wireless communication system and device therefor| US9942881B2|2014-03-14|2018-04-10|Telefonaktiebolaget Lm Ericsson |Uplink multi-TTI scheduling in TDD system| CN105210433B|2014-03-28|2019-01-18|华为技术有限公司|Determine the method and device of down control channel number of repetition| WO2015200804A1|2014-06-27|2015-12-30|Intel IP Corporation|Methods apparatus of enb and ue for mtc with narrowband deployment| US9775151B2|2014-07-21|2017-09-26|Intel IP Corporation|System and method for TDD communications| US10050818B2|2015-01-12|2018-08-14|Lg Electronics Inc.|Method for transmitting DMRS for narrow band transmission, and MTC device| DE102015200573A1|2015-01-15|2016-07-21|Volkswagen Aktiengesellschaft|Bipolar plate and fuel cell with such a| WO2016154875A1|2015-03-31|2016-10-06|Nec Corporation|Method and apparatus for data transmission in a wireless communication system| EP3286864A4|2015-04-21|2018-12-05|Intel IP Corporation|User equipment and methods for physical uplink control channel resource allocation and communication| US20180152271A1|2015-05-23|2018-05-31|Lg Electronics Inc.|Wireless device and method for uplink transmission using orthogonal spreading code| US10932256B2|2015-06-16|2021-02-23|Qualcomm Incorporated|Long-term evolution compatible very narrow band design| WO2016208897A1|2015-06-22|2016-12-29|엘지전자 주식회사|Method for transmitting uplink channel and nb-iot device| US10652872B2|2015-07-20|2020-05-12|Lg Electronics Inc.|Downlink control information receiving method and user equipment, and downlink control information transmitting method and base station| US10959244B2|2015-07-22|2021-03-23|Samsung Electronics Co., Ltd.|Method and device for communication in narrow band system| US9955385B2|2015-07-31|2018-04-24|Qualcomm Incorporated|Bundle size determination for narrowband communication| EP3349379B1|2015-09-08|2020-08-12|LG Electronics Inc.|Method and apparatus for receiving downlink physical broadcasting channel in radio access system that supports narrow band internet of things| CN108029008A|2015-09-10|2018-05-11|Lg电子株式会社|Use the communication means and MTC device of arrowband| EP3346783B1|2015-09-25|2020-04-01|Huawei Technologies Co., Ltd.|Uplink information transmission method, base station and user equipment| EP3357185B1|2015-09-29|2020-11-04|LG Electronics Inc.|Method and user equipment for receiving downlink control information, and method and base station for transmitting downlink control information| US10523353B2|2015-10-02|2019-12-31|Lg Electronics Inc.|Method and device for transmitting and receiving secondary synchronization signal in wireless access system supporting narrowband Internet of things| WO2017057984A1|2015-10-02|2017-04-06|엘지전자 주식회사|Method and device for transmitting and receiving primary synchronization signal in wireless access system supporting narrowband internet of things| US10110405B2|2015-11-05|2018-10-23|Qualcomm Incorporated|System and method for narrowband uplink single tone transmissions| US10277270B2|2015-12-08|2019-04-30|Lg Electronics Inc.|Method for transmitting uplink signal in a wireless communication system and apparatus for the same| EP3393069B1|2015-12-18|2021-03-17|LG Electronics Inc. -1-|Method and wireless device for transmitting random-access preamble by means of single-tone method| US10193734B2|2015-12-24|2019-01-29|Lg Electronics Inc.|Method for transceiving signal in a wireless communication system and apparatus for the same| JP2019054308A|2016-01-26|2019-04-04|シャープ株式会社|Base station device, terminal device, and communication method| EP3413495A4|2016-02-02|2019-09-04|LG Electronics Inc. -1-|Method for transmitting dmrs in wireless communication system supporting nb-iot and apparatus therefor| CN107040338B|2016-02-04|2020-11-06|株式会社Kt|Method and apparatus for configuring resource units for NB-IoT UE to transmit uplink signals| CN107040358A|2016-02-04|2017-08-11|株式会社Kt|The method and its device of upward signal are sent and received for NB IoT UE| CN107197524B|2016-03-15|2021-06-22|株式会社Kt|Method and device for sending uplink data of narrow-band Internet of things user equipment| JP2019091959A|2016-03-30|2019-06-13|シャープ株式会社|Terminal device, base station device, communication method, and integrated circuit| US11102779B2|2016-07-15|2021-08-24|Qualcomm Incorporated|Methods and apparatus for IOT operation in unlicensed spectrum| US10985899B2|2016-08-11|2021-04-20|Telefonaktiebolaget Lm Ericsson |Network node, wireless device and methods therein relating to time division duplex configurations for narrowband Internet of Things| US10218406B2|2016-09-02|2019-02-26|Qualcomm Incorporated|Narrowband communication for different device capabilities in unlicensed spectrum| US10291451B2|2016-11-07|2019-05-14|Qualcomm Incorporated|PRACH design for larger cell radius| US10958337B2|2017-02-14|2021-03-23|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| US10524258B2|2017-02-15|2019-12-31|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| US10454658B2|2017-02-28|2019-10-22|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| CN110771235A|2017-03-24|2020-02-07|英特尔Ip公司|sub-PRB resource allocation for PUSCH in even further enhanced MTC| US10798734B2|2017-03-28|2020-10-06|Centre Of Excellence In Wireless Technology|Method and wireless device for transmitting RACH preamble in wireless communication network| US11025403B2|2017-07-12|2021-06-01|Qualcomm Incorporated|Frame structure dependent configuration of physical channels| WO2019098681A1|2017-11-14|2019-05-23|엘지전자 주식회사|Method for transmitting random access preamble in narrowband iot system supporting time division duplexing and apparatus therefor| US10819470B2|2018-01-12|2020-10-27|Intel IP Corporation|Behavior of user equipment in scenarios of conflicting resource assignments in new radio systems|EP3403358B1|2016-01-11|2021-11-03|Sony Group Corporation|Signaling subcarrier spacing in narrowband internet of things communication system| CN107370701B|2016-05-11|2020-05-08|华为技术有限公司|Signal transmission method, sending end and receiving end| US10958337B2|2017-02-14|2021-03-23|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| US10524258B2|2017-02-15|2019-12-31|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| US10454658B2|2017-02-28|2019-10-22|Qualcomm Incorporated|Narrowband time-division duplex frame structure for narrowband communications| WO2018174526A1|2017-03-24|2018-09-27|Samsung Electronics Co., Ltd.|Method and device for scheduling request in nb iot systems| US10798734B2|2017-03-28|2020-10-06|Centre Of Excellence In Wireless Technology|Method and wireless device for transmitting RACH preamble in wireless communication network| US10813111B1|2017-07-07|2020-10-20|Sprint Spectrum L.P.|Scheduling low-priority transmissions| CN109587659A|2017-09-29|2019-04-05|中兴通讯股份有限公司|A kind of sending method and system of signal| WO2019098681A1|2017-11-14|2019-05-23|엘지전자 주식회사|Method for transmitting random access preamble in narrowband iot system supporting time division duplexing and apparatus therefor| US10707915B2|2017-12-04|2020-07-07|Qualcomm Incorporated|Narrowband frequency hopping mechanisms to overcome bandwidth restrictions in the unlicensed frequency spectrum| EP3614640B1|2018-01-25|2022-03-02|Lg Electronics Inc.|Method of transmitting nprach preambles in wireless communication system supporting tdd| US10959270B2|2018-06-21|2021-03-23|Apple Inc.|NPRACH configuration and format for unlicensed NBIoT system| CN112087807A|2019-06-13|2020-12-15|中兴通讯股份有限公司|Method, device and base station for realizing uplink authorization| US20210058111A1|2019-08-23|2021-02-25|Qualcomm Incorporated|Frequency hopping with slot bundling| CN111629328A|2020-06-05|2020-09-04|重庆科技学院|NB-IoT-based vehicle-mounted LED screen control system and method| US20220038151A1|2020-07-29|2022-02-03|Qualcomm Incorporated|Connected mode beam management for narrowband systems| CN111970660A|2020-08-31|2020-11-20|成都星联芯通科技有限公司|Shipborne satellite multimode terminal based on satellite Internet of things|
法律状态:
2021-10-13| B350| Update of information on the portal [chapter 15.35 patent gazette]|
优先权:
[返回顶部]
申请号 | 申请日 | 专利标题 IN201741007075|2017-02-28| IN201741007075|2017-02-28| US15/710,748|2017-09-20| US15/710,748|US10454659B2|2017-02-28|2017-09-20|Narrowband time-division duplex frame structure for narrowband communications| PCT/US2018/019224|WO2018160433A1|2017-02-28|2018-02-22|Narrowband time-division duplex frame structure for narrowband communications| 相关专利
Sulfonates, polymers, resist compositions and patterning process
Washing machine
Washing machine
Device for fixture finishing and tension adjusting of membrane
Structure for Equipping Band in a Plane Cathode Ray Tube
Process for preparation of 7 alpha-carboxyl 9, 11-epoxy steroids and intermediates useful therein an
国家/地区
|