wireless transmission / reception unit, and, method of transmitting an uplink control information.

专利摘要:
The invention features systems, methods and tools for reliable control signaling, for example, in the Novo Rádio (NR) technology. A receiver in a wireless transmit / receive unit (WTRU) can receive one or more downlink control physical channel (PDCCH) transmissions comprising downlink control (DCI) information. The WTRU can determine a transmission profile associated with uplink control (UCI) information. Based on the transmission profile, the WTRU can determine one or more transmission characteristics associated with the UCI transmission. The WTRU can transmit the UCI through a physical uplink control channel (PUCCH). The UCI can be transmitted using the transmission characteristics determined by the WTRU. The WTRU can transmit the UCI based on at least one of a set of control resources (CORESET), a search space, or a temporary radio network identifier (RNTI). The WTRU can determine a different transmission profile based on the content of the UCI.
公开号:BR112019026490A2
申请号:R112019026490-6
申请日:2018-06-11
公开日:2020-07-21
发明作者:Paul Marinier；J. Patrick Tooher；Tao Deng；Ghyslain Pelletier
申请人:Idac Holdings, Inc.；
IPC主号:

专利说明:

[001] [001] This application claims the benefit of Provisional Patent Applications No. US 62 / 519,585, filed on Wednesday, June 14, 2017, No. US 62 / 585,937, filed on Tuesday, April 3, 2018 and No. US 62 / 667,015, filed on Friday, May 4, 2018, the contents of which are incorporated by reference into this invention. BACKGROUND
[002] [002] Mobile communications using wireless communication continue to evolve. A fifth generation or Next Gen (NG, Next Generation, or next generation) of wireless systems can be called 5G or New Radio (NR, or new radio). A previous generation of mobile communication could be, for example, the fourth generation (4G) long term evolution (LTE). A set of NR use cases can generally be classified into one of: improved mobile broadband (eMBB), ultra-reliable and low-latency communication (URLLC, ultra-reliaoble and low-latency communications) or an massive machine type communication (mMTC). The current processing and transmission mechanisms used for such cases may be less efficient. SUMMARY
[003] [003] The invention presents systems, methods and instrumentalities for reliable control signaling, for example, in the Novo Rádio (NR) technology. A receiver in a wireless transmit / receive unit (WTRU) can receive one or more downlink control physical channel (PDCCH) transmissions comprising downlink control (DCI) information. The WTRU can determine a transmission profile associated with uplink control (UCDI) information. The transmission profile can be determined based on one or more of the following: an identity of a logical channel or a group of logical channels for data associated with the UCI and a property of at least one PDCCH transmission. The PDCCH transmission can be mapped to one or more resources from a set of control resources (CORESET).
[004] [004] The transmission profile can be determined based on one or more of: one or more DCI fields in the received DCI or an identity of a part of the bandwidth (BWP) used to transmit one or more of the DCI or the UCI.
[005] [005] The DCI can include a first DCI and a second DCI. The DCI field can indicate a hybrid automatic repeat request process index (HARQ) or a logical channel priority. The first DCI can be received using a first set of control features (CORESET), and the second DCI can be received using a second CORESET. The first CORESET and the second CORESET can comprise one or more of a component carrier, at least a BWP, a subset of resource blocks within each part of the bandwidth, a set of time symbols within a slot ) or mini-slot (mini-slot), a spacing between subcarriers, a subset of intervals within a subframe, or at least one reference signal.
[006] [006] The UCI may include a first UCI and a second UCI. The first UCI or the second UCI may include one or more of a hybrid automatic repeat request (HARQ), a scheduling request (SR), or a channel quality indicator (CQD. The UCI can be transmitted based on a CORESET, a search space or an RNTI. The UCI can be associated with a PDSCH transmission or a PDCCH transmission. In one example, the first UCI or the second UCI can include feedback bits for a data transmission assigned by first DCI or the second DCI In another example, the second UCI can correspond to a redundant transmission from the first UCI.
[007] [007] Based on the transmission profile, the WTRU can determine one or more transmission characteristics associated with the UCI transmission. The one or more transmission characteristics may include at least one of the following: one or more encoding parameters, one or more transmission power parameters, one or more resource allocation parameters, or a priority level.
[008] [008] The WTRU can transmit the UCI through a physical uplink control channel (PUCCH). The UCI can be transmitted using the transmission characteristics determined by the WTRU. The WTRU can transmit the UCI based on one or more of a CORESET, a search space or a temporary radio network identifier (RNTID). The PUCCH that carries the UCI is transmitted on an uplink carrier (UL) and / or a complementary uplink carrier (SUL).
[009] [009] The WTRU may determine a transmission profile associated with a PDSCH transmission based on one or more of the following, for example if the UCI comprises a hybrid automatic repeat request acknowledgment (HARQ ACK) : a transmission duration, a portion of bandwidth, a numerology or a modulation and coding scheme table (MCS) for control information.
[0010] [0010] The WTRU can determine a transmission profile based on one or more of the following, for example if the UCI understands channel state information (CSI): a target value of block error rate (BLER , block error rate) associated with the CSI, or a CSI reporting configuration.
[0011] [0011] The WTRU may determine a transmission profile based on one or more of the following, for example if the UCI understands a scheduling request (SR) associated with a configured uplink control (PUCCH) physical channel resource for an SR transmission: a subcarrier spacing, a duration of a PUCCH resource, a logical channel associated with an SR configuration, a priority associated with the logical channel. BRIEF DESCRIPTION OF THE DRAWINGS
[0012] [0012] A more detailed understanding can be obtained from the description below, given as an example in conjunction with the attached drawings.
[0013] [0013] Figure 1A is a system diagram illustrating an exemplary communication system, in which one or more revealed modalities can be implemented.
[0014] [0014] Figure IB is a system diagram of an exemplary wireless transmission / reception unit (WTRU) that can be used in the communication system illustrated in Figure 1A.
[0015] [0015] Figure 1C is a system diagram illustrating an exemplary radio access network (RAN) and an exemplary core network (CN) that can be used in the communication system illustrated in Figure 1A.
[0016] [0016] Figure ID is a system diagram illustrating an additional exemplary RAN and an additional exemplary CN that can be used in the communication system illustrated in Figure 1A.
[0017] [0017] Figure 2 illustrates an example of a diversity of downlink control (DCI) information.
[0018] [0018] Figure 3 illustrates an example of a diversity of uplink control (UCLI) information. DETAILED DESCRIPTION
[0019] [0019] A detailed description of the illustrative modalities will now be described with reference to the various Figures. Although this description provides a detailed example of possible implementations, it should be noted that the details are intended to be exemplary and in no way limit the scope of the request.
[0020] [0020] Figure 1A is a diagram of an example communication system 100 in which one or more revealed modalities can be implemented. The communication system 100 can be a multiple access system that provides content, such as voice, data, video, messages, broadcasting, etc., to multiple wireless users. The communication system 100 can enable multiple wireless users to access this content by sharing system resources, including wireless bandwidth. For example, communication systems 100 may employ one or more methods of channel access, such as code division multiple access ("(CDMA" - code division multiple access), time division multiple access ("TDMA" - time division multiple access), frequency division multiple access ("FDMA"), orthogonal FDMA ("(OFDMA '" - orthogonal frequency division multiple access), single carrier FDMA ("SC-FDMA'" - single-carrier frequency division multiple access), discrete Fourier transform spreading ("DFT" - discrete Fourier transform) OFDM "zero tail" ('ZT UW DTS-s OFDM' "- zero-tail unique-word discrete sine transform spread orthogonal frequency division multiplexing), OFDM filtered by single word ("UW-OFDM" - unique word orthogonal frequency division multiplexing), OFDM filtered by resource block, filter bank multicarrier ("FBMC" - filter bank multicarrier ) and the like.
[0021] [0021] As shown in Figure 1A, the communication system
[0022] [0022] Communication systems 100 may also include a base station 114a and / or a base station 114b. Each of the base stations 114a, 114b can be any type of device configured to wirelessly interface with at least one of the WTRUs 102a, 102b, 102c, 102d to facilitate access to one or more communication networks, such as CN 106 / 115, Internet 110 and / or other networks 112. For example, base stations 114a, 114b can be a transceiver base station ("BTS" - base transceiver station), a B node, a B node evolved (eNodeB), a Node B of origin, an eNodeB of origin, a gNB, a NodeB of new radio ("NR '" - new radio), a location controller, a connection point ("AP" - access point ), a wireless router and the like. Although each of base stations 114a, 114b is shown as a single element, it should be considered that base stations 114a, 114b can include any number of interconnected base stations and / or network elements.
[0023] [0023] Base station 114a may be part of RAN 104/113, which may also include other base stations and / or network elements (not shown), such as a base station controller ("BSC" - base station controller), a radio network controller ("RNC" - radio network controller), relay nodes, etc. Base station 114a and / or base station 114b can be configured to transmit and / or receive wireless signals on one or more carrier frequencies, which can be called a cell (not shown). These frequencies can be in licensed spectrum, unlicensed spectrum or a combination of licensed and unlicensed spectrum. A cell can provide wireless coverage for a specific geographic area that can be relatively fixed or that can change over time. The cell can also be divided into cell sectors. For example, the cell associated with base station 114a can be divided into three sectors. Thus, in one embodiment, base station 114a can include three transceivers, that is, one for each cell sector. In one embodiment, base station 114a can employ multiple input and multiple output technology ("MIMO" - multiple input multiple output) and can use multiple transceivers for each cell sector. For example, beam formation can be used to transmit and / or receive signals in desired spatial directions.
[0024] [0024] Base stations 114a, 114b can communicate with one or more of the WTRUs 102a, 102b, 102c, 102d via an air interface 116, which can be any suitable wireless communication link (e.g. radio frequency ( "RF" - radio frequency), microwave, centimeter wave, micrometric wave, infrared (IR - "Infrared"), ultraviolet ("UV" - ultraviolet), visible light, etc.). The air interface 116 can be established using any suitable radio access technology ("RAT" - radio access technology).
[0025] [0025] More specifically, as indicated above, communication system 100 may be a multiple access system and may employ one or more channel access schemes, such as CDMA, TDMA, FDMA, OFDMA, SC-FDMA and the like. For example, base station 114a on RAN 104/113 and WTRUs 102a, 102b, 102c can implement radio technology, such as universal terrestrial radio access ("UTRA" - universal terrestrial radio access) from the universal telecommunications system ("UMTS" - universal mobile telecommunications system), which can establish the aerial interface 115/116/117 using broadband CDMA "WCDMA" - wideband code division multiple access). WCDMA can include communication protocols, such as high-speed packet access ("HSPA") and / or advanced HSPA (HSPA +). HSPA may include high-speed downlink packet access ("DL" - downlink packet access) and / or high-speed downlink packet access ("UL" - uplink) speed ("HSUPA" - high-speed uplink packet access).
[0026] [0026] In one embodiment, base station 114a and WTRUs 102a, 102b, 102c can implement radio technology, such as terrestrial UMTS radio access (E-UTRA), which can establish air interface 116 through the use of long term evolution ("LTE" - long term evolution) and / or advanced LTE (LTE-A) and / or Advanced LTE Pro (LTE-A Pro).
[0027] [0027] In one embodiment, base station 114a and WTRUs 102a, 102b, 102c can implement radio technology, such as NR radio access, which can establish air interface 116 using Novo Rádio (NR, new radio).
[0028] [0028] In one embodiment, base station 114a and WTRUs 102a, 102b, 102c can implement multiple radio access technologies. For example, base station 114a and WTRUs 102a, 102b, 102c can implement LTE radio access and NR radio access together, for example, using dual connectivity ("DC") principles. In this way, the air interface used by WTRUs 102a, 102b, 102c can be characterized by multiple types of radio access technologies and / or transmissions sent to / from multiple types of base stations (for example, an eNB and a gNB).
[0029] [0029] In other modalities, base station 114a and WTRUs 102a, 102b, 102c can implement radio technologies, such as IEEE
[0030] [0030] Base station 114b in Figure 1A can be a wireless router, a source B node, a source eNodeB, or a connection point, for example, and can use any suitable RAT to facilitate wireless connectivity in a localized area, such as a workplace, a home, a carrier, a campus, an industrial facility, an air corridor (for example, for use by drones), a highway and the like. In one embodiment, base station 114b and WTRUs 102c, 102d can implement radio technology, such as IEEE 802.11, to establish a wireless local area network ('WLAN "). base station 114b and WTRUs 102c, 102d can implement radio technology, such as IEEE 802.15, to establish a wireless personal area network ('WPAN "). In yet another embodiment, base station 114b and WTRUs 102c, 102d can use a cell-based RAT (e.g., WCDMA, CDMA 2000, GSM, LTE, LTE-A, LTE-A Pro, NR etc.). ) to establish a picocell or femtocell. As shown in Figure 1A, base station 114b may have a direct connection to Internet 110. Thus, base station 114b may not be required to access Internet 110 through CN 106/115.
[0031] [0031] RAN 104/113 can be in communication with CN 106/115, which can be any type of network configured to provide voice, data, applications and / or voice over Internet protocol ("VolIP" - voice) over Internet protocol) for one or more of the WTRUs 102a, 102b, 102c, 102d. Data can have varying quality of service ("QoS") requirements, such as different processing capacity requirements, latency requirements, error tolerance requirements, reliability requirements, data processing capacity requirements , mobility requirements and the like. CN 106/115 can provide call control, billing services, location-based mobile services, prepaid calling, Internet connectivity, video distribution, etc., and / or perform high-level security functions, such as authentication user. Although not shown in Figure 1A, it should be considered that RAN 104/113 and / or CN 106/115 may be in direct or indirect communication with other RANs that use the same RAT, such as RAN 104/113, or a Different RAT. For example, in addition to being connected to RAN 104/113, which can use NR radio technology, CN 106/115 can also be in communication with another RAN (not shown) that uses GSM, UMTS, CDMA radio technology 2000, WiMAX, E-UTRA or Wi-Fi.
[0032] [0032] CN 106/115 can also serve as a communication port ("gateway") for WTRUs 102a, 102b, 102c, 102d to access PSTN 108, Internet 110 and / or other networks 112. PSTN 108 may include circuit switched telephone networks that provide conventional telephone service ("POTS" - plain old telephone service). Internet 110 may include a global system of computer networks and interconnected devices that use common communication protocols, such as the Transmission Control Protocol (TCP), the User Datagram Protocol ("UDP" - user datagram protocol) and the Internet protocol ("IP" - Internet protocol) in the set of Internet TCP / IP protocols. 112 networks may include wired and / or wireless communication networks owned by, and / or operated by, other service providers. For example, networks 112 may include another CN connected to one or more RANs, which may employ the same RAT, such as RAN 104/113, or a different RAT.
[0033] [0033] Some or all of the WTRUs 102a, 102b, 102c, 102d in the communication system 100 may include multiple mode capabilities (for example, the WTRUs 102a, 102b, 102c, 102d may include multiple transceivers for communication with different wireless networks through different wireless links). For example, WTRU 102c shown in Figure 1A can be configured to communicate with base station 114a, which can employ cellular-based radio technology, and with base station 114b, which can employ radio technology IEEE 802.
[0034] [0034] Figure 1B is a system diagram illustrating an example of WTRU 102. As shown in Figure 1B, WTRU 102 can include a processor 118, a transceiver 120, a transmit / receive element 122, a speaker / microphone 124, a numeric keypad 126, a monitor / touchpad 128, a non-removable memory 130, a removable memory 132, a power source 134, a global positioning system (GPS) chipset 136 and / or other peripherals 138, among others. It will be recognized that WTRU 102 may include any subcombination of the above elements while remaining consistent with a modality.
[0035] [0035] Processor 118 may be a general purpose processor, a special purpose processor, a conventional processor, a digital signal processor ("DSP"), a plurality of microprocessors, one or more microprocessors in association with a DSP core, a controller, a microcontroller, application specific integrated circuits ("ASICs"), field programmable gate array circuits ("FPGAs" - field programmable gate arrays), any other type integrated circuit (IC) - a state machine and the like. Processor 118 can perform signal encoding, data processing, power control, input / output processing and / or any other functionality that enables the WTRU 102 to operate in a wireless environment. Processor 118 can be coupled to transceiver 120, which can be coupled to transmit / receive element 122. Although Figure 1B represents processor 118 and transceiver 120 as separate components, it will be recognized that processor 118 and transceiver 120 can be integrated together in an electronic package or electronic circuit.
[0036] [0036] The transmit / receive element 122 can be configured to transmit signals to, or receive signals from, a base station (e.g.
[0037] [0037] Although the transmit / receive element 122 is represented in Figure 1B as a single element, the WTRU 102 can include any number of transmit / receive elements 122. More specifically, the WTRU 102 can employ MIMO technology. Thus, in one embodiment, the WTRU 102 may include two or more transmit / receive elements 122 (e.g., multiple antennas) to transmit and receive wireless signals over the air interface 116.
[0038] [0038] Transceiver 120 can be configured to modulate the signals that are intended to be transmitted by the transmit / receive element 122, and to demodulate the signals that are received by the transmit / receive element 122. As indicated above, WTRU 102 may have multimode capabilities. In this way, transceiver 120 can include multiple transceivers to enable WTRU 102 to communicate through multiple RATs, such as NR and IEEE 802.11, for example.
[0039] [0039] Processor 118 of WTRU 102 can be coupled to speaker / microphone 124, numeric keypad 126 and / or monitor / touchpad 128 (for example, a liquid crystal display unit ("LCD" - liquid crystal display) or an organic light-emitting diode (OLED) display unit), and can receive user input from them. Processor 118 can also output user data to speaker / microphone 124, keyboard 126 and / or monitor / touchpad 128. In addition, processor 118 can access information from, and store data in, any type of memory such as non-removable memory 130 and / or removable memory
[0040] [0040] Processor 118 can receive power from power source 134, and can be configured to distribute and / or control power to the other components in WTRU 102. Power source 134 can be any device suitable for powering WTRU 102 For example, power source 134 may include one or more dry cell batteries (for example, nickel-cadmium (NiCd), nickel-zinc (NiZn), nickel-metal hydride (NiMH), lithium ion (Li-ion) fon), etc.), solar cells, fuel cells and the like.
[0041] [0041] Processor 118 can also be coupled with the GPS chipset 136, which can be configured to provide location information (for example, longitude and latitude) in relation to the current location of WTRU 102. In addition to, or instead of , GPS circuitry information from GPS 136, WTRU 102 can receive location information via a base station's air interface 116 (for example, base stations 114a, 114b) and / or determine its location based on timing signals received from two or more nearby base stations. It must be considered that the WTRU 102 can capture location information using any suitable location determination method, and still remain compatible with a modality.
[0042] [0042] Processor 118 may also be coupled with other peripherals 138, which may include one or more software and / or hardware modules that provide additional wireless, wired, features and functionality or connectivity. For example, peripherals 138 may include an accelerometer, an electronic compass, a satellite transceiver, a digital camera (for photos and / or video), a universal serial bus port ("USB" - universal serial bus), a device vibrator, a television transceiver, a handsfree headset, a BluetoothO module, a frequency modulated radio unit ("FM" - frequency modulated), a digital music player, a media player, a video game player module , an Internet browser, a virtual reality device and / or augmented reality ("VR / AR" - virtual reality / augmented reality), an activity tracker and the like. Peripherals 138 may include one or more sensors, the sensors may be one or more from a gyroscope, an accelerometer, a hall effect sensor, a magnetometer, an orientation sensor, a proximity sensor, a temperature sensor, a sensor of time; a geolocation sensor; an altimeter, a light sensor, a touch sensor, a magnetometer, a barometer, a gesture sensor, a biometric sensor and / or a humidity sensor.
[0043] [0043] The WTRU 102 may include a complete duplex radio for which the transmission and reception of some or all of the signals (for example, associated with a particular one for both UL subframes (for example, for transmission) and link downward (for example, for reception) can be concurrent and / or simultaneous.The full duplex radio can include an interference management unit and substantially reduce or eliminate auto interference through hardware (for example, a shutter) or signal processing through of a processor (for example, a separate processor (not shown) or via processor 118). In one embodiment, the WTRU 102 can include a half duplex radio for which transmission and reception of some or all of the signals (for example, associated with specific subframes for UL (for example, for transmission) or for the downlink (for example, for reception)).
[0044] [0044] Figure IC is a system diagram illustrating RAN 104 and CN 106 according to a modality. As noted above, RAN 104 can employ E-UTRA radio technology to communicate with WTRUs 102a, 102b, 102c via air interface 116. RAN 104 can also be in communication with CN 106.
[0045] [0045] RAN 104 can include eNodeBs 160a, 160b, 160c, although it should be considered that RAN 104 can include any number of eNodeBs and still remain consistent with a modality. Each of the eNodeBs 160a, 160b, 160c can include one or more transceivers for communication with WTRUs 102a, 102b, 102c via the air interface
[0046] [0046] Each of the eNodeBs 160a, 160b, 160c can be associated with a specific cell (not shown) and can be configured to handle radio resource management decisions, automatic change decisions, UL scheduling and / or DL and the like. As shown in Figure 1C, eNodeBs 160a, 160b, 160c can communicate with each other via an X2 interface.
[0047] [0047] CN 106 shown in Figure 1C may include a mobility management entity (MME) 162,
[0048] [0048] MME 162 can be connected to each of the eNodeBs 1622, 162b, 162c in RAN 104 through an S1 interface and can serve as a control node. For example, MME 162 may be responsible for authenticating users of WTRUs 102a, 102b, 102c, for enabling / disabling the carrier, for selecting a specific server communication port during an initial connection for WTRUs 102a, 102b, 102c and the like . MME 162 can provide a control plan function for switching between RAN 104 and other RANs (not shown) that employ other radio technologies, such as GSM or WCDMA.
[0049] [0049] SGW 164 can be connected to each of the eNodeBs 160a, 160b, 160c on RAN 104 through the interface Sl. The SWH 164 can, in general, route and forward user data packets destined for / from WTRUs 102a, 102b, 102c. The SGW 164 can perform other functions, such as anchoring user plans during automatic changes between eNodeBs, triggering pagination when DL data is available for WTRUs 102a, 102b, 102c, managing and storing the contexts of WTRUs 102a, 102b, 102c and the like.
[0050] [0050] SGW 164 can be connected to PGW 166, which can provide WTRUs 102a, 102b, 102c with access to packet-switched networks, such as Internet 110, to facilitate communications between WTRUs 102a, 102b, 102c and IP-enabled devices.
[0051] [0051] CN 106 can facilitate communications with other networks. For example, CN 106 can provide WTRUs 102a, 102b, 102c with access to circuit switched networks, such as PSTN 108, to facilitate communications between WTRUs 102a, 102b, 102c and traditional terrestrial communication devices. For example, CN 106 can include, or can communicate with, an IP communication port (for example, an IP multimedia subsystem (IMS) server) that serves as an interface between CN 106 and PSTN 108. In addition in addition, CN 106 can provide access from WTRUs 102a, 102b, 102c to other networks 112, which may include other wired and / or wireless networks that are owned and / or operated by other service providers.
[0052] [0052] Although the WTRU is described in Figures 1A to 1D as a wireless terminal, it is contemplated that, in certain representative embodiments, such terminal may use (for example, temporarily or permanently) wired communication interfaces with the communication network .
[0053] [0053] In representative modalities, the other network 112 can be a WLAN.
[0054] [0054] A WLAN in basic service set mode ("BSS" - basic service set) can have a connection point ("AP" - access point) for the BSS and one or more stations ("STAs" - stations) associated with the AP. The AP can have access to or interface with a distribution system ("DS" - distribution system) or another type of wired / wireless network that carries traffic into and / or out of the BSS. Traffic to STAs that originate outside a BSS can arrive through the AP and can be delivered to STAs. Traffic from STAs to destinations outside the BSS can be sent to the AP to be delivered to the respective destinations. Traffic between STAs within the BSS can be sent through the AP, for example, where the originating STA can send traffic to the AP and the AP can deliver traffic to the destination STA. Traffic between STAs within a BSS can be considered and / or called as point-to-point traffic. Peer-to-peer traffic can be sent between (for example, directly between)
[0055] [0055] When using the operation mode or a similar operation mode of 802.11ac infrastructure, the AP can transmit a flag on a fixed channel, such as a primary channel. The primary channel can have a fixed width (for example, 20 MHz of bandwidth) or a dynamically defined width through signaling. The primary channel can be the operational channel of the BSS and can be used by the STAs to establish a connection with the AP. In certain representative modalities, multiple access with collision avoidance carrier detection ("CSMA / CA" - carrier sense multiple access with collision avoidance) can be implemented, for example, in 802.11 systems. For CSMA / CA, STAs (for example, each STA), including the AP, can detect the primary channel. If the primary channel is detected and / or determined / detected to be occupied by a particular STA, the specific STA can retreat. An STA (for example, only one station) can transmit at any given time in a given BSS.
[0056] [0056] High throughput STAs ("HT" - high throughput) can use a 40 MHz wide channel for communication, for example, by combining the primary 20 MHz channel with an adjacent 20 MHz channel or not adjacent to form a 40 MHz wide channel.
[0057] [0057] STAs with very high processing capacity ("VHT" -
[0058] [0058] Sub 1 GHz operating modes are supported by
[0059] [0059] WLAN systems, which can support multiple channels and channel bandwidths, such as 802.11n, 802.11ac, 802.11af and 802.11ah, include a channel that can be designated as the primary channel. The primary channel can, for example, have a bandwidth equal to the highest common operating bandwidth supported by all STAs in the BSS. The bandwidth of the primary channel can be defined and / or limited by one STA, among all STAs operating in a BSS, which supports the lowest bandwidth operating mode. In the 802.11ah example, the primary channel can be 1 MHz wide for STAs (for example, MTC type devices) that support (for example, only support) a 1 MHz mode, even if the AP, and other STAs in BSS mode they support 2 MHz, 4 MHz, 8 MHz, 16 MHz and / or other channels bandwidth operating modes. The settings for carrier detection and / or Network Allocation Vector ("NAV" - network allocation vector) may depend on the state of the primary channel. If the primary channel is busy, for example, due to a STA (which only supports a 1 MHz operating mode), transmitting to the AP, all available frequency bands can be considered occupied even if most frequency bands remains idle and can be available.
[0060] [0060] In the United States, the available frequency bands, which can be used over 802.11ah, are from 902 MHz to 928 MHz. In Korea, the available frequency bands are from 917.5 MHz to 923.5 MHz. Japan, the available frequency bands are 916.5 MHz to 927.5 MHz. For example, the total bandwidth available for 802.11ah is 6 MHz to 26 MHz, depending on the country code.
[0061] [0061] Figure 1D is a system diagram illustrating RAN 113 and CN 115 according to a modality. As noted above, the
[0062] [0062] RAN 113 can include gNBs 180a, 180b, 180c, although it should be considered that RAN 113 can include any number of gNBs and still remain consistent with a modality. The gNBs 180a, 180b, 180c can include one or more transceivers for communication with WTRUs 102a, 102b, 102c through the air interface 116. In some embodiments, gNBs 180a, 180b, 180c can implement MIMO technology. For example, gNBs 180a, 108b can use beam formation to transmit signals to and / or receive signals from gNBs 180a, 180b, 180C. In this way, gNBs 180a, for example, can use multiple antennas to transmit wireless signals and / or receive wireless signals from WTRU 102a. In one embodiment, gNBs 180a, 180b and 180c can implement carrier aggregation technology. For example, gNB 180a can transmit multi-component carriers to WTRU 102a (not shown). A subset of these component carriers may be in the unlicensed spectrum, while the rest of the component carriers may be in the licensed spectrum. In one embodiment, gNBs 180a, 180b and 180c can implement coordinated multi-point technology ("CoMP '" - coordinated multi-point). For example, WTRU 102a can receive coordinated transmissions of gNB 180a and gNB 180b (and / or gNB 180C).
[0063] [0063] WTRUs 102a, 102b, 102c can communicate with gNBs 180a, 180b, 180c using transmissions associated with scalable numerology. For example, the spacing of OFDM symbols and / or spacing of OFDM subcarriers may vary for different transmissions, different cells, and / or different portions of the wireless transmission spectrum. WTRUs 102a, 102b, 102c can communicate with gNBs 180a, 180b, 180c using subframe or transmission time slots
[0064] [0064] The gNBs 180a, 180b and 180c can be configured to communicate with WTRUs 102a, 102b, 102c in an autonomous configuration and / or a non-autonomous configuration. In the standalone configuration, WTRUs 102a, 102b, 102c can communicate with gNBs 180a, 180b, 180c without also accessing other RANs (for example, such as eNode-Bs 160a, 160b, 160c). In the standalone configuration, WTRUs 102a, 102b, 102c can use one or more of the gNBs 180a, 180b, 180c as a mobility anchor point. In the standalone configuration, WTRUs 102a, 102b, 102c can communicate with gNBs 180a, 180b, 180c using signals in an unlicensed band. In a non-autonomous configuration, WTRUs 102a, 102b, 102c can communicate with / connect with gNBs 180a, 180b, 180c while also communicating with / connecting to another RAN such as eNode-Bs 160a, 160b, 160C. For example, WTRUs 102a, 102b, 102c can implement DC principles to communicate with one or more gNBs 180a, 180b, 180c and one or more eNode-Bs 160a, 160b, 160c substantially simultaneously. In the non-autonomous configuration, eNode-Bs 160a, 160b, 160c can serve as a mobility anchor for WTRUs 102a, 102b, 102c and gNBs 180a, 180b, 180c can provide additional coverage and / or processing power for maintenance of WTRUs 102a , 102b, 102c.
[0065] [0065] Each of the gNBs 180a, 180b, 180c can be associated with a particular cell (not shown) and can be configured to support radio resource management decisions, delivery decisions, UL and user scheduling / or DL, slicing network support, double connections, number interconnection and E-UTRA, user plane data routing to the user plane function ("UPF") 184a, 184b, routing information control plan for the access and mobility management function ("AMF") 182a, 182b, and the like. As shown in Figure 1D, gNBs 180a, 180b, 180c can communicate with each other via an Xn interface.
[0066] [0066] CN 115 shown in Figure 1D can include at least one AMF 182a, 182b, at least one UPF 184a, 184b, at least one session management function ("SMF" - session management function) 183a, 183b and possibly a data network ("DN '" - data network) 185a, 185b. Although each of the aforementioned elements is shown as part of CN 115, it must be considered that any of these elements may belong to and / or be operated by an entity other than the operator of the CN.
[0067] [0067] AMF 182a, 182b can be connected to each of the gNBs 180a, 180b, 180c on RAN 113 via an N2 interface, and can serve as a control node. For example, AMF 182a, 182b may be responsible for authenticating users of WTRUs 102a, 102b, 102c, support for network division (for example, handling different protocol data unit sessions ("PDU") ) with different requirements), selecting an SMF 183a, 183b, registration area management, termination of network-attached storage ("NAS") signaling, mobility management and the like. The network split can be used by AMF 182a, 182b to customize CN support for WTRUs 102a, 102b, 102c based on the types of services that are used by WTRUs 102a, 102b, 102c. For example, different network slices can be established for different use cases such as services that rely on ultra reliable low latency access ("URLLC" - services that rely on mass mobile broadband access (" eMBB '"- enhanced massive mobile broadband), services for machine type communication access (MTC) and / or similar. AMF 162 can provide a control plan function to switch between RAN 113 and other RANs (not shown) that employ other radio technologies, such as LTE, LTE-A, LTE-A Pro and / or non-3GPP access technologies like Wi-Fi.
[0068] [0068] SMF 183a, 183b can be connected to an AMF 182a, 182b on CN 115 via an NI11 interface. SMF 183a, 183b can also be connected to an UPF 184a, 184b on CN 115 via an N4 interface. SMF 183a, 183b can select and control UPF 184a, 184b and configure traffic routing through UPF 184a, 184b. SMF 183a and 183b can perform other functions, such as managing and assigning the WTRU's IP address, managing PDU sessions, controlling the application of policies and QoS, providing downlink and similar data notifications. A type of PDU session can be IP based, non-IP based, Ethernet based and the like.
[0069] [0069] UPF 184a, 184b can be connected to one or more of the gNBs 180a, 180b, 180c on RAN 113 through an N3 interface, which can provide WTRUs 102a, 102b, 102c with access to packet switched networks, as Internet 110, to facilitate communications between WTRUs 102a, 102b, 102c and IP-enabled devices. UPF 184 and 184b can perform other functions, such as packet routing and forwarding, application of user plan policies, support for multi-base PDU sessions, handling of user plan QoS, temporary storage of downlink packets, provisioning anchoring systems and the like.
[0070] [0070] CN 115 can facilitate communication with other networks. For example, CN 115 can include, or can communicate with, an IP communication port (for example, an IP multimedia subsystem (IMS) server) that serves as an interface between CN 115 and PSTN 108. In addition In addition, CN 115 can provide WTRUs 102a, 102b, 102c access to other networks 112, which may include other wired and / or wireless networks that are owned and / or operated by other service providers. In one embodiment, WTRUs 102a, 102b, 102c can be connected to a local data network (DN) 185a, 185b via UPF 184a, 184b via the N3 interface to UPF 184a, 184b and an N6 interface between UPF 184a , 184b and DN 185a, 185b.
[0071] [0071] In view of Figures 1A to 1D and the corresponding description of Figures 1A to 1D, one or more, or all, of the functions described in the present invention in relation to one or more of: WTRU 102a-d, base 114a-b, eNode B 160a-c, MME 162, SGW 164, PGW 166, gNB 180a-c, AMF 182a-ab, UPF 184a-b, SMF 183a-b, DN 185a-be / and any other devices here described can be performed by one or more emulation devices (not shown). Emulation devices can be one or more devices configured to emulate one or more, or all, the functions described here. For example, emulation devices can be used to test other devices and / or to simulate network and / or WTRU functions.
[0072] [0072] Emulation devices can be designed to implement one or more tests of other devices in a laboratory environment and / or in an operator network environment. For example, the one or more emulation devices can perform one or more, or all, of the functions while being fully or partially implemented / deployed as part of a wired and / or wireless communication network in order to to test other devices within the communication network. The one or more emulation devices can perform one or more, or all, of the functions while they are temporarily implemented / deployed as part of a wired and / or wireless communication network. The emulation device can be directly attached to another device for testing purposes and / or can perform tests using wireless communication over the air.
[0073] [0073] The one or more emulation devices can perform one or more, including all, functions while they are not implemented / deployed as part of a wired and / or wireless communication network. For example, emulation devices can be used in a test scenario in a test lab and / or on a wired and / or wireless wireless communication network (for example, test) to implement testing of one or more components. The one or more emulation devices can be test equipment. Direct RF coupling and / or wireless communications via RF circuits (for example, which may include one or more antennas) can be used by emulation devices to transmit and / or receive data.
[0074] [0074] The new radio (NR) can be operable with current and future wireless mobile communication systems. NR use cases can include, for example, eMBB, ultra-reliable and low latency communications (URLLC, ultra high reliability and low latency communications) and mass machine type communications (mMmMTC, massive machine type communications). NR can support transmission in high frequency bands, such as centimeter wave frequencies (wave in cm) and / or millimeter wave (wave in mm). The operation in wave frequency bands in hundred and / or wave in mm can present challenges related to propagation, for example, in view of a loss of higher trajectory and shading.
[0075] [0075] High reliability services can be supported, for example, by very low block error rates, for example in the order of 0.001%. The lowest error rates can be achieved, for example, with greater reliability for physical layer control information (for example, hybrid automatic request recognition (HARQ-ACK, or HARQ ACK), uplink leases and assignments of downlink). In one example (for example, for HARQ ACK) a probability of misinterpreting a NACK as an ACK at a level of 0.1% may be adequate for some mobile broadband services (for example, general services), but may be too large, for example for ultra-reliable services (when, for example, an event of misinterpretation of negative recognition (NACK) as positive recognition (ACK) can result in the loss of a transport block).
[0076] [0076] A WTRU can be configured for multiple simultaneous transmissions. The NR can support a WTRU configuration that can include one or more cells for a given MAC entity and / or for multiple MAC entities. A single cell configuration can provide single cell operation. A multiple cell configuration can provide carrier aggregation (CA), for example CA operation by NR. A configuration of multiple MAC entities can include dual connectivity (DC, dual connectivity) to NR (DC to NR). A configuration of multiple MAC entities can provide a combination of LTE and NR (for example, dual connectivity to the evolved UMTS terrestrial radio access network (E-UTRAN) and Novo Rádio e (EN-DO)). The NR can provide a WTRU configuration comprising a cell configured with a downlink carrier, an uplink carrier and a complementary uplink carrier (SOUTH). The NR can support a cell configured with one or more parts of bandwidth (BWPs). A BWP can be characterized by at least one of a frequency location (for example, a central frequency and / or a frequency bandwidth) or a numerology.
[0077] [0077] For EN-DC, CA by NR and DC by NR in licensed bands, various combinations (for example, different combinations) of carriers can introduce different timing relationships (for example, different timing relationships) between transmissions associated with a WTRU (or between transmissions that can at least partially overlap in time) in terms of one or more among numerology, transmission start time or transmission duration. For example, each of the configured component carriers (downlink (DL) and / or uplink (UL)) and / or parts of bandwidth (BWPs) (DL and / or UL) for a WTRU can have the same numerology or a different numerology, and the overlapping transmissions between different component / BWP carriers can have the same start time or a different start time; and the same uplink shared physical channel (PUSCH) transmission duration / uplink control physical channel (PUCCH) or a different transmission duration.
[0078] [0078] The timing and / or scheduling aspects can be provided, for example, in the case of asynchronous transmissions and / or in cases of partial and / or complete overlap between different uplink transmissions associated with a WTRU. In one example, different broadcasts may operate with different HARQ timelines, for example based on dynamic scheduling information. For example, such scheduling information may include delay components related to dynamically variable scheduling. The delay components related to dynamically variable scheduling can be provided through downlink control (DCI) information. Scheduling-related delay components can include one or more of K1, K2, NI or N2. K1 can be a delay between a data reception (PDSCH) of a downlink (DL) and its corresponding transmission of ACK on the uplink (UL). K2 can be a delay between an UL grant reception in DL and an UL data transmission (e.g., PUSCH transmission). N1 can be several OFDM symbols used for WTRU processing between the end of NR-PDSCH reception and the closest possible start to the corresponding ACK / NACK transmission, for example, from the perspective of the WTRU. N2 can be several OFDM symbols used for WTRU processing between the end of
[0079] [0079] A scheduler can adjust an error probability of control information, for example by selecting transmission power parameters (for example, associated with an uplink transmission) and / or aggregation level (for example, associated with a downlink transmission). Getting very low error rates can be problematic.
[0080] [0080] In one example, very low error rates may not be achieved by adjusting the parameter using transmission techniques, for example when there is interference with peak activity and / or other channel problems (for example, heavy shading millimeter wave frequencies).
[0081] [0081] The efficiency of the spectrum and the processing capacity of the user can be severely degraded, for example when operating at very low levels of error rates, since a significantly greater number of resources (time, frequency and / or power) ) can be consumed, compared to the situation in which typical error rates operate, when such techniques are applied to one or more types of transmissions. Differentiated processing between ultra-reliable transmissions and other transmissions (for example, segregation of resources) may be less efficient, for example, since there may be ultra-reliable traffic with peak activity.
[0082] [0082] Very low error rates (for example, for ultra-reliable services) can be obtained. Efficient operation can be achieved (for example, in a system and / or a WTRU) with ultra-reliable mobile broadband data traffic and others (for example, non-ultra-reliable).
[0083] [0083] Uplink control (UCI) information can comprise, for example, HARQ feedback (eg, HARQ ACK), scheduling request (SR) and / or channel status information (CSI). The UCI can be transmitted via an uplink control channel (for example, a physical uplink control channel (PUCCH)) and / or an uplink data channel (for example, a shared physical channel of uplink (PUSCH)). The UCI can be transmitted with or without multiplexing with uplink data. HARQ feedback information (for example, HARQ ACK) may belong to the transport block (s), code block (s) and / or group (s) ) of code block (s).
[0084] [0084] Downlink control (DCI) information can refer to physical control signaling that can be received from a network (for example, uplink leases, downlink assignments, power control commands, power indicators interval format, HARQ information, and so on). The DCI can be transmitted, for example, through a downlink control channel (for example, PDCCH) (for example, in a common or specific WTRU search space or through a common group control channel (for example, PDCCH)). A PDCCH can be mapped to resources from a set of control resources (CORESET). A WTRU may attempt to decode the PDCCH, for example from one or more search spaces within a CORESET. A WTRU can be configured, for example, with at least one CORESET.
[0085] [0085] A diversity of DCI can be provided. In one example, the reliability of DCI transmission can be increased, for example, by transmitting multiple occurrences of DCI through separate resources in the domains of time, frequency and / or space. Multiple occurrences can provide a gain in diversity against short-term fading, long-term fading and / or interference.
[0086] [0086] A DCI (for example, each occurrence of DCI) can be transmitted over a physical downlink control channel (for example, a PDCCH, common group PDCCH, PHICH and so on). An occurrence can be transmitted via the PDSCH (for example, when the DCI in the PDSCH can be supported). A PDCCH (for example, each PDCCH) can be received based on a CORESET that can be configured by higher layers. A configuration can include one or more parameters. For example, a configuration can include a component carrier or a serving cell, one or more parts of bandwidth (BWPs), a subset of resource blocks within a BWP (for example, each BWP), a set of symbols of time within an interval or a mini-interval, a spacing of subcarriers, a subset of intervals within a subframe and / or one or more reference signals (for example, CSI-RS). An Independent configuration of one or more parameters can provide diversity in time, frequency and / or space. In one example, frequency diversity can be provided (for example, by configuring different component carriers or BWPs between CORESETs) with or without providing diversity of space and / or time (for example, by configuring different sets of weather symbols and / or different reference signs).
[0087] [0087] A diversity of DCI can be configurable. For example, DCI diversity can be enabled or disabled. Enabling or disabling DCI diversity, for example, can be based on MAC layer signaling or physical layer signaling. In one example, a WTRU can receive an activation command based on a first CORESET to start monitoring a second occurrence of DCI on the second CORESET. A WTRU can receive a deactivation command to monitor an occurrence of DCI on a specific CORESET.
[0088] [0088] A variety of DCI can be applied. The content of an DCI instance (for example, each DCI instance) can be configured according to one or more of the following: (1) the same content transmitted through multiple DCI occurrences (eg, repetition); (11) the same content transmitted by multiple DCI occurrences (for example, block encoding), or (111) nature of the content.
[0089] [0089] In an example, each of the multiple occurrences of DCI can include and encode the same bits of information for at least one type or format of DCI (for example, ACK from HARQ to PUSCH, assignment of PDSCH, grant of PUSCH) . A DCI can be decodable (for example, completely decodable) upon receipt of an occurrence (for example, a single occurrence).
[0090] [0090] In one example, a DCI can be encoded, for example, by segmenting the DCI into N blocks and encoding the DCI into D blocks. In one example, decoding at least N of the DCI D occurrences (for example, at a receiver) may be sufficient to recover the entire DCI. In one example, the encoding can consist of a parity code.
[0091] [0091] In one example, DCI occurrences may include one or more of the following: information associated with at least one DL data transmission through the PDSCH or information associated with at least one UL data transmission through the PUSCH.
[0092] [0092] In one example, a WTRU can be configured to monitor the PDCCH through multiple CORESETs (for example, two CORESETs). The WTRU can monitor the PDCCH on different carriers or parts of bandwidth. A WTRU can receive, for example, multiple occurrences of DCI (for example, up to two occurrences of DCI). In one example, DCI instances can include the same information received by the WTRU through the PDCCH on multiple carriers (for example, each carrier can be received on one carrier, in a case of multiple DCI). Information about a DCI (for example, each DCI) can include PDSCH (or PUSCH) assignments / grants to multiple carriers (for example, both carriers). A WTRU can receive the PDSCH or transmit the PUSCH on multiple carriers (for example, both carriers), for example, even in the case where, for example, one of the DCI occurrences may not be successfully decoded. A very low BLER can be achieved with low latency, for example when multiple PSDCH transmissions (for example, both PDSCH transmissions) or PUSCH transmissions can be encoded in the same transport block, for example, since DCI and the data can be (for example, are) independently protected by diversity, as illustrated, for example, in Figure 2. As shown in Figure 2, the DCI on the downlink component carrier 1 (DL CC1) 202 and the DCI on downlink component carrier 2 (DL CC2) 204 can have the same content. For example, each DCI can include information associated with the PDSCH 206 and PSDCH
[0093] [0093] A DCI index can be provided. In one example, a DCI instance (for example, each DCI instance) can include a field (for example, the DCI index) that can identify the content of the DCI. A WTRU can discard DCI instances that may include the same information. Duplicate DCIs can be discarded to reduce processing. In one example, a WTRU can receive a first occurrence of DCI with a first value from the DCI index. A WTRU can receive subsequent occurrences of DCI that may include the same value as the DCI index (for example, within a set of CORESETs in which a diversity of DCI can be configured within a period of time). A WTRU can (for example, after receipt) discard subsequent occurrences of DCI. A WTRU can use a DCI index, for example, to differentiate between a diversity of DCI and a DCI that may include new information.
[0094] [0094] A variety of UCI's can be provided. The transmission reliability of the UCI can be increased, for example, by the transmission of multiple occurrences through resources that can be separated into one or more of the following domains: time, frequency or space. Multiple instances of UCI can, for example, provide a gain in diversity against short-term fading, long-term fading and / or interference. One UCI instance (for example, each UCI instance) can be transmitted via a physical uplink control channel (PUCCH) or a physical uplink shared channel (PUSCH). In one example, UCI diversity may be applicable to certain types of UCI (for example, HARQ ACK).
[0095] [0095] In one example, UCI instances can be transmitted by multiple carriers and / or parts of bandwidth in which a WTRU can be configured to operate. As shown in Figure 3, the same HARQ ACK information that may be related to a downlink assignment (for example, received in an earlier 302 interval) can be transmitted by multiple occurrences of PUCCH (for example, two occurrences of PUCCH 306 and 308). The two occurrences of PUCCH can include a first occurrence of UCI 306 that can be transmitted on a component carrier of UL 1 (CC1) 310 and a second occurrence of UCI 308 that can be transmitted on a component carrier of UL 2 (CC2) 312. The UCI can be transmitted in the range 2 304. Each of the first UCI 306 occurrences and the second UCI 308 occurrences can include similar information (for example, the same HARQ ACK-NACK information).
[0096] [0096] Figure 3 is an example of the implementation of a diversity of DCI and a diversity of UCI. In one example, a UCI instance (for example, each of the UCI instances) may include the transmission of an OFDM symbol (for example, a single OFDM symbol) in adjacent symbols (for example, using the PUCCH format) I enjoy). Other examples in the time domain may include, for example, transmission in the same OFDM symbol or transmission at different intervals. The resources (for example, RB, time symbol, interval, etc.) that can be occupied by one UCI instance (for example, each UCI instance) can be configured independently.
[0097] [0097] In one example, UCI occurrences can be transmitted over multiple beams. For example, multiple beams can be transmitted using different precoders. A WTRU can be configured for beam determination associated with a UCI instance (for example, each UCI instance). A WTRU can be configured with information that includes one or more of the following: a beam index, a beam process identity, an SRS indicator, or a CSI-RS indicator (for example, when beam matching exists) etc. The information used by the WTRU for beam determination (for example, for PUCCH) can be configured by higher layers for one UCI instance (for example, each UCI instance) or can be indicated in a DCI that can include a ACK / NACK resource indicator (ARI, acknowledgment / non-acknowledgment resource indicator). The information used by the WTRU for beam determination (for example, for PUSCH) can be indicated by a DCI which may include a lease associated with a beam.
[0098] [0098] The information used by the WTRU for beam determination can be derived (for example, implicitly derived) from a PDCCH that can include an assignment. In one example, a beam associated with the transmission of a PUCCH instance can be derived from a reference signal (for example, a channel status information reference signal (CSI-RS)), or a beam indicator that can be associated with a set of control resources or a PDCCH transmission that may include an assignment. This approach can be used, for example, when a diversity of PDCCH (or diversity of DCI) can be used in addition to diversity of UCI. A WTRU can transmit a PUCCH instance (for example, a single PUCCH instance) to a received PDCCH instance (for example, each PDCCH instance received). The occurrence of PDCCH can include an assignment, for example when and / or how the UCI can be transmitted through the PUCCH.
[0099] [0099] A complementary uplink (SOUTH) can be provided. In one example, a WTRU can be configured with a SOUTH carrier for at least one server cell. The WTRU can be configured to transmit a UCI that includes, for example, a scheduling request (SR), channel status information (CSD, or an ACK / NACK of HARQ. The UCI can be transmitted over the normal UL carrier and by the SUL carrier associated with the serving cell.
[00100] [00100] The UCI diversity can be applied. The content of one UCI instance (for example, each UCI instance) can be configured, for example, according to one or more of the following: (1) whether the same content must be transmitted by each of the multiple occurrences of UCI UCI (for example, repetition); (il) if the same content must be transmitted by UCI occurrences (for example, block encoding); or (iii) the nature of the content.
[00101] [00101] In one example, an instance of UCI (for example, each instance of UCLI) can include and encode the same bits of information for at least one type of UCI (for example, ACK of HARQ). A UCI can be decodable upon receipt of a single occurrence. In one example,
[00102] [00102] In an example (for example, where DCI diversity may not be applied), a UCI may include a set of ACK bits from HARQ. An association between a specific HARQ ACK bit and a transport block reception result can be determined, for example, based on a downlink assignment index.
[00103] [00103] In an example (for example, where DCI diversity can be applied), a set of HARQ ACK bits can be generated and transmitted, for example, for each of the DCI occurrences that can be configured to be received in diversity (for example, based on the same content). This can happen for example, regardless of whether an DCI instance can be successfully decoded. A WTRU can report the NACK for transport blocks that correspond to a DCI instance that may not be received, for example, when the WTRU is configured to receive multiple DCI instances (for example, two DCI instances) in diversity, but receives less than the configured DCI instances (for example, two configured DCI instances). The report can be made, for example, when a WTRU receives at least one occurrence of DCI. A network may be allowed to determine lost assignments from one DCI instance (for example, each DCI instance). Determining lost assignments can be useful for adapting the PDCCH link.
[00104] [00104] In one example, DCI diversity can be applied. A WTRU can report a set of HARQ ACK bits for a set of DCI instances that can be configured to be received in diversity, for example, when the WTRU receives at least one DCI instance. A WTRU can report an indication of a subset of DCI occurrences that can be successfully decoded within a diversity set of DCI occurrences.
[00105] [00105] A WTRU can receive more than one DCI that can indicate DL data for the same HARQ process and transport block (s). DCIs can be coded using different versions of redundancy. A WTRU can report one HARQ ACK bit per transport block (for example, regardless of the number of PDSCH occurrences received that may include data for the transport block). A WTRU can transmit one HARQ ACK bit per transport block and one PDSCH instance that can include data from the transport block (for example, with the same value).
[00106] [00106] Power control with UCI diversity can be provided. The transmission power associated with a transmission (for example, a PUCCH transmission or a PUSCH transmission) can be adjusted independently, for example, when UCI diversity is applied. For example, a separate configuration of one or more reference signals can be used to estimate path loss, and other parameters can be used to determine the transmission power.
[00107] [00107] A power control with the diversity of UCI for the determination of transmission power control (TCP, transmit power control) can be provided. A WTRU can determine a TCP command that can be applied to a transmission for which UCI diversity can be applied.
[00108] [00108] In an example of determining TCP, a WTRU can apply similar TCP adjustment to each of the multiple transmissions of UCI occurrences. A TCP setting can be received, for example, from a DCI that can be associated with a UCI transmission. For example,
[00109] [00109] In an exemplary TCP determination, a WTRU may apply a separate TCP adjustment to each of the multiple UCI occurrence transmissions. A TCP setting (for example, each TCP setting) can be received, for example through a DCI that can be associated with a UCI transmission. In one example, an associated DCI can include two TCP tuning values, for example when a UCI diversity can be configured using two transmissions.
[00110] [00110] In an exemplary TCP determination, a WTRU can apply a separate TCP adjustment to each of the UCI occurrence transmissions. A TCP adjustment can be received for each of the UCI occurrences, for example through a specific DCI occurrence that can be associated with the UCI occurrence.
[00111] [00111] A power control with power control modes, for example for carrier aggregation (CA) and / or dual connectivity (DOC), can be provided. In one example, a WTRU can apply a priority level to a transmission that can include UCI, for example when UCI diversity is enabled. The WTRU can apply the priority level, for example if configured with a power control mode (PCM). The WTRU can be configured to group one or more types of transmissions. The WTRU can be configured to assign at least a quantity (for example, a fraction) of the total available power of the WTRU to a group of transmissions, for example with a guaranteed minimum power. The WTRU can determine that transmissions that include UCI are part of the same transmission group. The WTRU can perform such a grouping, for example if the UCI is associated with a transmission profile. For example, this transmission profile may correspond to an ultra-reliable, low-latency communication transmission type (URLLCO). The WTRU may give such a group of transmissions a higher priority than other data transmissions (for example, data transmissions associated with a transmission profile that corresponds to the type of non-URLLC transmission). In a WTRU configured with CA, for example a transmission that includes at least some UCIs generated when applying the UCI diversity, may have a higher priority in relation to other transmissions for a given MAC instance. For a WTRU configured with DC and / or with multiple transmission groups, for example, a transmission group (or a group of cells) with at least one transmission including at least some UCIs (generated, for example when a diversity of UCI) may have a higher priority than other group (s).
[00112] [00112] Resource allocation can be provided with the diversity of UCIs using PUCCH. A resource and format of a PUCCH transmission can be determined (for example, when an instance of UCI is transmitted through PUCCH), for example, according to one or more exemplary procedures. In one example, a WTRU can be configured with one or more combinations of PUCCH resources. A PUCCH resource (for example, each PUCCH resource) can correspond to a resource by which an UCI instance can be transmitted. In one example (for example, with two instances of UCI), a combination can be defined as index # 24 of PUCCH resource in a first CC or part of bandwidth and index # 13 of PUCCH resource in a second CC or part of bandwidth. A combination can be called a PUCCH diversity resource or a super PUCCH diversity resource. A WTRU can be configured (for example, by higher layers) with more than one PUCCH diversity feature. The diversity feature of PUCCH can be indicated in a field (for example, ARI field) of an associated DCI. A WTRU can be configured (for example, by higher layers) with a pool. The pool can include normal PUCCH resources and PUCCH diversity resources that can enable a network to control (for example, dynamically) the use of UCL diversity.
[00113] [00113] In one example, a WTRU can be configured with DCI diversity in addition to UCI diversity. A WTRU can transmit a UCI instance on a resource that can be indicated by an associated DCI instance. A DCI instance (for example, each DCI instance) can comprise an ARI that can indicate a PUCCH resource. A WTRU can transmit a UCI instance, for example when the WTRU may have received a corresponding DCI instance.
[00114] [00114] DTX feedback transmission can be provided. In one example, a WTRU can transmit HARQ ACK information on a specific PUCCH resource. The HARQ ACK may indicate (for example, explicitly) that a DL transmission or a DL assignment has not been received (for example, in the case of batch transmission (DTX)) from a specific CORESET in a given interval or mini-interval . The timing of a PUCCH resource can be obtained, for example, from an interval or mini-interval timing where a DL assignment has not been received.
[00115] [00115] A PUCCH interference randomization can be provided. In one example, a PUCCH transmission from two or more WTRUs to two or more transmit / receive points (TRPs) may collide. Interference randomization can be used, for example, to reduce the effect of a highly interfering PUCCH transmission on an interfering PUCCH transmission. Interference randomization can be used, for example, by a pair of WTRUSs to avoid using PUCCH collision features.
[00116] [00116] Interference randomization can be used to increase transmission diversity. Interference randomization may include, for example, one or more of the following hopping features: a beam hop or pair of transmit beams, hop PUCCH symbols within a range or between intervals or hop a pattern duplication.
[00117] [00117] In an example of jump features, the jump can be done within a BWP or by multiple BWPs. A PUCCH transmission (for example, each PUCCH transmission) can, for example, traverse a pattern of frequency resources. In one example, a jump can be performed within a PUCCH transmission.
[00118] [00118] In an example of skipping a beam or pair of transmission beams, PUCCH transmissions can complete a cycle between a set of beams. In one example, cycling between beams can be performed, for example, using one beam per set of PUCCH symbols within a PUCCH transmission. In an example of jumping PUCCH symbols within a range or across ranges, a short PUCCH can occupy different symbols in a range for each of the multiple PUCCH transmissions.
[00119] [00119] In an example of jumping a duplication pattern, a PUCCH transmission (for example, each PUCCH transmission) can use multiple duplications. Each duplication can use different resources. A subsequent PUCCH transmission (for example, each subsequent PUCCH transmission) can use a different set (for example, a different set) of resources. The different sets of resources can be used to enable multiple duplications.
[00120] [00120] The use of interference randomization and / or jump patterns may be indicated for a WTRU. For example, such use of interference randomization and / or jump patterns may be indicated
[00121] [00121] A configuration of PUCCH resources can be provided. A WTRU can be configured to use one or more formats or types of PUCCH formats (for example, a short PUCCH or a long PUCCH). A WTRU can be configured with parameters associated with one or more PUCCH formats. A configuration of PUCCH resources can be provided, for example semi-statically.
[00122] [00122] The configuration of PUCCH resources can include, for example, one or more of: (1) a PUCCH format (for example, a short PUCCH format or a long PUCCH format); (1) a PUCCH duration in symbols (for example, short PUCCH and long PUCCH duration of 1 or 2 symbols); (1ii) a waveform used for PUCCH transmission (for example, cyclic prefix based orthogonal frequency division multiplexing based on orthogonal frequency division multiplexing) or expanded transform orthogonal frequency division multiplexing Distinct Fourier (DFT-s-OFDM, discrete Fourier transform spread orthogonal frequency division multiplexing)); (1v) a numerology used for PUCCH (for example, spacing of subcarriers, a type of CP etc.); (v) a time location (for example, a symbol location within a range where the PUCCH can be transmitted); (vi) a frequency location (for example, subcarriers, PRBs, part of bandwidth (BWP)); (vii) a frequency interlacing index (for example, used to activate FDMs of multiple PUCCHs in the same PRB or BWP, where a PUCCH transmission can be assigned to one or more interlaces within a PRB or BWP); (viii) hop pattern (s) (for example, for hop within a PUCCH transmission or between PUCCH transmissions); (ix) a bundle or pair of bundles; (x) a duplication pattern (for example, for a PUCCH transmission that can be duplicated by multiple resources); (xi) an orthogonal cover code (OCC) (for example, it can include whether or not the OCC applies over time or from subcarrier elements); (xii) a cyclical shift; or (xiii) a transmission diversity scheme.
[00123] [00123] A frequency location can include, for example, a frequency assignment where a PUCCH can be transmitted. A frequency location can be provided, for example, as an offset value. An offset can be applied, for example, to a frequency location of a PDCCH that can configure a PUCCH, or a PDSCH by assigning a PDCCH or a PDSCH. An offset can be applied to a frequency location of a concomitant PUSCH. A frequency location can include, for example, a set of subcarriers, PRBs and / or BWPs. A set can be used to indicate (for example, dynamically indicate) a frequency location for a PUCCH transmission occurrence (for example, each PUCCH transmission occurrence). A set can be used, for example, to allow diversity of frequencies through repetition. A set can be used, for example, to make it possible to skip frequencies.
[00124] [00124] A configuration (for example, including a duplication pattern) can include a set of resources through which a PUCCH transmission can be duplicated. Different duplication patterns can be selected (for example, dynamically selected).
[00125] [00125] A semi-static configuration can include one or more tables. A table can include a set of code points and a set of PUCCH configurations that can be linked to each code point in the set of code points. In one example, a first table can include settings for short PUCCH transmissions and a second table can include settings for long PUCCH transmissions. In one example, a table can be applicable to multiple PUCCH durations and PUCCH formats.
[00126] [00126] A dynamic indication of the PUCCH configuration can be provided. In an example, an indication (for example, a dynamic indication) can be provided (for example, for a WTRU) indicating a combination of PUCCH configurations for transmitting UCI, such as HARQ or CSI A / N. A dynamic indication can include, for example, a table index and a code point index to be used within the table. In one example, a dynamic indication can be provided (for example, implicitly provided). For example, the dynamic indication can be provided as a function of a transmission (for example, as a function of a parameter of a PDCCH transmission or a PDSCH transmission). In one example, a hybrid procedure can be used. A WTRU can determine a PUCCH configuration, for example, based on a combination of an explicit index and an implicit relationship. In one example, a WTRU can dynamically determine a PUCCH configuration. In one example, a WTRU can determine a first set of configurations or a table of PUCCH configurations and can determine a second set of configurations or a code point within a table. For example, the PUCCH settings table can be determined implicitly, and a second set of settings or a code point can be determined explicitly.
[00127] [00127] An implied indication may include one or more of the following: (1) an interval size, an UL / DL configuration of an interval, (ill) a type of service, (iv) a UCI multiplexing, (v ) feedback timing, (vi) feedback type, or (vii) collision of different types of feedback. In an example of a gap size, a mini gap can indicate the use of a short PUCCH or a normal range can indicate the use of a long PUCCH. In an example of a one-time UL / DL configuration, a WTRU can determine a type of PUCCH (for example, short or long) or a long-term PUCCH, for example based on the number of symbols assigned for UL transmissions. In an example of a service type, the URLLC may involve a PUCCH to HARQ format that can provide greater reliability. In one example, URLLC streams may require PUCCH diversity. In an example of UCI multiplexing, the transmission of HARQ linked to multiple TBs (transport blocks) (for example, due to multiple carriers or gap aggregation) may have a higher capacity PUCCH format. In an example of feedback feedback, a feedback feedback that uses an offset less than a threshold may use a first PUCCH table, while a feedback delay that uses an offset greater than the threshold can use a second PUCCH table. In one example, a short PUCCH can be used, for example, for a self-contained interval where feedback can be provided in the same interval as DL data. In an example of a feedback type, HARQ feedback can use a first PUCCH configuration, while CSI can use a second PUCCH configuration. In one example, HARQ feedback based on transport block (TB) can use a first PUCCH configuration (for example, a short PUCCH) and HARQ feedback from a group of code blocks based on (CBG) can use a second PUCCH configuration. In an example of a collision between different types of feedback (for example, associated with different types of services), a PUCCH setting for a higher priority type of service can be used. In one example, feedback multiplexing can be used in PUCCH configurations for URLLC service for example when eMBB HARQ feedback can collide with URLLC HARQ feedback.
[00128] [00128] The feedback feedback based on the PUCCH configuration can be provided. In one example, a WTRU can determine a type of feedback based on the PUCCH setting to be used for feedback. A WTRU that is assigned with short PUCCH resources can, for example, determine that a TB-based HARQ feedback may be required for a PDSCH transmission. A WTRU that is assigned with long PUCCH resources may, for example, determine that a CBG-based HARQ feedback may be required. In one example, a WTRU can determine a type of CSI feedback, for example, based on a PUCCH configuration.
[00129] [00129] PUCCH transmissions can be multiplexed. In one example, a WTRU can be configured to multiplex multiple PUCCH transmissions. Multiplexing can be achieved, for example, by assigning multiple PUCCH transmissions on the same resources. A WTRU can be assigned with interlacing of different frequencies, hop patterns and / or orthogonal coverage code (OCC) for each of the multiple PUCCH transmissions.
[00130] [00130] A WTRU can be assigned with resources for multiple PUCCH transmissions. Resources, for example, can be collision resources. In one example, a WTRU can multiplex multiple UCIs on the same PUCCH resources. In one example, a WTRU may have a priority rating associated with the UCIs. The WTRU can discard UCI or feedback with a lower priority. In one example, a WTRU can have a priority rating associated with UCls and can use PUCCH resources for the top priority UCI and can use another set of PUCCH resources (for example, a fallback set of PUCCH resources) to another UCI transmission. In one example, a WTRU can use PUCCH reserve resources for multiple UCI transmissions. In one example, each of the multiple UCIs can be assigned to a different reserve resource. Reserve resources can enable multiplexing (for example, efficient multiplexing). In one example, a PUCCH configuration for an UCI may not use interlacing. In one example, a standby configuration may use standard interlacing that can enable multiplexing. In one example, a PUCCH configuration for an UCI may include a BWP offset (for example, in the event of a collision with another UCI transmission). In one example, the short PUCCH configuration timing (for example, symbol location (s)) may depend on whether a UCI transmission may or may not notice a collision. In one example, the PUCCH jump setting may depend on whether a collision occurs or not.
[00131] [00131] Differentiated processing can be provided. The determination of a profile applicable to a transmission can be provided. A WTRU can process and transmit UCI, for example, according to a transmission profile (for example, a certain transmission profile) that can be associated with the UCI. A transmission profile can be determined, for example, so that an amount of resources and prioritization can satisfy objective reliability for a UCI. This determination of a transmission profile can enable efficient use of resources.
[00132] [00132] In one example, a transmission profile can be associated with uplink data or side link data. For example, a transmission profile associated with uplink data or side link data can be used to enable prioritization between uplink or side link data and UCIs of different profiles.
[00133] [00133] It is possible to determine the transmission profile applicable to DCI, UCI or data. In one example, a UCI-associated transmission profile may be equivalent to or determined from, for example, one or more of the following: (1) a transmission profile for an associated downlink data transmission (for example, for a HARQ ACK or a CSFIJ); (11) a transmission profile for an associated uplink data transmission (for example, for an SR); or (ii) a portion of the bandwidth on which the UCI is transmitted.
[00134] [00134] A transmission profile associated with UCI or uplink data can be determined, for example, based on one or more of the following: (1) a logical channel, or group of logical channels, from which data can be transmitted based on the highest layer configuration (for example, a transmission profile can be configured for each logical channel or group of logical channels, or the WTRU can determine a transmission profile based on a configuration of a logical channel (LCH) for one or more physical layer properties of a given transmission (for example, a transmission duration or similar); (11) a logical channel or group of logical data channels that may have triggered a SR; (11i) a field value in the DCI that may be associated with a UCI transmission or uplink data (for example, an explicit transmission profile indication, or implicitly from an existing field (for example, an Indian HARQ process ce) or a field that can be used for prioritizing the logical channel (for example, for an uplink lease), or a temporary radio network identifier (RNTI) value that can be used to mask a cyclic redundancy check (CRC); (iv) a PDCCH property that may be associated with UCI transmission or uplink data (for example, a CORESET, a monitoring period, a determination of whether the MPDCCH is monitored at the beginning of an interval, a space search level or aggregation level that can be used for decoding PDCCH, or part of the bandwidth), as in the case where a transmission profile can be configured (for example, by higher layers) for a CORESET (for example, each CORESET) or a PDCCH configuration (for example, each PDCCH configuration); (v) higher layer signaling (for example, for CSI) and / or a field in the DCI that can indicate a set of parameters, for example, configured for higher layers (for example, a CSI reporting configuration that can be indicated by an aperiodic CSI field); (vi) a property of, or associated with, the transmission of the PDSCH, such as a duration, a portion of bandwidth, a property of numerology (for example, spacing of subcarriers, a symbol duration, etc.), a state of transmission configuration indication (TCI) (for example, for HARQ ACK), a modulation and coding scheme table (MCS) configured or indicated for the control information (for example, in the DCI) associated with the PDSCH transmission; (vii) a property of, or associated with, the PUCCH resource is configured for the transmission of the SR (such as a spacing of subcarriers, a duration of the PUCCH resource, a logical channel associated with the SR configuration, or a property thereof, such as a priority and / or a transmission profile configured explicitly as part of the SR configuration); (viii) a property of, or associated with, the concession or transmission of PUSCH (for example, for uplink data), for example a property used to determine a logical channel constraint for prioritizing the logical channel (such as a duration PUSCH transmission, a numerology property (for example, sub carrier spacing, symbol duration), or a carrier property); or (1x) a portion of the bandwidth over which a PDSCH transmission or an associated PUSCH transmission is made. With respect to item (iv), a transmission profile can take precedence based on an order of priority that can be configured. For example, a transmission profile can take precedence based on a configured priority order, if a candidate PDCCH is part of the search spaces that are associated with more than one transmission profile. With respect to item (1), a transmission profile associated with a UCI can be determined based on an attribute (for example, a QoS metric) associated with the logical channel, or the group of logical channels, from the which data can be transmitted. With respect to item (v), a BLER target value can be configured for a CSI reporting configuration. The target value of BLER can implicitly indicate a transmission profile. For example, a lower BLER target value may indicate a higher priority transmission profile. In one example, the CQI reporting table can be configured for a CSI reporting configuration.
[00135] [00135] A transmission profile for DCI or downlink data can be determined, for example, based on one or more of the following: (1) a PDCCH property from which the DCI can be decoded or the from which an assignment for downlink data can be decoded, for example, as disclosed herein, into UCI or uplink data (eg, search space, explicit configuration, etc.); (11) a modulation and coding scheme table (MCS) indicated for the control information (for example, in the DCI) that is associated with the transmission of the PDSCH; such indication can be configured by higher layers or can be included in a DCI field; (il) the value of a field in the DCI that can be associated with a downlink data transmission or an RNTI value that can be used to mask a CRC; or (iv) a property of, or associated with, the allocation or transmission of the PDSCH (for example, for downlink data), such as a duration of the transmission of the PDSCH and / or a property of the numerology (for example, a spacing of subcarriers) , a symbol duration, etc.)
[00136] [00136] In one example, a transmission profile can be defined for a physical channel (for example, a PDCCH, PUCCH, PDSCH or PUSCH). A transmission profile can be determined, for example, based on a type of data or control information that can be transported over a physical channel. A transmission profile can be defined based on the highest priority level among the profiles, for example when the transmission of a physical channel includes control information and / or data from different profiles (for example, UCI multiplexed in the PUSCH).
[00137] [00137] The determination of a profile can indicate a timing characteristic. In one example, a transmission profile can be associated with a timing characteristic. Such a timing characteristic can correspond to at least one of the following: (1) scheduling-related delay components, for example such a component can correspond to one within NI or N2; (2) WTRU processing time, for example, such processing time may correspond to one of NI or N2; (3) the initial symbol of a transmission; or (4) the duration of a transmission. NI and / or N2 can represent several OFDM symbols as described in the present disclosure. In one example, a transmission profile can correspond to a transmission for which one or more of such timing characteristics up to a given value can be provided. The specific value can represent an aspect of the configuration of a WTRU. A transmission profile can be associated with at least one priority level or at least one parameter that determines the properties of access to the channel for operation in unlicensed band. For example, the at least one parameter can include a maximum containment window size or a postponement period.
[00138] [00138] The handling of transmission characteristics based on a profile (for example, a transmission profile) can be provided. The aspects of coding, transmission power and / or selection or resource assignment can be determined, for example, based on a transmission profile as described in the present disclosure.
[00139] [00139] In an example, a WTRU can determine one or more aspects that may be related to channel encoding for a physical channel (for example, PDCCH, PDSCH, PUCCH or PUSCH) from a transmission profile. The coding aspects that can be determined may include one or more of the following: (1) a type of code (for example, polar, LDPC, turbo, repetition); (ii) a code fee; (111) a length of a cyclic redundancy check (CRC) that can be attached to a set of information bits for error detection; (iv) a mapping between a modulation and coding scheme (MCS) field, and a modulation order and code rate; or (v) one or more search spaces for one or more levels of aggregation to decode a PDCCH.
[00140] [00140] In one example, a WTRU can be configured with a 16-bit CRC for PDCCH, for example when a higher layer configuration for a PDCCH can indicate a first transmission profile. The WTRU can be configured with a 24-bit CRC, for example, when a configuration can indicate a second transmission profile. The use of the variable size of CRC, for example, can enable a network to use a more reliable PDCCH transmission, when required by the characteristics of the data being transmitted.
[00141] [00141] In one example, an encoding rate that can be applied to at least one type of UCI (for example, ACK of HARQ), may be dependent, for example, on a transmission profile. In one example, the UCI of multiple transmission profiles can be multiplexed in the same transmission (for example, PUCCH). The UCI (for example, each UCI) can be encoded separately, for example with a profile-dependent encoding rate. Such encoding can represent a first stage of encoding. The bits encoded from the first encoding stage associated with each UCI can be concatenated and submitted to a second encoding stage.
[00142] [00142] The transmission power can be determined based on a transmission profile. In one example, a WTRU can determine and apply a transmission power associated with a transmission. A transmission power can be determined using formula and / or parameters that may be dependent on a transmission profile. In one example, the parameters that can be used in a power control formula can be configured (for example, independently configured) for each transmission profile. In one example, a power control configuration can be based on an offset value that can be configured by a transmission profile. In one example, an interpretation of a TCP field (for example, in terms of the number of dBs for up or down adjustments) may be dependent on a transmission profile. The use of a transmission profile to determine transmission power can facilitate the use of an appropriate level of power to achieve a desired reliability associated with a transmission (for example, each transmission).
[00143] [00143] In one example, the power control parameters applied to a transmission of a scheduling request (SR) may depend on an SR configuration. The SR configuration can be mapped to a logical channel that may have triggered the SR.
[00144] [00144] In one example, the power control parameters applied to a HARQ ACK transmission may depend on the duration of the corresponding PDSCH transmission. For example, if a PDSCH transmission is below a threshold configured by higher layers, the WTRU can apply a first set of power control parameters. If a PDSCH transmission is above a threshold, the WTRU can apply a second set of power control parameters.
[00145] [00145] In one example, the power control parameters applied to the HARQ ACK transmission may depend on a UL bandwidth portion (for example, the active bandwidth portion) on which the HARQ ACK is transmitted, or in the DL bandwidth portion on which the corresponding PDSCH is transmitted. Each part of bandwidth can be configured with a set of power control parameters by higher layers.
[00146] [00146] In one example, the power control parameters applied for the transmission of CSI through PUCCH (or PUSCH) can be dependent on the BLER target value configured for the configuration of CSI reports. For example, a WTRU can apply a power shift based on the BLER target value. The BLER target value can be configured by higher layers, for example for each of the BLER target values. A power offset can be configured, for example, for each CSI reporting configuration.
[00147] [00147] Data or UCI of multiple transmission profiles can be multiplexed in the same transmission. The power control parameters for a common transmission can be determined, for example, based on a profile, for example a profile with the highest level of priority.
[00148] [00148] In one example, power control parameters can include a specific power control mode (PCM, power control mode) or a guaranteed minimum power level. For example, PCM can include PCM1, PCM, etc.
[00149] [00149] A selection or resource assignment can be determined, for example, based on a transmission profile. In one example, a resource and / or format that can be used by a transmission can be a function of a transmission profile. For example, in the case of PUCCH, a set of resources and / or format, indicated by the ARI grant, may be dependent on a transmission profile. A network can, for example, configure at least one set of resources for a transmission profile, for example each transmission profile. A set of features that may be subject to less interference can be associated with transmission profiles that can be used for more reliable transmissions.
[00150] [00150] In one example, the use of a long or short PUCCH format and / or a number of symbols may be a function of a transmission profile. In one example, a WTRU can be configured to transmit a PUCCH by multiple symbols (for example, two symbols) to a transmission profile (for example, a first transmission profile) that may be suitable for ultra-reliable traffic. A WTRU can be configured to transmit a PUCCH by one symbol (for example, a single symbol) to another transmission profile (for example, a second transmission profile) that may be suitable for other non-ultra-reliable mobile broadband traffic.
[00151] [00151] In an example, a set of parts of bandwidth and numerology (for example, including one or more of a subcarrier spacing, length of a cyclic prefix or number of symbols per interval or mini-interval) that can be used for a downlink transmission or an uplink transmission within a carrier can, for example, be dependent on a transmission profile.
[00152] [00152] In one example, a waveform may be dependent on a transmission profile. For example, a waveform can be an orthogonal frequency division multiplexing waveform (OFDM) or a single carrier frequency division waveform (SC-FDMA). In one example, the use of frequency hopping may be dependent on a transmission profile.
[00153] [00153] In one example, with respect to at least one type of UCI (for example, ACK of HARQ), the UCI can be transmitted by a PUCCH or multiplexed with data transmitted by a PUSCH. The determination of whether the UCI is transmitted by a PUCCH or multiplexed with data transmitted by a PUSCH may be dependent on transmission profiles associated with the UCI and the data. In one example, a UCI can be multiplexed with data by the PUSCH, for example when the UCI and the data can have the same transmission profile or the same priority level associated with the transmission profile. An UCI can be transmitted separately by PUCCH. In one example, at least one type of UCI (for example, channel state information (CSI)) can be discarded.
[00154] [00154] In an example, a number or fraction of resource elements can be determined that can be used by at least one type of UCI (for example, when multiplexed with data in the PUSCH), for example, by one or more factors ( for example, beta parameters). Such factors may be a function of a transmission profile. In one example, for a given type of UCI, a WTRU can be configured with a first set of factors that may be applicable to a first transmission profile and a second set of factors that may be applicable to a second transmission profile. A transmission profile that may be suitable for ultra-reliable traffic can, for example, make it possible to use a greater proportion of PUSCH resources.
[00155] [00155] In one example, a WTRU can determine whether UCI diversity is applied or not. For example, an SR configuration can include a PUCCH resource configuration applicable to UCI diversity (or a PUCCH diversity resource). For example, when the SR is triggered by a logical channel (LCH) mapped to such an SR configuration, a WTRU can transmit the SR via more than one PUCCH resource (or a PUCCH diversity resource).
[00156] [00156] A prioritization between transmissions can be provided. In one example, a priority level can be set or configured for a transmission profile (for example, each transmission profile). A priority level can be used, for example, to determine whether one or more transmissions can be interrupted or anticipated, reduced gradually, have fewer resources allocated or processed later, for example in the event of a conflict. A conflict event can be beneficial (for example, from a systemic perspective) for example, by allowing the use of a greater proportion of system resources (for example, compared to a situation where resources can be reserved).
[00157] [00157] Prioritization can be provided for changing the power scale. In one example, a WTRU can gradually decrease at least one transmission, for example when a configured maximum total power can be exceeded over a period of time (for example, during a subframe, an interval or a mini-interval). An order of priority for scaling may be dependent on a transmission profile (for example, in addition to other criteria such as UCI or data type). In one example, a transmission profile criterion can take precedence over, or replace, other criteria. In one example, if a first transmission profile has a higher priority level than a second transmission profile, power can be assigned to one
[00158] [00158] Prioritization can be provided to interrupt a transmission or at least a portion of a transmission. In one example, a WTRU can determine that more than one transmission can overlap a subset of resources and that at least a portion of at least one of the transmissions can be stopped or anticipated, for example, based on the transmission profiles associated with the overlapping transmissions. A WTRU can, for example, determine that a transmission with the highest priority (for example, based on the transmission profile) can be transmitted by the resource.
[00159] [00159] An overlap can result, for example, from scheduling instructions that can be received at various times and with different latency requirements. In one example, a WTRU may receive a downlink assignment that may require the transmission of HARQ ACK by PUCCH on certain symbols within a certain range. A WTRU can receive a lease (for example, subsequently receive a lease) for a PUSCH transmission for the same interval. A WTRU may determine that the PUSCH transmission takes precedence over the PUCCH transmission, for example when the transmission profile associated with the uplink data that can be transmitted via the PUSCH has a higher priority level than the transmission profile associated with the HARQ ACK that can be transmitted via PUCCH. Based on this determination, a WTRU can use overlapping resources for PUSCH transmission and can interrupt PUCCH transmission. In one example, a WTRU can transmit PUCCH through the overlapping resources. The WTRU can use remaining resources that can be referred to the PUSCH, for example, taking into account a reduced amount of resources in rate correlation calculations.
[00160] [00160] A WTRU can receive a first downlink assignment indicating the transmission of HARQ ACK through PUCCH on a first resource. The WTRU can receive (for example, subsequently receive) a second downlink assignment indicating the transmission of HARQ ACK through PUCCH in a second resource. The WTRU can transmit the HARQ ACK corresponding to the PDSCH (or PDCCH) with a higher priority transmission profile, for example if the first resource and the second resource overlap or are the same. The WTRU can transmit HARQ ACK corresponding to PDSCH (or PDCCH) based, for example, on CORESET, search space and / or RNTI.
[00161] [00161] In one example, a WTRU can receive a lease for PUSCH through an interval. The WTRU may receive (for example, subsequently receive) a downlink assignment (or trigger a scheduling request) that may require the transmission of a PUCCH over one or more resources in the same range (for example, through the last symbols of time for a short PUCCH or through one or more time symbols (for example, most or all of the time symbols) available for the uplink to a long PUCCH). A WTRU can determine that a PUCCH can be transmitted via an overlapping resource, for example when the PUCCH includes an UCI associated with a higher transmission profile than the data transmitted via a PUSCH. A WTRU can determine that a PUSCH can be discarded or that the PUSCH can be transmitted via a non-overlapping resource, for example, with drilling applied over an overlapping resource. A course of action may depend on a type of anticipated transmission (for example, PUSCH can still be transmitted when anticipated by a short PUCCH) and / or if a proportion of anticipated resources is above a threshold.
[00162] [00162] A WTRU can multiplex an HARQ and CSI ACK into a single PUCCH transmission or PUSCH transmission and determine that a subset of CSI report (s) (for example, Nreportea *) can be selected based on a maximum code rate that can be configured. The order of priority for the CSI report (s) may depend on a transmission profile (or the configured BLER target value), so that a CSI report associated with a lower BLER target value can be considered to have a higher priority than a CSI report associated with a higher BLER target value. The priority determined from the target value of BLER or the transmission profile can take precedence over at least one among other priority criteria used to select CSI reports, for example the type of CSI. For example, this can result in information from a pre-coding matrix information (PMI) from a CSI report associated with a lower BLER target value, which has a higher overall priority than information from rank (RI, rank information) of a CSI report associated with a higher BLER target value.
[00163] [00163] Prioritization can be provided for processing DL data. In one example, a WTRU can be scheduled to receive DL data with different transmission profiles through at least one PDSCH and can report the HARQ ACK (for example, at specific times) associated with the DL data. A WTRU may be unable to complete the decoding of at least one block of code in time for the transmission of a corresponding HARQ ACK. The WTRU can prioritize the decoding of higher priority DL data, for example, according to a transmission profile associated with the DL data.
[00164] [00164] In one example, an HARQ ACK can be transmitted before the decoding of at least one group of code blocks is complete for a transport block. Depending on the transmission profile associated with the data, a WTRU can define the HARQ ACK in one of the ways below. A WTRU can define the HARQ ACK of a group of code blocks not yet decoded as ACK, for example, when decoding can be completed and it can be configured as NACK for at least one other group of code blocks in the transport. A WTRU can define the HARQ ACK as an ACK for one or more groups of code blocks, except one that can be defined as a NACK. This can minimize the amount of resources that a network can use for retransmissions, for example in the case that some blocks of code, not yet decoded, can be successful and do not require retransmissions. This example procedure can be selected, for example, for a transmission profile that may have a lower priority.
[00165] [00165] In one example, a WTRU can define the HARQ ACK of a group of blocks of code not yet decoded as NACK. This can minimize the delivery latency of a transport block, for example where the retransmitted data may be available more quickly, for example, when decryption is unsuccessful. This example procedure can be selected, for example, for a transmission profile that may have a higher priority.
[00166] [00166] Prioritization can be provided for resource sharing. In one example, a WTRU can be configured to multiplex UCI and / or uplink data according to different transmission profiles in one (for example, the same) PUSCH transmission or a PUCCH transmission. A proportion of resources (for example, resource elements (REs)) that can be assigned to a UCI or data according to a transmission profile can depend on the priority levels of the transmission profiles. In an example (for example, for UCI multiplexing on the PUSCH), a first value of a beta parameter for a UCI type can be applied, for example, when a priority of a transmission profile associated with an UCI is higher than a priority of a data-associated transmission profile. A second value of a beta parameter can be applied, for example, when the transmission profiles have equal priorities. A third value can be applied, for example, when a priority of a transmission profile associated with a UCI is less than a priority associated with a data transmission profile.
[00167] [00167] Payload / MCS selection can be based on prioritization. In one example, a WTRU can be configured to use a first modulation and encoding scheme, transport block size and / or payload for a transmission, for example when the transmission does not conflict with a higher priority transmission according to a transmission profile. A WTRU can be configured to use a second modulation and coding scheme, transport block size or payload for a transmission, for example, when the transmission conflicts with a transmission of a higher priority according to a profile of streaming. A conflict may correspond to a situation, for example, when multiple transmission resources overlap or when the maximum total transmission power is exceeded.
[00168] [00168] Differentiated state-based processing can be provided. In one example, a WTRU can apply a set of parameters that correspond to a transmission profile (for example, based on the state of the transmission profile). The status of the transmission profile can be changed by an indication of the network. For example, the state of the transmission profile can be changed by a MAC control element (MAC CE) or downlink control information (DCI). The status of the transmission profile can be changed when an event occurs, such as the expiration of a timer (for example, a timing advance timer). The set of parameters that correspond to a transmission profile can include a set of PUCCH resources for ACK / NACK from HARQ, a set of parameters used to determine the fraction of resource elements used for UCI in the PUSCH etc.
[00169] [00169] In one example, a transmission profile and associated parameters can be configured for a part of bandwidth. A WTRU configured with multiple parts of bandwidth can apply the transmission profile and associated parameters corresponding to an active part of bandwidth. The WTRU can receive a DCI or a MAC CE indicating a change in the active bandwidth portion. The WTRU can (for example, upon receiving this indication) apply the transmission profile and parameters associated with the received (or indicated) active bandwidth portion.
[00170] [00170] In one example, a WTRU can receive a DCI indicating a change in a portion of the active bandwidth (for example, where the new portion of active bandwidth and the portion of existing active bandwidth can share the same configuration, except at least in relation to the transmission profile and associated parameters). For example, the WTRU can be configured with two parts of bandwidth with the same frequency assignment. When the WTRU receives an indication of a change in the active bandwidth portion (for example, that satisfies this condition), the WTRU can receive a PDSCH in the same interval as the interval in which the DCI is received based on the parameters indicated in the DCI
[00171] [00171] Systems, methods and tools can be provided for handling transmission characteristics with an overlap between a plurality of transmissions. A WTRU can determine that an overlap exists in time between a plurality of transmissions, for example a first transmission and a second transmission. The WTRU can perform at least one of the following actions: (1) perform a subset of one of the transmissions; (2) cancel, interrupt or stop (for example, if already in progress) one of the transmissions; (3) suspend and / or postpone one of the transmissions; (4) execute both transmissions and / or apply a power scaling function for at least one transmission, for example if there is no frequency overlap between transmissions; or (5) modify at least one property of a first transmission, for example to transmit at least part of the information that may have otherwise been transmitted using a second transmission. For example, a WTRU can modify a demodulation reference signal (DM-RS) property for a first PUSCH transmission to indicate a scheduling request (SR). The modification, for example, may include assigning zero power, switching to a second pre-configured feature, changing the phase, etc. The WTRU can perform this action in combination with assigning zero power to a second transmission, for example an SR in the PUCCH that may, on the other hand, have overlapped in time.
[00172] [00172] In other examples of transmissions described here, a first transmission may include an SR, and a second transmission may include a PUSCH (or a PUCCH). An SR associated with high priority traffic can be multiplexed with PUSCH or PUCCH. A WTRU can indicate and / or transmit uplink control information, such as an SR associated with a first transmission profile by modifying at least one transmission property associated with a second transmission profile, such as a PUSCH transmission or a PUCCH transmission. In one example, the first transmission profile may have a higher priority than the second transmission profile. In one example, the duration of the PUSCH transmission or the PUCCH transmission may be longer (for example, significantly longer) than the schedule request schedule frequency for the first transmission profile. The length of the PUSCH transmission or the PUCCH transmission may be of such a nature that waiting for the end of the PUSCH transmission or the PUCCH transmission before transmitting the SR, may exceed a latency value (for example, an acceptable latency value).
[00173] [00173] The at least one transmission property that can be modified may include a reference signal property embedded in the transmission, such as a demodulation reference signal (DM-RS). For example, such a property may include a relative phase between two time symbols that carry the DM-RS. The relative phase can be a first value, for example, if no SR is transmitted. The relative phase can be a second value, if a scheduling request is transmitted.
[00174] [00174] The at least one transmission property that can be modified can include a transmission power parameter of at least one time symbol (or a resource element). For example, the transmission power of at least one symbol can be reduced compared to the transmission power of the other symbols, when the
[00175] [00175] The at least one time symbol (or resource element) through which a transmission can be modified can be limited to a subset of the transmission time symbols. For example, if the indication is carried by modifying a property of a reference signal, the time symbols may be restricted to time symbols carrying that reference signal. The time symbols affected by the modification may include the time symbols (for example, all time symbols) that carry the reference signal after the SR is triggered. In an example, if the indication is carried by modifying the transmission power of at least one time symbol, the subset can be determined based on a configured frequency of the scheduling request. The at least one affected time symbol can include a single symbol or the time symbols (for example, all time symbols) immediately after the SR is triggered which can coincide with configured scheduling request occasions. In one example, one or more time symbols that include reference signs can be excluded from the subset.
[00176] [00176] In one example, a subset of resource elements (or time symbols) of a PUCCH transmission or a PUSCH transmission can be configured to indicate whether the SR has been triggered since the beginning of the transmission. A WTRU can be configured with at least a subset of resource elements that occur regularly (for example, periodically) in the time domain. Such a configuration may depend on a configured periodicity of the SR, or it may coincide with occasions configured for the transmission of SR. In a given subset, a WTRU can transmit a first predefined sequence of modulated symbols, for example if an SR has not been triggered until an offset before the subset's time symbol (s). The WTRU can transmit a second predefined sequence of modulated symbols, for example if an SR has been triggered. The predefined sequence may overwrite (for example, using perforation) modulated PUSCH or PUCCH symbols that may have been mapped (for example, previously mapped) to the subsets of resource elements, or the subsets of resource elements. resource may have been initially excluded from the set of resource elements to which the modulated symbols of the PUSCH transmission or the PUCCH transmission are mapped.
[00177] [00177] Systems, methods and tools can be provided for handling transmission characteristics based on timing. One or more aspects can be determined as a function of the available WTRU processing, for example the processing time of the WTRU.
[00178] [00178] A WTRU can determine that it can apply at least one prioritization or multiplexing solution. The prioritization or multiplexing solution may be a function of one or more timing aspects including, for example, at least one of the following: (1) timing aspect of when the data may be available for transmission, or when the data available for transmission may trigger the transmission of a BSR and / or the transmission of an SR; (2) timing aspect of when a scheduling request (SR) can be triggered; (3) timing aspect when downlink control information indicating an uplink transmission (for example, a PUSCH transmission or a PUSCH transmission) can be received; (4) timing aspect of receiving higher layer signaling, for example at least in the case of a configured lease or other periodic or semi-persistent transmission (for example, CSI, SRS); (5) timing aspect of when a PUSCH transmission can be scheduled to start (and / or end) according to a dynamic or configured lease; (6) timing aspect of when a PUCCH transmission can start (and / or end), for example according to a semi-static configuration or an indication in the downlink control information; (7) the duration of a PUCCH or PUSCH transmission; or (8) timing aspect of when a transmission can be determined to exist in the future for any other reasons, for example, the receipt of a paging request, initiation of a procedure such as re-establishing RRC connection, etc. In the case of (1), for example, a WTRU can make such a determination when new data can become available for transmission to a logical channel (LCH) of a specific priority and / or specific type, or when the data available for transmission can trigger transmission of a buffer status report (BSR) and / or an SR. The WTRU can perform such determination for data associated with a mapping constraint (for example, LCH for transmission mapping constraint), a profile and / or an LCH priority / logical channel group (LCG).
[00179] [00179] A WTRU can carry out the determination to apply at least one prioritization or multiplexing solution for data and / or for a transmission associated with a certain mapping restriction (LCH for transmission), for a specific profile and / or for a given LCH / LCG priority. For example, a WTRU can determine the prioritization or multiplexing solution that can be applied during at least two or more transmissions (for example, partially overlapping transmissions). The determination can be made based on the difference between the initial time of a first transmission and the time when a second transmission is determined to exist, as described in the present disclosure.
[00180] [00180] A WTRU can perform a first action 1 (Action 1) or a second action 2 (Action 2), for example if the WTRU determines that a first event A (Event A) occurs at least x time symbol (s) before the start of event B (Event B). Event B can be a known event.
[00181] [00181] One or more timing cases can be provided to indicate that an SR trigger can be a function of concession adequacy. Event A may correspond to an autonomous WTRU trigger associated with receiving downlink control signaling and / or an event that may correspond to a higher priority than Event B (for example, based on a profile of applicable transmission). Autonomous triggering can be one of the timing aspects as described in the present disclosure, for example, triggering an SR when new data can become available for transmission. Event B can correspond to a scheduled event (for example, an uplink transmission).
[00182] [00182] In Action 1, a WTRU may determine that sufficient time is available to act on the scheduled information and / or prioritize one of the two events before the lowest priority event is initiated. In Action 2, a WTRU may determine that there is not enough time to adjust its transmissions and / or prioritize one of the two events before the lowest priority event is initiated so that it can instead determine the modification of the properties of the corresponding continuous transmission. The WTRU can be configured with a value of x, for example, by RRC, where x can be a time value in symbols, in a framing unit (for example, mini-interval, interval, subframe) or in absolute time, for example, in milliseconds.
[00183] [00183] In one example, Event À may correspond to an SR trigger for data associated with a transmission profile, for example a transmission profile corresponding to the transmission of URLLC data. Event B can correspond to the start of an uplink transmission on the PUSCH for data associated with a transmission profile, for example a transmission profile corresponding to the transmission of eMBB data.
[00184] [00184] Action 1 may correspond to the cancellation of an uplink transmission, for example the PUSCH transmission corresponding to eMBB data, and to the WTRU performing an SR transmission using a resource / method corresponding to the data type of URLLC. Action 2 can correspond to the cancellation / interruption / zero power setting of one or more specific symbols and / or a DM-RS modification of the transmission from PUSCH to eMBB, for example to indicate an SR for URLLC, as described here.
[00185] [00185] In one example, one of the transmissions can correspond to a first transmission profile or similar, for example a URLLC service, and another can correspond to a second transmission profile, for example an eMBB service. In such an example, if the WTRU determines that there is sufficient processing time (for example, the time between two events is less than x), and if the WTRU makes such a determination before the start of any of the overlapping transmissions at least partially, the WTRU may perform at least one of the following actions for different signal combinations: (1) the WTRU can prioritize the SR (for URLLO), interrupt the PUSCH (for eMBB); (2) the WTRU can precede and / or drill the PUSCH (for eMBB) with the SR (for URLLO), for example using a similar concatenation principle as used for UCI in the PUSCH for LTE; (3) the WTRU can embed the transmission, for example interrupting a part of the PUSCH (for eMBB) and replacing it with sSPUSCH (including BSR (for URLLO)); (4) the WTRU can signal the SR using a modification in the PUSCH DM-RS sequence (for eMBB); (5) the WTRU can adjust the uplink power control (UL PC), for example, apply a power scale change, for example if the WTRU has limited power.
[00186] [00186] In an example, if the WTRU determines that there is not enough processing time (for example, the time between two events is less than x), or if the WTRU does not make this determination before the start of any of the transmissions that overlap at least partially, the WTRU may perform at least one of the following actions for different signal combinations: (1) the WTUR may remove / interrupt or drill a PUSCH in progress (for eMBB), and the WTRU may transmit a SR (for URLLO) using an associated resource, for example in the short PUCCH; or, instead, transmit a BSR (for URLLO), for example in the short PUSCH (for URLLO); and / or instead, transmit a TB of URLLC, for example, in the short PUSCH (for URLLCO); (2) the WTRU can signal the SR using the DM-RS sequence change to the current PUSCH (for eMBB); (3) the WTU can adjust the UL PC as needed (for example, to reinforce the DM-RS).
[00187] [00187] In one example, a WTRU can initiate an additional transmission on the same carrier, for example if the WTRU is configured with simultaneous PUSCH + PUSCH or PUSCH + PUCCH. The WTRU can send the additional transmission in the same part of the bandwidth or in different parts of the bandwidth, for example, if configured and / or active. The WTRU may perform such transmission using distinct and / or combined resources. The separate resources may include separate PUSCH and / or PUCCH transmissions that can be started with other ongoing transmission (s). The combined resources can be used, for example, when the URLLC is configured and / or any concession for other types of traffic (for example, of lower priority) may include resources for additional SR, BSR transmissions.
[00188] [00188] A WTRU can assign power using one or more power control functions. A WTRU may consider transmissions that can be made with at least a partial overlap in time, but for which the WTRU may not have made a determination as to whether that transmission will be made or not. When determining whether or not to make such a transmission, the WTRU may include the following factors: the respective priority in the power allocation function, the method and / or the resources that can be used, for example, if executed for the maximum reduction configuration maximum power reduction (MPR).
[00189] [00189] The systems and / or methods described in this document can be implemented in a computer program, software and / or firmware incorporated in a computer-readable medium for execution by a computer and / or processor. Examples of computer-readable media include electronic signals (transmitted over wired and / or wireless connections) and / or computer-readable storage media. Examples of computer-readable storage media include, but are not limited to, read-only memories (ROM), random access memories (RAM), registers, cache memories, semiconductor memory devices, magnetic media, such as, but not limited to, limiting to, internal hard drives and removable disks, magneto-optical media and / or optical media such as CD-ROM disks and / or digital versatile disks (DVDs). A processor in association with software can be used to implement a radio frequency transceiver for use in a WTRU, terminal, base station, RNC and / or any host computer.

权利要求:
Claims (16)
[1]
1. Wireless transmission / reception unit (WTRU), characterized by the fact that it comprises: a receiver configured to receive at least one downlink control physical channel (PDCCH) transmission comprising downlink control (DCI) information ); a processor configured for at least: determining one or more transmission characteristics associated with uplink control information (UCI), with one or more transmission characteristics being determined based on at least one attribute associated with at least one PDCCH transmission received and a data attribute associated with the UCI, the PDCCH transmission being mapped to one or more resources from a set of control resources (CORESET), with one or more transmission characteristics comprising one or more among: at least one coding parameter, at least one transmission power parameter, at least one resource allocation parameter or a priority level; and a transmitter configured to transmit the UCI through a physical uplink control channel (PUCCH), the UCI being transmitted using the determined transmission characteristics.
[2]
2. Wireless transmission / reception unit (WTRU) according to claim 1, characterized by the fact that the transmitter is configured to transmit the UCI based on one or more of: CORESET, a search space or an identifier temporary radio network (RNTD).
[3]
3. Wireless transmission / reception unit (WTRU) according to claim 1, characterized by the fact that one or more of the transmission characteristics are determined based on one or more of: at least one DCI field in the received DCI or a bandwidth portion (BWP) identity used to transmit at least one of the DCI or UCL.
[4]
4. Wireless transmission / reception unit (WTRU) according to claim 1, characterized by the fact that the DCI comprises a first DCI and a second DCI, the first DCI being received using a first set of control resources (CORESET) and the second DCI is received using a second CORESET.
[5]
5. Wireless transmission / reception unit (WTRU) according to claim 4, characterized by the fact that each of the first CORESET and the second CORESET comprises one or more of a component carrier, at least one BWP, a subset resource blocks within each part of bandwidth, a set of time symbols within an interval or mini-interval, a spacing between subcarriers, a subset of intervals within a subframe, or at least one reference signal.
[6]
6. Wireless transmission / reception unit (WTRU) according to claim 4, characterized by the fact that the UCI comprises feedback bits associated with one or more of the first DCI or the second DCI, and the fact that the UCI comprises a first UCI and a second UCI, the first UCI or the second UCI comprising feedback bits for a data transmission assigned by the first DCI or the second DCI.
[7]
7. Wireless transmission / reception unit (WTRU) according to claim 1, characterized by the fact that the UCI comprises a first UCI and a second UCI, the second UCI corresponding to a redundant transmission of the first UCI, being that the first UCI or second UCI comprises one or more of a hybrid automatic retry request (HARQ), a scheduling request (SR) or a channel quality indicator (CQI).
[8]
8. Wireless transmission / reception unit (WTRU) according to claim 1, characterized by the fact that the data attribute is at least one among: an identity of a logical channel or an identity of a group of logical channels of data associated with the UCI, the attribute being a quality of service (QoS) metric.
[9]
9. Uplink control information (UCI) transmission method, the method characterized by the fact that it comprises: receiving at least one downlink control physical channel transmission (PDCCH) comprising downlink control information ( DCI); determine one or more transmission characteristics associated with uplink control (UCI) information, with one or more transmission characteristics being determined based on at least one attribute associated with at least one received PDCCH transmission and one attribute data associated with the UCI, and the PDCCH transmission is mapped to one or more resources of a set of control resources (CORESET), with one or more transmission characteristics comprising one or more of: at least one parameter of coding, at least one transmission power parameter, at least one resource allocation parameter or a priority level; and transmitting the UCI through a physical uplink control channel (PUCCH), the UCI being transmitted using the determined transmission characteristics.
[10]
10. Method according to claim 9, characterized by the fact that it additionally comprises transmitting the UCI based on one or more among: CORESET, a search space or a temporary radio network identifier (RNTI).
[11]
11. Method according to claim 9, characterized in that one or more transmission characteristics are determined based on one or more of: at least one DCI field in the received DCI or an identity of a part of the bandwidth (BWP) used to transmit at least one of the DCI or UCI.
[12]
12. Method according to claim 9, characterized by the fact that the DCI comprises a first DCI and a second DCI, the first DCI being received using a first set of control resources (CORESET) and the second DCI is received using a second CORESET.
[13]
13. Method according to claim 12, characterized by the fact that each of the first CORESET and the second CORESET comprises one or more of a component carrier, at least one BWP, a subset of resource blocks within each part of bandwidth, a set of time symbols within an interval or mini-interval, a spacing between subcarriers, a subset of intervals within a subframe, or at least one reference signal.
[14]
14. Method according to claim 12, characterized by the fact that the UCI comprises feedback bits associated with one or more of the first DCI or the second DCI, and the fact that the UCI comprises a first UCI and a second UCI , the first UCI or the second UCI comprising feedback bits for a data transmission assigned by the first DCI or the second DCI.
[15]
15. Method according to claim 9, characterized by the fact that the UCI comprises a first UCI and a second UCI, the second UCI corresponding to a redundant transmission of the first UCI, the first UCI or the second UCI comprising one or more of a hybrid automatic retry request (HARQ), a scheduling request (SR) or a channel quality indicator (CQD).
[16]
16. Method according to claim 9, characterized by the fact that the data attribute is an identity of a logical channel or a group of logical channels of data associated with the UCI, the attribute being a metric of quality of service (QoS).

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法律状态:
2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

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申请号 | 申请日 | 专利标题

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US201762519585P| true| 2017-06-14|2017-06-14|

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US62/519,585|2017-06-14|

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US201762585937P| true| 2017-11-14|2017-11-14|

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US62/585,937|2017-11-14|

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US201862652002P| true| 2018-04-03|2018-04-03|

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US62/652,002|2018-04-03|

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US201862667015P| true| 2018-05-04|2018-05-04|

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US62/667,015|2018-05-04|

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PCT/US2018/036967|WO2018231728A1|2017-06-14|2018-06-11|Reliable control signaling|

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