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    • 专利摘要:
    it is a method (500) and an apparatus (600) that provide a procedure for reporting power capacity for a new radio carrier, such as 5g aggregation. a first component carrier (cc) that has a first transmission time slot (tti) and a second cc that has a second tti can be communicated at (510). it can be seen that a power capacity report (phr) was triggered for at least one selected from the first cc and the second cc (520). an uplink grant corresponding to an uplink transmission can be received on the first cc (530). a first phr reference tti corresponding to the uplink transmission in the first cc (540) can be determined. a first phr can be generated for the first cc based on the first phr reference tti (550). a second phr reference tti can be determined in the second cc (560). a second phr can be generated for the second cc based on the second phr reference tti (590). the first phr and the second phr can be transmitted in the uplink transmission (595).
    公开号:BR112019019684A2
    申请号:R112019019684
    申请日:2018-02-28
    公开日:2020-04-14
    发明作者:Lohr Joachim;Basu Mallick Prateek;Kuchibhotla Ravi
    申请人:Motorola Mobility Llc;
    IPC主号:
    专利说明:

    METHOD AND APPARATUS FOR PROCEDURE FOR REPORTING POWER CAPACITY FOR AGGREGATION OF NEW RADIO CARRIER BACKGROUND
    1. FIELD [001] The present disclosure refers to a method and apparatus for reporting the power capacity for aggregating a new radio carrier, such as 5G.
    2. INTRODUCTION [002] Currently a User Equipment (UE), such as wireless user communication devices, communicates with other communication devices using wireless signals. To support various requirements for different services that include at least Enhanced Mobile Broadband (eMBB), Ultra-Trusted Low Latency Communications (URLLC) and Massive Machine Type Communications (mMTC), it is intended that the 5G / New Radio ( NR) support different Orthogonal Frequency Division Multiplexing (OFDM) numerologies, such as subcarrier spacing (SCS) and Cycle Prefix length (CP) in a single structure.
    [003] As identified in the Technical Report (TR) 38 913 of the 3rd Generation Partnership Project (3GPP), the number of cases of use / deployment scenarios for NR have different requirements in terms of data rates, latency and coverage. For example, eMBB is expected to support peak data rates such as 20 Gbps for downlink and 10 Gbps for uplink and data rates experienced by user in the order of three times what is offered by
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    International Mobile Telecommunications (IMT) - Advanced. On the other hand, in the case of URLLC, the stricter requirements are applied in ultra-low latency as 0.5 ms for each of UL and DL for user-level latency and high reliability, such as 1 to 10 5 probability that a packet does not pass within 1 ms. Finally, mMTC requires high connection density, high coverage in hostile environments and extremely long battery life for low-cost devices. Therefore, OFDM numerology, such as subcarrier spacing, OFDM symbol duration, CP duration and number of symbols per programming interval, suitable for one use case may not work well for another.
    [004] For example, low latency services may require shorter symbol duration and, therefore, greater subcarrier spacing and / or fewer symbols per programming interval such as Transmission Time Interval (TTI), than an mMTC service. In addition, deployment scenarios with large channel delay distributions require a longer CP duration than scenarios with small delay distributions. Subcarrier spacing should be optimized accordingly to keep CP overload similar. It was agreed to study different numerologies on different carrier (s) for a given UE, as well as different numerologies on the same carrier for a given UE. For example, different OFDM numerologies are multiplexed in the frequency domain and / or in the time domain within the same carrier or between different carriers. This benefits the simultaneous support of services with very different requirements like communications
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    3/37 ultra-low latency with short symbols and, therefore, wide spacing of subcarriers and Multimedia Broadcast / Selective Broadcasting Service (MBMS) with long symbols to allow long cyclic prefix and thus narrow subcarrier spacing.
    [005] In Long Term Evolution (LTE), a UE reports an extended Power Capacity (PHR) report for carrier aggregation. For example, Power Capacity (PH) information for each activated server cell is included together with Pcmax. As the subframe / TTI length is the same for all carriers in LTE, the PHR reporting subframes, such as the subframes to which the power capacity information refers, are aligned. However, for NR, an interval / TTI of one carrier may overlap with several intervals / TTIs of another carrier due to the support of different numerologies. For example, an eMBB on one carrier may overlap with URLLC on another carrier. In this case, a 5G NodeB (gNB), such as a 5G base station, will not be aware of what range the power capacity information refers to when receiving an extended PHR. For example, in a scenario where an extended PHR report is triggered and subsequently transmitted on an interval / TTI that overlaps multiple intervals / TTIs on a different carrier, gNB does not know which overlapping interval / TTI is the reference for the PH calculation. Therefore, it can base future programming decisions based on erroneous assumptions, such as how close the UE operates to the power limit, which can lead to either a staggered power or an underutilization of resources.
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    BRIEF DESCRIPTION OF THE DRAWINGS [006] In order to describe the way in which the advantages and characteristics of the disclosure can be obtained, a description of the disclosure is made by reference to specific modalities of the same which are illustrated in the attached drawings. These drawings represent only examples of the disclosure and, therefore, should not be considered as limiting the scope of the disclosure. The drawings may have been simplified for clarity and are not necessarily drawn to scale.
    [007] Figure 1 is an example block diagram of a system according to a possible modality;
    Figure 2 is an example illustration of a scenario that shows sub-frames of power capacity reporting and uplink concessions for different component carriers according to a possible modality;
    Figures 3 and 4 are example scenarios that illustrate when interval / transmission timeout limits for component carriers are not aligned according to a possible modality;
    Figure 5 is an example flow chart illustrating the operation of an apparatus according to a possible modality; and
    Figure 6 is an example block diagram of an apparatus according to a possible embodiment.
    DETAILED DESCRIPTION [008] The modalities provide a method and apparatus for the procedure of reporting the capacity of power for aggregation of carrier of Novo Rádio (NR), such as 5G. According to a possible modality, a first Carrier
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    Component (CC) that has a first Transmission Time Interval (TTI) and a second CC that has a second TTI can be communicated. It can be seen that a Power Capacity Report (PHR) was triggered for at least one selected from the first DC and the second DC. An uplink lease corresponding to an uplink transmission can be received at the first CC. A first PHR reference TTI corresponding to the uplink transmission in the first CC can be determined. A first PHR can be generated for the first CC based on the first PHR reference TTI. A second PHR reference TTI can be determined in the second CC. A second PHR can be generated for the second CC based on the second PHR reference TTI. The first PHR and the second PHR can be transmitted in the uplink transmission.
    [00 9] Figure 1 is an example block diagram of a system 100 according to a possible modality. System 100 can include User Equipment (UE) 110, base stations 120 and 130 and a network 130. UE 110 can be a wireless wide area network communication device, a wireless terminal, a communication device portable wireless, a smartphone, a cell phone, a flip phone, a personal digital assistant, a personal computer, a selective call receiver, a tablet computer, a laptop computer, an Internet of Things (ΙοΤ) device or any other user device that can send and receive communication signals over a wireless network. At least one of the base stations 120 and 130 can be a wireless wide area network base station, a NodeB,
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    6/37 an enhanced NodeB (eNB), a 5G, such as an NR, NodeB (gNB), an unlicensed network base station, an access point or any other base station that can provide wireless access between an UE and a network.
    [010] Network 140 can include any type of network that can send and receive wireless communication signals. For example, network 140 may include a wireless communication network, a cell phone network, a Time Division Multiple Access (TDMA) -based network, a Code Division Multiple Access (CDMA) -based network , a network based on Orthogonal Frequency Division Multiple Access (OFDMA), a Long Term Evolution (LTE) network, a network based on the Third Generation Partnership Project (3GPP), a 4G network, a 5G network NR, a satellite communications network, a high altitude platform network, the Internet and / or other communication networks. In operation, the UE 110 can communicate with other devices over network 140 by sending and receiving signals to and from base stations 120 and 130 over component carriers 122, 124 and 132.
    [011] The uplink transmission power control in a mobile communication system, such as the 100 system, serves to balance the need for power per transmitter bit enough to achieve the Quality of Service (QoS) required with the need to minimize interference to other system users and to maximize the battery life of the UE 110. To achieve these objectives, an uplink power control can adapt to the conditions of a radio propagation channel, which includes loss of path, shading and
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    7/37 rapid fading fluctuations while limiting the interference effects of other users, within a cell and neighboring cells. The 3GPP has adopted a power control scheme for LTE that allows total or partial compensation for loss of path and shading. This functionality causes users with a greater loss of travel to operate with a lower SINR requirement so that they are likely to generate less interference in neighboring cells. The power control scheme used in LTE employs a combination of open-loop and closed-loop control. The open loop component compensates for slow channel variations based on signal strength measurements made by the terminal, for example, loss of path measurement. The closed-loop component, on the other hand, directly controls the power that the UE uses, for example, Transmission Power Control (TPC) commands explicit on the downlink to optimize system performance. This controls interference and fine-tunes the power settings to suit channel conditions that include rapid fading.
    [012] The detailed power control formulas are described in Section 5.1 of the Technical Specification (TS) 36.213 Partnership Project 3 Generation (3GPP) for Channel Physical Shared Liaison Ascending (PUSCH), Channel Physical Control Uplink Link (PUCCH) and the Sounding Reference Signals (SRS). For example, the definition of the transmission power of a UE 110 for a U-Link Shared Physical Channel (PUSCH) transmission in a subframe i in a server cell c is defined as follows:
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    H Ologjs W Usctí _ ; (0) * Pq pusíck .//) * «XJ) '+ YswX) + Λ <0] where Pcmax, c can be the UE transmission power configured in a subframe i for a server cell c. For LTE 8/9, there can be only one server cell. Therefore, Pcmax, c can be replaced by Pcmax in the above equation. The same can also be done for the other variables. For example, Mpusch, c can be replaced by Mpusch, etc. In Rel-10, support for multiple server cells, also known as carrier aggregation, was introduced. Mpusch, c can be the number of Physical Resource Blocks (PRBs) allocated to the UE 110. The more PRBs are allocated to the UE 110, the greater the UE transmission power required. Po_pusch, c may be the target received power, a c may be the path loss compensation factor and PL C may be the path loss between the UE 110 and the base station serving it, such as a base station 120 Atf, ce fc (i) can be the closed-loop power control parameters that represent the parameter dependent on the Modulation and Coding Scheme (MCS) and the Transmission Power Control (TPC) command, respectively.
    [013] The formula for each of these uplink signals, PUSCH, PUCCH and SRS, can follow the same basic principles, where in all cases they can be considered as a sum of two main terms: a basic operational point of open loop derived from static or semi-static parameters signaled by base station 120 and an updated dynamic offset from subframe to subframe. Base station 120 can also be referred to as an eNB 120 and / or a gNB 120 in the present
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    9/37 document, depending on the context of the reference.
    [014] In order to assist the eNB 120 to properly program uplink transmission resources for different UEs, the UE 110 can report its available power capacity to the eNB 120. The eNB 120 can, based on a received power capacity report, determining how much uplink bandwidth per additional subframe the UE 110 can use, as well as how close the UE 110 operates to its transmission power limits. The power capacity indicates the difference between the maximum UE uplink transmission power and the estimated power for an Uplink Shared Channel (UL-SCH) transmission. For Rel-8/9, the EU power capacity in dB valid for a subframe i can be defined by:
    ΡΗιφ - Fcmía (IOlog 1'Pa. Mv (/) ·· · «(/) 1 .P £ 0 ή / V)} where Pcmax can be the total maximum EU transmission power and can be a chosen value by UE 110 in the given range of Pcmax_l and Pcmax_h based on the following restrictions:
    j. / Wr Pcutv, u
    A w I, - AO
    Fímií ja-minfPiMOh [015] Pemax can be the value signaled by the network 140 and ATC, MPR and AMPR can be specified in 3GPP TS 36.101. An MPR can be a power reduction value used to control the Power Ratio for Adjacent Leakage (ACLR) associated with the various modulation schemes and the transmission bandwidth. AMPR, like A-MPR, can be the Additional Maximum Power Reduction. The same
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    10/37 can be a specific band value and can be applied by UE 110 when configured by the network.
    [016] The range of the power capacity report can be from +40 to -23 dB. The negative part of the band may allow the UE 110 to signal to the eNB 120 as it has received an UL grant that would require more transmission power than the UE 110 has available. This can allow the eNB 120 to reduce the amount of uplink resources in a subsequent concession, thereby freeing up transmission resources that can then be allocated to other UEs.
    [017] A Power Capacity Report (PHR), such as a PHR Media Access Control (EC) Control Element (MAC), can only be sent in a subframe for which the UE 110 has a resource uplink link, such as a PUSCH resource. The report can be related to the subframe in which it is sent. The PHR can therefore be an estimate, rather than a direct measure. For example, the UE 110 may not directly measure an actual transmission power capacity of the same for the subframe in which the report is to be transmitted.
    [018] Several criteria can be defined to trigger a PHR. These criteria may include a significant change in an estimated loss of travel since the last PHR was sent, such as above a configured threshold, may be a periodic power capacity report and may be other criteria. The eNB 120 can configure parameters to control each of these triggers depending on the system load and the requirements of the system's programming algorithm. The PHR can be sent as a MAC Control Element (CE). For Rel-8/9, the
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    11/37 can even include a single octet in which the two highest bits can be reserved and the lowest six bits can represent the 64 dB values mentioned above in 1 dB steps. For PHR MAC CE details, refer to TS 36.321, section 6.1.3.6.
    [019] For the case of carrier aggregation, which is a Rel-10 resource, there is an independent power control loop for each component carrier / UL server cell configured for UE 110. As already mentioned above, the definition the transmission power of the UE for a PUSCH transmission in a subframe i in a server cell c is defined as follows:
    n,. pCMAX.JÀ) «· j υ Ί . ΐϊ) ™ me
    Additional details on the power control formulas for PUSCH, PUCCH and SRS can be found in TS 36.213.
    [020] Since a UL power control is operated by a component carrier / server cell, a power capacity can also be reported per component carrier / server cell, that is, PH = Pcmax, c - estimated PUSCH power. For the case of carrier aggregation, there can be basically two defined power limits, a maximum total EU transmission power Pcmax and a maximum maximum transmission power specific for component carrier Pcmax, c. Additional information on the definition of a maximum transmission power specific to the component carrier and respectively of the total maximum transmission power of UE can be found in TS 36.101. For carrier aggregation, a
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    12/37 simultaneous PUSCH-PUCCH transmission. A type of additional power capacity can indicate the differences between Pcmax, c and the estimated TX PUSCH + PUCCH power. Consequently, two different types of PH types are reported for CA:
    PH type 1: Pcmax, c - estimated PUSCH power
    PH type 2: Pcmax, c - estimated PUSCH + PUCCH power in which a PH type 2 can be applicable only to a primary cell, P Cell, while a PH type 1 can be reported for a P Cell and a secondary cell, Cells. A PHR may be responsible for the Maximum Power Reduction (MPR). In other words, the power reduction applied by the UE 110 can be taken into account in the maximum transmission power specific for component carrier Pcmax, c. It should be noted that the eNB 120 may not be aware of the power reduction applied by the UE 110, since the actual power reduction depends on the type of allocation, the standardized MPR value and also on the implementation of the UE. Therefore, the eNB 120 may not know the maximum transmission power specific to the component carrier for which the UE 110 calculates the power capacity. In particular, the eNB 120 may not know precisely how close the UE 110 is operating to its maximum total transmission power Pcmax. Therefore, there may be situations in which the UE 110 exceeds the maximum transmission power Pcmax of a total user equipment, which would require power scaling. Therefore, in Rel10, a new power capacity MAC control element, also known as extended PHR MAC EC, can be used. How can it be beneficial for the eNB 120 to always know the power situation of all carriers of
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    13/37 uplink / server carriers activated for future uplink programming, the new extended power capacity MAC CE may include power capacity information (Type 1 / Type 2) for each activated uplink component carrier. Whenever a PHR is triggered on any of the configured component server / carrier cells, the UE 110 can send an extended PHR MAC CE that can contain information for all server cells.
    [021] In addition, the UE 110 can not only report the Power Capacity value for a component carrier, but can also report the corresponding Pcmax, c value. When a power capacity report is triggered, the UE can transmit the MAC control element of extended power capacity in one of the server cells, such as P Cell and S Cell, which has a valid uplink feature for PUSCH. In cases where PUSCH and PUCCH are not transmitted, a PH Type 1 and Type 2 can be calculated based on some predefined reference format. The corresponding PH report can also be called a virtual PHR. For example, PH can be calculated using some PUSCH and / or virtual PUCCH transmission, respectively. Additional details of the extended power capacity MAC control element can be found in section 6.1.3.6a of the TS 36.321 standard.
    [022] Dual connectivity (DC), which was introduced in Rel-12, can allow a UE to receive data simultaneously from different eNBs in order to increase performance in a heterogeneous network with deployment of
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    14/37 dedicated carrier. In more detail, a UE in the RRC_CONNECTED state can be configured to use radio resources provided by two different programmers, located in two eNBs connected via an interface, also known as an X2 interface.
    [023] There may be one Master eNB (MeNB) and one or more Secondary eNBs (SeNB). In the specifications of version 12 of the LTE, only the case of a MeNB and a SeNB is considered. The group of server cells associated with MeNB can be called the Group of Master Cells (MCG), while the group of server cells associated with MeNB can be called the Group of Secondary Cells (SCG). A schedule of uplink transmissions in double connectivity can be more challenging than a carrier aggregation, since the scheduling decisions made in MeNB and SeNB cannot be coordinated instantly due to the non-ideal interface between the two programmers. Therefore, it can easily happen that the MeNB and SeNB programming concessions can result in a situation in which the maximum transmission power of the UE is exceeded, which leads to a power escalation. To avoid these situations, a guaranteed minimum power for groups of cells was introduced, such as P_MCG for MCG and P_SCG for SCG, respectively. In more detail, the guaranteed minimum power level of a group of cells can be configured as a percentage of the maximum UE transmission power Pcmax. The sum of the minimum guaranteed power level for both groups of cells can be equal to or less than Pcmax. For the case of P_MCG + P_SCC <Pcmax, the remaining power that is not dedicated to a specific group of cells can be allocated
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    15/37 dynamically to MCG or SCG depending on the programming decision. In the event that less than the minimum guaranteed power is required for a transmission in one of the cell groups, the power can be allocated to the other group of cells.
    [024] Dual connectivity can be used for both synchronous and asynchronous networks. To meet both network deployments, two power control modes were introduced for the Rel-12. In particular, Power Control Mode 1 (PCM1) can be used for synchronous networks, while PCM2 can be used for asynchronous networks. All Rel-12 must support PCM1. For UEs that also support PCM2 for asynchronous networks, eNB can configure which power control mode to use. For PCM1, the remaining power, Pcmax - (P_MCG + P_SCG), can be allocated to MCG and / or SCG according to some predefined order of priority, such as according to the type of Uplink Control Information ( UCI). Basically, the highest priority can be given to the Hybrid Automatic Repeat Request (HARQ) feedback and Program Request (SR) transmissions. The second highest priority can be given to Channel State Information (CSI), followed by PUSCH transmissions without Uplink Control Information (UCI) and, finally, by the transmission of a Polling Reference Signal (SRS). In the event that the same UCI type transmission occurs for MCG and SCG, MCG transmissions can be prioritized. Additional details on PCM1 for dual connectivity can be found in section 5.1.4 of TS 36.213.
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    16/37 [025] In the case of an asynchronous network, limits of a subframe may not be aligned between MCG and SCG transmissions. Since the UE 110 cannot process incoming uplink leases to the other GC quickly enough when determining the transmit power for the cell group itself, the UE 110 may not consider the required transmit power for data transmissions. PUSCH / PUCCH in the other group of cells for the overlapping symbols. Therefore, for PCM2, the remaining power can be allocated simply for the transmission that starts earlier. More details on PCM2 can also be found in section 5.1.4 of TS 36.213.
    [026] In Dual Connectivity, when a PHR has been triggered, the UE 110 can send power capacity information for all activated cells, which include server cells from both groups of cells, to eNB 120. When the UE 110 reports PH information from SCG cells for MeNB or PH information from MCG cells for SeNB, PH type 2 information for cell PUCCH, sPUCCH for SCG, can always be included. The power capacity information for the server cells in the other CG can depend on the eNB configuration, either calculated based on some reference format, such as a virtual PHR, or based on actual PUSCH / PUCCH transmissions.
    [027] According to a possible modality, a reference interval / Transmission Time Interval (TTI) of power capacity can be defined in the case of aggregating carriers with different numerologies. Any of the overlapping ranges / TTIs can be defined as a reference range / TTI for the calculation
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    17/37 of a power capacity. The gNB 120 can know which range / TTI the power capacity calculation is based on so that it can interpret a received PHR correctly.
    [028] Figure 2 is an example illustration of a scenario 200 showing TTIs reporting PHR and uplink concessions for different component carriers, CC1, CC2 and CC3, according to a possible modality in which TTIs are referred to as subframes . In this scenario 200, the UE 110 can be configured with three component carriers / server cells, each of which has a different numerology / TTI length. The PHR was triggered before a TTIn-3 based on some defined criteria and is transmitted in a TTIn on the first carrier (CC1).
    [029] Since a TTIn on CC1 covers TTIi to TTIi + 3 on CC2 and TTIs to TTIs + i on CC3, a PHR reference TTI should be defined to ensure that gNB 120 interprets the received PHR correctly. In more detail, the reference TTI can be defined, for example, based on whether PH information for CC2, as reported in the PH of MAC of PHR MAC extended in CC1, was calculated for TTIi, TTIi + i, TTIi + 2 or TTIi +3.
    [030] From a technical point of view, there are some reasons for defining the reference TTI in a specific way, which are described below, although, as mentioned above, it is generally sufficient to have a defined rule to determine the reference TTI for PHR calculation.
    [031] Since the power capacity can be calculated on the basis of an UL concession received, such as
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    18/37 a UL power estimated according to the concession, by having different lengths of TTI and potentially also having different timing relationships (HARQ), such as from a UL grant to a corresponding UL transmission, it may be that the UE 110, when generating the extended PHR MAC CE, you may not know if there will be any uplink transmission on the other carriers in the reference intervals / TTIs / subframes. The UE 110 may not be fast enough to process the UL grant (s) of the overlapping TTI (s) on the other carriers when calculating the power capacity information. As an example related to scenario 200, when generating the extended PHR MAC CE for a TT1 CC1 transmission, the UE may not be aware of the presence of a TTi + i UL grant corresponding to a PHR reference TTI in TTIi + 3 in CC2. Therefore, TTIi + 3 may not be a good choice as a PHR reference TTI. According to this example, if the PHR reference TTI is defined as TTIi + 3, just like the last overlapping TTI, the corresponding uplink grant can be received in TTIi + i. In this implementation, scenario 200 may be just an example that shows that a UL concession in TTL can correspond to an uplink transmission in TTIi + 2.
    [032] Given the above considerations, according to this modality, the reference TTI for the calculation of PH can be defined as the first overlapping TTI, as shown in scenario 200. The detailed behavior of the UE 110 according to this modality can include the following: when the maximum power procedure has determined that at least
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    19/37 minus a PHR was triggered at TTIn-2 at CC1, in which an uplink lease is received, the corresponding uplink transmission occurs at TTIn at CC1, UE 110 can start generating PHR MAC CE extended. To do this, the UE 110 can first determine the PHR reference range / TTI for the other activated carrier cells / server cells, that is, TTIi on a CC2 and TTIs on a CC3 according to this modality. In addition, UE 110 can determine the interval / TTI at which UL concessions associated with the respective PHR reference TTI occur, that is, TTIi-2 in a CC2 and TTIs-2 in a CC3. The UE 110 can monitor a PDCCH (UL grant) at these intervals / TTIs to know if a transmission will occur in the PHR reference TTI and, therefore, to be able to calculate the power capacity for the reference TTI. The UE 110 can then calculate the power capacity for TTIn in a CC1, the power capacity for TTIi in a CC2 and the power capacity for TTIs in a CC3 and generate the PHR MAC CE that is transmitted in the TTIn in a CC1.
    [033] The definition of the PHR reference TTI according to this modality can guarantee that the corresponding UL concessions for the other carriers / server cells can be considered by the UE for the calculation of the extended PHR MAC CE. However, it may still be the case that the processing time can be very tight and the UE 110 can report a virtual PHR to other component cells / carriers. For example, uplink leases in other cells may not be considered for a PH calculation.
    [034] Again, referring to scenario 200, it can be
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    20/37 it is preferable, from a processing point of view of a UE 110, to transmit the extended power capacity report MAC CE on a CC3 in TTIs, rather than on a CC1 in a TTL. The reason is that the UE 110 may already be aware of an uplink lease received on a CC1 on a TTIn-2 when calculating the transmission capacity report MAC MAC for transmission on a CC3 and may also consider a concession of Potential UL received in a TTIi-2 in a CC2. In general, the UE 110 can transmit the PHR MAC CE extended on that carrier which allows the UE 110 to consider uplink concessions on the other carriers / server cells, such as the shortest period of time between the uplink grant and the corresponding uplink transmission.
    [035] Due to the support of several numerologies through and within a server cell, there may be different time relationships between a UL concession and the corresponding uplink transmission for different component carriers / server cells, as already described above. Therefore, it may occur that the UE 110 cannot process and consider all potential uplink leases associated with the PHR reference TTI for all server cells when calculating the PH information for transmission of the PHR MAC CE. As another example related to scenario 200, UE 110 may fail to consider a potential link transmission
    Ascending in TTIi in a CC2, an time that an concession in Potential UL is received in TTIi-2 to calculate at PH information for all at three carriers server components / cells for generate the CE MAC's PHR
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    21/37 extended that is transmitted on a TTIN on a CC1. Although scenario 200 shows an exemplary concession on CC2 to show the time relationship between an UL concession and a corresponding uplink transmission, in this example, since the reference PHR TTI for CC2 is in accordance with a TTIi of one mode, the corresponding uplink grant can be received on a TTIi-2. According to this modality, in the case where the UE 110 is unable to determine if there is an uplink transmission in the PHR reference TTI to any of the server cells activated when generating the PHR MAC CE, the ability to power can be calculated assuming that no uplink transmission occurs. For example, a virtual PH can be reported for the corresponding server cell.
    [036] For NR, an uplink transmission mode without concession can be supported, in which uplink resources are pre-allocated to the UE 110, similar to the Semi-Persistent Programming (SPS) operation in LTE, which avoids the need to send a schedule request first and wait for an uplink lease before you can send an uplink transmission. The transmission mode without concession can be used for services that are very critical in terms of delay, such as URLLC. Since the UE 110 can have a valid uplink grant for each TTI, such as in which an SPS periodicity is defined for a TTI, the UE 110 can use only the allocated resources and make an uplink transmission when there is uplink data available for transmission. The UE 110 can prevent a
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    22/37 uplink transmission opportunity, such as ignoring the uplink concession if data is not available for transmission. Similar to the modality described above, the UE 110 may not be able to determine whether there will be an uplink transmission for a transmission mode without concession in the PHR reference TTI when generating the extended PHR MAC CE content, depending on availability data, the UE 110 can ignore or proceed with the UL grant. In this case, the UE 110 may, according to this modality, assume that no uplink transmission occurs. For example, a virtual PH can be reported for the corresponding server cell.
    [037] Figures 3 and 4 are examples of scenarios 300 and 400 that illustrate when intervals / TTI / limits for CC1 and CC3 are not aligned according to a possible modality. For example, for CA in NR, even though a symbol timing may be aligned between different carriers / server cells, the TTI range / limits may not be aligned. For those cases presented in scenarios 300 and 400, the reference PHR TTI can be defined. As shown in scenario 400, according to this modality, the PHR reference TTI can be defined as the first fully overlapping TTI, such as TTIs + i in a CC3 and TTI in a CC2. Choosing, for example, TTIs for CC3 as the reference TTI may mean that the reference TTI starts earlier than the TTI where the PHR is transmitted, such as in the TTIn on a CC1, which can be avoided according to this modality . By the same token, the PHR reference TTI for CC1 can be defined as TTIn in scenario 300, for
    Petition 870190094439, of 9/20/2019, p. 38/79
    23/37 example, the PHR reference TTI cannot be started before the TTI in which the PHR MAC CE is transmitted.
    [038] According to another modality, the UE 110 can calculate the power capacity for component carriers / server cells in which the PHR MAC CE is not always transmitted based on some reference format, such as usage as predefined resource allocation. Taking scenario 200 as an example, according to this modality, the UE 110 can calculate the PH for CC1, for example, the PHR MAC CE can be transmitted on a CC1 based on the actual uplink transmissions and the UE 110 can calculate the PH for CC2 and CC3 based on a reference format, such as using a virtual PHR. This modality can allow a simple calculation of the power capacity information for all active carriers / server cells from a processing power point of view. For example, there may be no dependence on different timing / length ratios of TTI due to different numerologies used on carriers. According to a possible implementation, network 140 can configure whether the PH for the component carriers / server cells in which the PHR MAC CE is not transmitted can be calculated based on a real uplink transmission or based on some reference format / allocation.
    [039] Power control parameters specific to numerology can also be supported. For example, to meet the strict reliability requirements for URLLC traffic, the parameter P0_PUSCH and / or a can be configured differently for a numerology used
    Petition 870190094439, of 9/20/2019, p. 39/79
    24/37 for URLLC compared to a numerology used for eMBB. For a power capacity report calculated based on a transmission / reference format, such as a virtual PHR, gNB 120 can be aware of which uplink power control parameters the UE 110 uses for the calculation in order to interpret PH information correctly. Therefore, according to this modality, a predefined numerology can be used for the calculation of a virtual PHR. According to an implementation, the UE 110 can use the reference numerology of the component carrier / server cell to calculate the power capacity based on a transmission / reference format. A UE can have a reference numerology on a given NR carrier that can define the duration of a subframe for the given NR carrier.
    [040] According to another modality, carriers / server cells for AC in NR can be grouped into several groups of power capacity reports. For example, according to an implementation, server cells with the same numerologies or length of TTI can be grouped. Since a timing granularity can be the same between server / carrier cells within a PHR group, the PHR reports for a PHR group can be similar to a case of CA in LTE. The network 140 can configure the UE 110 with the different PHR pooling information. The UE 110 can send power capacity information to all activated server / carrier cells in a PHR group, such as an extended PHR MAC CE per PHR group. The PH report, such as a PHR MAC CE, can
    Petition 870190094439, of 9/20/2019, p. 40/79
    25/37 be sent to any server cell in the PHR group with uplink resources available.
    [041] There may be PHR triggering conditions defined by PHR group. For example, the PHR can be triggered for a PHR group, in case the trigger conditions are met by at least one of the server cells contained in a PHR group. Alternatively, the trigger conditions can be common to all server / carrier cells, regardless of a PHR group. Since for NR a UE can aggregate server cells / carriers of different frequency bands, such as high frequency carriers above 6 Ghz and low frequency carriers below 6 Ghz, in which the conditions of a radio channel are quite different, there may be a dl-PathlossChange value defined by PHR group report with the assumption that HF and LF carriers are grouped into different PHR groups.
    [042] According to another additional modality, the PHR trigger can be propagated to the other PHR groups when a PHR is triggered for a PHR group. This spread of the PHR trigger can ensure that a PHR is transmitted to all PHR groups when a PHR is triggered in any of the PHR groups.
    [043] Since there may be different parameter definitions for different beam links, the loss of path can also be quite different when changing the beam link. According to another additional modality, when changing the beam / pair link and informing the gNB about it, the UE can also trigger a PHR (since conditions of
    Petition 870190094439, of 9/20/2019, p. 41/79
    26/37 channel can also change significantly when changing the beam link). According to one modality, the PHR is reported together with information related to the beam / pair link.
    [044] Figure 5 is an example flow chart 500 that illustrates the operation of an apparatus, such as the UE 110, according to a possible modality. In 510, a first component carrier that has a first TTI and a second component carrier that has a second TTI can be communicated. The second TTI can be different or equal to the first TTI. In 520, it can be seen that a PHR was triggered for at least one of the first component carrier and / or the second component carrier.
    [045] In 530, a first uplink grant can be received corresponding to a first uplink transmission on the first component carrier. In 540, a first PHR reference TTI corresponding to the first uplink transmission on the first carrier can be determined. The first PHR reference TTI can be a TTI for which the first uplink grant grants the first uplink transmission on the first component carrier. In 550, a first PHR for the first carrier
    component can be generated based in the first TTI in reference from PHR • [046] In 560, Can be given a second TTI in reference from PHR on Monday carrier component. In wake up
    with a possible implementation, the first PHR reference TTI can start at a first moment, the uplink transmission can be a first link transmission
    Petition 870190094439, of 9/20/2019, p. 42/79
    27/37 ascending and the second PHR reference TTI can be the first TTI superimposed on the second component carrier where the first PHR reference TTI overlaps the second PHR reference TTI. For example, the second PHR reference TTI may be the first TTI superimposed on the second component carrier in which the first uplink transmission overlaps the second PHR reference TTI. According to another possible implementation, the second PHR reference TTI can start at a second moment in which the first moment of the first PHR reference TTI can be before the second moment. According to another possible implementation, the second PHR reference TTI can be an overlapping TTI in which one of the first uplink transmission and the second uplink transmission completely overlaps the other among the first uplink transmission and the second uplink transmission. According to another possible implementation, the second PHR reference TTI can be the first TTI superimposed on the second component carrier in which one of the first PHR reference TTI and the second PHR reference TTI totally overlaps the other among the first PHR reference TTI and the second PHR reference TTI.
    [047] In 570, an uplink concession TTI can be determined in which a second uplink concession can be received. The second uplink grant may correspond to a second uplink transmission in the second PHR reference TTI on the second component carrier. In 580, the second uplink concession can be monitored in the
    Petition 870190094439, of 9/20/2019, p. 43/79
    28/37 uplink. The second uplink grant can grant the second uplink transmission in the second PHR reference TTI that starts at the same time as the first PHR reference TTI.
    [048] In 590, a second PHR can be generated for the second component carrier based on the second PHR reference TTI. There may be additional component carriers, such as a third component carrier, and a PHR reference TTI can be determined and a corresponding PHR can be generated for each additional component carrier. The second PHR for the second component carrier for the second PHR reference TTI can be generated based on a monitoring of the second uplink concession. The second PHR for the second PHR reference TTI can also be generated when the second uplink grant is received in the uplink grant TTI. The second PHR can be additionally generated using a predefined uplink transmission for the second component carrier when the UE 110 is unable to determine whether there is an uplink transmission on the second component carrier. The predefined uplink transmission can be a virtual uplink transmission. For example, the UE can generate the power capacity report assuming that no uplink transmission occurs on the second component carrier. The UE can also generate the PHR in this way when the second uplink lease is not sent, such as when a non-lease transmission mode is used. The UE can additionally generate the PHR in this way as a standard way to generate the PHR and may not
    Petition 870190094439, of 9/20/2019, p. 44/79
    29/37 depending on the different timing / length ratios of TTI due to different numerologies used on different carriers. According to a possible implementation, the second PHR can be generated based on a predefined numerology when using a predefined uplink transmission for the calculation of the second power capacity report. For example, the UE 110 can use component carrier / cell reference reference numerology to calculate power capacity based on a transmission / reference format. Component carriers with the same TTI may have the same numerology. According to another possible implementation, the second PHR can be generated only when the second TTI is equal to the first TTI. In this implementation, power capacity information can only be sent to a group of component carriers with the same TTI, in contrast to a power capacity report for each component carrier.
    [049] In 595, the first PHR and the second PHR can be transmitted in an uplink transmission, such as in the first uplink transmission. According to a possible implementation, the first uplink lease can be a first time period outside the first PHR reference TTI, the second uplink lease can be a second time period outside the second PHR reference TTI. and the PHR can be transmitted on the component carrier with the shortest period of time between the corresponding uplink grant and the corresponding PHR reference TTI. For example, the UE 110 can transmit the PHR MAC CE extended in the
    Petition 870190094439, of 9/20/2019, p. 45/79
    30/37 carrier that allows UE 110 to consider uplink concessions on other carriers / server cells. According to a possible implementation, the first PHR and the second PHR can be transmitted in a PHR MAC CE in the uplink transmission.
    [050] It should be understood that, despite the specific steps as shown in the figures, a variety of additional or different steps can be performed depending on the modality, and one or more of the specific steps can be reorganized, repeated or eliminated entirely, depending on the modality. In addition, some of the steps taken can be repeated on a continuous or permanent basis while other steps are taken. In addition, different steps can be performed by different elements or in a single element of the revealed modalities.
    [051] Figure 6 is an example block diagram of an apparatus 600, such as UE 110, base station 120, an access point or any other device disclosed in this document, according to a possible embodiment. Apparatus 600 may include a housing 610, a controller 620 within housing 610, a set of audio input and output circuits 630 coupled to controller 620, a screen 640 coupled to controller 620, at least one transceiver 650 coupled to controller 620 , an antenna 655 attached to transceiver 650, a user interface 660 attached to controller 620, a memory 670 attached to controller 620 and a network interface 680 attached to controller 620. Apparatus 600 can perform the methods described in all modes.
    Petition 870190094439, of 9/20/2019, p. 46/79
    31/37 [052] Screen 640 can be a viewfinder, a liquid crystal display (LCD), a light emitting diode (LED) screen, a plasma screen, a projection screen, a touchscreen or any other device that displays information. The at least one transceiver 650 may include a different transmitter, receiver, multiple transceivers and / or transceivers for different frequencies and / or different wireless communication interfaces. The 630 audio input and output circuitry may include a microphone, speaker, transducer or any other audio input and output circuitry. The 660 user interface can include an alphanumeric keyboard, a keyboard, buttons, a touch panel, a joystick, a touch screen, another additional screen, or any other useful device to provide an interface between a user and an electronic device . The 680 network interface can be a Universal Serial Bus (USB) port, an Ethernet port, an infrared transmitter / receiver, an IEEE 1394 port, a Wireless Local Area Network (WLAN) transceiver or any other interface that can connect a device to a network, device or computer and that can transmit and receive data communication signals. The 670 memory can include a random access memory, a read-only memory, an optical memory, a solid state memory, a flash memory, a removable memory, a hard disk, a cache or any other memory that can be attached to an appliance.
    [053] Device 600 or controller 620 can implement any operating system, such as Microsoft Windows®, UNIX®, LINUX®, Android ™ or any other system
    Petition 870190094439, of 9/20/2019, p. 4ΊΠ9
    32/37 operational. The device's operating software can be written in any programming language, such as, for example, C, C ++, Java or Visual Basic. The device's software can also be run in an application framework, such as, for example, a Java® framework, a .NET® framework or any other application framework. The software and / or the operating system can be stored in memory 670 or elsewhere on device 600. Device 600 or controller 620 may also use hardware to implement the disclosed operations. For example, controller 620 can be any programmable processor. The revealed modalities can also be implemented in a general purpose or specific computer, a programmed microprocessor or a microprocessor, elements of peripheral integrated circuits, a specific application integrated circuit or other integrated circuits, hardware / electronic logic circuits, such as a discrete element circuit, a programmable logic device, such as a programmable logic matrix, field programmable gate matrix or the like. In general, controller 620 can be any controller, processor device or devices that can operate an apparatus and implement the disclosed modalities. Some or all of the additional elements of the apparatus 600 may also perform some or all of the operations of the disclosed modalities.
    [054] In operation, at least one transceiver 650 can communicate at least on a first component carrier that has a first TTI and on a second component carrier that has a second TTI. Controller 620 can verify that a PHR has been triggered for at least one of the first
    Petition 870190094439, of 9/20/2019, p. 48/79
    33/37 component carrier, the second component carrier and / or other component carriers. Transceiver 650 can receive an uplink lease corresponding to an uplink transmission on the first component carrier. Controller 620 can determine a first PHR reference TTI corresponding to the uplink transmission on the first component carrier. Controller 620 can generate a first PHR for the first component carrier based on the first PHR reference TTI.
    [055] Controller 620 can determine a second PHR reference TTI on the second component carrier. According to a possible implementation, the second PHR reference TTI can be the first TTI superimposed on the second component carrier in which the first PHR reference TTI overlaps the second PHR reference TTI. According to another possible implementation, the second PHR reference TTI can be the first TTI superimposed on the second component carrier in which one of the first PHR reference TTI and the second PHR reference TTI totally overlaps the other among the first PHR reference TTI and the second PHR reference TTI.
    [056] Controller 620 can generate a second PHR for the second component carrier based on the second PHR reference TTI. According to a possible implementation, the second PHR can be generated based on a predefined numerology when using a predefined uplink transmission for the calculation of the second PHR. According to another possible implementation, the second PHR can be generated
    Petition 870190094439, of 9/20/2019, p. 49/79
    34/37 only when the second TTI is equal to the first TTI. Transceiver 650 can transmit the first PHR and the second PHR in the uplink transmission.
    [057] According to a possible modality, the uplink concession can be a first uplink concession and the uplink transmission can be a first uplink transmission. Controller 620 can determine an uplink lease TTI in which a second uplink lease can be received. The second uplink grant may correspond to a second uplink transmission in the second PHR reference TTI on the second component carrier. The second uplink grant can grant the second uplink transmission in the second PHR reference TTI that starts at the same time as the first PHR reference TTI. Controller 620 can monitor the second uplink lease in the uplink lease TTI. Controller 620 can generate the second PHR for the second component carrier for the second PHR reference TTI based on a monitoring of the second uplink concession. Controller 620 can generate the second PHR for the second PHR reference TTI when the second uplink lease is received at the uplink lease TTI. The first uplink lease can be a first time period outside the first PHR reference TTI, the second uplink lease can be a second time period outside the second PHR reference TTI and transceiver 650 can transmit the PHR on the component carrier with the shortest time period
    Petition 870190094439, of 9/20/2019, p. 50/79
    35/37 between the corresponding uplink concession and the corresponding PHR reference TTI. According to a possible implementation, controller 620 may generate the second PHR using a predefined uplink transmission for the second component carrier when the device 600 is unable to determine whether there is an uplink transmission on the second component carrier. According to another possible implementation, the second PHR reference TTI can be an overlapping TTI in which one of the first uplink transmission and the second uplink transmission completely overlaps the other among the first uplink transmission and the second uplink transmission.
    [058] It should be noted that, throughout the present disclosure, the term interval / TTI / subframe was used to denote the unit to program a data transmission. Data transmissions can also be programmed to cover one or more intervals.
    [059] The method of this disclosure can be implemented on a programmed processor. However, controllers, flowcharts and modules can also be implemented in a general purpose or specific purpose computer, a programmed microcontroller or microprocessor and peripheral integrated circuit elements, an integrated circuit, an electronic or hardware logic circuit, such as a discrete element circuit, programmable logic device or the like. In general, any device on which a finite state machine resides capable of implementing the flowcharts shown in the figures can be used to
    Petition 870190094439, of 9/20/2019, p. 51/79
    36/37 implement the processor functions of that disclosure.
    [060] Although this disclosure has been described in specific ways, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. For example, several components of the modalities can be exchanged, added or replaced in the other modalities. In addition, all elements of each figure are not necessary for the operation of the revealed modalities. For example, a technician on the subject of revealed modalities can make and use the teachings of revelation by simply employing the elements of the independent claims. Consequently, the disclosure modalities as presented in this document are intended to be illustrative and not limiting. Various modifications can be made without departing from the spirit and scope of the revelation.
    [061] In this document, relational terms, such as first, second and similar, can be used only to distinguish an entity or action from another entity or action, without necessarily requiring or implying any such relationship or actual order between such entities or actions. The phrase at least one of, at least one selected from the group of, or at least one selected from, followed by a list is defined as meaning one, some or all, but not necessarily all, elements in the list. The terms comprises, which comprises, which includes or any other variation thereof, are intended to cover a non-exclusive inclusion, so that a process, method, article or apparatus comprising a list of elements does not include only those elements, but can include others
    Petition 870190094439, of 9/20/2019, p. 52/79
    37/37 elements not expressly listed or inherent in such a process, method, article or apparatus. An element carried out by one, one or similar does not exclude, without further restrictions, the existence of additional identical elements in the process, method, article or apparatus comprising the element. In addition, the term other is defined as at least one second or more. The terms it includes, has and the like, as used in this document, are defined as you understand. In addition, the background section is written according to the inventor's own understanding of the context of some modalities at the time of registration and includes the inventor's own recognition of any problems with existing technologies and / or problems experienced in the inventor's own work.
    权利要求:
    Claims (25)
    [1]
    1. Method in user equipment, the method is characterized by the fact that it comprises:
    communicating on a first component carrier that has a first transmission time slot and on a second component carrier that has a second transmission time slot;
    verify that a power capacity report was triggered for at least one selected from the first component carrier and the second component carrier;
    receiving an uplink grant corresponding to an uplink transmission on the first component carrier;
    determining a first reference capacity transmission time interval corresponding to the uplink transmission on the first component carrier;
    generating a first power capacity report for the first component carrier based on the first power capacity report reference transmission time interval;
    determining a second power capacity report reference transmission time interval on the second component carrier;
    generating a second power capacity report for the second component carrier based on the second power capacity report reference transmission time interval; and transmit the first power capacity report and the second power capacity report on
    Petition 870190094439, of 9/20/2019, p. 54/79
    [2]
    2/10 uplink transmission.
    2. Method according to claim 1, characterized by the fact that the uplink concession comprises a first uplink concession and the uplink transmission comprises a first uplink transmission, and in which the method further comprises determining a uplink lease transmission time slot in which a second uplink lease can be received, the second uplink lease corresponding to a second uplink transmission in the second reference transmission time slot. power capacity report on the second component carrier, and monitor the second uplink grant in the uplink grant transmission time interval and in which generating the second power capacity report comprises generating the second power capacity report for the second carrier co component for the second power capacity report reference time interval based on a monitoring of the second uplink concession.
    [3]
    3. Method, according to claim 2, characterized by the fact that generating the second power capacity report comprises generating the second power capacity report for the second power capacity report reference transmission time interval when the second uplink lease is received in the link lease transmission time slot
    Petition 870190094439, of 9/20/2019, p. 55/79
    Ascending 3/10.
    [4]
    4. Method according to claim 2, characterized by the fact that the second uplink grant grants the second uplink transmission in the second power capacity report reference transmission time interval that starts at the same time as the first power capacity report reference transmission time interval.
    [5]
    5. Method, according to claim 2, characterized by the fact that the first uplink concession is a first time period outside the first power capacity report reference transmission time interval, in which the second concession uplink is a second time period outside the second power capacity report reference transmission time interval, and in which transmission comprises transmitting the power capacity report on the component carrier with the shortest time between concession corresponding uplink link and the corresponding power capacity report reference transmission time interval.
    [6]
    6. Method, according to claim 2, characterized by the fact that generating the second power capacity report comprises generating the second power capacity report using a predefined uplink transmission for the second component carrier when the user equipment is unable to determine whether an uplink transmission exists on the second carrier
    Petition 870190094439, of 9/20/2019, p. 56/79
    4/10 component.
    [7]
    Method according to claim 2, characterized in that the second power capacity report reference transmission time interval comprises an overlapping transmission time interval in which one of the first uplink transmission and the second uplink transmission completely overlaps the other between the first uplink transmission and the second uplink transmission.
    [8]
    8. Method according to claim 1, characterized by the fact that the second power capacity report reference transmission time interval comprises the first transmission time interval superimposed on the second component carrier in which the first transmission interval power capacity report reference transmission time overlaps with the second power capacity report reference transmission time interval.
    [9]
    9. Method according to claim 7, characterized by the fact that the first power capacity report reference transmission time interval starts at a first moment, and in which the second reference transmission time interval of power Power capacity report starts at a second moment in which the first moment is before the second moment.
    [10]
    10. Method according to claim 1, characterized by the fact that the second transmission capacity report reference time interval
    Petition 870190094439, of 9/20/2019, p. 57/79
    5/10 power comprises the first transmission time interval superimposed on the second component carrier in which one of the first capacity report reference transmission time interval and the second capacity report reference transmission time interval of power completely overlaps the other of the first power capacity report reference transmission time interval and the second power capacity report reference transmission time interval.
    [11]
    11. Method according to claim 1, characterized by the fact that the second transmission time interval is different from the first transmission time interval.
    [12]
    12. Method, according to claim 1, characterized by the fact that generating comprises generating the second power capacity report based on a predefined numerology when using a predefined uplink transmission for the calculation of the second power capacity report .
    [13]
    13. Method, according to claim 1, characterized by the fact that generating comprises generating the second power capacity report only when the second transmission time interval is the same as the first transmission time interval.
    [14]
    14. Method, according to claim 1, characterized by the fact that transmit comprises transmitting the first power capacity report and the second power capacity report in an access control control element to the media report medium.
    Petition 870190094439, of 9/20/2019, p. 58/79
    6/10 power capacity in uplink transmission.
    [15]
    15. Apparatus characterized by the fact that it comprises: at least one transceiver that communicates in a first component carrier that has a first transmission time interval and in a second component carrier that has a second transmission time interval; and a controller coupled to the transceiver in which the controller checks whether a power capacity report has been triggered for at least one selected from the first component carrier and the second component carrier, in which the transceiver receives an uplink lease corresponding to a transmission of uplink on the first component carrier, where the controller determines a first time interval of reference transmission of power capacity corresponding to the uplink transmission on the first component carrier, with the controller generating a first report of capacity power for the first component carrier based on the first power capacity report reference transmission time interval, the controller determining a second power capacity report reference transmission time interval on the second component capacity and the controller generates a second power capacity report for the second component carrier based on the second power capacity report reference transmission time interval, and on which the transceiver transmits the first power report
    Petition 870190094439, of 9/20/2019, p. 59/79
    7/10 power capacity and the second power capacity report on the uplink transmission.
    [16]
    16. Apparatus according to claim 15, characterized by the fact that the uplink concession comprises a first uplink concession and the uplink transmission comprises a first uplink transmission, in which the controller determines an interval uplink lease transmission time period in which a second uplink lease can be received, the second uplink lease corresponding to a second uplink transmission in the second reporting report reference transmission time slot. power capacity on the second component carrier, monitors the second uplink grant in the uplink grant transmission time interval, and generates the second power capacity report for the second component carrier for the second uplink transmission time interval cover report reference power city based on a monitoring of the second uplink concession.
    [17]
    17. Apparatus according to claim 16, characterized by the fact that the controller generates the second power capacity report for the second power capacity report reference transmission time interval when the second uplink concession is received in the uplink concession transmission time slot.
    Petition 870190094439, of 9/20/2019, p. 60/79
    8/10
    [18]
    18. Apparatus according to claim 16, characterized by the fact that the second uplink grant grants the second uplink transmission in the second power capacity report reference transmission time interval that starts at the same time as the first power capacity report reference transmission time interval.
    [19]
    19. Apparatus according to claim 16, characterized by the fact that the first uplink concession is a first time period outside the first power capacity report reference transmission time interval, in which the second concession uplink is a second time period outside the second power capacity report reference transmission time interval, and in which the transceiver transmits the power capacity report on the component carrier with the shortest time between concession corresponding uplink link and the corresponding power capacity report reference transmission time interval.
    [20]
    20. Device, according to claim 16, characterized by the fact that the controller generates the second power capacity report using a predefined uplink transmission for the second component carrier when the device cannot determine if there is a uplink transmission on the second component carrier.
    [21]
    21. Apparatus according to claim 16,
    Petition 870190094439, of 9/20/2019, p. 61/79
    9/10 characterized by the fact that the uplink transmission comprises a first uplink transmission, and the second power capacity report reference transmission time interval comprises an overlapping transmission time interval in which one of the first uplink transmission and the second uplink transmission completely overlaps the other between the first uplink transmission and the second uplink transmission.
    [22]
    22. Apparatus according to claim 15, characterized in that the second power capacity report reference transmission time interval comprises the first transmission time interval superimposed on the second component carrier in which the first transmission interval power capacity report reference transmission time overlaps with the second power capacity report reference transmission time interval.
    [23]
    23. Apparatus according to claim 15, characterized by the fact that the second power capacity report reference transmission time interval comprises the first transmission time interval superimposed on the second component carrier in which one of the first power capacity report reference transmission time interval and the second power capacity report reference transmission time interval overlaps the other among the first power capacity report reference transmission time interval it's the
    Petition 870190094439, of 9/20/2019, p. 62/79
    10/10 second power capacity report reference time interval.
    [24]
    24. Apparatus according to claim 15, characterized by the fact that generating comprises generating the second power capacity report based on a predefined numerology when using a predefined uplink transmission for the calculation of the second power capacity report .
    [25]
    25. Apparatus according to claim 15, characterized by the fact that generating comprises generating the second power capacity report only when the second transmission time interval is the same as the first transmission time interval.
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    同族专利:
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    US10980046B2|2021-04-13|
    US20190306874A1|2019-10-03|
    WO2018175077A1|2018-09-27|
    CN110463290A|2019-11-15|
    EP3603229A1|2020-02-05|
    US20210212092A1|2021-07-08|
    US20180279339A1|2018-09-27|
    US10375719B2|2019-08-06|
    KR20190128175A|2019-11-15|
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    法律状态:
    2021-10-19| B350| Update of information on the portal [chapter 15.35 patent gazette]|
    优先权:
    申请号 | 申请日 | 专利标题
    US15/465,235|US10375719B2|2017-03-21|2017-03-21|Method and apparatus for power headroom reporting procedure for new radio carrier aggregation|
    PCT/US2018/020280|WO2018175077A1|2017-03-21|2018-02-28|Method and apparatus for power headroom reporting procedure for new radio carrier aggregation|
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