CN108702238A - Uplink control information and data are physically multiplexed on ink Shared Channel - Google Patents

Abstract

Technology for transmitting uplink control information (UCI) in 5G physical uplink shared channels (xPUSCH) is provided.By allowing to transmit UCI on xPUSCH, UCI performances can be improved.UCI and data can be multiplexed on xPUSCH.UCI and data can be multiplexed by time division multiplexing (TDM) or frequency division multiplexing (FDM) mode.UCI can be mapped on xPUSCH by time priority mode or frequency-first fashion.Down link control information can provide the resource allocation for UCI for mobile device, and provide the mode for being multiplexed UCI and data on xPUSCH.XPUSCH can be a part for the self-contained time division duplexs of 5G (TDD) subframe structure or frequency division duplex (FDD) subframe structure.

Description

Uplink control information and data are physically multiplexed on ink Shared Channel

Related application

This application claims the preferential of No. 62/295,927 U.S. Provisional Patent Application submitted for 16 days 2 months in 2016 Power, entire contents are incorporated herein by reference.

Technical field

The embodiments herein relates in general to the communication between the equipment in broadband wireless communication network.

Background technology

Uplink control information (UCI) is usually carried with message authentication agreement (for example, hybrid automatic repeat-request (HARQ) retransmission scheme) related information and the information about the operating conditions at mobile device.In many instances, UCI Payload may be very big.For many conventional wireless communication systems, UCI is restricted to be communicated by control channel.It will UCI, which is restricted to certain control channels, may prevent the UCI performances of robust.It not yet develops and overcomes lacking for these conventional wireless systems The sunken improved technology and system for ensuring improved UCI performances, includes these technology and systems for 5G systems.

Description of the drawings

Fig. 1 shows Illustrative Operating Environment.

Fig. 2A shows the self-contained time division duplex subframe structure of exemplary downlink.

Fig. 2 B show the self-contained time division duplex subframe structure of example uplink.

Fig. 3 shows exemplary self-contained subframe structure, based on for physical uplink shared channel (xPUSCH) biography Defeated frequency prioritized resources mapping scheme.

Fig. 4 shows exemplary self-contained subframe structure, based on for including uplink control information (UCI) The frequency prioritized resources mapping scheme of xPUSCH transmission.

Fig. 5 A show the first exemplary self-contained subframe structure, based on for including the UCI and data on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of frequency division multiplexing (FDM).

Fig. 5 B show the second exemplary self-contained subframe structure, based on for including the UCI and data on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of multiplexing based on FDM.

Fig. 6 A show the first exemplary self-contained subframe structure, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing based on FDM of UCI and data.

Fig. 6 B show the second exemplary self-contained subframe structure, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing based on FDM of UCI and data.

Fig. 6 C show the exemplary self-contained subframe structure of third, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing based on FDM of UCI and data.

Fig. 7 shows exemplary self-contained subframe structure, wherein is mapped in a manner of time priority with data in xPUSCH UCI。

Fig. 8 shows the exemplary coding schemes for UCI transmission.

Fig. 9 shows the embodiment of logic flow.

Figure 10 shows the embodiment of storage medium.

Figure 11 shows the embodiment of the first equipment.

Figure 12 shows the embodiment of the second equipment.

Figure 13 shows the embodiment of wireless network.

Specific implementation mode

Various embodiments can usually be related to for transmitting uplink in 5G physical uplink shared channels (xPUSCH) The technology of link control message (UCI).By allowing to transmit UCI on xPUSCH, UCI performances can be improved.In various implementations In example, UCI and data can be multiplexed on xPUSCH.Time division multiplexing (TDM) or frequency division multiplexing (FDM) side can be passed through UCI and data are multiplexed by formula.UCI can be mapped on xPUSCH by time priority mode or frequency-first fashion. Down link control information can provide the resource allocation for UCI for mobile device, and provide for being incited somebody to action on xPUSCH The mode that UCI and data are multiplexed.XPUSCH can be the self-contained time division duplexs of 5G (TDD) subframe structure or frequency division duplex (FDD) part for subframe structure.It is described and claimed other embodiment.

Various embodiments may include one or more elements.Element may include being arranged as executing any of certain operations Structure.According to given design parameter or the needs of performance constraints set, each element may be implemented as hardware, software or Any combination thereof.Although for example, embodiment can be described with the element of the limited quantity in particular topology, the reality It substituting topology can includes more or fewer elements according to the needs of given realization method to apply example.It is worth noting that, The a particular feature, structure, or characteristic that any reference of " one embodiment " or " embodiment " is meaned that the embodiment is combined to describe It is included at least one embodiment.The phrase " in one embodiment " that occurs everywhere in specification, " in some embodiments In " and be not necessarily all referring to the same embodiment " in various embodiments ".

Presently disclosed technology can be related to using one or more wireless mobile broadband technologys one or more wireless Connect transmitting data.For example, various embodiments can be related to according to one or more third generation partner programs (3GPP), 3GPP long term evolutions (LTE) and/or advanced (LTE-A) technologies of 3GPP LTE and/or including its revision, derived version and variant Transmission of the standard of (including 4G and 5G wireless networks) on one or more be wirelessly connected.Various embodiments can additionally or Alternatively it is related to according to one or more global system for mobile communications (GSM)/Enhanced Data rates for GSM Evolution (EDGE), general Mobile communication system (UMTS)/high-speed packet accesses (HSPA) and/or has general packet radio service (GPRS) system (GSM/ GPRS) the transmission of the GSM (including its revision, derived version and variant) of technology and/or standard and/or standard.

The example of wireless mobile broadband technology and/or standard can also include but not limited to any Electrical and Electronic engineer 802.16 wireless broadband standard of association (IEEE) (such as IEEE 802.16m and/or 802.16p), ternational Mobile Telecommunications are advanced (IMT-ADV), global intercommunication microwave access (WiMAX) and/or WiMAX II, CDMA (CDMA) 2000 (for example, CDMA20001xRTT, CDMA2000EV-DO, CDMA EV-DV etc.), high-performance wireless Metropolitan Area Network (MAN) (HIPERMAN), WiMAX (WiBro), high-speed downlink packet access (HSDPA), high speed Orthogonal frequency division multiplexing (OFDM) grouping access (HSOPA), height Speed uplink packet access (HSUPA) technology and/or standard, including its revision, derived version and variant.

Some embodiments can additionally or alternatively be related to the channel radio according to other wireless communication techniques and/or standard Letter.The example of other wireless communication techniques and/or standard that can use in various embodiments can include but is not limited to it His IEEE wireless communication standards (such as IEEE 802.11, IEEE 802.11a, IEEE 802.11b, IEEE 802.11g, IEEE 802.11n, IEEE 802.11u, IEEE 802.11ac, IEEE 802.11ad, IEEE 802.11af and/or IEEE 802.11ah standards), by IEEE 802.11 efficient WLAN (HEW) seminar exploitation efficient Wi-Fi standards, Wi-Fi Alliance (WFA) wireless communication standard (such as Wi-Fi, Wi-Fi direct, Wi-Fi direct service, wireless gigabit (WiGig), WiGig Display extension (WDE), WiGig bus extensions (WBE), WiGig Serial Extensions (WSE) standard and/or by WFA adjacent to sensing network (NAN) task groups exploitation standard), machine type communication (MTC) standard (such as 3GPP technical reports (TR) 23.887,3GPP Those of embodied in technical specification (TS) 22.368 and/or 3GPP TS 23.682) and/or near-field communication (NFC) standard it is (all The standard such as developed by NFC forums), include revision, derived version and/or the variant of any of the above described content.Embodiment is not limited to These examples.

Other than the transmission on one or more be wirelessly connected, presently disclosed technology can also relate to by one or Multiple wired communication medias transferring content in one or more wired connections.The example of wired communication media may include drawing Line, cable, metal wire, printed circuit board (PCB), backboard, construction of switch, semi-conducting material, twisted-pair feeder, coaxial cable, optical fiber Deng.Embodiment is unrestricted in this regard.

Fig. 1 shows can such as to represent technology some realities that may be implemented for being multiplexed uplink control information and data Apply the Illustrative Operating Environment 100 of example.As further described herein, these technologies may include total in 5G physical uplink links It enjoys and is multiplexed uplink control information and data on channel (PUSCH).Operating environment 100 may include mobile device 102 and bee Nest base station 104.Mobile device 102 interface 106 can be communicated with base station 104 by radio communication.Mobile device 102 can be with It is smart phone, tablet computer, laptop, net book or can be carried out with one or more cordless communication networks wireless Other mobile computing devices of communication.As an example, mobile device 102 can be user equipment (UE).For example, base station 104 can To be cellular base station, such as evolution node B (eNB).For example, base station 104 can be the serving cell of UE 102, such as main service Cell or auxiliary serving cell.Wireless communication interface 106 can be for example for any wireless network described herein or standard (packet Include such as 4G, LTE or 5G wireless network) wireless interface.Mobile device 102 and base station 104 may be implemented described herein multiple Use technology.

It is expected that 5G wireless communication systems provide the visit to information for various users whenever and wherever possible in a wide variety of applications It asks and data sharing.Additionally, it is contemplated that 5G wireless communication systems are based on the 3GPP LTE with potential new wireless access technology (RAT) Advanced carry out evolution, to provide a user the seamless wireless solution connected with low latency including high speed.In order to provide low prolong Transmission, 5G wireless communication systems can use self-contained time division duplex (TDD) subframe structure late.

Fig. 2A and Fig. 2 B show exemplary self-contained TDD subframe structures.Self-contained TDD subframes can wrap in same subframe Include uplink (UL) and downlink (DL) communication.In some instances, self-contained TDD subframes may include confirming (ACK) Message and/or negative confirmation (NACK) message.In addition, self-contained TDD subframes can disappear in same subframe including ACK/NACK Breath, as can reception data corresponding with ACK/NACK message.ACK/NACK message can be automatic repeat request (ARQ) weight A part for biography scheme or hybrid automatic repeat-request (HARQ) retransmission scheme.

Fig. 2A shows the self-contained TDD subframe structures of exemplary DL 202.The self-contained TDD subframe structures of DL 202 can be by Fig. 1 The base station 104 of middle description and/or mobile device 102 are realized.The self-contained TDD subframe structures of DL 202 can be such as 5G DL from wrapping Subframe structure containing TDD.In this way, the channel and communication in the self-contained TDD subframe structures of DL 202 can be 5G channels and communication.

As shown in Figure 2 A, the self-contained TDD subframe structures of DL 202 may include physical downlink control channel (xPDCCH) 204, physical down link sharing channel (xPDSCH) 206, protection interval (GP) 208 and physical uplink control channel (xPUCCH)210.It, can be in xPDSCH 206 in order to adapt to the switching time between DL and UL communications and round-trip propagation delay GP 208 is inserted between xPUCCH 210.GP 208 can be with the duration of such as one or two OFDM symbol.DL The duration of self-contained TDD subframe structures 202 is by 212 instructions.

Fig. 2 B show the self-contained TDD subframe structures of exemplary UL 214.The self-contained TDD subframe structures of UL 214 can be by Fig. 1 The base station 104 of middle description and/or mobile device 102 are realized.The self-contained TDD subframe structures of UL 214 can be such as 5G DL from wrapping Subframe structure containing TDD.In this way, the channel and communication in the self-contained TDD subframe structures of UL 214 can be 5G channels and communication.

As shown in Figure 2 B, the self-contained TDD subframe structures of UL 202 may include xPDCCH 204, GP 208, physical uplink chain Share channel (xPUSCH) 216 and xPUCCH 210 in road.In order to adapt to the switching time between DL and UL communications and past back pass Delay is broadcast, GP 208 can be inserted between xPDCCH 204 and xPUSCH 216.The self-contained TDD subframe structures of UL 214 are held The continuous time can also be by 212 instructions.

XPUCCH 210 may include uplink control information (UCI).UCI may include HARQ ACK/NACK feedbacks And/or channel state information (CSI), including such as channel quality indicator (CQI), precoding matrix indicators (PMI) and/or Order designator (RI).For cmWave and mmWave frequency bands, UCI can also include wave beam relevant information, and such as wave beam forming is joined It examines signal (BRS) index and/or BRS receives power (BRS-RP) report.

In general, UCI may need performance more more robust than data channel.Further, since UCI payloads can include about The information content of the situation of mobile device (for example, mobile device or UE 102 for describing in Fig. 1), therefore UCI payloads may be opposite It is larger.Technique described herein makes it possible to carry UCI in the xPUSCH 216, with by xPUSCH 216 by UCI and Data are multiplexed to improve link budget, to improve the performance for the system for being limited to carry UCI in xPUCCH 210.

As shown in Figure 2 B, the data being multiplexed in a manner of time division multiplexing (TDM) in xPUSCH 216 and xPUCCH 210. XPUCCH 210 can have the duration of for example one or more OFDM symbols.A symbol is being distributed for xPUCCH 210 In the case of, increasing the quantity of the frequency resource for being used for transmission xPUCCH 210, may not to improve link as expection pre- It calculates.When distributing more frequency resources for xPUCCH 210, since code rate is reduced using increased noise power as cost, Therefore possibly it can not improve link budget.Therefore, in the case of identical transmission power, mobile device is (for example, mobile device 102) the maximum coupling loss (MCL) between base station (for example, base station 104) can keep identical -- and be used for transmission The link budget of xPUCCH 210 is also same.

In order to improve the link budget for being used for transmission UCI, technique described herein provides the data one with xPUSCH 216 It rises and carries UCI in xPUSCH 216.It is assigned on uplink shared channel (UL-SCH) in mobile device 102 In the case that the uplink resource and UCI payload sizes of transmission are relatively large, technique described herein enable UCI with The UL-SCH data of coding are transmitted in xPUSCH 216 together.

Fig. 3 shows exemplary self-contained subframe structure 300, based on the frequency prioritized resources mapping transmitted for xPUSCH Scheme.As shown in figure 3, self-contained subframe structure 300 may include xPDCCH 314, GP 316 and xPUSCH 318.It is self-contained The duration of subframe structure 300 can be by 320 instructions.Indicator 302 indicates the self-contained subframe relative to increased frequency Structure 300.Indicator 304 indicates the self-contained subframe structure 300 relative to the increased time.OFDM symbol index 322 is shown The content of self-contained subframe structure 300 relative to the OFDM symbol number occupied by self-contained subframe structure 300.As schemed Show, xPDCCH 314 occupies OFDM symbol " 0 ", and GP 316 occupies OFDM symbol " 1 ", and xPUSCH 318 occupies OFDM symbol " 2 " are arrived " 13 ".

It can be mapped by frequency domain mode of priority and be passed for the data in xPUSCH 318 of self-contained subframe structure 300 It is defeated.By mapping data transmission in xPUSCH 318 with frequency-first fashion, received from the base station for including subframe structure 300 (for example, base station 104) can decode xPUSCH 318 more quickly, this is because the pipeline of xPUSCH 318 and parallel processing can To be maximized.As shown in figure 3, xPUSCH 318 can be with acquisition frequency range 306.In the frequency model occupied by xPUSCH 318 Enclosing under 306 can be lower frequency range 308.Can be upper frequency on the frequency range 306 occupied by xPUSCH 318 Range 310.Frequency range 308 and 310 can be the frequency range not occupied by xPUSCH 318.Frequency range 308 and 310 can To be by another user occupancy or the frequency range used.It, can be most although not shown in FIG. 3 for the sake of simplicity XPUCCH is distributed in OFDM symbol (that is, OFDM symbol " 13 ") afterwards.Arrow 312 is shown with frequency-first fashion (for example, passing through (for example, from opposite lower frequency to upper frequency) acquisition frequency range 306 in a manner of symbol-by-symbol) it fills in xPUSCH 318 Data.

According to technique described herein, when UCI is scheduled for transmitting together with data in xPUSCH 318, UCI Resource impact (for example, frequency resource mapping) can follow principle identical with the resource impact of the data in xPUSCH 318 -- That is, with frequency-first fashion.Fig. 4 shows exemplary self-contained subframe structure 400, based on for the xPUSCH biographies including UCI Defeated frequency prioritized resources mapping scheme.It is arrived " 13 " as shown in figure 4, xPUSCH 318 can occupy OFDM symbol " 2 ", and UCI 402 can occupy OFDM symbol " 2 " -- that is, first OFDM symbol distributed for xPUSCH 318.OFDM symbol " 3 " arrives " 13 " may include data 404.The UCI 402 and data 404 in xPUSCH 318 can be mapped by frequency-first fashion, In, UCI 402 occupies the single OFDM symbol after GP 208.

Fig. 4 shows the multiplexing side based on TDM for UCI 402 and the transmission of data 404 in xPUSCH 318 or thereon One example of case.In general, UCI 402 can in xPUSCH 318, in any region of xPUSCH 318, in any frequency One or more OFDM symbols are occupied on rate region, and wherein, multiple occupied OFDM symbols are adjacent or non-conterminous.Each In kind embodiment, UCI 402 can cross over the entire uplink transmission region other than the region distributed for xPUCCH.This Sample is done, and can improve the link budget for UCI 402.Furthermore, it is possible to by frequency division multiplexing (FDM) mode in xPUSCH 318 The middle UL-SCH data by coding are multiplexed with UCI 402.

Various embodiments provide the multiplexing based on FDM of UCI and data on xPUSCH.Various embodiments will be used for The FDM schemes of the upper multiplex datas of PUSCH are provided as SC-FDMA schemes.Fig. 5 A show exemplary self-contained subframe structure 502, Frequency prioritized resources mapping based on the xPUSCH transmission for the multiplexing based on FDM including UCI and data on xPUSCH Scheme.As shown in Figure 5A, UCI 504 can be contained in the xPUSCH 318 of distribution.XPUSCH 318 can be with acquisition frequency model Enclose 506.Can be lower frequency range 510 under the frequency range 506 occupied by xPUSCH 318.It is accounted for by xPUSCH 318 It can be upper frequency range 508 on frequency range 506.Frequency range 508 and 510 can not accounted for by xPUSCH 318 Frequency range.Frequency range 508 and 510 can be by another user occupancy or the frequency range used.

UCI 504 can be with acquisition frequency range 512.Frequency range 512 can be the frequency range in frequency range 506. That is, UCI 504 can be assigned to as the upper frequency field of the data transmission regions distributed xPUSCH 318.UCI 504 can occupy or be assigned the entire duration that frequency range 512 reaches xPUSCH 318.As shown in Figure 5A, UCI 504 is accounted for With the upper frequency range 512 of the xPUSCH 318 of assigned frequency range 506.In this way, in xPUSCH 318 by UCI 504 with Data are multiplexed in a manner of FDM.

Fig. 5 B show exemplary self-contained subframe structure 514, based on the base for including UCI and data on xPUSCH In the frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing of FDM.As shown in Figure 5 B, UCI 516 can be contained in point In the xPUSCH 318 matched.XPUSCH 318 can be with acquisition frequency range 518.In the frequency range occupied by xPUSCH 318 It can be lower frequency range 522 under 518.Can be upper frequency model on the frequency range 518 occupied by xPUSCH 318 Enclose 520.Frequency range 520 and 522 can be the frequency range not occupied by xPUSCH 318.Frequency range 520 and 520 can be with It is by another user occupancy or the frequency range used.

UCI 516 can be with acquisition frequency range 524.Frequency range 524 can be the frequency range in frequency range 518. That is, UCI 516 can be assigned to as the lower frequency region of the data transmission regions distributed xPUSCH 318.UCI 516 can occupy or be assigned the entire duration that frequency range 524 reaches xPUSCH 318.As shown in Figure 5 B, UCI 516 is accounted for With the lower frequency range 524 of the xPUSCH 318 of assigned frequency range 518.In this way, in xPUSCH 318 by UCI 516 with Data are multiplexed in a manner of FDM.

In various embodiments, any frequency range that can be assigned to UCI by FDM modes in xPUSCH.Each In kind embodiment, UCI can be assigned to the lower edge (for example, as shown in Figure 5 B) of xPUSCH, or UCI can be assigned to The top edge of xPUSCH (for example, as shown in Figure 5A).In various embodiments, UCI can be assigned to the upper frequency with xPUSCH The non-conterminous frequency range in rate boundary or lower frequency boundary.Divide for example, UCI can be assigned to the data for including in xPUSCH Frequency range on the either side on boundary.In addition, UCI can be occupied in xPUSCH assigned designated frequency range reach with Equal period entire duration of xPUSCH or period up to the entire duration equal to or less than xPUSCH.

In various embodiments, base station (for example, base station 104) can provide control and/or signaling information, be moved for passing through Dynamic equipment (for example, mobile device 102) coordinates the multiplexing of UCI and data on xPUSCH.The control of base station 104 or signaling information can To include various instructions and/or bit field.For example, base station 104 can provide the first instruction, indicated to mobile device 102 UCI and data can be multiplexed on xPUSCH.In addition, base station 104 can provide the second instruction, instruction will be The distribution for the UCI being multiplexed with data in xPUSCH or the payload of UCI.In various embodiments, which can be by It is considered resource allocation (for example, can be by the UCI frequency resources occupied or amount of time resource in xPUSCH).In various realities It applies in example, mobile device 102 can determine the resource allocation of UCI using the instruction provided by base station 104 in DCI.Determining Resource allocation can be specified for the UCI time quantums transmitted in the xPUSCH with data and frequency range.In general, determine How many resource can be used for UCI by resource allocation in terms of can specifying time and frequency in the resource distributed for xPUSCH.

In various embodiments, base station 104 can also provide third instruction, positions of the instruction UCI in xPUSCH. In various embodiments, it can specify UCI can be located at where by the bit field that base station 104 provides.For example, bit value " 0 " can indicate that UCI will be assigned in the upper frequency range of xPUSCH (for example, as shown in Figure 5A), and bit value " 1 " can To indicate that UCI will be assigned to the lower frequency range of xPUSCH (for example, as shown in Figure 5 B).In general, indicating UCI in xPUSCH Interior positioning bit field wherein can be any size, and can in size can with the various of the UCI in xPUSCH The quantity of energy position is proportional.

In various embodiments, it can complete to come from base station 104 using one or more bit fields of all size About allow multiplexing, payload size and payload positioning instruction.In various embodiments, can xPDCCH (for example, XPDCCH 204) in provide these instruction.In various embodiments, these instructions can be by down link control information (DCI) It provides.

In various embodiments, can individually be referred to by the DCI format that the uplink distributed from data resource is ratified Show the resource allocation (for example, payload size) of the UCI on xPUSCH.In various embodiments, it can be based on for instruction The UCI transmission that is construed to for the bit field how many is reserved distributes multiple Physical Resource Block (PRB).Following table 1 shows to use In based on the exemplary approach that two bit fields are one, two, four or eight PRB of UCI transmission distribution.

Table 1

In various embodiments, base station 104 can be provided about being used to be multiplexed UCI and data on xPUSCH Duplex type further instruction.For example, instruction can be provided, waited for frequency-first fashion with instruction or excellent with the time First mode executes multiplexing, as described further below.

Fig. 6 A to Fig. 6 C show the additional exemplary multiplexing of UCI and data with frequency-first fashion on xPUSCH.It is special Not, Fig. 6 A to Fig. 6 C show that the exemplary transmission scheme for UCI of frequency diversity can be utilized.

Fig. 6 A show exemplary self-contained subframe structure 602, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme for xPUSCH transmission of the multiplexing based on FDM of UCI and data.As shown in Figure 6A, UCI 604 can be contained in the xPUSCH 318 of distribution.XPUSCH 318 can be with acquisition frequency range 606.By xPUSCH 318 Can be lower frequency range 608 under the frequency range 606 of occupancy.On the frequency range 606 occupied by xPUSCH 318 It can be upper frequency range 610.Frequency range 608 and 610 can be the frequency range not occupied by xPUSCH 318.Frequency model It can be by another user occupancy or the frequency range used to enclose 608 and 610.

UCI 604 can occupy two different regions in xPUSCH 318.Specifically, UCI 604 may include accounting for With the 2nd parts UCI of the parts the first UCI and occupancy second frequency range 614 of first frequency range 612.First UCI frequencies Range 612 and the 2nd UCI frequency ranges 614 can be contained in 318 frequency ranges 606 of xPUSCH.First UCI frequency ranges 612 can be adjacent with the data transmitted in the upper frequency field of xPUSCH 318 in xPUSCH 318.2nd UCI frequency models Enclosing 614 can be adjacent with the data transmitted in the lower frequency region of xPUSCH 318 in xPUSCH 318.UCI 604 can be with Occupy or be dispensed on the entire duration that xPUSCH 318 is reached in frequency range 612 and 614.For self-contained subframe structure 602, UCI 604 are multiplexed in xPUSCH 318 with data in a manner of FDM, and by being distributed in different frequency ranges On, the benefit of frequency diversity can be utilized.

Fig. 6 B show exemplary self-contained subframe structure 616, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing based on FDM of UCI and data.As shown in Figure 6B, 618 UCI It can be contained in the xPUSCH 318 of distribution.XPUSCH 318 can be with acquisition frequency range 620.It is occupied by xPUSCH 318 Frequency range 620 under can be lower frequency range 622.It can be on the frequency range 620 occupied by xPUSCH 318 It is upper frequency range 624.Frequency range 622 and 624 can be the frequency range not occupied by xPUSCH 318.Frequency range 622 and 624 can be by another user occupancy or the frequency range used.

Similar with shown in Fig. 6 A, UCI 618 can occupy two different regions in xPUSCH 318.Specifically, UCI 618 may include occupying first frequency range 626 up to the parts the first UCI of amount 630 at the first time and occupying second frequency range 626 up to the 2nd parts UCI of the second time quantum 632.As shown in Figure 6B, amount 630 and the second time quantum 632 do not weigh at the first time It is folded, but not limited to this.First UCI frequency ranges 626 and the 2nd UCI frequency ranges 628 can be contained in 318 frequencies of xPUSCH In range 620.First UCI frequency ranges 626 can be passed in xPUSCH 318 in the upper frequency field of xPUSCH 318 Defeated data are adjacent.2nd UCI frequency ranges 628 can in xPUSCH 318 in the lower frequency region of xPUSCH 318 The data of transmission are adjacent.UCI 618 can be occupied or be dispensed in frequency range 626 and 628 up to less than xPUSCH's 318 The entire duration.For self-contained subframe structure 616, UCI 618 is answered in xPUSCH 318 with data in a manner of FDM With, and by being distributed in different frequency ranges, the benefit of frequency diversity can be utilized.

Fig. 6 C show exemplary self-contained subframe structure 634, based on for including utilizing frequency diversity on xPUSCH The frequency prioritized resources mapping scheme of the xPUSCH transmission of the multiplexing based on FDM of UCI and data.As shown in Figure 6 C, 636 UCI It can be contained in the xPUSCH 318 of distribution.XPUSCH 318 can be with acquisition frequency range 638.It is occupied by xPUSCH 318 Frequency range 638 under can be lower frequency range 640.It can be on the frequency range 638 occupied by xPUSCH 318 It is upper frequency range 642.Frequency range 640 and 642 can be the frequency range not occupied by xPUSCH 318.Frequency range 640 and 642 can be by another user occupancy or the frequency range used.

Similar with shown in Fig. 6 A and Fig. 6 B, UCI 636 can occupy two different regions in xPUSCH 318.Specifically Ground, UCI 636 may include occupying first frequency range 644 up to the parts the first UCI of amount 650 at the first time and occupying the second frequency Rate range 646 is up to the 2nd parts UCI of the second time quantum 646.As shown in Figure 6 C, first time amount 648 and the second time quantum 650 It is not overlapped, but not limited to this.In addition, the time for the parts the first UCI distribution of acquisition frequency range 644 can appear in occupancy After the transmission of 2nd parts UCI of frequency range 646.First UCI frequency ranges 644 and the 2nd UCI frequency ranges 646 can be with It is contained in 318 frequency ranges 638 of xPUSCH.

First UCI frequency ranges 644 can be transmitted in xPUSCH 318 in the upper frequency field of xPUSCH 318 Data it is adjacent.2nd UCI frequency ranges 646 can be passed in xPUSCH 318 in the lower frequency region of xPUSCH 318 Defeated data are adjacent.UCI 636 can be occupied or be dispensed in frequency range 644 and 646 up to whole less than xPUSCH 318 A duration.For self-contained subframe structure 634, UCI 638 is answered in xPUSCH 318 with data in a manner of FDM With, and by being distributed in different frequency ranges, the benefit of frequency diversity can be utilized.

In short, in various embodiments, self-contained subframe structure as described herein can include one in xPUSCH Or the part multiple UCI or region.It can be based on the time and frequency distribution positions or distribute in any way one in xPUSCH Or multiple regions UCI, to benefit from time and/or frequency diversity.One or more regions UCI can be overlapped in time or It is not overlapped.In various embodiments, from base station (for example, base station 104) provide signaling can to receive mobile device (for example, Mobile device 102) instruction position in xPUSCH how much different regions UCI, in frequency and time-related resource allocation And payload size (for example, frequency range, time and its amount for occupying).

In various embodiments, UCI can be mapped in xPUSCH by time priority mode.In various embodiments, A part of xPUSCH may include the UCI being mapped in a manner of time priority in xPUSCH, and the remainder of xPUSCH May include that the data of (on the surplus resources of xPUSCH) are mapped (for example, the UL-SCH numbers of coding with frequency-first fashion According to).By mapping UCI in a manner of time priority, the added bit word of the resource size for UCI transmission is used to indicate in DCI Section can not be it is necessary, to reduce control signaling expense.

Fig. 7 shows exemplary self-contained subframe structure 700, wherein is reflected in a manner of time priority with data in xPUSCH Penetrate UCI.As shown in fig. 7, UCI 702 is mapped in xPUSCH 318 in a manner of time priority.XPUSCH 318 occupies certain frequency Range (does not mark) in the figure 7 for the sake of simplicity, can be less than the frequency range that xPDCCH 314 and GP 316 is occupied.Pass through The first part of UCI 702 is set to occupy the entire time range of xPUSCH 318 in first frequency range 704 (that is, OFDM is accorded with Number " 2 " to " 13 ") and the second part of UCI 702 is made to occupy in second frequency range 706 less than xPUSCH's 318 Entire time range (that is, OFDM symbol " 2 " to " 6 "), can map UCI 702 by time priority mode.

Arrow 708 is shown in a manner of time priority (by making UCI 702 in the first frequency part 704 of xPUSCH 318 The entire time range of interior covering xPUSCH 318, then makes any extention of UCI 702 the second of xPUSCH 318 Any additional required time range of covering xPUSCH 318 in frequency-portions 706) UCI 702 in filling xPUSCH 318. As shown in fig. 7, the exemplary map of UCI 702 is not limited to the distribution of UCI as shown in the figure.On the contrary, in various embodiments, UCI 702 may include occupy xPUSCH 318 all entire time ranges or than smaller one or more different frequencies Region.In addition, the separated region of UCI 702 can be adjacent to each other, or can be by the data separating in xPUSCH 318.

UCI 702 is being reflected (by occupying more xPUSCH 318 such as required or distribution) in a manner of time priority After being mapped in xPUSCH 318, the surplus resources part of xPUSCH 318 can be mapped by frequency-first fashion and data, As shown by arrow 710.

In various embodiments, base station 104 can ask the offer of movement station 102 to be directed to for example in dynamic TDD system The ACK/NACK feedbacks of HARQ processing and CSI and/or BRS-RP reports.It, can be right first in such various embodiments It is encoded for the ACK/NACK feedbacks of HARQ processing, and it is concatenated with CSI and/or BRS-RP reports.It then, can be with The bit of concatenation is encoded by other encoding schemes.In turn, the performance of ACK/NACK feedbacks can be improved.

Fig. 8 shows the exemplary coding schemes for UCI transmission 1000.As shown in figure 8, providing the ACK/ for UCI NACK feedback informations 802, CSI report information 804 and BRS-RP report informations 806.ACK/NACK feedback informations 802, CSI report Information 804 and BRS-RP report informations 806 may include being waited for and data-reusing in xPUSCH based on technique described herein UCI information.ACK/NACK feedback informations 802 can be encoded by block encoding 808.For example, block encoding 808 can be with Based on block code, such as Reed-M ü ller codes.

The ACK/NACK feedback informations 802 of the coding exported by block encoding 808 can merge 810 and CSI by bit Report information 804 and BRS-RP report informations 806 concatenate.In the ACK/NACK feedback informations that concatenation is exported by block encoding 808 802, after CSI report information 804 and BRS-RP report informations 806, cyclic redundancy check (CRC) 812 can be attached to bit Merge the output of 810 concatenation.The CRC of (for example, as specified in LTE standard) with 8 or 16 length can be used. It is attached after CRC 812, the further coding carried out by tail biting convolutional encoding device (TBCC) 814 can be provided.TBCC codings can To be the coding defined in such as LTE specification.The output 816 of TBCC codings 814 is considered the UCI information 816 of coding. The UCI information 816 of coding can be multiplexed with data in the xPUSCH of self-contained subframe structure as described herein.

Fig. 9 shows the example of logic flow 900, can indicate for being answered UCI and data on 5G xPUSCH The realization method of one or more disclosed technologies.For example, can indicate can be in some embodiments for logic flow 900 The operation executed in the operating environment 100 of Fig. 1 by mobile device 102 (for example, as UE), and can indicate for generating The behaviour of the subframe structure or transmission structure described in Fig. 2A, Fig. 2 B, Fig. 3, Fig. 4, Fig. 5 A, Fig. 5 B, Fig. 6 A, Fig. 6 B, Fig. 6 C and Fig. 7 Make, and can indicate the operation for executing the encoding operation 1000 described in Fig. 8.

902, mobile device can receive DCI.DCI can be received on xPDCCH.

904, DCI information can be handled.Particularly, the instruction in DCI can be handled.It in various embodiments, can be with Instruction in DCI is decoded.Instruction may include one or more fields or message structure.Instruction may include about with In on xPUSCH by the various information of UCI and the data coordination being multiplexed and setting.In various embodiments, instruction can be with Indicate one of the following or multiple:UCI and data are subjected to multiplexing permission on xPUSCH or do not allowed;UCI's Payload size;The resource allocation of UCI;One or more frequency ranges of UCI;One or more periods of UCI;For inciting somebody to action The mode (for example, the specification of multiplexing scheme includes FDM and TDM) that UCI and data are multiplexed;Be in a manner of time priority or UCI is mapped with frequency-first fashion;How UCI is encoded;And what information to include the part for UCI by.

906, it may be determined that the resource allocation of UCI.The money of DCI can be determined based on processed or decoded instruction Source is distributed.The resource allocation of DCI may include various information comprising but be not limited to the payload size of UCI, one of UCI or One or more periods of multiple frequency ranges and UCI.

908, it may be determined that the multiplexing scheme of UCI.It in various embodiments, can be based on the resource of determining DCI point Match to determine the multiplexing scheme of DCI.In various embodiments, the multiplexing scheme of DCI can be determined based on processed instruction. The multiplexing scheme of DCI may include various information comprising but it is not limited to use in the mode (example being multiplexed to UCI and data Such as, the specification of multiplexing scheme includes FDM and TDM) and be to map UCI in a manner of time priority or with frequency-first fashion.

910, UCI data are generated.In various embodiments, UCI data can be encoded, for being included in In xPUSCH.It can be as above with respect to generating UCI data as specified by Fig. 8 and encoded to it.

912, the UCI of generation is transmitted on xPUSCH.UCI and data can be multiplexed on xPUSCH. The transmission of the upper UCI of xPUSCH and data can based on the determination carried out for resource allocation and/or for the determination that multiplexing carries out, It is based on the instruction provided in the DCI from remote base stations (for example, base station 104).

Figure 10 shows the embodiment of storage medium 1000.Storage medium 1000 may include any non-transient computer can Read storage medium or machine readable storage medium, such as optics, magnetism or semiconductor storage medium.In various embodiments, it deposits Storage media 1000 may include manufacture article.In some embodiments, storage medium 1000 can store the executable finger of computer It enables, such as computer executable instructions for realizing the logic flow of Fig. 9 900.Computer readable storage medium or machine can Read storage medium example may include can store any tangible medium of electronic data, including volatile memory or it is non-easily The property lost memory, removable or non-removable memory, erasable or nonerasable memory, writeable or recordable memory Deng.The example of computer executable instructions may include the code of any suitable type, such as source code, compiled code, interpretation Code, executable code, static code, dynamic code, the code of object-oriented, visual code etc..Embodiment is in this respect not It is restricted.

As used herein, term " circuit " may refer to, for part of it or including:It executes one or more soft The application-specific integrated circuit (ASIC) of part or firmware program, electronic circuit, processor (shared, special or group) and/or memory are (altogether With, special or group), the combinational logic circuit and/or other suitable hardware components of described function are provided.In some implementations In example, circuit may be implemented in one or more softwares or firmware module, or function associated with circuit can be by one A or multiple softwares or firmware module are realized.In some embodiments, circuit may include within hardware may be used at least partly The logic of operation.Embodiment described herein can use in hardware and/or the software realization to system of suitable configurations.

Figure 11 shows to indicate the example of the mobile device 1100 of mobile device, such as real in various embodiments The UE of existing one or more disclosed technologies.For example, according to some embodiments, mobile device 1100 can indicate mobile device 102.In some embodiments, mobile device 1100 may include application circuit 1102, baseband circuit 1104, radio frequency (RF) circuit 1106, front-end module (FEM) circuit 1108 and one or more antenna 1110, at least it is coupled as shown together.

Application circuit 1102 may include one or more application processor.For example, application circuit 1102 may include all As but be not limited to the circuit of one or more single core processors or multi-core processor.Processor may include general processor and specially With any combinations of processor (for example, graphics processor, application processor etc.).Processor can be coupled in and/or can wrap Memory/storage is included, and is configurable to:Execute the instruction that is stored in memory/storage so that various applications and/ Or operating system can operate in system.

Baseband circuit 1104 may include the electricity of such as, but not limited to one or more single core processors or multi-core processor Road.Baseband circuit 1104 may include one or more baseband processor and/or control logic, to handle from RF circuits 1106 It receives the baseband signal that signal path receives and generates the baseband signal of the transmission signal path for RF circuits 1106.Base Band circuit 1104 can be with application circuit 1102 into line interface, for generating and handling baseband signal and control RF circuits 1106 operation.For example, in some embodiments, baseband circuit 1104 may include the second generation (2G) baseband processor 1104a, The third generation (3G) baseband processor 1104b, forth generation (4G) baseband processor 1104c and/or in other existing generation, exploitations Or will future exploitation generation (for example, the 5th generation (5G), 6G etc.) other baseband processor 1104d.Baseband circuit 1104 (for example, one or more of baseband processor 1104a-d), which can be handled, to be allowed for via RF circuits 1106 With the various Radio Control Function of the communication of one or more wireless networks.Radio Control Function can include but is not limited to signal Modulating/demodulating, coding/decoding, radio frequency shift etc..In some embodiments, the modulation/demodulation circuit of baseband circuit 1104 can be with Including Fast Fourier Transform (FFT), precoding and/or constellation mapping/demapping function.In some embodiments, base band electricity The coding/decoding circuit on road 1104 may include convolution, tail biting convolution, turbo, Viterbi and/or low-density checksum (LDPC) coder/decoder functionalities.The embodiment of modulating/demodulating and coder/decoder functionalities is not limited to these examples, and And in other embodiments may include other suitable functions.

In some embodiments, baseband circuit 1104 may include the element of protocol stack, such as Evolved Universal Terrestrial The element of wireless access network (EUTRAN) agreement, including such as physics (PHY) element, media access control (MAC) element, wireless Link controls (RLC) element, Packet Data Convergence Protocol (PDCP) element and/or wireless heterogeneous networks (RRC) element.Base band electricity Central processing unit (CPU) 1104e on road 1104 is configurable to:Run protocol stack element, for PHY, MAC, RLC, The signaling of PDCP and/or rrc layer.In some embodiments, baseband circuit may include at one or more audio digital signals Manage device (DSP) 1104f.Audio DSP 1104f may include the element for compression/de-compression and echo cancellor, and at it May include other suitable processing elements in his embodiment.In some embodiments, the component of baseband circuit can be appropriate Ground combines in one single chip, one single chip group, or is arranged on identical circuit board.In some embodiments, base band Some or all of circuit 1104 and application circuit 1102 constitute component and can realize together, such as realize in system on chip (SOC) on.

In some embodiments, baseband circuit 1104 can provide the communication compatible with one or more radiotechnics. For example, in some embodiments, baseband circuit 1104 can support with Evolved Universal Terrestrial wireless access network (EUTRAN) and/or The communication of other wireless MANs (WMAN), WLAN (WLAN), wireless personal area network (WPAN).Baseband circuit 1104 by with It is set to and the embodiment of the wireless communication of more than one wireless protocols is supported to be properly termed as multimode baseband circuit.

RF circuits 1106 can enable to the electromagnetic radiation progress using modulation and wireless network by non-solid medium Communication.In various embodiments, RF circuits 1106 may include switch, filter, amplifier etc., to contribute to and wireless network The communication of network.RF circuits 1106 may include receiving signal path, may include being received from FEM circuits 1108 for down coversion To RF signals and baseband signal is supplied to the circuit of baseband circuit 1104.RF circuits 1106 can further include sending signal Path may include the baseband signal provided for up-conversion baseband circuit 1104 and be supplied to RF output signals FEM circuits 1108 for transmission circuit.

In some embodiments, RF circuits 1106 may include receiving signal path and transmission signal path.RF circuits 1106 reception signal path may include mixer 1106a, amplifier circuit 1106b and filter circuit 1106c. The transmission signal path of RF circuits 1106 may include filter circuit 1106c and mixer 1106a.RF circuits 1106 can To further include synthesizer circuit 1106d, for the mixer 1106a in synthesized received signal path and transmission signal path The frequency used.In some embodiments, the mixer 1106a for receiving signal path is configurable to:Based on synthesizer The frequency synthesis that circuit 1106d is provided carrys out the RF signals that down coversion is received from FEM circuits 1108.Amplifier circuit 1106b It is configurable to:Amplify the signal after down coversion, and filter circuit 1106c can be low-pass filter (LPF) or band logical Filter (BPF), they are configured to:Undesired signal is removed from the signal after down coversion, to generate output baseband signal.It is defeated Baseband circuit 1104 can be supplied to by going out baseband signal, for being further processed.In some embodiments, baseband signal is exported Can be zero frequency baseband signal, but this is not required that.In some embodiments, the mixer of signal path is received 1106a may include passive frequency mixer, but the range of embodiment is without being limited thereto.

In some embodiments, the mixer 1106a for sending signal path can be configured as:Based on synthesizer electricity The frequency synthesis that road 1106d is provided carrys out up-conversion input baseband signal, to generate the RF output letters for FEM circuits 1108 Number.Baseband signal can be provided by baseband circuit 1104, and can be filtered by filter circuit 1106c.Filter circuit 1106c may include low-pass filter (LPF), but the range of embodiment is without being limited thereto.

In some embodiments, it receives the mixer 1106a of signal path and sends the frequency mixer electricity of signal path Road 1106a may include two or more frequency mixers, and can be arranged to quadrature frequency conversion and/or upper change respectively Frequently.In some embodiments, it receives the mixer 1106a of signal path and sends the mixer of signal path 1106a may include two or more frequency mixers, and can be arranged to mirror image and inhibit (for example, Hartley mirror images press down System).In some embodiments, it receives the mixer 1106a of signal path and sends the mixer of signal path 1106a can be arranged to Direct-conversion and/or Direct conversion respectively.In some embodiments, signal path is received Mixer 1106a and send signal path mixer 1106a may be configured to superheterodyne operation.

In some embodiments, output baseband signal and input baseband signal can be analog baseband signals, but implement The range of example is without being limited thereto.In some alternative embodiments, output baseband signal and input baseband signal can be digital basebands Signal.In these alternate embodiments, RF circuits 1106 may include analog-digital converter (ADC) and digital analog converter (DAC) electricity Road, and baseband circuit 1104 may include digital baseband interface, to be communicated with RF circuits 1106.

In some bimodulus embodiments, individual radio IC circuits can be provided, for believing each frequency spectrum processing Number, but the range of embodiment is without being limited thereto.

In some embodiments, synthesizer circuit 1106d can be decimal N synthesizers or decimal N/N+1 synthesizers, still The range of embodiment is without being limited thereto, because other kinds of frequency synthesizer can be suitable.For example, synthesizer circuit 1106d can be delta-sigma synthesizer, frequency multiplier or the synthesizer including having the phaselocked loop of frequency divider.

Synthesizer circuit 1106d is configurable to:RF circuits are synthesized based on frequency input and divider control input The output frequency that 1106 mixer 1106a is used.In some embodiments, synthesizer circuit 1106d can be decimal N/N+1 synthesizers.

In some embodiments, frequency input can be provided by voltage controlled oscillator (VCO), but this is not required that.It depends on Desired output frequency, divider control input can be provided by baseband circuit 1104 or application processor 1102.In some realities Apply in example, can based on the channel indicated by application processor 1102 and from look-up table determine divider control input (for example, N)。

The synthesizer circuit 1106d of RF circuits 1106 may include divider, delay phase-locked loop (DLL), multiplexer and phase Bit accumulator.In some embodiments, divider can be bimodulus divider (DMD), and phase accumulator can be number Phase accumulator (DPA).In some embodiments, DMD is configurable to:(for example, be based on carry) by input signal divided by N or N+1, to provide division of decimal ratio.In some example embodiments, DLL may include one group of cascade tunable delay member Part, phase detectors, charge pump and D flip-flop.In these embodiments, delay element can be configured as the VCO periods It is decomposed into Nd equal phase groupings, wherein Nd is the quantity of the delay element in delay line.By this method, DLL provides negative Feedback, to assist in ensuring that the total delay by delay line is a VCO period.

In some embodiments, synthesizer circuit 1106d can be configured as:Carrier frequency is generated as output frequency, And in other embodiments, output frequency can be the multiple of carrier frequency (for example, twice of carrier frequency, carrier frequency Four times), and be used in combination with quadrature generator and divider circuit, to be generated relative to each other with more in carrier frequency Multiple signals of a out of phase.In some embodiments, output frequency can be LO frequencies (fLO).In some embodiments, RF circuits 1106 may include IQ/ polar converters.

FEM circuits 1108 may include receiving signal path, may be configured to from one or more antennas The 1110 RF signals received are operated, and are amplified the signal received and are supplied to RF electric the amplified version for receiving signal Road 1106 is for the circuit that is further processed.FEM circuits 1108 can further include sending signal path, may include configuration For amplification RF circuits 1106 provided for transmission signal for by one or more in one or more antennas 1110 A circuit sent.

In some embodiments, FEM circuits 1108 may include TX/RX switch, in sending mode and reception pattern It is switched between operation.FEM circuits may include receiving signal path and transmission signal path.The reception signal of FEM circuits Path may include low-noise amplifier (LNA), and to amplify the RF signals received, and (for example, to RF circuits 1106) carries It is used as output for the RF signals of amplification received.The transmission signal path of FEM circuits 1108 may include:Power amplifier (PA), for amplifying (for example, what RF circuits 1106 were provided) input rf signal;And one or more filters, for giving birth to At RF signals, then sent for (for example, being carried out by one or more of one or more antennas 1110).

In some embodiments, mobile device 1100 may include add ons, such as memory/storage, display, phase Machine, sensor and/or input/output (I/O) interface.

Figure 12 shows that mobile device 102, base station 104, logic flow 900, storage medium 1000 and movement, which may be implemented, to be set The embodiment of standby one or more of 1100 communication equipment 1200.In various embodiments, equipment 1200 may include patrolling Collect circuit 1228.For example, logic circuit 1228 may include physical circuit, with execute Fig. 9 for mobile device 102, base station 104, it is operated described in one or more of logic flow 200, logic flow 700 and mobile device 1100.Such as Figure 10 institutes Show, equipment 1200 may include radio interface 1210, baseband circuit 1220 and computing platform 1230, but embodiment is not limited to This configuration.

Equipment 1200 can realize mobile device 102, base in single computational entity (such as completely in individual equipment) It stands 104, logic flow 200, logic flow 700, storage medium 1200, storage medium 850, mobile device 1100 and logic circuit One or more of 1228 some or all structures and/or operation.Alternatively, equipment 1200 can use distributed system Framework (such as client-server architecture, 3 layer architectures, N layer architectures, close-coupled or aggregated structure, Peer to Peer Architecture, principal and subordinate Framework, shared data bank framework and other kinds of distributed system) by mobile device 102, base station 104, logic flow 200, one in logic flow 700, storage medium 1200, storage medium 850, mobile device 1100 and logic circuit 1228 or A part for multiple structures and/or operation is distributed on multiple computational entities.Embodiment is unrestricted in this regard.

In one embodiment, radio interface 1210 may include adapting to send and/or receive single carrier or overloading Wave modulated signal (e.g., including complementary code keying (CCK), orthogonal frequency division multiplexing (OFDM) and/or single-carrier frequency division multiple access (SC- FDMA) symbol) component or component combination, but embodiment is not limited to any specific air interface or modulation scheme.Nothing Line electrical interface 1210 may include such as receiver 1212, frequency synthesizer 1214 and/or transmitter 1216.Radio interface 1210 may include biasing control, crystal oscillator and/or one or more antenna 1218-f.In another embodiment, wirelessly Electrical interface 1210 can use external voltage-controlled oscillators (VCO), surface acoustic wave filter, intermediate frequency (IF) filter as needed And/or RF filters.Due to the diversity of possible RF Interface designs, the generalized description to it is omitted.

Baseband circuit 1220 can be communicated with radio interface 1210 to handle reception and/or send signal, and can be with Frequency mixer including the RF signals for example received for down conversion, the analog-to-digital conversion for converting analog signals into digital form Device 1222, the digital analog converter 1224 for converting digital signals into analog form and for up conversion signal to be transmitted Frequency mixer.In addition, baseband circuit 1220 may include for it is correspondingly received/send signal PHY link layer process base band or Physical layer (PHY) processing circuit 1226.Baseband circuit 1220 may include the medium for example for MAC/ data link layer deals Access control (MAC) processing circuit 1227.Baseband circuit 1220 may include for for example via one or more interfaces 1234 The Memory Controller 1232 communicated with MAC processing circuits 1227 and/or computing platform 1230.

In some embodiments, PHY processing circuits 1226 may include frame construction and/or detection module, and such as buffer The adjunct circuit of memory is combined to construct and/or deconstruct communication frame.Alternatively or additionally, MAC processing circuits 1227 can To share the processing for certain functions in these functions, or execute these processing independently of PHY processing circuits 1226. In some embodiments, MAC and PHY processing is desirably integrated into single circuit.

Computing platform 1230 can be that equipment 1200 provides computing function.As shown, computing platform 1230 may include Processing component 1040.Other than baseband circuit 1220 or as an alternative, equipment 1200 can use processing component 1040 To execute mobile device 102, base station 104, logic flow 200, logic flow 700, storage medium 1200, storage medium 850, move Move the processing operation or logic of one or more of equipment 1100 and logic circuit 1228.Processing component 1040 (and/or PHY 1226 and/or MAC 1227) may include various hardware elements, software elements or both combination.The example of hardware elements can To include equipment, logical device, component, processor, microprocessor, circuit, processor circuit, circuit element (for example, crystal Pipe, resistor, capacitor, inductor etc.), integrated circuit, application-specific integrated circuit (ASIC), programmable logic device (PLD), number Word signal processor (DSP), field programmable gate array (FPGA), memory cell, logic gate, register, semiconductor devices, Chip, microchip, chipset etc..The example of software elements may include component software, program, application, computer program, application Program, system program, software development procedures, machine program, operating system software, middleware, firmware, software module, routine, son Program, function, method, process, software interface, Application Program Interface (API), instruction set, calculation code, computer code, generation Code section, computer code segments, word, value, symbol or any combination thereof.Determine whether real using hardware elements and/or software elements Current embodiment can change according to any number of factor, all computation rates as desired, power level, heat resistance, processing Cycle budget, input data rate, output data rate, memory resource, data bus speed and other designs or performance are about Beam, as given embodiment is desired.

Computing platform 1230 may further include other platform assemblies 1250.Other platform assemblies 1250 include public meter Calculate element, such as one or more processors, multi-core processor, coprocessor, memory cell, chipset, controller, outer If, interface, oscillator, timing device, video card, audio card, multimedia input/output (I/O) component (for example, number display Device), power supply etc..The example of memory cell can include but is not limited to one or more fair speed memory cell forms Various types of computer-readable and machine readable storage medium, such as read-only memory (ROM), random access memory (RAM), dynamic ram (DRAM), double data rate DRAM (DDRAM), synchronous dram (SDRAM), static state RAM (SRAM), can compile Journey ROM (PROM), erasable programmable ROM (EPROM), electrically erasable ROM (EEPROM), flash memory, polymer storage Device (such as ferroelectric polymer memory, ovonic memory, phase transformation or ferroelectric memory, silicon-oxide-nitride-oxide- Silicon (SONOS) memory), magnetic card or optical card, such as equipment array of redundant array of independent disks (RAID) driver, solid-state Memory devices (for example, USB storage, solid state drive (SSD)) and any other type for being suitable for storing information are deposited Storage media.

Equipment 1200 can be such as ultra-mobile device, mobile device, fixed equipment, Machine To Machine (M2M) equipment, a Personal digital assistant (PDA), mobile computing device, smart phone, phone, digital telephone, cellular phone, user equipment, e-book It is reader, handheld device, unidirectional pager, bidirection pager, messaging devices, computer, personal computer (PC), desk-top Computer, laptop computer, notebook computer, netbook computer, handheld computer, tablet computer, server, Server array or server zone, web page server, network server, Internet Server, work station, minicomputer, master Frame computer, the network equipment, webpage equipment, distributed computing system, multicomputer system, is based on processing at supercomputer The system of device, consumption electronic product, programmable consumer electronics, game station, display, TV, DTV, machine top Box, wireless access point, base station, node B, subscriber station, subscriber station, radio network controller, router, hub, Gateway, bridge, interchanger, machine or combinations thereof.It therefore, can be in the various embodiments of equipment 1200 according to needs appropriate In include or omit the function and/or specific configuration of equipment 1200 described herein.

It can carry out the embodiment of facilities and equipments 1200 using single-input single-output (SISO) framework.However, certain embodiment party Formula may include mutiple antennas (for example, using being used for wave beam forming or space division multiple access (SDMA) and/or using the MIMO communication technologys The adaptive antenna technology antenna 1218-f that is sent and/or received).

It can be come using any combinations of discrete circuit, application-specific integrated circuit (ASIC), logic gate and/or single-chip framework The component and feature of facilities and equipments 1200.In addition it is possible to use microcontroller, programmable logic array and/or microprocessor or Carry out the feature of facilities and equipments 1200 in appropriate suitable aforementioned any combinations.Note that hardware, firmware and/or software are wanted Element can be known as " logic " or " circuit " collectively or individually herein.

It should be understood that example devices 1200 shown in the block diagram of Figure 12 can indicate many possible embodiment party One functional descriptions example of formula.Therefore, the division for the block function of describing in the accompanying drawings is omitted or including not would conclude that use In realizing that hardware component, circuit, software and/or the element of these functions will necessarily be divided, omit or including in embodiment.

Figure 13 shows the embodiment of broadband wireless access system 1300.As shown in figure 13, broadband wireless access system 1300 Can be Internet protocol (IP) type network comprising can support the mobile wireless access to internet 1310 and/or consolidate Determine 1310 type network of internet etc. of wireless access.In one or more embodiments, broadband wireless access system 1300 can To include any kind of wireless network based on orthogonal frequency division multiple access (OFDMA) or based on single-carrier frequency division multiple access (SC-FDMA) Network such as meets the system of one or more of 802.16 standard of 3GPP LTE specifications and/or IEEE, and required guarantor The range of the theme of shield is not limited to these aspects.

In exemplary wideband wireless access system 1300, Radio Access Network (RAN) 1312 and 1318 can respectively with Evolution node B or base station (eNB) 1314 and 1320 are coupled, between one or more fixed equipments 1316 and internet 1310 And/or provide wireless communication between one or more mobile devices 1322 and internet 1310.Fixed equipment 1316 and movement Equipment 1322 another example is the equipment 1200 of Figure 12, wherein fixed equipment 1316 includes the equipment 1200 of fixed version, and And mobile device 1322 includes the equipment 1200 of mobile version.RAN 1312 and 1318, which may be implemented that network function can be defined, to be arrived The configuration file of the mapping of one or more physical entities in broadband wireless access system 1300.ENB 1314 and 1320 can be with It is communicated with the RF of fixed equipment 1316 and/or mobile device 1322 including wireless device with providing, such as reference device 1200 It is described, and may include the PHY and MAC layer equipment for for example meeting 802.16 standard of 3GPP LTE specifications or IEEE.Base Stand or eNB 1314 and 1320 can also include be coupled to the IP backboards of internet 1310 via RAN 1312 and 1318 respectively, but It is in terms of the range of theme claimed is not limited to these.

Broadband wireless access system 1300 can also include the access that each is capable of providing one or more network functions Core network (CN) 1324 and/or ownership CN 1326 comprising but be not limited to agency and/or relay-type function (for example, certification, Authorize and charging (AAA) function), dynamic host configuration protocol (DHCP) function or domain name service control etc., domain gateway it is (such as public Switched telephone network (PSTN) gateway or voice over internet protocol (VoIP) gateway altogether) and/or Internet protocol (IP) type service Device function etc..However, these are only can be by accessing CN 1324 and/or belonging to showing for the function type that CN 1326 is provided Example, and the range of theme claimed is unrestricted in these areas.It is not fixed equipment 1316 accessing CN 1324 Or in the case of the part of the regular service provider of mobile device 1322, such as in fixed equipment 1316 or mobile device In the case that 1322 roamings are far from its respective home CN 1326, or in broadband wireless access system 1300 it is fixed equipment 1316 or mobile device 1322 regular service provider a part, but broadband wireless access system 1300 is likely to be at not Be fixed equipment 1316 or mobile device 1322 main or homing position another location or state in the case of, access CN 1324 can be referred to as accessing CN.Embodiment is unrestricted in this regard.

From anywhere in fixed equipment 1316 can be located in the range of one or both of base station or eNB 1314 and 1320, Such as in family or enterprise or near, with respectively via base station or eNB 1314 and 1320 and RAN 1312 and 1318 to family Front yard or corporate client provide the broadband access to internet 1310 and ownership CN 1326.It is worth noting that, although fixed equipment 1316 are generally arranged at fixed position, but can be moved into different positions as needed.For example, if mobile device 1322 in the range of one or both of base station or eNB 1314 and 1320, then can use movement in one or more positions Equipment 1322.According to one or more embodiments, operations support systems (OSS) 1328 can be broadband wireless access system 1300 A part, to provide management function for broadband wireless access system 1300 and provide the function of broadband wireless access system 1300 Interface between entity.The broadband wireless access system 1300 of Figure 13 is only show broadband wireless access system 1300 certain The a type of wireless network of the component of quantity, however, the range of theme claimed is unrestricted in these areas.

Various embodiments can be realized using the combination of hardware elements, software elements or both.The example of hardware elements May include processor, microprocessor, circuit, circuit element (for example, transistor, resistor, capacitor, inductor etc.), collection At circuit, application-specific integrated circuit (ASIC), programmable logic device (PLD), digital signal processor (DSP), field-programmable Gate array (FPGA), logic gate, register, semiconductor devices, chip, microchip, chipset etc..The example of software may include Component software, program, application, computer program, application program, system program, machine program, operating system software, middleware, Firmware, software module, routine, subprogram, function, method, process, software interface, Application Program Interface (API), instruction set, meter Calculation code, computer code, code segment, computer code segments, word, value, symbol or any combination thereof.Determine whether to use hardware Element and/or software elements, which implement embodiment, to be changed according to any number of factor, such as desired computation rate, work( Rate level, heat resistance, process cycle budget, input data rate, output data rate, memory resource, data bus speed With other designs or performance constraints.

The one or more aspects of at least one embodiment can be referred to by representativeness stored on a machine readable medium Order is achieved, which indicates that the various logic in processor, instruction make machine manufacture when being read by machine Logic is to execute technique described herein.Tangible machine readable media can be stored in by being referred to as this expression of " IP kernel " Above and various clients or manufacturing works are provided to be loaded into the manufacture machine of actual manufacture logic or processor.Some Embodiment can be for example achieved using machine readable media or article, and the machine readable media or article can store one Instruction or one group of instruction, if machine executable instructions, an instruction or one group of instruction can be such that machine is executed according to embodiment Method and/or operation.Such machine may include for example any suitable processing platform, computing platform, computing device, processing Equipment, computing system, processing system, computer, processor etc., and any suitable of hardware and/or software can be used Combination is achieved.Machine readable media or article may include that memory cell, the memory of for example any suitable type are set Standby, memory article, storage medium, storage device, storage article, storage medium and/or storage unit, such as memory, It can be removed or nonremovable medium, erasable or non-erasable medium, writeable or rewritable media, number or simulation medium, hard Disk, floppy disk, compact disk read-only memory (CD-ROM), compact disc recordable (CD-R), solid state drive (CD-RW), CD, Magnetic medium, magnet-optical medium, removable memory card or disk, various types of digital versatile discs (DVD), band, box etc..Instruction can be with It is any suitable including using any suitable advanced, rudimentary, object-oriented, visual, compiling and/or interpreted programming language to realize The code of type, such as source code, compiled code, interpreted code, executable code, static code, dynamic code, encrypted code Deng.

Following example belongs to further embodiment:

Example 1 is a kind of user equipment (UE), including memory and logic, at least one of the logic realized in circuit Divide and be coupled to memory, which is used for:Processing is contained in the instruction in the down link control information (DCI) of reception;It is based on The instruction determines the money of the uplink control information (UCI) transmitted on physically ink Shared Channel (PUSCH) Source is distributed;And generate the UCI for being transmitted on PUSCH.

Example 2 is example 1 or any other exemplary extension disclosed herein, which further includes in physical down The reception logic of DCI is received on link control channel (PDCCH).

Example 3 is example 1 or any other exemplary extension disclosed herein, which further includes in PUSCH Send the transmission logic of UCI.

Example 4 is example 3 or any other exemplary extension disclosed herein, sends logic for being sent on PUSCH It is multiplexed with the UCI of data.

Example 5 is example 3 or any other exemplary extension disclosed herein, and PUSCH includes the self-contained time division duplexs of 5G (TDD) part of subframe or frequency division duplex (FDD) subframe.

Example 6 is that example 1 or any other exemplary extension disclosed herein, the instruction are used to indicate UCI on PUSCH Transmission be allowed.

Example 7 is example 1 or any other exemplary extension disclosed herein, which is used to indicate on PUSCH will The mode that UCI and data are multiplexed.

Example 8 is example 7 or any other exemplary extension disclosed herein, and which includes time division multiplexing (TDM).

Example 9 is example 8 or any other exemplary extension disclosed herein, resource allocation include one of PUSCH or Multiple symbols.

Example 10 is example 7 or any other exemplary extension disclosed herein, and which includes frequency division multiplexing (FDM).

Example 11 is example 10 or any other exemplary extension disclosed herein, resource allocation include it is one or more not Same frequency range.

Example 12 is example 10 or any other exemplary extension disclosed herein, resource allocation include it is one or more not The same period.

Example 13 is example 12 or any other exemplary extension disclosed herein, the different periods include overlapping when Between section.

Example 14 is example 12 or any other exemplary extension disclosed herein, and the different periods includes non-overlapping Period.

Example 15 is example 10 or any other exemplary extension disclosed herein, which is used in a manner of time priority UCI is mapped in PUSCH.

Example 16 is example 10 or any other exemplary extension disclosed herein, resource allocation include on PUSCH with The adjacent UCI frequency ranges of the frequency ranges of data.

Example 17 is example 16 or any other exemplary extension disclosed herein, which is used to be based on a bit words Section instruction UCI frequency ranges are above or below the frequency range of data.

Example 18 is example 1 or any other exemplary extension disclosed herein, and UCI includes and channel state information (CSI) hybrid automatic repeat-request (HARQ) of feedback or wave beam relevant feedback concatenation confirms that (ACK)/negative confirmation (NACK) is anti- Feedback, HARQ ACK/NACK feedbacks are encoded before concatenation by block code.

Example 19 is a kind of according to any example in example 1 to 18 or any other exemplary UE disclosed herein and extremely Few radio frequency (RF) transceiver and at least one RF antennas.

Example 20 is a kind of wireless communications method, including:Processing is contained in the down link control information (DCI) of reception Instruction;Based on the instruction, the uplink control for being transmitted in 5G physical uplink shared channels (xPUSCH) is identified The resource allocation of information (UCI) processed;And UCI of the generation for being transmitted on xPUSCH.

Example 21 is example 20 or any other exemplary extension disclosed herein, including:In 5G physical down link controls DCI is received on channel (xPDCCH) processed.

Example 22 is example 20 or any other exemplary extension disclosed herein, including:UCI is transmitted on xPUSCH.

Example 23 is example 22 or any other exemplary extension disclosed herein, including:Multiplexing is transmitted on xPUSCH There is the UCI of data.

Example 24 is example 23 or any other exemplary extension disclosed herein, including:Multiplexing is transmitted on xPUSCH The UCI for having data, as the self-contained time division duplexs of 5G (TDD) subframe or the part of frequency division duplex (FDD) subframe.

Example 25 is that example 20 or any other exemplary extension disclosed herein, the instruction are used to indicate UCI and exist Transmission on xPUSCH is allowed.

Example 26 is that example 20 or any other exemplary extension disclosed herein, the instruction are used to indicate on xPUSCH The mode that UCI and data are multiplexed.

Example 27 is example 26 or any other exemplary extension disclosed herein, and the mode of multiplexing includes time division multiplexing (TDM)。

Example 28 is example 27 or any other exemplary extension disclosed herein, and identification resource allocation includes xPUSCH's One or more symbols.

Example 29 is example 26 or any other exemplary extension disclosed herein, and the mode of multiplexing includes frequency division multiplexing (FDM)。

Example 30 is example 29 or any other exemplary extension disclosed herein, and identification resource allocation includes one or more A different frequency range.

Example 31 is example 29 or any other exemplary extension disclosed herein, and identification resource allocation includes one or more A different period.

Example 32 is example 31 or any other exemplary extension disclosed herein, the different periods include overlapping when Between section.

Example 33 is example 31 or any other exemplary extension disclosed herein, and the different periods includes non-overlapping Period.

Example 34 is example 29 or any other exemplary extension disclosed herein, including:In a manner of time priority UCI is mapped in xPUSCH.

Example 35 is example 29 or any other exemplary extension disclosed herein, and identification resource allocation is included in xPUSCH The upper UCI frequency range adjacent with the frequency range of data.

Example 36 is example 35 or any other exemplary extension disclosed herein, which is used to be based on a bit words Section instruction UCI frequency ranges are above or below the frequency range of data.

Example 37 is example 20 or any other exemplary extension disclosed herein, including:Using block code to mixing certainly Dynamic retransmission request (HARQ) confirms that (ACK)/negative confirmation (NACK) feedback data is encoded, and concatenates the HARQ of coding ACK/NACK feedback data is fed back with channel state information (CSI) to form UCI.

Example 38 is at least one computer readable storage medium for including instruction set, and the instruction is in response in computing device Upper execution and so that computing device is executed according to the wireless communications method of any one of claim 20 to 38.

Example 39 is a kind of user equipment (UE), including:For executing the nothing according to any one of claim 20 to 38 The module of line communication means.

Example 40 is at least one computer readable storage medium for including instruction set, and the instruction is in response in computing device It is upper execution and make computing device:Processing is contained in the instruction in the down link control information (DCI) of reception;Based on the instruction, The resource allocation for the uplink control information (UCI) that identification is transmitted on physically ink Shared Channel (PUSCH); And generate the UCI for being transmitted on PUSCH.

Example 41 is example 40 or any other exemplary extension disclosed herein, including in response to holding on the computing device The instruction gone and computing device is made to receive DCI on physical downlink control channel (PDCCH).

Example 42 is example 40 or any other exemplary extension disclosed herein, including in response to holding on the computing device The instruction gone and computing device is made to transmit UCI on PUSCH.

Example 43 is example 42 or any other exemplary extension disclosed herein, including in response to holding on the computing device The instruction gone and computing device is made to transmit the UCI for being multiplexed with data on PUSCH.

Example 44 is example 43 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to transmit the UCI for being multiplexed with data on PUSCH as the self-contained time division duplexs of 5G (TDD) subframe or frequency division The instruction of the part of duplexing (FDD) subframe.

Example 45 is example 40 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that the transmission of the UCI on PUSCH is allowed instruction based on the instruction.

Example 46 is example 40 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to be determined the instruction of UCI and the data mode being multiplexed on PUSCH based on the instruction.

Example 47 is example 46 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that the mode of multiplexing includes the instruction of time division multiplexing (TDM).

Example 48 is example 47 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device identification resource allocation is made to include the instruction of one or more symbols of PUSCH.

Example 49 is example 46 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that the mode of multiplexing includes the instruction of frequency division multiplexing (FDM).

Example 50 is example 49 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device identification resource allocation is made to include the instruction of one or more different frequency ranges.

Example 51 is example 49 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device identification resource allocation is made to include the instruction of one or more different periods.

Example 52 is example 51 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that the different periods includes the instruction of the period of overlapping.

Example 53 is example 51 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that the different periods includes the instruction of non-overlapping period.

Example 54 is example 49 or any other exemplary extension disclosed herein, including in response to holding on the computing device The instruction gone and computing device is made to map UCI in PUSCH in a manner of time priority.

Example 55 is example 49 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device identification resource allocation is made to include the finger of the adjacent UCI frequency ranges of frequency range with data on PUSCH It enables.

Example 56 is example 55 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to determine that UCI frequency ranges are higher or lower than the frequency range of data based on a bit field of instruction Instruction.

Example 57 is example 40 or any other exemplary extension disclosed herein, including in response to holding on the computing device It goes and computing device is made to confirm that (ACK)/negative confirmation (NACK) is fed back to hybrid automatic repeat-request (HARQ) using block code Data carry out coding and concatenate the HARQ ACK/NACK feedback data of coding to be formed with channel state information (CSI) feedback The instruction of UCI.

Example 58 is a kind of device, including memory and the baseband circuit for being coupled to memory, the baseband circuit are used for:It is right The instruction being contained in the down link control information (DCI) of reception is decoded;Based on the instruction, determine for being included in object Manage the resource allocation of the uplink control information (UCI) on uplink shared channel (PUSCH);And to being used to be included in UCI on PUSCH is encoded.

Example 59 is example 58 or any other exemplary extension disclosed herein, which is used for UCI and number According to multiplexing to include on PUSCH.

Example 60 is example 58 or any other exemplary extension disclosed herein, and PUSCH includes the self-contained subframes of 5G A part.

Example 61 is example 58 or any other exemplary extension, and it is fair that it includes UCI which, which is used to indicate on PUSCH, Perhaps.

Example 62 is that example 58 or any other exemplary extension disclosed herein, the instruction are used to indicate UCI sum numbers According to be multiplexed by include on PUSCH in a manner of.

Example 63 is example 62 or any other exemplary extension disclosed herein, and which includes time division multiplexing (TDM).

Example 64 is example 62 or any other exemplary extension disclosed herein, and which includes frequency division multiplexing (FDM).

Example 64a is example 62 or any other exemplary extension disclosed herein, for the multiplex data on PUSCH FDM schemes may include single-carrier frequency division multiple access (SC-FDMA).

Example 65 is example 64 or any other exemplary extension disclosed herein, resource allocation include it is one or more not Same frequency range.

Example 66 is example 64 or any other exemplary extension disclosed herein, resource allocation include it is one or more not The same period.

Example 67 is example 58 or any other exemplary extension disclosed herein, and the baseband circuit is in a manner of time priority Map UCI.

Example 68 is example 58 or any other exemplary extension disclosed herein, and UCI includes and channel state information (CSI) feedback and wave beam relevant information feedback at least one of concatenation hybrid automatic repeat-request (HARQ) confirm (ACK)/ Negative confirmation (NACK) is fed back, and HARQ ACK/NACK feedbacks are encoded before concatenation by block code.

Example 69 is example 58 or any other exemplary extension disclosed herein, which includes user equipment (UE).

Example 70 is a kind of device, including:Memory;Radio frequency (RF) circuit, the RF circuits are used to pass through physical down chain Road control channel (PDCCH) receives down link control information (DCI);And baseband circuit, it is coupled to memory and couples To RF circuits, the baseband circuit is for being decoded the instruction being contained in the down link control information (DCI) of reception, base The uplink control information (UCI) for being included in physical uplink shared channel (PUSCH) is determined in the instruction Resource allocation, and to for including that the UCI on PUSCH is encoded, the RF circuits on PUSCH for transmitting UCI.

Example 71 is example 70 or any other exemplary extension disclosed herein, and PUSCH includes the self-contained subframes of 5G A part.

Example 72 is example 70 or any other exemplary extension disclosed herein, which includes user equipment (UE).

There is set forth herein many details to provide a thorough understanding of embodiments.However, those skilled in the art will It will be appreciated that these embodiments can be put into practice without these specific details.In other instances, it is well known operation, Component and circuit are not described in detail in order to avoid obscuring embodiment.It is understood that concrete structure disclosed herein and function are thin Section can be representative, and the range for the definite limitation embodiment that differs.

Some embodiments can be described using expression " coupling " and " connection " and its derivative.These terms are not intended to As mutual synonym.It is, for example, possible to use term " connection " and/or " coupling " describe some embodiments, to indicate two A or more element physically or electrically contacts directly with one another.However, term " coupling " can also indicate two or more elements It is not directly contacted with each other, but still coordination with one another or interaction.

Unless otherwise specified, it is appreciated that, " processing ", " calculating ", " operation ", " determination " etc. Term refers to the action and/or processing of computer or computing system or similar electronic computing device, by posting in computing system It is expressed as the data manipulation of physical quantity (for example, electronics) in storage and/or memory and/or is converted into being similarly represented as calculating Other data of physical quantity in memory, register or other such information storages of system, transmission or display equipment.It is real It is unrestricted in this regard to apply example.

It should be noted that method described herein is not necessarily in described sequence or holds in any particular order Row.In addition, the various activities about methods identified herein description can be carried out in a manner of serial or parallel.

Although specific embodiment has been illustrated and described, it is understood that, it is calculated as realizing phase With purpose any arrangement can substitute shown in specific embodiment.The disclosure is intended to cover any and all of various embodiments Modification or variation.It should be understood that above description carries out by way of illustration, rather than it is restrictive.Above-mentioned implementation Example combination and other embodiment not specifically disclosed herein after having read above description for people in the art It will be apparent for member.Therefore, the range of various embodiments include using said combination, structures and methods it is any its He applies.

It is emphasized that provide the abstract of the disclosure required will allow reader to meet in 37C.F.R. § 1.72 (b) The rapid abstract for determining property disclosed in technology.Understanding when submission is that it will not be used to explain or limit claim Range or meaning.In addition, in specific implementation mode in front, it can be seen that for the purpose for simplifying the disclosure, various features It is grouped together in single embodiment.Disclosed method is not necessarily to be construed as reflecting embodiment needs claimed Intention than the more features being expressly recited in each claim.But as the following claims reflect, subject matter It is all features less than single open embodiment.Therefore, it is included in specific implementation mode in this attached claims, Wherein, each single item claim can be based on itself, as individual preferred embodiment.In the following claims, word Language " comprising " and the equivalent common term for " wherein " being used separately as corresponding term "comprising" and " wherein ".In addition, term " the One ", " second " and " third " etc. are merely used as marking, it is no intended to apply numerical requirements to its object.

Although having used this theme of the dedicated language description of structural features and or methods of action, but it is to be understood that institute The theme limited in attached claim is not necessarily limited to above-mentioned special characteristic or action.On the contrary, above-mentioned specific features and action are It is disclosed as the exemplary forms for realizing claim.

Claims (25)

1. a kind of device, including:

Memory;With

Baseband circuit, is coupled to the memory, and the baseband circuit is used for:

The instruction being contained in the down link control information (DCI) of reception is decoded;

Based on the instruction, the uplink control letter for being included in physical uplink shared channel (PUSCH) is determined Cease the resource allocation of (UCI);And

To for including that the UCI on the PUSCH is encoded.

2. the apparatus according to claim 1, the baseband circuit is used for:

The UCI is multiplexed with data, to include on the PUSCH.

3. device according to claim 1 or 2, the PUSCH includes a part for the self-contained subframes of 5G.

4. it is to allow that the apparatus according to claim 1, it includes the UCI that the instruction, which is used to indicate on the PUSCH, 's.

5. device according to claim 1 or 4, the instruction, which is used to indicate, is multiplexed the UCI and data to wrap Include the mode on the PUSCH.

6. device according to claim 5, the mode includes time division multiplexing (TDM).

7. device according to claim 5, the mode includes frequency division multiplexing (FDM).

8. device according to claim 7, the resource allocation includes one or more different frequency ranges.

9. device according to claim 7 or 8, the resource allocation includes one or more different periods.

10. device according to claim 7, the baseband circuit is used for:

The UCI is mapped in a manner of time priority.

11. the apparatus according to claim 1, the UCI includes letter related to channel state information (CSI) feedback and wave beam The hybrid automatic repeat-request (HARQ) of at least one of breath feedback concatenation confirms that (ACK)/negative confirmation (NACK) is fed back, institute HARQ ACK/NACK feedbacks are stated to be encoded by block code before concatenation.

12. at least one computer readable storage medium, including one group of wireless communication instruction, the wireless communication instruct in response to It executes on the computing device and makes the computing device:

Processing is contained in the instruction in the down link control information (DCI) of reception;

Based on the instruction, the uplink control that identification is transmitted on physically ink Shared Channel (PUSCH) is believed Cease the resource allocation of (UCI);And

Generate the UCI for being transmitted on the PUSCH.

13. at least one computer readable storage medium according to claim 12, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Transmission is multiplexed with the UCI of data on the PUSCH.

14. at least one computer readable storage medium according to claim 13, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Transmission is multiplexed with the UCI of data, the part as the self-contained subframes of 5G on the PUSCH.

15. at least one computer readable storage medium according to claim 12, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Based on the instruction, determine that the UCI is transmitted on the PUSCH to be allowed.

16. at least one computer readable storage medium according to claim 12 or 15, including wirelessly communicate refer to as follows It enables, the wireless communication instruction makes the computing device in response to executing on said computing device:

Based on the instruction, the mode that the UCI and data are multiplexed on the PUSCH is determined.

17. at least one computer readable storage medium according to claim 16, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Determine that the mode of multiplexing includes time division multiplexing (TDM).

18. at least one computer readable storage medium according to claim 16, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Determine that the mode of multiplexing includes frequency division multiplexing (FDM).

19. at least one computer readable storage medium according to claim 18, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Identify that the resource allocation includes one or more different frequency ranges.

20. at least one computer readable storage medium according to claim 18 or 19, including wirelessly communicate refer to as follows It enables, the wireless communication instruction makes the computing device in response to executing on said computing device:

Identify that the resource allocation includes one or more different periods.

21. at least one computer readable storage medium according to claim 18, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

Identify the UCI frequency ranges that the resource allocation includes adjacent with the frequency range of the data on the PUSCH.

22. at least one computer readable storage medium according to claim 21, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

A bit field based on the instruction determines that the UCI frequency ranges are higher or lower than the frequency model of the data It encloses.

23. at least one computer readable storage medium according to claim 12, including instruction is wirelessly communicated as follows, institute State wireless communication instruction makes the computing device in response to executing on said computing device:

(ACK)/negative confirmation (NACK) feedback data, which is compiled, to be confirmed to hybrid automatic repeat-request (HARQ) using block code Code, and by the HARQ ACK/NACK feedback data of coding and channel state information (CSI) feed back and wave beam relevant feedback in extremely A few concatenation is to form the UCI.

24. a kind of device, including:

Memory;

Radio frequency (RF) circuit, the RF circuits are used for:Downlink control is received by physical downlink control channel (PDCCH) Information (DCI) processed;With

Baseband circuit is coupled to the memory and is coupled to the RF circuits, and the baseband circuit is used for:

The instruction being contained in the down link control information (DCI) of reception is decoded;

Based on the instruction, the uplink control letter for being included in physical uplink shared channel (PUSCH) is determined Cease the resource allocation of (UCI);And

To for including that the UCI on the PUSCH is encoded,

The RF circuits are used for:The UCI is transmitted on the PUSCH.

25. device according to claim 25, the PUSCH includes a part for the self-contained subframes of 5G.