WO2017144002A1 - 探测参考信号的传输方法、装置、芯片及终端 - Google Patents
探测参考信号的传输方法、装置、芯片及终端 Download PDFInfo
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- WO2017144002A1 WO2017144002A1 PCT/CN2017/074671 CN2017074671W WO2017144002A1 WO 2017144002 A1 WO2017144002 A1 WO 2017144002A1 CN 2017074671 W CN2017074671 W CN 2017074671W WO 2017144002 A1 WO2017144002 A1 WO 2017144002A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0001—Arrangements for dividing the transmission path
- H04L5/0003—Two-dimensional division
- H04L5/0005—Time-frequency
- H04L5/0007—Time-frequency the frequencies being orthogonal, e.g. OFDM(A), DMT
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0001—Arrangements for dividing the transmission path
- H04L5/0014—Three-dimensional division
- H04L5/0016—Time-frequency-code
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
- H04L5/005—Allocation of pilot signals, i.e. of signals known to the receiver of common pilots, i.e. pilots destined for multiple users or terminals
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
- H04L5/0051—Allocation of pilot signals, i.e. of signals known to the receiver of dedicated pilots, i.e. pilots destined for a single user or terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0091—Signaling for the administration of the divided path
- H04L5/0094—Indication of how sub-channels of the path are allocated
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/12—Wireless traffic scheduling
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/12—Wireless traffic scheduling
- H04W72/1263—Mapping of traffic onto schedule, e.g. scheduled allocation or multiplexing of flows
- H04W72/1268—Mapping of traffic onto schedule, e.g. scheduled allocation or multiplexing of flows of uplink data flows
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/21—Control channels or signalling for resource management in the uplink direction of a wireless link, i.e. towards the network
Definitions
- the present disclosure relates to the field of communications technologies, and in particular, to a method, an apparatus, a chip, and a terminal for transmitting a sounding reference signal.
- the first generation of mobile communication refers to the original analog, voice-only cellular phone standard, mainly using analog technology and frequency division multiple access (FDMA) access method; second generation mobile communication introduced Digital technology, improved network capacity, improved voice quality and confidentiality, with "GSM, Global System for Mobile Communication” and "Code Division Multiple Access” (CDMA IS-95, Code Division Multiple Access) As the representative; the third generation mobile communication is based on code division multiple access as the access technology, mainly CDMA2000, WCDMA, TD-SCDMA three technologies; the fourth generation mobile communication system is the long-term evolution of the International Organization for Standardization 3GPP Access technology (LTE/LTE-A, Long Term Evolution/Long Term Evolution-Advanced), whose standards are relatively uniform internationally, and its downlink is based on Orthogonal Frequency Division Multiple Access (OFDMA).
- FDMA frequency division multiple access
- OFDMA Orthogonal Frequency Division Multiple Access
- the uplink is based on the single carrier frequency division multiple access (SC-FDMA, Single Carrier-Frequency Division Multiple Access) access method. According to its flexible bandwidth and adaptive modulation and coding scheme, the downlink peak rate reached 1Gbps, up peak rate of 500Mbps high-speed transmission.
- SC-FDMA Single Carrier-Frequency Division Multiple Access
- the MulteFire (MF) network is a new LTE-based network that can operate independently in the unlicensed spectrum and does not need to have an "anchor point" in the licensed spectrum for the LTE R13LAA (Licensed-Assisted Access, The authorization-assisted access) downlink transmission method is based on the newly defined uplink transmission method, namely stand-alone LTE-U (independent LTE-U). Among them, on the MuLTEfire The line multiplexing method uses a block-interleaved frequency division multiple access (B-IFDMA) method different from the traditional LTE uplink SC-FDMA, and is used to meet the regional specification requirements for the bandwidth occupation of the unlicensed frequency band.
- B-IFDMA block-interleaved frequency division multiple access
- An extended physical uplink control channel (MF-ePUCCH, MF Extended Physical Uplink Control Channel) and a short physical uplink control channel (MF-sPUCCH, MF Short Physical Uplink Control Channel) are introduced in the uplink physical channel to transmit the traditional LTE.
- Uplink Control Information (UCI) transmitted through a Physical Uplink Control Channel (PUCCH), for example, ACK/NACK (Acknowledgement/Rejection Response), CSI (Channel State Information), SR (uplink scheduling request, scheduling request), and the like.
- the MF network may also use the same physical channel format as the PUCCH to transmit uplink physical channel information such as a Sounding Reference Signal (SRS) and a Physical Random Access Channel (PRACH).
- SRS Sounding Reference Signal
- PRACH Physical Random Access Channel
- the MF-ePUCCH in the uplink control channel occupies one subframe consisting of 14 B-IFDMA symbols in the time domain, and for the MF-sPUCCH, its time domain only occupies 1 to 4 B-IFDMA symbols.
- the MF-sPUCCH can be sent separately periodically. For example, it is mainly used to transmit RACH (Random Access Channel), perform random access, or transmit opportunities (TXOP, Transmission Opportunity).
- RACH Random Access Channel
- TXOP Transmission Opportunity
- the transmission in the downlink is transmitted to the subframe of the uplink transmission handover for transmission, that is, the MF-sPUCCH region is transmitted at the beginning of the uplink transmission.
- the description of the MF-s PUCCH region may also have other equivalent names, such as an uplink partial subframe, an uplink partial TTI, an UpPTS, etc., and the MF-sPUCCH region is uniformly used in the present disclosure for simplicity of description.
- the UE's Listening Mechanism (LBT, Listen Before Talk) is Before MF-sPUCCH;
- the UE When the UE transmits only on the adjacent PUSCH/MF-ePUCCH after scheduling the MF-sPUCCH, the UE needs to perform LBT before the MF-sPUCCH region and transmit a specific signal (such as SRS or other signals) on the MF-sPUCCH region to ensure that the channel is in the LBT.
- a specific signal such as SRS or other signals
- the time before success to the scheduled PUSCH/MF-ePUCCH is continuously occupied; wherein the SRS is used to estimate the uplink channel frequency domain information for frequency selective scheduling; and the uplink channel is estimated for downlink beamforming.
- the resources of the signals transmitted in the MF-sPUCCH region may not be scheduled by the eNB (evolved Node B), but are selected by the UE.
- the resources in the MF-sPUCCH area are transmitted. Therefore, different UEs may select resources in the same MF-sPUCCH area, which may cause resource collisions between multiple UEs. The worst result may result in the MF being scheduled.
- -sPUCCH collides and affects the correct reception of information such as UCI.
- the inventors have found in the related art that the unscheduled MF is still unavoidable in the related art.
- - Collision problem in the -sPUCCH region which causes the signal transmitted in the unscheduled MF-sPUCCH region to be untrustworthy.
- the channel estimation error of the base station may occur due to the collision, thereby affecting the subsequent uplink scheduling. Performance, if you ignore this part of the signal information is equivalent to wasting this part of the transmit power and spectrum resources.
- the SRS transmitted in the MF-sPUCCH and the immediately adjacent PUSCH/MF-ePUCCH are due to the frequency domain resource allocation characteristics of the B-IFDMA.
- the transmitted DMRS (for uplink control and related demodulation of the data channel) is uniformly distributed in the frequency domain within the entire system bandwidth, so the contribution of the SRS to estimating the channel quality in the entire system bandwidth channel is much smaller than that in the conventional LTE uplink.
- the frequency domain resource allocation mode of SC-OFDMA so how to improve the estimation accuracy of SRS for channel quality estimation within the system bandwidth is also an urgent problem to be solved.
- the present disclosure provides a method, an apparatus, and a terminal for transmitting a sounding reference signal, which solves the problem of resource collision in a non-scheduled MF-sPUCCH region in the related art.
- a method for transmitting a sounding reference signal including:
- the sounding reference signal SRS is transmitted using resources used by the uplink control channel.
- a transmission apparatus for detecting a reference signal including:
- An acquiring module configured to acquire scheduling information when an uplink transport channel is scheduled
- the processing module is configured to determine, according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel for transmitting the uplink control signal, the uplink control channel corresponding to the scheduling information when the uplink transport channel is scheduled. Resources used;
- a sending module configured to transmit the sounding reference signal SRS by using resources used by the uplink control channel.
- a terminal including:
- a receiver configured to receive scheduling information when an uplink transport channel is scheduled
- the processor is connected to the receiver, and is configured to: determine that the uplink transport channel is scheduled according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel used for transmitting the uplink control signal.
- the transmitter is coupled to the processor for transmitting the sounding reference signal SRS by using resources used by the uplink control channel.
- the method, device, and terminal for transmitting a sounding reference signal determine a resource location of a non-scheduled uplink control channel according to a preset mapping relationship between scheduling information of an uplink transport channel and resources used by an uplink control channel, to reduce It even avoids the collision problem of occupying uplink control resources between different user terminals.
- FIG. 1 shows a schematic diagram of a basic architecture of a mobile communication network
- 2 is a schematic diagram showing frequency domain resource allocation of an uplink channel
- Figure 3 is a schematic diagram showing the transmission of a data transmission opportunity
- FIG. 4 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments of the present disclosure
- FIG. 5 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments of the present disclosure
- FIG. 6 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments of the present disclosure
- FIG. 7 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments of the present disclosure
- FIG. 8 is a schematic diagram showing resource mapping of SRS of scenario 1 in some embodiments of the present disclosure.
- FIG. 9 is a schematic diagram showing resource mapping of SRS of scenario 2 in some embodiments of the present disclosure.
- FIG. 10 is a schematic diagram showing resource mapping of SRS of scenario 3 in some embodiments of the present disclosure.
- FIG. 11 is a schematic diagram showing resource mapping of SRS of scenario 4 in some embodiments of the present disclosure.
- FIG. 12 is a block diagram showing a transmission of a sounding reference signal transmission device according to some embodiments of the present disclosure
- Figure 13 is a block diagram showing the structure of a terminal of some embodiments of the present disclosure.
- FIG. 14 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments.
- 15 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments.
- 16 is a flow chart showing a method for transmitting a sounding reference signal according to some embodiments.
- Figure 17 is a diagram showing resource mapping of SRS in some embodiments.
- Figure 18 is a block diagram showing the transmission of a sounding reference signal of some embodiments.
- Figure 19 is a block diagram showing the structure of a terminal of some embodiments.
- Figure 20 is a block diagram showing the structure of a computer system suitable for implementing the transmission method of the sounding reference signal or the transmission device for detecting the reference signal in the embodiment of the present application.
- the present disclosure is directed to the MF network in the related art. Since only UEs that are transmitted on the PUSCH/MF-ePUCCH are scheduled, the uplink control signal is within the resources in the MF-sPUCCH region selected by the UE. The transmission is performed, so different UEs may select resources in the same MF-sPUCCH area, thereby causing a problem of resource collision.
- the following embodiments of the present disclosure provide a method, an apparatus, and a terminal for transmitting a sounding reference signal, and determining a non-scheduled uplink according to a mapping relationship between a preset uplink transmission channel scheduling information and a resource used by an uplink control channel. The resource location of the control channel is used to reduce or even avoid the collision problem of occupying uplink control resources between different user terminals.
- FIG. 1 shows a schematic diagram of the basic architecture of a mobile communication network.
- the mobile communication system refers to an operator providing communication services for user terminals (such as mobile terminals such as mobile phones) by deploying radio access network devices (such as base stations) and core network devices (such as Home Location Registers). system.
- radio access network devices such as base stations
- core network devices such as Home Location Registers
- FIG. 2 shows a frequency domain resource allocation mode B-IFDMA of an uplink channel (including a physical uplink control channel and/or a physical uplink shared channel), and 10 interlaces (interleaving units) in a 20 MHz bandwidth, the size of each interleaved unit It is a physical resource block (PRB) that is equally spaced in the 10 frequency domains.
- PRB physical resource block
- the interleaved unit of No. 0 corresponds to 10 PRBs with slashes in the figure.
- the MF-sPUCCH may be transmitted in a downlink transmission to a subframe of an uplink transmission handover in a transmission opportunity (TXOP, Transmission Opportunity), that is, the MF-sPUCCH region is transmitted at the beginning of the uplink transmission.
- TXOP Transmission Opportunity
- some embodiments of the present disclosure provide a method for transmitting a sounding reference signal, which specifically includes the following steps:
- Step 41 Obtain scheduling information of the uplink transport channel when the uplink transport channel is scheduled.
- the uplink transmission channel may be an uplink transmission channel for transmitting an uplink data signal, such as a PUSCH, or an uplink transmission channel for transmitting a control signal, such as MF-ePUCCH or MF-sPUCCH.
- the scheduling information of the uplink transmission channel carries information indicating the location of the resource occupied by the uplink transmission channel, such as the number of the occupied resource location.
- the UE may directly receive the scheduling information when the uplink transmission channel for transmitting the uplink data signal is scheduled from the base station, and may obtain the scheduling information by parsing the channel information of the scheduled uplink transmission channel by itself.
- Step 42 Determine a resource used by the uplink control channel corresponding to the scheduling information of the uplink transport channel according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel for transmitting the uplink control signal.
- the preset mapping relationship between the scheduling information of the uplink transport channel and the resources used by the uplink control channel for transmitting the uplink control signal refers to the identifier of the resource used by the uplink transport channel and the identifier of the resource used by the uplink control channel.
- the mapping relationship between the uplink transmission channel scheduling information and all resources used by the uplink control channel for transmitting the uplink control signal is preset; or the scheduling information of the uplink transmission channel is used for A preset mapping relationship between non-scheduled resources used by the uplink control channel for transmitting the uplink control signal.
- the resource identifier used by the corresponding uplink control channel may be determined according to the mapping relationship, thereby determining the resource location of the resource used.
- Step 43 Transmit the SRS by using resources used by the uplink control channel.
- the SRS is mapped to the resource used by the uplink control channel determined in step 42, or
- the resource used by the uplink control channel determined in step 42 is used as a resource for transmitting the SRS.
- the user terminal determines the mapping relationship between the scheduling information of the uplink transmission channel and the resources used by the uplink control channel, and the acquired scheduling information of the scheduled uplink transmission channel.
- the resource location used by the corresponding uplink control channel to reduce or even avoid the collision problem of the uplink control channel resources occupied by different user terminals.
- some embodiments of the present disclosure provide a method for transmitting a sounding reference signal, which specifically includes the following steps:
- Step 51 Acquire scheduling information of an uplink transport channel when the uplink transport channel is scheduled.
- Step 52 Determine a non-scheduled uplink control channel corresponding to the scheduling information of the uplink transport channel in a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used for the uplink control channel used for transmitting the uplink control signal. Resources used;
- Step 53 Transmit the SRS by using resources used by the uplink control channel.
- the transmission method of the sounding reference signal provided by this embodiment is performed after the LBT is performed.
- the uplink transmission generally includes: an MF-s PUCCH area for transmitting uplink control information or special information (such as SRS) and an uplink subframe (PUSCH/MF-ePUCCH) adjacent thereto.
- uplink control information or special information such as SRS
- PUSCH/MF-ePUCCH uplink subframe
- the UE simultaneously selects the SRS in the MF-sPUCCH region according to the scheduling information (or
- the transmission resource location referred to as the uplink partial subframe and the transmission resource location of the PUSCH/MF-ePUCCH in the uplink subframe.
- a UE configured to trigger type 2 (S2) SRS transmission on the serving cell c is configured, and when the subframe n-1 of the serving cell c is detected, MF- exists. sPUCCH and when there is no UCI transmission on the subframe in which the MF-sPUCCH exists, and when the subframe #0 position for the subframe n from the serving cell c is received in the subframe no later than the subframe n-4
- the SRS transmission is started using the MF-sPUCCH resource in the subframe n-1.
- the preset mapping relationship between the scheduling information of the uplink transport channel and the resource used for the uplink control channel used for transmitting the uplink control signal is that the resource identifier used by the uplink transport channel is not allocated (it is also understandable)
- the resource identifier used by the corresponding unallocated unscheduled uplink control channel may be determined according to the mapping relationship, thereby determining the resource location of the resource used.
- the uplink transport channel is a PUSCH/MF-ePUCCH; and the uplink control channel is an MF-sPUCCH.
- step 52 includes:
- the uplink transport channel is The resources used by the unscheduled uplink control channel corresponding to the scheduling information at the time of scheduling.
- the base station first informs the UE of the current scheduling resource and the split information of the non-scheduled resource, so that the UE determines the corresponding resource location according to the split information and the scheduling information.
- the resource grouping of resources used by the uplink control channel is specifically divided into: scheduling uplink control channel resources (scheduling MF-sPUCCH) and non-scheduled uplink control channel resources (unscheduled MF-sPUCCH), and the SRS transmission format may be adopted.
- the demodulation reference signal DMRS sequence has the same sequence, and the DMRS multiplexing mode (or bearer mode) is related to the data transmission format, and the specific resource grouping can be divided according to the data transmission format.
- Scheduling uplink control channel resources (scheduling)
- the MF-sPUCCH) and the unscheduled uplink control channel resource (non-scheduled MF-sPUCCH) are divided into: only the resource number range of the scheduling uplink control channel resource (scheduling MF-sPUCCH) is notified, and only the non-scheduled uplink control channel resource is notified ( Non-scheduled MF-s PUCCH), or simultaneously notify scheduling uplink control channel resources (scheduling MF-sPUCCH) and non-scheduled uplink control channel resources (non-scheduled MF-sPUCCH).
- the notification manner of scheduling the uplink control channel resource (scheduling MF-sPUCCH) and the non-scheduled uplink control channel resource (non-scheduled MF-sPUCCH) includes: pre-specifying, through RRC configuration, or through a common physical downlink common channel (C-PDCCH) ) instructions and so on.
- different SRS time-frequency resource allocation modes are used to distinguish the unscheduled MF-s PUCCH region resources (sending SRS) and the scheduled MF-sPUCCH region resources, specifically :
- the SRS adopts the SRS transmission format in the existing LTE and the IFDMA (Interleaved Frequency Division Multiple Access) with the subcarrier spacing of 2, that is, only the odd or even subcarriers in the consecutive multiple PRBs are occupied. Because of the difference between B-IFDMA and IFDMA, the continuous PRB occupied by the SRS needs to be allocated outside the PRB occupied by the scheduled MF-s PUCCH, and the SRS occupies consecutive symbols in the time domain, for example, the time domain occupies all of the MF-sPUCCH area. symbol.
- IFDMA Interleaved Frequency Division Multiple Access
- the SRS and the MF-sPUCCH may be allocated the same or different interlaces, and may be implemented in the same PRB and interlace by assigning different cyclic shifts of the same sequence and/or OCC (Orthogonal Cover Code).
- the SRS time domain occupies consecutive symbols, for example, the time domain occupies all symbols of the MF-sPUCCH region.
- the SRS adopts the mapping mode of the odd or even subcarriers in the interleaving unit of the B-IFDMA, that is, the odd or even subcarriers in the multiple PRBs of the frequency domain equally spaced, due to the B-IFDMA and the interleaving unit
- the difference between IFDMA, SRS and MF-sPUCCH allocates different interleaving units, and the SRS time domain occupies consecutive symbols, for example, all symbols of the MF-sPUCCH region are occupied by the time domain.
- Scheduling MF-sPUCCH resources and non-scheduled according to different transmission formats of SRS The resources of the MF-s PUCCH are separated, so that the resources used by the unscheduled MF-sPUCCH corresponding to the scheduling information of the uplink transport channel are determined from the resources of the unscheduled MF-s PUCCH, thereby reducing or even avoiding resource collision between different users. .
- the foregoing scheduling information includes: a Control Channel Element (CCE) number carried in the uplink grant information of the uplink transport channel, an Enhanced Control Channel Element (ECCE) number, a frequency domain resource number occupied by the uplink transport channel when scheduled, and an uplink transport channel. At least one of the sequence number occupied by the scheduling and the cyclic shift number and the OCC sequence number occupied when the uplink transport channel is scheduled.
- CCE Control Channel Element
- ECCE Enhanced Control Channel Element
- the CCE number or ECCE number occupied by the uplink grant information (UL Grant) of the uplink transport channel that is, the CCE number or ECCE number occupied by the UL grant of the scheduled PUSCH/MF-ePUCCH, for example, when the PDCCH transmits the UL grant
- the number of the Nth CCEs occupied by the UL grant may be numbered, for example, the number corresponding to the first CCE.
- the CCE is an abbreviation of the Control Channel Element, that is, a control channel unit, a time-frequency resource unit of the LTE transmission control channel
- the ECCE is an abbreviation of the Enhanced Control Channel Element, that is, an enhanced control channel unit, and another transmission control channel of the LTE. Time-frequency resource unit.
- the frequency domain resource number occupied by the uplink transport channel when it is scheduled that is, the resource allocation indication information in the DCI (Downlink Control Information) carrying the UL grant and/or the RRC configured scheduled PUSCH/MF-ePUCCH occupation
- the numbers of the N interleaved units or PRBs for example, the number of the first interleaved unit or the PRB.
- the sequence number occupied by the uplink transport channel and the cyclic shift number that is, the DMRS sequence occupied by the MF-ePUCCH or the sequence number thereof and the number of the cyclic shift size information.
- the OCC sequence number occupied when the uplink transport channel is scheduled such as the Walsh code and the number of the orthogonal mask based on DFT (Discrete Fourier Transformation) or the like.
- the mapping relationship includes a mapping relationship between scheduling information of an uplink transport channel and a number of resources used by the uplink control channel.
- the mapping relationship between the scheduling information of the uplink transmission channel and the resource used by the uplink control channel for transmitting the uplink control signal specifically refers to: establishing scheduling The mapping relationship between the (E)CCE number occupied by the UL grant of the PUSCH/MF-ePUCCH and the resource number of all MF-s PUCCHs, or the interleaving unit or PRB number occupied by the PUSCH/MF-ePUCCH and the resource number of all MF-sPUCCHs Mapping relationship, or the frequency domain sequence number occupied by the MF-ePUCCH and the mapping relationship between the cyclic shift number of the sequence and the resource number of all MF-s PUCCHs, or the OCC sequence number occupied by the PUSCH/MF-ePUCCH and all MF- The mapping relationship of resource numbers of sPUCCH.
- the mapping relationship between the scheduling information of the uplink transmission channel and the resource used by the uplink control channel for transmitting the uplink control signal specifically refers to: occupying a UL grant of the scheduled PUSCH/MF-ePUCCH ( E) mapping relationship between the CCE number and the resource number of the unscheduled MF-s PUCCH, or the mapping relationship between the interleaved unit or the PRB number occupied by the PUSCH/MF-ePUCCH and the resource number of the unscheduled MF-s PUCCH, or occupied by the MF-ePUCCH
- E mapping relationship between the frequency domain sequence number and the cyclic shift number of the sequence and the resource number of the unscheduled MF-s PUCCH, or the mapping relationship between the OCC sequence number occupied by the PUSCH/MF-ePUCCH and the resource number of the unscheduled MF-sPUCCH.
- the foregoing embodiment determines the resource location used by the corresponding unscheduled MF-sPUCCH according to the mapping relationship between the scheduling information of the uplink transport channel and the number of the resource used by the uplink control channel, and scheduling the scheduling information of the PUSCH/MF-ePUCCH. Therefore, the resource collision problem of the same MF-s PUCCH resource location is avoided by multiple user terminals at the same time.
- some embodiments of the present disclosure provide a method for transmitting a sounding reference signal, which specifically includes:
- Step 61 is the same as step 41 above;
- Step 62 is the same as step 42 above;
- Step 63 The SRS is transmitted to the base station by using resources used by the uplink control channel by occupying different frequency domain resources in different time domain resource symbols.
- the SRS is mapped to the resource location used by the uplink control channel determined in step 62 above, and the resource location occupied by the MF-sPUCCH/SRS determined in step 62.
- the MF-sPUCCH/SRS occupies different time domain symbols on different time domain symbols, that is, the frequency resource location selected on the first time domain symbol of the MF-sPUCCH/SRS, and the MF-sPUCCH/SRS
- the frequency domain resources selected on the two time domain symbols are different in position, so that multiple When the time domain symbols are combined, the frequency resources occupied by the channels transmitting the SRS are dense, which can reduce the frequency interval between the frequency domain resources for transmitting the SRS, thereby improving the channel estimation accuracy to a certain extent.
- some embodiments of the present disclosure provide a method for transmitting a sounding reference signal, which specifically includes:
- Step 71 is the same as step 41 above;
- Step 72 is the same as step 42 above;
- Step 73 Map the SRS to different frequency domain resources in different time domain resources according to the cyclic shift on the frequency domain resource location, and transmit the SRS to the base station.
- the cyclic shift size on the frequency domain resource location is determined by the number of time domain resource symbols of the resource used by the uplink control channel and the frequency interval of the frequency domain resources occupied by the SRS in the same time domain resource.
- the frequency resource location (interleaving unit number) selected on the first symbol of the MF-sPUCCH/SRS is determined by the scheduling information of the PUSCH/MF-ePUCCH, and the frequency resource location of the second symbol is the first symbol frequency resource location. Based on the cyclic shift of the T bit, and so on until the time domain symbols are transmitted.
- the frequency interval of the frequency domain resources occupied by the SRS in the same time domain resource may be determined by the frequency interval of the total time domain resource symbol of the MF-sPUCCH/SRS, and optionally, the same time domain may be used.
- the frequency interval of the frequency domain resources occupied by the SRS and the PUSCH/MF-ePUCCH in the resource determines the cyclic shift T on the frequency domain resource. In this way, the frequency interval between frequency resources used for SRS transmission can be reduced, thereby improving the accuracy of SRS evaluation.
- the multiplexing mode (or the bearer mode) of the DMRS is related to the data transmission format.
- the MF-s PUCCH resource including the scheduling MF-s PUCCH and the unscheduled MF-s PUCCH
- the MF-sPUCCH adopts an orthogonal multiplexing manner of the B-IFDMA code (the B-IFDMA code is essentially a special resource allocation).
- the OFDMA code occupies 1 to 4 time domain resource symbols. When more than 2 time domain resource symbols are occupied, the demodulation reference signal DMRS may be transmitted by some symbols, and some symbols are used for transmitting data.
- the multiplexing manner of the MF-sPUCCH includes multiplexing of DMRS symbols and multiplexing of data symbols.
- frequency division of frequency domain can be achieved by transmitting different cyclic shifts of the same sequence on each symbol, such as Zadoff-Chu sequence adopted by DMRS in LTE, and/or OCC between multiple symbols.
- the time domain is orthogonal, for example, 2 symbols pass Walsh codes with a code length of 2: 00 and 01.
- the multiplexing mode of DMRS can depend on how the data symbols are mapped. For the symbols of the transmitted data, the number of modulation symbols that can be transmitted by each data symbol on each PRB is different, and the multiplexing manner is also different. The following will be described in conjunction with specific application scenarios.
- different data symbols on one PRB transmit different modulation symbols
- one data symbol on one PRB can transmit one modulation symbol
- the modulation symbol is mapped to the cyclically shifted sequence of 12 code lengths.
- 12 REs Resource Element
- the data symbols of different UEs are frequency domain orthogonalized by different cyclic shifts.
- the DMRS can also use a cyclically shifted sequence for frequency domain orthogonality.
- two data symbols of one PRB can transmit two modulation symbols, and one interleaving unit (10 PRBs) at 20 MHz can transmit 20 modulation symbols, and 40 codes can be transmitted under QPSK modulation.
- different data symbols on one PRB transmit the same modulation symbol, and the modulation symbol is extended to multiple data symbols by OCC, and one data symbol on one PRB can transmit one modulation symbol, and the modulation symbol is multiplied by 12
- the cyclically shifted sequence of code lengths is mapped to 12 REs, for example, Zadoff-Chu sequences, and data of different UEs are simultaneously time-domain orthogonalized by frequency domain orthogonality and different OCCs by different cyclic shifts.
- two data symbols of one PRB can transmit one modulation symbol, and one interleaving unit (10 PRBs) at 20 MHz can transmit 10 modulation symbols in QPSK (Quadrature Phase Shift Keying, orthogonal). Under phase shift keying modulation, 20 coded bits can be transmitted.
- different data symbols on one PRB transmit the same modulation symbol
- the modulation symbol is extended to multiple data symbols by OCC
- one data symbol on one PRB can transmit 12 modulation symbols
- 12 modulation symbols are mapped to 12
- data of different UEs are time-domain orthogonal through different OCCs.
- two data symbols as an example, two data symbols of one PRB can transmit 12 modulation symbols, and one interleaving unit (10 PRBs) at 20 MHz can transmit 120.
- the modulation symbol can transmit 240 coded bits under QPSK modulation.
- the cyclic shift interval of the sequence is 1, one interleaving unit supports the MF-sPUCCH of 2 UEs at the same time.
- the transmission format of the SRS can be the same sequence as the DMRS sequence of the demodulation reference signal, for example, a Zadoff-Chu sequence
- the SRS can also adopt multiple mapping modes in the frequency domain, including:
- Manner 1 The existing LTE SRS transmission format, IFDMA with subcarrier spacing of 2, that is, only occupying odd or even subcarriers in consecutive PRBs in the frequency domain.
- Manner 2 The same B-IFDMA mapping mode as MF-sPUCCH/PUSCH/MF-ePUCCH in MuLTEfire is adopted, that is, all subcarriers in multiple PRBs with equal intervals in the frequency domain.
- Manner 3 The mapping mode of occupying only odd or even subcarriers in the interleaving unit of B-IFDMA is adopted, that is, odd or even subcarriers in multiple PRBs of equal frequency interval in the frequency domain.
- the scenario corresponds to the SRS adopting the mapping mode of the foregoing mode 2 or mode 3.
- the resource used by the uplink control channel occupies N time domain resource symbols and the M time zone resource symbols occupy M interleaving units, the N indicators of the SRS are indicated.
- the different time domain resources in the time domain resource symbols are respectively matched with different M interleaving units, and the SRS is mapped to the resources used by the uplink control channel, and transmitted to the base station.
- the frequency interval between the physical resource blocks of the frequency domain non-contiguous discontinuous inter-units is determined according to the cyclic shift of the frequency domain resource positions, M and N Both are positive integers.
- the SRS adopts a B-IFDMA mapping mode, occupies one interleaving unit and four time domain resource symbols, and the MF-sPUCCH and the SRS are on each time domain resource symbol.
- the frequency domain orthogonality is performed by using different cyclic shifts of the same sequence, and the multiple symbols of the MF-sPUCCH or SRS are not orthogonal to the time domain OCC, so each symbol of the SRS can be mapped to a different interleaving unit. As shown in FIG.
- the base station performs joint time-frequency domain interpolation on the SRS information in the above four B-IFDMA symbols, so that the minimum frequency interval is reduced from 10 PRBs to 3 PRBs, and the evaluation accuracy is greatly improved.
- the scenario corresponds to another scenario in which the SRS adopts the mapping mode of the foregoing mode 2 or mode 3.
- the indication is
- Each L adjacent resource symbol of the SRS is a group of the same interleaved unit, and performs time domain orthogonal code division; the SRS is mapped to resources used by the uplink control channel, and transmitted to the base station.
- the frequency of the interleaved units occupied by the resource symbols of different groups is different, and among all the frequency resource positions occupied by the N time domain resource symbols, the physical resource blocks PRB of the interleaved units that are not adjacent to the frequency domain are in the frequency domain.
- the frequency spacing is determined based on the cyclic shift at the location of the frequency domain resource, where M, N, and L are all positive integers.
- the SRS adopts the B-IFDMA mapping mode, occupies one interleaving unit and four time domain resource symbols, and the MF-sPUCCH and the SRS use the same at the same time on the first two symbols.
- the different cyclic shifts of the sequence are performed in the frequency domain orthogonal manner and the time domain orthogonal of different OCCs (for example, the first two symbols are DMRS, and the last two symbols are data), so the first two symbols of the SRS can be combined with the last two symbols. Symbols are mapped to different interleaved units. As shown in FIG.
- interleaving units there are 10 interleaving units in the 20 MHz system bandwidth, SRS of the same UE (with a hatched portion in the figure), and the first B-IFDMA symbol and the second B-IFDMA symbol occupy the first one.
- the interleaving unit (the interleaving unit numbered 0), the third B-IFDMA symbol and the fourth B-IFDMA symbol occupy the sixth interleaving unit (the interleaving unit numbered 5), so that the interval of the SRS in the frequency domain is as far as possible Small and uniform
- the base station performs joint time-frequency interpolation on the SRS information in the above four B-IFDMA symbols, so that the minimum frequency interval is reduced from 10 PRBs to 5 PRBs, which improves the channel estimation accuracy of the SRS to some extent.
- the scenario corresponds to the mapping manner of the SRS in the foregoing manner, and is used when the uplink control channel is used.
- the resource occupies N time domain resource symbols, each time domain resource symbol indicating that the SRS occupies different M frequency bands consecutive uninterleaved (or allocated to SRS transmission) interlace unit combination, and the SRS is mapped to the uplink.
- the resources used by the control channel are transmitted to the base station.
- the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving unit combination is determined according to the cyclic shift on the frequency domain resource location
- M and N are both positive integers.
- the frequency hopping of the SRS needs to be performed in an area other than the resources allocated to the MF-sPUCCH.
- FIG. 10 there are 10 interleaving units in the 20 MHz system bandwidth, and it is assumed that the interleaved units 0 to 5 (the black background portion in the figure) are allocated for the scheduled MF-s PUCCH, and the interleaving unit 6 is allocated for the unscheduled SRS.
- the SRS of the same UE occupies the odd or even subcarriers in 4 consecutive PRBs, and the first IFDMA symbol occupies the PRB.
- the odd or even subcarriers numbered 6 to 9 the second IFDMA symbol occupying an odd or even subcarrier with a PRB number of 26 to 29, and the third IFDMA symbol occupying an odd or even subcarrier with a PRB number of 56 to 59
- the fourth IFDMA symbol occupies an odd or even subcarrier with a PRB number of 76 to 79.
- the base station can perform joint frequency and frequency interpolation on the SRS information in the four symbols, so that the interval of the SRS in the frequency domain is as small as possible, and the minimum frequency interval is It is 17 PRBs.
- the scenario corresponds to another scenario in which the SRS adopts the mode of the third mode.
- the resource used by the uplink control channel occupies N time domain resource symbols
- different time domain resource symbols in the N time domain resource symbols of the SRS are respectively indicated.
- the M interleaving units that are not allocated to other channels are occupied, and the SRS is mapped to the resources used by the uplink control channel and transmitted to the base station.
- the frequency interval between the physical resource blocks PRB of the interleaved units that are not adjacent to each other in the frequency domain is determined according to the cyclic shift in the frequency domain position, where all the frequency resource positions occupied by the N time domain resource symbols are determined, wherein , M and N are both positive integers.
- the frequency hopping of the SRS needs to be performed in an area other than the resource allocated to the MF-sPUCCH.
- FIG. 11 there are 10 interleaving units in the 20 MHz system bandwidth, and it is assumed that the scheduled MF-sPUCCH is assigned an even-numbered interleaving unit (numbered 0/2/4/6/8), which is an unscheduled SRS. Odd numbered Interleaved unit (numbered as 1/3/5/7/9).
- the SRS of the same UE occupies the odd or even subcarriers of one interleaving unit.
- the first IFDMA symbol occupies the odd or even subcarrier of the interleaved unit numbered 1
- the second IFDMA symbol occupies the odd or even subcarrier of the interleaved unit numbered 3
- the third IFDMA symbol occupies the interlace numbered 7.
- the odd or even subcarrier of the unit, the fourth IFDMA symbol occupies the odd or even subcarrier of the interleaved unit numbered 9, and the base station performs joint frequency-frequency interpolation on the SRS information in the four IFDMA symbols due to the minimum frequency interval
- the 10 PRBs are reduced to 3 PRBs, so that the interval of the SRS in the frequency domain is as small and uniform as possible, thereby improving the channel estimation accuracy of the SRS to some extent.
- the user terminal determines the corresponding uplink according to the mapping relationship between the scheduling information of the preset uplink transmission channel and the resource used by the uplink control channel, and the acquired scheduling information of the scheduled uplink transmission channel. Control the resource location used by the channel to reduce or even avoid the collision of uplink control channel resources between different user terminals. Further, after determining the uplink control channel, the sounding reference signal SRS to be transmitted is mapped to the uplink control channel and transmitted to the base station to narrow the frequency domain of the transmitted SRS by adopting different time domain resource symbols occupying different frequency domain resources. The frequency spacing between resources can improve channel estimation accuracy to some extent.
- some embodiments of the present disclosure provide a transmission apparatus 120 for detecting a reference signal, including:
- the obtaining module 121 is configured to acquire scheduling information of an uplink transport channel when the uplink transport channel is scheduled;
- the processing module 122 is configured to determine, according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel for transmitting the uplink control signal, the uplink control channel corresponding to the scheduling information of the uplink transport channel. resource of;
- the sending module 123 is configured to transmit the sounding reference signal by using resources used by the uplink control channel.
- the obtaining module 121 includes:
- an acquiring unit configured to acquire scheduling information of the uplink transport channel from the base station when the uplink transport channel used for transmitting the uplink data signal is scheduled.
- the processing module 122 includes:
- a processing unit configured to determine a non-scheduled uplink control corresponding to scheduling information of the uplink transport channel in a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel used for transmitting the uplink control signal The resources used by the channel.
- the processing unit includes:
- Obtaining a sub-unit configured to acquire, by the eNB, the division information of the scheduling resource and the non-scheduled resource indicated by the RRC configuration or by using the common physical downlink common channel;
- a processing subunit configured to determine, according to the split information, the scheduling information, and a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel used for transmitting the uplink control signal, to determine that the uplink transport channel is scheduled
- the scheduling information corresponds to the resources used by the non-scheduled uplink control channel.
- the scheduling information includes: a CCE number or an ECCE number carried in the uplink grant information of the uplink transport channel, a frequency domain resource number occupied when the uplink transport channel is scheduled, and a sequence number occupied when the uplink transport channel is scheduled, and At least one of a cyclic shift number and an OCC sequence number occupied when the uplink transport channel is scheduled;
- the mapping relationship includes a mapping relationship between scheduling information of an uplink transport channel and a number of resources used by the uplink control channel.
- the sending module 123 includes:
- the sending unit is configured to transmit the SRS to the base station by using resources used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- the specific sending unit is mainly used for:
- the SRS is mapped to different frequency domain resources in different time domain resources according to cyclic shifts in the frequency domain resource locations, and transmitted to the base station; wherein the cyclic shift in the frequency domain resource location is adopted by the uplink control channel.
- the number of time domain resource symbols of the resource and the frequency interval of the frequency domain resources occupied by the SRS within the same time domain resource are determined.
- the sending unit includes:
- a first indicator sub-unit configured to: when the resource used by the uplink control channel occupies N time-domain resource symbols, and when the M-interlace units are occupied in one time-domain resource symbol, indicating different time in the N time-domain resource symbols of the SRS
- the domain resources are respectively occupied by different M interleaving units, wherein in the frequency resource positions occupied by the N time domain resource symbols, the frequency domain is not adjacent to the discontinuous interleaving unit.
- the frequency interval between physical resource blocks is determined according to a cyclic shift of a frequency domain resource location, where M and N are positive integers;
- the first sending subunit is configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit further includes:
- a second indicator sub-unit configured to: when the resource used by the uplink control channel occupies N time-domain resource symbols, and when the M-interleave unit is occupied by one time domain resource symbol, each L adjacent resource symbol indicating the SRS is one
- the group occupies the same interleaving unit and performs time domain orthogonal code division; wherein, the frequency of the interleaving unit occupied by the resource symbols of different groups is different, and within all frequency resource positions occupied by the N time domain resource symbols, the frequency The frequency interval between the physical resource blocks PRB of the interleaving unit that is not adjacent to the domain is determined according to the cyclic shift in the frequency domain resource position, where M, N, and L are positive integers;
- a second sending subunit configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit also includes:
- a third indication subunit configured to: when each resource used by the uplink control channel occupies N time domain resource symbols, indicating that each time domain resource symbol of the SRS occupies different M frequency domain continuous unallocated interleaving units Combining, wherein, among all the frequency resource positions occupied in the N time domain resource symbols, the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving unit combination is cyclically shifted according to the frequency domain resource position Bit determined, where M and N are both positive integers;
- a third sending subunit configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit also includes:
- a fourth indicator subunit configured to: when the resource used by the uplink control channel occupies N time domain resource symbols, the different time domain resource symbols in the N time domain resource symbols indicating the SRS respectively occupy different assignments and are not allocated to other M interleaving units of the channel, wherein, among all the frequency resource positions occupied in the N time domain resource symbols, the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving units is according to the frequency domain position The cyclic shift is determined, wherein M and N are both positive integers;
- a fourth sending subunit configured to map the SRS to a resource used by the uplink control channel, and Transfer to the base station.
- the uplink transmission channel is a physical uplink shared channel (PUSCH)/extended physical uplink control channel (MF-ePUCCH), and the uplink control channel is a short physical uplink control channel (MF-sPUCCH).
- PUSCH physical uplink shared channel
- MF-ePUCCH extended physical uplink control channel
- MF-sPUCCH short physical uplink control channel
- the resource location used by the corresponding unscheduled MF-sPUCCH is determined. Therefore, the resource collision problem of the same MF-s PUCCH resource location is avoided by multiple user terminals at the same time.
- the sounding reference signal SRS to be transmitted is mapped to the uplink control channel and transmitted to the base station to narrow the frequency domain of the transmitted SRS by adopting different time domain resource symbols occupying different frequency domain resources. The frequency spacing between resources can improve channel estimation accuracy to some extent.
- the device embodiment of the present disclosure is a device corresponding to the embodiment of the foregoing method, and all the implementation means in the foregoing method embodiments are applicable to the embodiment of the device, and the same technical effects can be achieved.
- some embodiments of the present disclosure provide a terminal, including:
- the receiver 131 is configured to receive scheduling information of an uplink transport channel when the uplink transport channel is scheduled;
- the processor 132 is connected to the receiver, and is configured to: determine the uplink transmission channel according to the mapping relationship between the scheduling information of the uplink transmission channel and the resource preset used by the uplink control channel for transmitting the uplink control signal.
- the transmitter 133 is coupled to the processor and configured to transmit the sounding reference signal by using resources used by the uplink control channel.
- the processor 152 can also be configured and implement the functions implemented by all the modules in the foregoing device embodiments, and can achieve the same technical effects as those of the foregoing device embodiments.
- some embodiments provide a method for transmitting a sounding reference signal, which specifically includes:
- Step 141 Determine a resource location used by the uplink control channel of the sounding reference signal SRS.
- the uplink control channel is used to transmit various control signals.
- the resource location used for determining the uplink control channel of the sounding reference signal SRS may be scheduled by the base station, or may be terminated by the user. The way of independent monitoring.
- Step 142 The SRS is transmitted to the base station by using resources used by the uplink control channel by occupying different frequency domain resources in different time domain resource symbols.
- the MF-sPUCCH uses multiple frequency domain resource locations on multiple time domain symbols, that is, the frequency resource location selected on the first symbol of the MF-sPUCCH, and the frequency domain selected on the second symbol of the MF-sPUCCH.
- the resource locations are different, so that the multiple time domain symbols are combined, which is equivalent to the frequency resources occupied by the channel for transmitting the SRS, so that the frequency interval between the frequency domain resources for transmitting the SRS can be narrowed, so that the frequency interval can be reduced to some extent. Improve channel estimation accuracy.
- some embodiments provide a method for transmitting a sounding reference signal, which specifically includes:
- Step 151 is the same as step 141 above;
- Step 152 Map the SRS to different frequency domain resources in different time domain resources according to the cyclic shift on the frequency domain resource location, and transmit the SRS to the base station.
- the cyclic shift on the frequency domain resource location is determined by the number of time domain resource symbols of the resource used by the uplink control channel and the frequency interval of the frequency domain resources occupied by the SRS in the same time domain resource.
- the frequency resource location (interleaving unit number) selected on the first symbol of the MF-sPUCCH is determined by the scheduling information of the PUSCH/MF-ePUCCH, and the frequency resource location of the second symbol is the basis of the first symbol frequency resource location.
- the frequency interval of the frequency domain resource occupied by the SRS in the same time domain resource may be determined by the frequency interval of the frequency domain resource occupied by the SRS in the same time domain resource, and optionally, may also be used in the same time domain resource.
- the frequency interval of the frequency domain resources occupied by the SRS and the PUSCH/MF-ePUCCH determines the cyclic shift T on the frequency domain resources. In this way, the frequency interval between frequency resources used for SRS transmission can be reduced, thereby improving the accuracy of SRS evaluation.
- the multiplexing mode (or the bearer mode) of the DMRS is related to the data transmission format.
- the transmission format is specifically as described in the fourth embodiment.
- the SRS may also adopt multiple mapping manners, such as the DMRS sequence, in the frequency domain, including: the first mode, the second mode, and the third mode listed in the fourth embodiment.
- the following describes the process of mapping the SRS to the frequency domain resources occupied by the MF-sPUCCH and transmitting them in combination with specific application scenarios.
- the SRS adopts the mapping mode of the foregoing mode 2 or mode 3.
- the N time domain resource symbols indicating the SRS are used.
- the different time domain resources in the network are consistent with the different M interleaving units, and the SRS is mapped to the resources used by the uplink control channel, and transmitted to the base station.
- the frequency interval between the physical resource blocks of the frequency domain non-contiguous discontinuous inter-units is determined according to the cyclic shift of the frequency domain resource positions, M and N Both are positive integers. For specific examples, reference may be made to scenario one in the above embodiment.
- the SRS adopts the mapping mode of the foregoing mode 2 or mode 3, when the resources used by the uplink control channel occupy N time domain resource symbols, and when one time domain resource symbol occupies M interleaving units, each L of the SRS is indicated.
- the adjacent resource symbols are a group of the same interleaved unit, and the time domain orthogonal code division is performed; the SRS is mapped to the resources used by the uplink control channel, and transmitted to the base station.
- the frequency of the interleaved units occupied by the resource symbols of different groups is different, and among all the frequency resource positions occupied by the N time domain resource symbols, the physical resource blocks PRB of the interleaved units that are not adjacent to the frequency domain are in the frequency domain.
- the frequency spacing is determined based on the cyclic shift at the location of the frequency domain resource, where M, N, and L are all positive integers. For specific example description, reference may be made to scenario 2 in the above embodiment.
- the SRS adopts the mapping mode of the foregoing mode 1.
- each time domain resource symbol indicating the SRS occupies different M frequency domain continuous unallocated interlaces.
- the unit combines the SRS into the resources used by the uplink control channel and transmits the data to the base station.
- the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving unit combination is determined according to the cyclic shift on the frequency domain resource location
- M and N are both positive integers.
- the SRS adopts the mode 1 mapping mode
- the different time domain resource symbols in the N time domain resource symbols indicating the SRS respectively occupy different
- the M interleaving units allocated to other channels map the SRS to the resources used by the uplink control channel and transmit to the base station.
- the frequency interval between the physical resource blocks PRB of the interleaved units that are not adjacent to each other in the frequency domain is determined according to the cyclic shift in the frequency domain position, where all the frequency resource positions occupied by the N time domain resource symbols are determined, wherein , M and N are both positive integers.
- M and N are both positive integers.
- the sounding reference signal SRS to be transmitted is mapped to the uplink control channel and transmitted to the base station to reduce the transmission by using different time domain resource symbols occupying different frequency domain resources.
- the frequency spacing between the frequency domain resources of the SRS can improve the channel estimation accuracy to some extent.
- some embodiments provide a method for transmitting a sounding reference signal, which specifically includes:
- Step S161 Determine the time domain resource location used by the first A symbol or the last A symbols of the uplink transport channel as the uplink control channel of the fixed sounding reference signal SRS.
- the uplink transport channel includes: a PUSCH/MF-ePUCCH, and the first A or the last A symbols of the PUSCH/MF-ePUCCH subframe are used as an uplink control channel of the SRS, that is, in the time domain, the SRS may be
- the PUSCH/MF-ePUCCH is transmitted in the first A symbols or may be transmitted in the last A symbols of the PUSCH/MF-ePUCCH.
- Step S162 Mapping the SRS to the uplink control channel by using the first A symbol of the uplink control channel or the frequency domain resource location occupied by the last A symbol is different from the frequency domain resource location occupied by other symbols of the uplink transmission channel.
- the first A symbol or the last A symbols are transmitted to the base station.
- the frequency domain resource location occupied by other data transmitted in the PUSCH/MF-ePUCCH is different from the frequency domain resource location occupied by the transmission SRS, thus by combining the PUSCH.
- /MF-ePUCCH other control signals (such as DMRS) and SRS to improve the frequency domain density of the reference signal, thereby improving channel estimation accuracy.
- the SRS occupation is different from the PUSCH/MF-ePUCCH occupation.
- the SRS in the time domain may be after the PUSCH/MF-ePUCCH (case1) or before (case2), and the interlace occupied by the SRS in the frequency domain may be the intermediate frequency position of the resource interval occupied by the PUSCH/MF-ePUCCH, by combining PUSCH/MF-
- the DMRS and SRS in the ePUCCH improve the frequency domain density of the reference signal, thereby improving channel estimation accuracy.
- some embodiments provide a transmission apparatus 160 for detecting a reference signal, including:
- the processing module 181 is configured to determine a resource location used by the uplink control channel of the sounding reference signal SRS;
- the sending module 182 is configured to transmit the SRS to the base station by using resources used by the uplink control channel by using different time domain resource symbols to occupy different frequency domain resources.
- the sending module 182 includes:
- a sending unit configured to map the SRS to different frequency domain resources in different time domain resources according to a cyclic shift on a frequency domain resource location, and transmit the data to a base station; where the frequency domain resource location is cyclically shifted
- the bit is determined by the number of time domain resource symbols of the resource used by the uplink control channel and the frequency interval of the frequency domain resources occupied by the SRS in the same time domain resource.
- the sending unit includes:
- a first indicator sub-unit configured to: when the resource used by the uplink control channel occupies N time-domain resource symbols, and when the M-interlace units are occupied in one time-domain resource symbol, indicating different time in the N time-domain resource symbols of the SRS
- the domain resources are respectively occupied by different M interleaving units, wherein, among all the frequency resource positions occupied by the N time domain resource symbols, the frequency interval between the physical resource blocks of the interleaved units in the frequency domain not adjacent to each other is frequency A cyclic shift of a location of a domain resource, where M and N are both positive integers;
- the first sending subunit is configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit further includes:
- a second indicator sub-unit configured to: when the resource used by the uplink control channel occupies N time-domain resource symbols, and when the M-interleave unit is occupied by one time domain resource symbol, each L adjacent resource symbol indicating the SRS is one
- the group occupies the same interleaving unit and performs time domain orthogonal code division; wherein, the frequency of the interleaving unit occupied by the resource symbols of different groups is different, and within all frequency resource positions occupied by the N time domain resource symbols,
- the frequency interval between the physical resource blocks PRB of the interleaving unit that is not adjacent to the frequency domain is a cyclic shift in the frequency domain resource position, where M, N, and L are positive integers;
- a second sending unit configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit also includes:
- a third indication subunit configured to: when each resource used by the uplink control channel occupies N time domain resource symbols, indicating that each time domain resource symbol of the SRS occupies different M frequency domain continuous unallocated interleaving units Combination, wherein, in all frequency resource locations occupied by N time domain resource symbols, a frequency interval between physical resource blocks PRB combined by frequency domain non-contiguous discontinuous interleaving units is a cycle on a frequency domain resource location Shift, wherein M and N are both positive integers;
- a third sending subunit configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the sending unit also includes:
- a fourth indicator subunit configured to: when the resource used by the uplink control channel occupies N time domain resource symbols, the different time domain resource symbols in the N time domain resource symbols indicating the SRS respectively occupy different assignments and are not allocated to other M interleaving units of the channel, wherein, among all the frequency resource positions occupied in the N time domain resource symbols, the frequency interval between the physical resource blocks PRB of the interleaving units that are not adjacent to each other in the frequency domain is the frequency domain position a cyclic shift on which M and N are both positive integers;
- a fourth sending subunit configured to map the SRS into a resource used by the uplink control channel, and transmit the signal to the base station.
- the processing module 181 further includes:
- a processing unit configured to determine a time domain resource location used by the first A symbol or the last A symbols of the uplink transport channel as an uplink control channel of the fixed sounding reference signal SRS; wherein A is a positive integer.
- sending module 182 further includes:
- a transmitting unit configured to adopt a manner that a frequency domain resource location occupied by a first A symbol or a last A symbol of the uplink control channel is different from a frequency domain resource location occupied by other symbols of the uplink transmission channel,
- the SRS is mapped to the first A symbol or the last A symbols of the uplink control channel and transmitted to the base station.
- some embodiments provide a terminal, including:
- the processor 191 is configured to: determine a resource location used by the uplink control channel of the sounding reference signal SRS;
- the transmitter 192 is connected to the processor, and is configured to transmit the SRS to the base station by using resources used by the uplink control channel by using different time domain resource symbols to occupy different frequency domain resources.
- FIG 20 shows a structure suitable for realizing a schematic diagram of a computer system of the present application, or a terminal transmission apparatus 200 according to an embodiment.
- computer system 200 includes a central processing unit (CPU) 201 that can be loaded from a program stored in read only memory (ROM) 202 or a program loaded from random storage memory (RAM) 203 from storage portion 208. And perform various appropriate actions and processes.
- ROM read only memory
- RAM random storage memory
- various programs and data required for the operation of the system 200 are also stored.
- the CPU 201, the ROM 202, and the RAM 203 are connected to each other through a bus 204.
- An input/output (I/O) interface 205 is also coupled to bus 204.
- the following components are connected to the I/O interface 205: an input portion 206 including a keyboard, a mouse, etc.; an output portion 207 including, for example, a cathode ray tube (CRT), a liquid crystal display (LCD), and the like, and a storage portion 208 including a hard disk or the like. And a communication portion 209 including a network interface card such as a LAN card, a modem, or the like. The communication section 209 performs communication processing via a network such as the Internet.
- Driver 210 is also connected to I/O interface 205 as needed.
- a removable medium 211 such as a magnetic disk, an optical disk, a magneto-optical disk, a semiconductor memory or the like, is mounted on the drive 210 as needed so that a computer program read therefrom is installed into the storage portion 208 as needed.
- an embodiment of the present disclosure includes a computer program product comprising a computer program tangibly embodied on a machine readable medium, the computer program comprising program code for performing the method of the above flow chart.
- the computer program can be downloaded and installed from the network via communication portion 209, and/or installed from removable media 211.
- each block of the flowchart or block diagrams can represent a module, a program segment, or a portion of code that includes one or more logic for implementing the specified.
- Functional executable instructions can also occur in a different order than that illustrated in the drawings. For example, two successively represented blocks may in fact be executed substantially in parallel, and they may sometimes be executed in the reverse order, depending upon the functionality involved.
- each block of the block diagrams and/or flowcharts, and combinations of blocks in the block diagrams and/or flowcharts can be implemented in a dedicated hardware-based system that performs the specified function or operation. Implementation, or can be implemented in a combination of dedicated hardware and computer instructions.
- the units or modules described in the embodiments of the present application may be implemented by software or by hardware.
- the described unit or module can also be provided in the processor.
- the names of these units or modules do not in any way constitute a limitation on the unit or module itself.
- the various components or steps may be decomposed and/or recombined. These decompositions and/or recombinations should be considered as equivalents to the present disclosure.
- the steps of performing the series of processes described above may naturally be performed in chronological order in the order illustrated, but need not necessarily be performed in chronological order. Certain steps may be performed in parallel or independently of one another.
- a method for transmitting a sounding reference signal comprising:
- the SRS is transmitted to the base station by using channel resources used by the uplink control channel in a manner of occupying different frequency domain resources in different time domain resource symbols.
- A2 The method for transmitting a sounding reference signal according to A1, wherein the SRS is transmitted to a base station by using a channel resource used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- the steps include:
- A3 The method for transmitting a sounding reference signal according to A2, wherein the SRS is mapped to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource position, and is transmitted to the base station.
- the SRS is mapped to a channel resource used by the uplink control channel and transmitted to a base station.
- the method for transmitting a sounding reference signal according to A2, wherein the step of mapping the SRS to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource location, and transmitting to the base station include:
- each L adjacent resource symbols indicating the SRS are occupied by the same group.
- the frequency interval between physical resource blocks PRB of the adjacent discontinuous interleaving unit is determined according to a cyclic shift in the frequency domain resource location, where M, N, and L are positive integers;
- the SRS is mapped to a channel resource used by the uplink control channel and transmitted to a base station.
- A5. The method for transmitting a sounding reference signal according to A2, wherein the step of mapping the SRS to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource location, and transmitting to the base station include:
- each time domain resource symbol indicating the SRS occupies different M frequency domain continuous uninterleaved interleaving unit combinations, where The frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving unit combination is cyclically shifted according to the frequency domain resource position in all frequency resource locations occupied by the N time domain resource symbols Determine, wherein M and N are positive integers;
- the SRS is mapped to a channel resource used by the uplink control channel and transmitted to a base station.
- A6 The method for transmitting a sounding reference signal according to A2, wherein the SRS is mapped to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource position, and is transmitted to the base station.
- the channel resources used by the uplink control channel occupy N time domain resource symbols
- different time domain resource symbols in the N time domain resource symbols indicating the SRS respectively occupy different unassigned points.
- M interleaving units allocated to other channels wherein, among all frequency resource positions occupied in the N time domain resource symbols, the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous interleaving units is according to the A cyclic shift in the frequency domain position is determined, wherein M and N are positive integers;
- the SRS is mapped to a channel resource used by the uplink control channel and transmitted to a base station.
- A7 The method for transmitting a sounding reference signal according to A1, wherein the determining the resource location used by the uplink control channel of the sounding reference signal SRS comprises:
- A8 The method for transmitting a sounding reference signal according to A7, wherein the SRS is transmitted to a base station by using a channel resource used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- the steps include:
- the first A symbols or the last A symbols of the uplink control channel are transmitted to the base station.
- a transmission device for detecting a reference signal comprising:
- a processing module configured to determine a resource location used by an uplink control channel of the sounding reference signal SRS;
- a sending module configured to transmit the SRS to the base station by using a channel resource used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- a terminal comprising:
- a processor configured to: determine a resource location used by an uplink control channel of the sounding reference signal SRS;
- the transmitter is connected to the processor, and is configured to transmit the SRS to the base station by using a channel resource used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- a method for transmitting a sounding reference signal comprising:
- Determining the scheduling when the uplink transport channel is scheduled according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel for transmitting the uplink control signal The resources used by the uplink control channel corresponding to the information;
- the sounding reference signal SRS is transmitted by using resources used by the uplink control channel.
- the method for transmitting a sounding reference signal according to D1, wherein the step of acquiring scheduling information when the uplink transport channel is scheduled comprises:
- the scheduling information when the uplink transport channel is scheduled is obtained from the base station.
- the steps of the resources used by the uplink control channel corresponding to the scheduling information when the transport channel is scheduled include:
- the unscheduled scheduling information corresponding to the scheduling information when the uplink transport channel is scheduled The resources used by the uplink control channel.
- D4 The method for transmitting a sounding reference signal according to D1, wherein the scheduling information comprises: a control channel unit CCE number or an enhanced control channel unit ECCE number carried in uplink grant information of the uplink transport channel, a frequency domain resource number occupied when the uplink transport channel is scheduled, a sequence number occupied by the uplink transport channel when scheduled, and a cyclic shift number, or an orthogonal mask OCC occupied when the uplink transport channel is scheduled At least one of the sequence numbers;
- the mapping relationship includes a mapping relationship between scheduling information of the uplink transport channel and a number of resources used by the uplink control channel.
- D5. The method for transmitting a sounding reference signal according to D1, wherein the step of transmitting the sounding reference signal SRS by using the resource used by the uplink control channel comprises:
- the SRS is transmitted to the base station by using resources used by the uplink control channel in a manner of occupying different frequency domain resources in different time domain resource symbols.
- D6 The method for transmitting a sounding reference signal according to D5, wherein the SRS is transmitted to a base station by using a resource used by the uplink control channel by using different frequency domain resources in different time domain resource symbols.
- the steps include:
- the SRS is mapped to different frequency domain resources in different time domain resources according to cyclic shifts in frequency domain resource locations, and transmitted to the base station;
- the cyclic shift on the frequency domain resource location is determined by the number of time domain resource symbols of the resource used by the uplink control channel and the frequency interval of the frequency domain resource occupied by the SRS in the same time domain resource. of.
- D7 The method for transmitting a sounding reference signal according to D6, wherein the SRS is mapped to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource location, and transmitted to a base station.
- the steps include:
- a frequency interval between physical resource blocks of the frequency domain non-contiguous discontinuous interleaving units is determined according to a cyclic shift of the frequency domain resource locations, where , M and N are positive integers;
- D8 The method for transmitting a sounding reference signal according to D6, wherein the SRS is mapped to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource location, and transmitted to a base station.
- the steps include:
- each L adjacent resource symbols indicating the SRS are occupied by the same group. Interleaving units and performing time domain orthogonal code division;
- the frequency of the interleaved units occupied by the different groups of time domain resource symbols is different, and the physical resource blocks PRB of the interleaved units that are not adjacent to each other in the frequency domain are located in all the frequency resource positions occupied by the N time domain resource symbols.
- the frequency interval between the two is determined according to a cyclic shift in the frequency domain resource location, wherein M, N, and L are positive integers;
- D9 The method for transmitting a sounding reference signal according to D6, wherein the SRS is mapped to different frequency domain resources in different time domain resources according to a cyclic shift in a frequency domain resource location, and transmitted to a base station.
- the steps include:
- each time domain resource symbol indicating the SRS occupies different M frequency domain continuous unallocated interleaving units combination
- the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous interleaving unit combination is cyclically shifted according to the frequency domain resource position in all the frequency resource positions occupied by the N time domain resource symbols. Bit determined, where M and N are both positive integers;
- the steps include:
- the frequency interval between the physical resource blocks PRB of the frequency domain non-contiguous discontinuous inter-units is determined according to the cyclic shift in the frequency domain position.
- the method for transmitting a sounding reference signal according to any one of D7 to D10, wherein the uplink transmission channel is a physical uplink shared channel PUSCH/physical uplink control channel MF-ePUCCH; and the uplink control channel is a short physical uplink Control channel MF-sPUCCH.
- the method for transmitting the sounding reference signal according to D1, wherein the preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel for transmitting the uplink control signal comprises:
- the steps of the resources used by the unscheduled uplink control channel corresponding to the scheduling information when the uplink transmission channel is scheduled include:
- the scheduling information corresponds to the resources used by the non-scheduled uplink control channel.
- a transmission device for detecting a reference signal comprising:
- An acquiring module configured to acquire scheduling information when an uplink transport channel is scheduled
- the processing module is configured to determine, according to a preset mapping relationship between the scheduling information of the uplink transport channel and the resource used by the uplink control channel used for transmitting the uplink control signal, the uplink corresponding to the scheduling information when the uplink transport channel is scheduled.
- the resources used by the control channel
- a sending module configured to transmit the sounding reference signal SRS by using resources used by the uplink control channel.
- a terminal comprising:
- a receiver configured to receive scheduling information when an uplink transport channel is scheduled
- the processor is connected to the receiver, and is configured to: determine the uplink according to a preset mapping relationship between scheduling information of the uplink transport channel and resources used by the uplink control channel for transmitting the uplink control signal. a resource used by the uplink control channel corresponding to the scheduling information when the transport channel is scheduled;
- a transmitter coupled to the processor, configured to transmit the sounding reference signal SRS by using resources used by the uplink control channel.
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Abstract
Description
Claims (27)
- 一种探测参考信号的传输方法,包括:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源;利用所述上行控制信道所采用的资源,传输探测参考信号。
- 根据权利要求1所述的探测参考信号的传输方法,其中,当上行传输信道被调度,获取所述上行传输信道的所述调度信息的步骤包括:当所述上行传输信道被调度时,从基站获取所述上行传输信道的所述调度信息。
- 根据权利要求1所述的探测参考信号的传输方法,其中,根据上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源的步骤包括:在所述上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系中,确定所述上行传输信道的所述调度信息对应的非调度的上行控制信道所采用的资源。
- 根据权利要求1所述的探测参考信号的传输方法,其中,所述调度信息包括:所述上行传输信道的上行授权信息中所携带的控制信道单元编号或增强控制信道单元编号、所述上行传输信道被调度时所占用的频域资源编号、所述上行传输信道被调度时所占用的序列编号以及循环移位编号、以及所述上行传输信道被调度时所占用的正交掩码序列编号中的至少一项;所述映射关系包括:所述上行传输信道的调度信息与上行控制信道所采用的资源的编号之间的映射关系。
- 根据权利要求1所述的探测参考信号的传输方法,其中,利用所述上行控制信道所采用的资源,传输探测参考信号的步骤包括:采用在不同的时域资源符号内占用不同频域资源的方式,通过所述上行 控制信道所采用的资源向基站传输所述探测参考信号。
- 根据权利要求5所述的探测参考信号的传输方法,其中,采用在不同的时域资源符号内占用不同频域资源的方式,通过所述上行控制信道所采用的资源向基站传输所述探测参考信号的步骤包括:按照频域资源位置上的循环移位,将所述探测参考信号在不同时域资源内映射至不同频域资源上,并传输至基站;其中,所述频域资源位置上的循环移位是由所述上行控制信道所采用的资源的时域资源符号数目以及在同一时域资源内所述探测参考信号所占用的频域资源的频率间隔确定的。
- 根据权利要求6所述的探测参考信号的传输方法,其中,按照频域资源位置上的循环移位,将所述探测参考信号在不同时域资源内映射至不同频域资源上,并传输至基站的步骤包括:当所述上行控制信道所采用的资源占用N个时域资源符号,一个时域资源符号内占用M个交织单元时,指示所述探测参考信号的N个时域资源符号中的不同时域资源符号分别占用不同的M个交织单元;以及将所述探测参考信号映射至所述上行控制信道所采用的资源中,并传输至基站,其中,在N个时域资源符号占用的所有频率资源位置内,频域不相邻不连续的交织单元的物理资源块之间的频率间隔根据所述频域资源位置的循环移位确定,其中,M和N均为正整数。
- 根据权利要求6所述的探测参考信号的传输方法,其中,按照频域资源位置上的循环移位,将所述探测参考信号在不同时域资源内映射至不同频域资源上,并传输至基站的步骤包括:当所述上行控制信道所采用的资源占用N个时域资源符号,一个时域资源符号内占用M个交织单元时,指示所述探测参考信号的每L个相邻的资源符号为一组占用相同的交织单元,并进行时域正交码分;以及将所述探测参考信号映射至所述上行控制信道所采用的资源中,并传输至基站,其中,不同组的时域资源符号所占用的交织单元的频率不同,且在N个 时域资源符号中占用的所有频率资源位置内,频域不相邻不连续的交织单元的物理资源块之间的频率间隔根据所述频域资源位置上的循环移位确定,其中,M、N和L均为正整数。
- 根据权利要求6所述的探测参考信号的传输方法,其中,按照频域资源位置上的循环移位,将所述探测参考信号在不同时域资源内映射至不同频域资源上,并传输至基站的步骤包括:当所述上行控制信道所采用的资源占用N个时域资源符号时,指示所述探测参考信号的每个时域资源符号均占用不同的M个频域连续的未被分配的交织单元组合;以及将所述探测参考信号映射至所述上行控制信道所采用的资源中,并传输至基站,其中,在N个时域资源符号中占用的所有频率资源位置内,频域不相邻不连续的交织单元组合的物理资源块之间的频率间隔根据所述频域资源位置上的循环移位确定,其中,M和N均为正整数。
- 根据权利要求6所述的探测参考信号的传输方法,其中,按照频域资源位置上的循环移位,将所述探测参考信号在不同时域资源内映射至不同频域资源上,并传输至基站的步骤包括:当所述上行控制信道所采用的资源占用N个时域资源符号时,指示所述探测参考信号的N个时域资源符号中的不同时域资源符号分别占用不同的未被分配给其他信道的M个交织单元;以及将所述探测参考信号映射至所述上行控制信道所采用的资源中,并传输至基站,其中,在N个时域资源符号中占用的所有频率资源位置内,频域不相邻不连续的交织单元的物理资源块之间的频率间隔根据所述频域位置上的循环移位确定,其中,M和N均为正整数。
- 根据权利要求7至10中任一项所述的探测参考信号的传输方法,其中,所述上行传输信道为物理上行共享信道或扩展的物理上行控制信道;所述上行控制信道为短物理上行控制信道。
- 根据权利要求1所述的探测参考信号的传输方法,其中,所述上行 传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系包括:所述上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的所有资源之间预设的映射关系;或者,所述上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的非调度资源之间预设的映射关系。
- 根据权利要求3所述的探测参考信号的传输方法,其中,在所述上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系中,确定所述上行传输信道被调度时的调度信息对应的非调度的上行控制信道所采用的资源的步骤包括:获取基站通过无线电资源控制配置或者通过公共物理下行公共信道指示的调度资源和非调度资源的划分信息;根据所述划分信息、所述调度信息、以及上行传输信道的调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道被调度时的调度信息对应的非调度的上行控制信道所采用的资源。
- 根据权利要求1至13中任一项所述的探测参考信号的传输方法,还包括:在当上行传输信道被调度时,获取所述上行传输信道的调度信息的步骤之前,执行先听后说的监听机制。
- 根据权利要求1至13中任一项所述的探测参考信号的传输方法,其中所述上行控制信道为短物理上行控制信道。
- 一种探测参考信号的传输方法,包括:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述调度信息确定对应的上行控制信道;以及利用所述上行控制信道,传输探测参考信号。
- 根据权利要求16所述的探测参考信号的传输方法,其中,所述利用所述上行控制信道,传输探测参考信号的步骤包括:根据下行控制信息,如果仅在所述上行控制信道后相邻的上行传输信道进行上行调度传输,则在所述上行控制信道上传输所述探测参考信号。
- 根据权利要求17所述的探测参考信号的传输方法,其中,如果仅在上行控制信道后相邻的上行传输信道进行上行调度传输,则在所述上行控制信道上传输所述探测参考信号的步骤包括:当检测到在子帧n-1中存在所述上行控制信道而在该上行控制信道所存在的子帧上没有上行控制信息传输时,并且当在不晚于子帧n-4的子帧中接收到用于从子帧n的起始位置开始调度上行传输信道的下行控制信息时,在子帧n-1中使用所述上行控制信道开始传输所述探测参考信号。
- 根据权利要求16-18中任一项所述的探测参考信号的传输方法,其中所述上行控制信道为短物理上行控制信道。
- 根据权利要求16-18中任一项所述的探测参考信号的传输方法,还包括:在当上行传输信道被调度时,获取所述上行传输信道的调度信息的步骤之前,执行先听后说的监听机制。
- 一种探测参考信号的传输装置,包括:获取模块,用于当上行传输信道被调度时,获取所述上行传输信道的调度信息;处理模块,用于根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源;发送模块,用于利用所述上行控制信道所采用的资源,传输探测参考信号。
- 一种终端,包括:接收机,用于当上行传输信道被调度时,接收所述上行传输信道的调度信息;处理器,与所述接收机连接,用于:根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源;发射机,与所述处理器连接,用于利用所述上行控制信道所采用的资源,传输探测参考信号。
- 一种探测参考信号的传输装置,包括:处理器;以及存储器,所述存储器中存储有能够被所述处理器执行的计算机可读指令,在所述计算机可读指令被执行时,所述处理器执行以下操作:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源;以及利用所述上行控制信道所采用的资源,传输探测参考信号。
- 一种探测参考信号的传输芯片,包括:处理器;以及存储器,所述存储器中存储有能够被所述处理器执行的指令,在所述指令被执行时,所述处理器执行以下操作:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输信道的所述调度信息对应的上行控制信道所采用的资源;以及利用所述上行控制信道所采用的资源,传输探测参考信号。
- 一种终端,包括探测参考信号的传输芯片,其中所述传输芯片包括:处理器;以及存储器,所述存储器中存储有能够被所述处理器执行的指令,在所述指令被执行时,所述处理器执行以下操作:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述上行传输信道的所述调度信息与用于传输上行控制信号的上行控制信道所采用的资源之间预设的映射关系,确定所述上行传输 信道的所述调度信息对应的上行控制信道所采用的资源;以及利用所述上行控制信道所采用的资源,传输探测参考信号。
- 一种探测参考信号的传输芯片,包括:处理器;以及存储器,所述存储器中存储有能够被所述处理器执行的指令,在所述指令被执行时,所述处理器执行以下操作:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述调度信息确定对应的上行控制信道;以及利用所述上行控制信道,传输探测参考信号。
- 一种终端,包括探测参考信号的传输芯片,其中所述传输芯片包括:处理器;以及存储器,所述存储器中存储有能够被所述处理器执行的指令,在所述指令被执行时,所述处理器执行以下操作:当上行传输信道被调度时,获取所述上行传输信道的调度信息;根据所述调度信息确定对应的上行控制信道;以及利用所述上行控制信道,传输探测参考信号。
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