WO2016138633A1 - 用于调度终端设备的方法和网络设备 - Google Patents

用于调度终端设备的方法和网络设备 Download PDF

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Publication number
WO2016138633A1
WO2016138633A1 PCT/CN2015/073571 CN2015073571W WO2016138633A1 WO 2016138633 A1 WO2016138633 A1 WO 2016138633A1 CN 2015073571 W CN2015073571 W CN 2015073571W WO 2016138633 A1 WO2016138633 A1 WO 2016138633A1
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Prior art keywords
codebook
pilot
terminal device
pilot set
determining
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PCT/CN2015/073571
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English (en)
French (fr)
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时代
郭文婷
卢磊
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华为技术有限公司
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Priority to PCT/CN2015/073571 priority Critical patent/WO2016138633A1/zh
Priority to CN201580077310.6A priority patent/CN107409007B/zh
Publication of WO2016138633A1 publication Critical patent/WO2016138633A1/zh
Priority to US15/694,716 priority patent/US10271346B2/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/20Control channels or signalling for resource management
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/0001Arrangements for dividing the transmission path
    • H04L5/0014Three-dimensional division
    • H04L5/0023Time-frequency-space
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0048Allocation of pilot signals, i.e. of signals known to the receiver
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0078Timing of allocation
    • H04L5/0082Timing of allocation at predetermined intervals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0058Allocation criteria
    • H04L5/006Quality of the received signal, e.g. BER, SNR, water filling
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/02Terminal devices
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/08Access point devices

Definitions

  • the present invention relates to the field of communications, and more particularly to a method and network device for scheduling a terminal device.
  • the Sparse Code Multiple Access (SCMA) technology is a typical non-orthogonal multiple access and transmission technology.
  • SCMA technology can also be called other names in the communication field.
  • M is an integer not less than 1
  • N is an integer not less than 1
  • M is an integer not less than 1
  • M is an integer not less than 1
  • N is an integer not less than 1
  • SCMA technology can effectively improve network capacity, including the number of system accessible terminals and spectrum efficiency. Therefore, as an important non-orthogonal access technology, SCMA technology has attracted more and more attention and become an important alternative access technology for the evolution of wireless cellular networks in the future.
  • Grant free is a special scheduling mechanism for small packet transmission in SCMA technology, which can reduce the overhead and redundancy caused by frequent scheduling requests.
  • the Grant free terminal does not request the resource, but directly uses the codebook in the at least one codebook and the pilot corresponding to the codebook to perform uplink transmission on the unlicensed resource, and the base station uses at least one codebook and the codebook.
  • the corresponding pilots perform blind detection on the unauthorized resources.
  • the Grant free scheduling mode can reduce uplink resource request signaling. Thereby reducing the data transmission delay and saving bandwidth.
  • the embodiment of the invention provides a method and a network device for scheduling a terminal device, which can be compatible with the problem of complex decoding of the network device caused by improving the spectrum multiplexing rate, and reducing at least two terminal devices caused by the spectrum multiplexing rate. Collision problems caused by selecting the same codebook and pilot.
  • a method for scheduling a terminal device including:
  • pilot of terminal data determining, according to the result of the blind detection, the first pilot set corresponding to each codebook in each subframe, where the pilot in the first pilot set is blindly detected by combining the corresponding codebook, and the correct detection cannot be obtained. Pilot of terminal data;
  • the pilot is a pilot that has been sent by the terminal device in the first pilot set;
  • a product of a number of codebooks in the at least one codebook and a number of pilots corresponding to the codebook is smaller than the access of each subframe The number of terminal devices.
  • the second pilot corresponding to each codebook in each of the subframes determines the mode of the terminal device to be transmitted, including:
  • the determining, by the terminal device, the mode to be transmitted includes:
  • the mode to be transmitted of the terminal device is determined to be the first transmission mode, where the spectrum multiplexing rate corresponding to the first transmission mode is greater than the spectrum multiplexing rate corresponding to the current transmission mode of the terminal device.
  • the method further includes:
  • the determining, by the terminal device, the mode to be transmitted includes:
  • the method further includes:
  • each codebook corresponding to the second pilot set including :
  • the method before the performing blind detection on each of the N subframes, the method further includes:
  • the transmission mode is used to indicate the pilot corresponding to each codebook in the at least one codebook and the at least one codebook.
  • the seventh aspect in the first aspect in combination with the first aspect or any of the above possible implementations, the seventh aspect in the first aspect in an implementation manner, the method further includes:
  • Determining, according to the second pilot set corresponding to each codebook in each of the subframes, the mode to be transmitted of the terminal device including:
  • the transmission mode corresponding to the transmission mode of the terminal device includes 150% and 300%.
  • a network device including:
  • a blind detection unit configured to perform blind detection on each of the N subframes by using at least one codebook and a pilot corresponding to each codebook in the at least one codebook, where the N is a positive integer;
  • a first determining unit configured to determine, according to the blind detection result acquired by the blind detection unit, a first pilot set corresponding to each codebook in each subframe, where the guide in the first pilot set The frequency is blindly detected in combination with the corresponding codebook, and the pilot of the correct terminal data cannot be obtained;
  • a second determining unit configured to determine, according to the first pilot set corresponding to each codebook in each subframe determined by the first determining unit, that each codebook in each subframe corresponds to a second a pilot set, where the pilot in the second pilot set is a pilot that has been sent by the terminal device in the first pilot set;
  • a third determining unit configured to determine, according to the second pilot set corresponding to each codebook in each subframe determined by the second determining unit, a mode to be transmitted of the terminal device, where different transmission modes Corresponding to different spectrum reuse rates.
  • a product of the number of codebooks in the at least one codebook and the number of pilots corresponding to the codebook is smaller than the access of each subframe The number of terminal devices.
  • the third determining unit is specifically configured to:
  • the third determining unit is specifically configured to:
  • the network device further includes:
  • the first notification unit is configured to send a first notification message to the terminal device, where the first notification message is used to instruct the terminal device to perform data transmission by using the first transmission mode.
  • the third determining unit is specifically configured to:
  • the network device further includes:
  • the second notification unit is configured to send a second notification message to the terminal device, where the second notification message is used to instruct the terminal device to perform data transmission by using the second transmission mode.
  • the second determining unit is specifically configured to:
  • the network device further includes a third notification unit, configured to: Sending a third notification message to the terminal device, where the third notification message is used to indicate a transmission mode adopted by the terminal device in the N subframes, where each subframe in each of the subframes is blindly detected, where And the transmission mode adopted in the N subframes is used to indicate a pilot corresponding to each codebook in the at least one codebook and the at least one codebook.
  • a third notification unit configured to: Sending a third notification message to the terminal device, where the third notification message is used to indicate a transmission mode adopted by the terminal device in the N subframes, where each subframe in each of the subframes is blindly detected, where And the transmission mode adopted in the N subframes is used to indicate a pilot corresponding to each codebook in the at least one codebook and the at least one codebook.
  • the network device further includes:
  • a fourth determining unit configured to determine, according to the blind detection result, a number of times that the plurality of terminal devices in the N subframes use the same codebook
  • the third determining unit is specifically configured to:
  • the transmission mode corresponding to the transmission mode of the terminal device includes 150% and 300%.
  • the network device is a base station.
  • a network device including: a processor, a memory, a bus system, and a transceiver, wherein the processor, the memory, and the transceiver are connected by the bus system, and the memory is used by In the storage instruction, the transceiver is configured to receive data sent by the terminal device, and the processor invokes an instruction in the memory to perform the following operations:
  • pilot of terminal data determining, according to the result of the blind detection, the first pilot set corresponding to each codebook in each subframe, where the pilot in the first pilot set is blindly detected by combining the corresponding codebook, and the correct detection cannot be obtained. Pilot of terminal data;
  • the pilot is a pilot that has been sent by the terminal device in the first pilot set;
  • a product of the number of codebooks in the at least one codebook and the number of pilots corresponding to the codebook is smaller than the access of each subframe The number of terminal devices.
  • the processor instructs the instruction in the memory to determine, according to the second pilot set corresponding to each codebook in each subframe, a process of determining a mode to be transmitted of the terminal device, The processor performs the following operations:
  • the processor when the instruction in the memory is used to determine a mode of the terminal device to be transmitted, The processor performs the following operations:
  • the processor invoking an instruction in the memory also performs the following operations:
  • the processor invokes an instruction in the memory to determine a mode of the terminal device to be transmitted.
  • the processor specifically performs the following operations:
  • the processor invoking an instruction in the memory also performs the following operations:
  • the processor by using an instruction in the memory, to determine each code in each of the sub-frames In the process corresponding to the second pilot set, the processor specifically performs the following operations:
  • the processor invokes the memory before performing blind detection on each of the N subframes
  • the instructions in the file also do the following:
  • the transmission mode is used to indicate the pilot corresponding to each codebook in the at least one codebook and the at least one codebook.
  • the processor by using the instruction in the memory, further performs the following operations:
  • the processor instructs the instruction in the memory to determine a mode to be transmitted of the terminal device according to a second pilot set corresponding to each codebook in each subframe, where the processor specifically executes the following operating:
  • the transmission mode corresponding to the transmission mode of the terminal device includes 150% and 300%.
  • the network device is a base station.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • FIG. 1 is an application scenario diagram 100 in accordance with an embodiment of the present invention.
  • FIG. 2 is a coding principle diagram of an SCMA according to an embodiment of the present invention.
  • FIG. 3 is a schematic flowchart of a method 200 for scheduling a terminal device according to an embodiment of the present invention.
  • FIG. 4 is a schematic diagram showing an example of a spectrum multiplexing rate according to an embodiment of the present invention.
  • FIG. 6 is a schematic flowchart of a method 400 for scheduling a terminal device according to an embodiment of the present invention.
  • FIG. 7 is a schematic block diagram of a network device 500 in accordance with an embodiment of the present invention.
  • FIG. 8 is another schematic block diagram of a network device 500 in accordance with an embodiment of the present invention.
  • the terminal device may communicate with one or more core networks via a radio access network (Radio Access Network, hereinafter referred to as "RAN”), and the terminal device may be referred to as an access terminal and a user equipment (User Equipment, referred to as "UE"), subscriber unit, subscriber station, mobile station, mobile station, remote station, remote terminal, mobile device, user terminal, terminal, wireless communication device, user agent or user equipment.
  • RAN Radio Access Network
  • UE User Equipment
  • the access terminal can be a cellular phone, a cordless phone, a Session Initiation Protocol ("SIP") phone, a wireless local loop (Wireless local loop) Local Loop, referred to as "WLL” station, Personal Digital Assistant (PDA), handheld devices with wireless communication capabilities, computing devices or other processing devices connected to wireless modems, in-vehicle devices, Wearable devices and terminal devices in future 5G networks.
  • SIP Session Initiation Protocol
  • WLL wireless local loop
  • PDA Personal Digital Assistant
  • the communication system 100 includes a network device 102, which may include multiple antenna groups.
  • Each antenna group may include one or more antennas, for example, one antenna group may include antennas 104 and 106, another antenna group may include antennas 108 and 110, and an additional group may include antennas 112 and 114.
  • Two antennas are shown in Figure 1 for each antenna group, although more or fewer antennas may be used for each group.
  • Network device 102 may additionally include a transmitter chain and a receiver chain, as will be understood by those of ordinary skill in the art, which may include multiple components related to signal transmission and reception (eg, processor, modulator, multiplexer, solution) Tuner, demultiplexer or antenna, etc.).
  • a transmitter chain and a receiver chain may include multiple components related to signal transmission and reception (eg, processor, modulator, multiplexer, solution) Tuner, demultiplexer or antenna, etc.).
  • Network device 102 can communicate with a plurality of terminal devices, such as terminal device 116 and terminal device 122. However, it will be appreciated that network device 102 can communicate with any number of terminal devices similar to terminal device 116 or 122.
  • Terminal devices 116 and 122 may be, for example, cellular telephones, smart phones, portable computers, handheld communication devices, handheld computing devices, satellite radios, global positioning systems, PDAs, and/or any other suitable for communicating over wireless communication system 100. device.
  • terminal device 116 is in communication with antennas 112 and 114, wherein antennas 112 and 114 transmit information to terminal device 116 over forward link 118 and receive information from terminal device 116 over reverse link 120.
  • terminal device 122 is in communication with antennas 104 and 106, wherein antennas 104 and 106 transmit information to terminal device 122 over forward link 124 and receive information from terminal device 122 over reverse link 126.
  • the forward link 118 and the reverse link 120 can use a common frequency band, a forward link 124, and a reverse link.
  • Link 126 can use a common frequency band.
  • Each set of antennas and/or regions designed for communication is referred to as a sector of network device 102.
  • the antenna group can be designed to communicate with terminal devices in sectors of the network device 102 coverage area.
  • the transmit antenna of network device 102 may utilize beamforming to improve the signal to noise ratio of forward links 118 and 124.
  • the network device 102 uses beamforming to transmit signals to the randomly dispersed terminal devices 116 and 122 in the relevant coverage area, the network device 102 uses a single antenna to transmit signals to all of its terminal devices. Mobile devices are subject to less interference.
  • network device 102, terminal device 116, or terminal device 122 may be a wireless communication transmitting device and/or a wireless communication receiving device.
  • the wireless communication transmitting device can encode the data for transmission.
  • the wireless communication transmitting device may acquire (eg, generate, receive from other communication devices, or store in memory, etc.) a certain number of data bits to be transmitted over the channel to the wireless communication receiving device.
  • Such data bits can be included in a transport block (or multiple transport blocks) of data.
  • the time-frequency resource may be a time-frequency resource block composed of multiple REs (also referred to as time) Frequency resource group).
  • the communication system is a sparse code division multiple access communication system
  • the time-frequency resource is a time-frequency resource block including at least two resource units RE.
  • SCMA Sparse Code Multiple Access
  • the access mode multiple terminals multiplex the same time-frequency resource block for data transmission.
  • Each resource block is composed of a number of resource REs, where the REs may be subcarrier-symbol units in OFDM technology, or may be resource units in the time domain or frequency domain of other air interface technologies.
  • the available resources are divided into orthogonal time-frequency resource blocks, each resource block containing L REs, wherein the L REs may be the same in the time domain. .
  • the data to be transmitted is first divided into data blocks of S bit size, and each data block is mapped by searching a codebook of the terminal device #k (determined by the network device and sent to the terminal device).
  • a set of modulation symbols X#k ⁇ X#k 1 , X#k 2 , . . . , X#k L ⁇ , each modulation symbol corresponds to one RE in the resource block, and then a signal waveform is generated according to the modulation symbol.
  • each codebook contains 2S different modulation symbol groups, corresponding to 2S possible data blocks.
  • the codeword can be represented as a multi-dimensional complex vector having a dimension of two or more dimensions for representing a mapping relationship between data and two or more modulation symbols, the modulation symbol including at least one zero modulation symbol and at least A non-zero modulation symbol, the relationship between the zero modulation symbol and the non-zero modulation symbol may be zero, the number of modulation symbols is not less than the number of non-zero modulation symbols, and the data may be binary bit data or multi-dimensional data.
  • a codebook consists of two or more codewords. The codebook may represent a mapping relationship between a possible data combination of a certain length of data and a codeword in the codebook.
  • the SCMA technology realizes the extended transmission of data on multiple resource units by directly mapping the data in the data stream to a code word in the codebook according to a certain mapping relationship, that is, a multi-dimensional complex vector.
  • the data here may be binary bit data or multi-dimensional data
  • multiple resource units may be resource elements in a time domain, a frequency domain, an air domain, a time-frequency domain, a spatio-temporal domain, and a time-frequency spatial domain.
  • the above bipartite graph gives an example of multiplexing four resource units with six data streams.
  • the data stream may also be referred to as a variable node, and the resource unit may also be referred to as a function node, wherein six data streams form one group, and four resource units form one coding unit.
  • a resource unit can be a resource unit, or a resource particle (English: Resource Element, English abbreviation: RE), or an antenna port.
  • the bipartite graph there is a line between the data stream and the resource unit indicating that at least one data combination of the data stream is transmitted by the codeword, and a non-zero modulation symbol is transmitted on the resource unit, and the data stream and the resource unit are If there is no connection, it means that all possible data combinations of the data stream are coded and the modulation symbols sent on the resource unit are zero.
  • the data combination of the data streams can be understood as follows, for example, in a binary bit data stream, 00, 01, 10, 11 are all possible two-bit data combinations.
  • the data combinations to be transmitted of the six data streams in the bipartite graph are sequentially represented by s1 to s6, and the symbols transmitted on the four resource units in the bipartite graph are sequentially represented by x1 to x4. It can be seen from the bipartite graph that the data of each data stream is transmitted by two or more resource units after the codeword mapping, and the symbols sent by each resource unit are from two or two. The data of more than one data stream is superimposed by the modulation symbols mapped by the respective codewords.
  • the data combination s3 of the data stream 3 may be sent with non-zero modulation symbols on the resource unit 1 and the resource unit 2 after the codeword mapping, and the data x3 sent by the resource unit 3 is the data stream 2, the data stream 4 and The superposition of non-zero modulation symbols obtained by mapping the data combinations s2, s4 and s6 of the data stream 6 to the respective codewords. Since the number of data streams can be greater than the number of resource units, the SCMA system can effectively increase network capacity, including the number of accessible users and spectrum efficiency of the system.
  • the codewords in the codebook typically have the following form:
  • the corresponding codebook usually has the following form: Where N is a positive integer greater than 1, and can be expressed as the number of resource units included in one coding unit, and can also be understood as the length of the codeword; Qm is a positive integer greater than 1, indicating the number of codewords included in the codebook, Corresponding to the modulation order, such as Quadrature Phase Shift Keying (QPSK) or 4th-order modulation, Qm is 4; q is a positive integer, and 1 ⁇ q ⁇ Qm.
  • QPSK Quadrature Phase Shift Keying
  • the combination of the codeword in the codebook and the data stream can form a certain mapping relationship.
  • the codeword in the codebook can be combined with the two-bit data of the binary data stream to form a mapping relationship: "00" can be mapped to a codeword.
  • the codebook corresponding to the data stream and the codeword in the codebook should have the following characteristics: at least one codeword exists in the codebook on the corresponding resource unit.
  • the codebook corresponding to the data stream 3 in the above bipartite graph may have the following forms and features:
  • SCMA system is only an example of a communication system for applying the method and apparatus for scheduling a terminal device of the present invention, and the present invention is not limited thereto. Others can enable the terminal device to reuse the same in the same period. Communication systems in which time-frequency resources perform data transmission are all within the scope of the present invention.
  • FIG. 3 is a schematic flowchart of a method 200 for scheduling a terminal device according to an embodiment of the present invention. As shown in FIG. 3, the method 200 includes:
  • the first pilot set corresponding to each codebook in each subframe is determined according to the blind detection result, where the blind detection by using the pilot in the first pilot set and the corresponding codebook cannot be correctly obtained.
  • the terminal device in each subframe, does not request resources from the network device, but directly uses the codebook corresponding to the codebook and the codebook in at least one codebook to perform uplink transmission on the unlicensed resource.
  • the network device performs blind detection on the unlicensed resource by using at least one codebook and the pilot corresponding to each codebook in the at least one codebook; since each terminal device cannot know the selection of the other terminal device Codebook and pilot, different terminal devices may select the same codebook and the same pilot, so that the network device cannot detect the data sent by the different terminal device, or if a certain codebook and its corresponding one
  • the pilot device is not selected by the terminal device, and the network device cannot decode the terminal data through the codebook and the pilot; for the above two cases, the network device is The correct terminal data cannot be obtained.
  • the network device can determine the first pilot set corresponding to each codebook, and blind detection by using the pilot in the first pilot set and the corresponding codebook cannot obtain the correct terminal.
  • the network device may determine, from the first pilot set corresponding to each codebook in each subframe, a pilot set of pilots corresponding to each codebook in each subframe that has been sent by the terminal device, that is,
  • the second set of pilots can also be understood as a pilot set of pilots that are simultaneously selected by at least two terminal devices for each pilot; and the mode of the terminal device to be transmitted is determined according to the second set of pilots, wherein different transmissions are performed.
  • the modes correspond to different spectrum reuse rates.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the at least one codebook includes a codebook used by a plurality of terminal devices to perform uplink transmission on a certain time-frequency resource that is multiplexed by the terminal device; each codebook may correspond to at least one pilot, and each codebook may correspond to at least one pilot.
  • the codebook may correspond to different pilots, where the pilot may be a De Modulation Reference Signal (DMRS).
  • DMRS De Modulation Reference Signal
  • the pilot can be allocated to a plurality of terminal devices, and the product of the number of codebooks available for selection by the terminal device and the number of pilots corresponding to all codebooks at this time is smaller than the number of connected terminal devices.
  • the system capacity may be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the codebook is reduced. / or the number of pilots to reduce interference on the same time-frequency resource block, can improve the decoding rate programmatically, thereby providing a better channel environment in the case of fewer terminal devices, thereby improving spectrum utilization.
  • the spectrum multiplexing rate corresponding to the transmission mode of the terminal device may refer to the number of resource elements (RE elements) and the number of terminal devices that multiplex the number of REs.
  • the spectrum multiplexing rate is 150%; if 12 terminal devices jointly multiplex 4 RE resources, the spectrum multiplexing rate is 300%.
  • a total of six terminal devices use six codebooks (from left to right in FIG. 4, codebook 1, codebook 2, codebook 3, codebook 4, codebook 5, and codebook). 6); wherein (10), (01), (11), (00) in the figure represent data to be encoded, and arrows indicate different code blocks in the codebook for different data, for example, for data (11)
  • the terminal device 1 can be encoded using the fourth code block in the codebook 1, and the terminal device 6 is encoded using the fourth code block in the codebook 6.
  • the six terminal devices are multiplexed with four REs at the same time, that is, a maximum of six terminal devices can be implemented at a time to multiplex four REs, instead of having to reuse four REs by six terminal devices, and currently
  • the number of connected terminal devices can also be more than six.
  • the determining, by the template, the second pilot set corresponding to each codebook in each of the subframes includes:
  • the terminal may not use the codebook and the pilot for uplink transmission, or have different terminals.
  • the device uses the codebook and the pilot; in order to determine which situation, the signal strength of the pilot can be detected, and if the signal strength of the pilot is greater than a certain threshold, it is considered that there are different terminal devices.
  • the use of the pilot results in incorrect decoding; wherein the threshold can be simply set to zero.
  • determining, according to the second pilot set corresponding to each codebook in each subframe, a mode to be transmitted of the terminal device including:
  • the network device may determine that the mode to be transmitted of the terminal device is the first transmission when the sum of the pilot numbers of the second pilot sets corresponding to all the codebooks in the N subframes is greater than or equal to the first threshold.
  • the transmission mode wherein the first transmission mode corresponds to a spectrum multiplexing rate that is greater than a spectrum multiplexing rate corresponding to a current transmission mode of the terminal device.
  • the sum of the pilot numbers of the second pilot sets corresponding to all the codebooks in the N subframes can be considered as the total occurrence of the same (codebook*pilot) combination in different terminal devices in the N subframes.
  • the number of times that is, the total number of collisions between terminal devices.
  • the transmission mode of the terminal device can be changed, for example, the transmission mode with the spectrum multiplexing rate of 150% is changed to the spectrum multiplexing rate of 300. % transfer mode.
  • the network device may determine that the to-be-transmitted mode of the terminal device is the second transmission mode, when the number of the subframes is equal to or greater than the second threshold when the second pilot set corresponding to each codebook is an empty set, where The spectrum multiplexing rate corresponding to the second transmission mode is smaller than the spectrum multiplexing rate corresponding to the current transmission mode of the terminal device.
  • the number of subframes when the second pilot set corresponding to each codebook is an empty set can be considered to be the same in the number of subframes, and there are no two different terminal devices selected (codebook* In the case of frequency, if the number of these subframes is greater than or equal to a certain threshold, the transmission mode of the terminal device can be changed, for example, the transmission mode from the spectrum multiplexing rate of 300% is changed to the transmission with the spectrum multiplexing rate of 150%. mode.
  • the mode of transmission of the terminal device is not limited to the above description. For example, when the total number of pilots of the second pilot set corresponding to all the codebooks in the N subframes is less than or equal to a certain threshold, and the second pilot set corresponding to each codebook is an empty set, the number of subframes is greater than When the threshold is equal to a certain threshold, the mode of the to-be-transmitted mode of the terminal device is reduced; or, the sum of the pilot numbers of the second pilot set corresponding to all the codebooks in the N subframes is greater than or equal to a certain threshold and the corresponding number of each codebook When the number of subframes when the two pilot sets are both empty sets is less than or equal to a certain threshold, the mode of the terminal device to be transmitted is improved. For example, it may be determined according to the number of subframes in which the second pilot set is that the number of empty sets is greater than or equal to a certain threshold, and the threshold may be less than the total number of codebooks.
  • the notification message when the mode to be transmitted of the terminal device determined by the network device is different from the current transmission mode, the notification message may be sent to the terminal device through the broadcast channel or the control channel, to indicate that the terminal device uses the changed transmission mode.
  • Uplink transmission wherein the transmission mode may indicate at least one codebook adopted by the terminal device and a pilot corresponding to each codebook.
  • the method before performing blind detection on each of the N subframes, the method further includes:
  • the notification message is used to indicate that the terminal device is in the A transmission mode employed in the N subframes, wherein the transmission mode employed in the N subframes is used to indicate pilots corresponding to each codebook in the at least one codebook and the at least one codebook.
  • the network device may further determine, according to the result of the blind detection, the number of times that the plurality of terminal devices in the N subframes use the same codebook; and the network device may be based on multiple terminals in the N subframes. The number of times the device uses the same codebook and the second pilot set corresponding to each codebook in each subframe determines the mode to be transmitted of the terminal device.
  • FIG. 5 is a schematic flowchart of a method 300 for scheduling a terminal device according to an embodiment of the present invention. As shown in FIG. 5, the method 300 includes:
  • the network device allocates an unlicensed resource group for the unlicensed area, performs at least one codebook used for uplink transmission, and a pilot corresponding to each codebook in the at least one codebook on the unlicensed resource group, and passes the broadcast channel. Or the control channel is sent to multiple UEs.
  • the product of the number of codebooks selectable by the terminal device and the number of pilots corresponding to all codebooks may be smaller than the maximum number of terminal devices accessed by each subframe.
  • the codebook may be randomly selected from the at least one codebook, and The pilot is randomly selected from the pilot corresponding to the randomly selected codebook, and the uplink code is performed by using the randomly selected codebook and the pilot.
  • the network device performs blind detection on the unlicensed resource group by using a pilot corresponding to each codebook in at least one codebook and at least one codebook in each subframe, where the network device can use each codebook and polls. Detecting a pilot corresponding to each codebook to perform blind detection; determining, according to the result of the blind detection, a first pilot set, wherein blind detection by using the pilot in the first pilot set and the corresponding codebook cannot be obtained Correcting terminal data; and determining a second pilot set from the first pilot set, wherein the pilot in the second pilot set is a pilot that has been sent by the terminal device in the first pilot set; specifically
  • the network device may determine the pilot that has been transmitted by the terminal device according to the signal strength of each pilot in the first pilot set.
  • the network device may also record the number of times that at least two terminal devices use the same codebook in each subframe.
  • the network device determines, in a period of time T (the time period corresponding to the N subframes), the number of times that the different terminal devices select the same (codebook*pilot) combination in the same subframe, that is, the corresponding number of all the codebooks in the N subframes. The total number of pilots in the two pilot sets.
  • the network device changes the to-be-transmitted mode of the terminal device, where the modified spectrum multiplexing rate corresponding to the to-be-transmitted mode is greater than the spectrum multiplexing rate corresponding to the current transmission mode, and is sent to the terminal.
  • the device sends a notification message to indicate that the subsequent transmission of the terminal device adopts the changed mode to be transmitted.
  • the network device records the number of times that the different terminal devices use the same codebook in each subframe, the total number of times that the at least two terminal devices use the same codebook in the M and N subframes may jointly determine the to-be-transmitted.
  • the mode for example, increases the spectrum reuse rate if M is greater than or equal to a certain threshold and W is greater than or equal to a certain threshold.
  • FIG. 6 is a schematic flowchart of a method 400 for scheduling a terminal device according to an embodiment of the present invention. As shown in FIG. 6, the method 400 includes:
  • the network device allocates an unlicensed resource group for the unlicensed area, performs at least one codebook used for uplink transmission, and a pilot corresponding to each codebook in the at least one codebook on the unlicensed resource group, and passes the broadcast channel. Or the control channel is sent to multiple UEs.
  • the product of the number of codebooks selectable by the terminal device and the number of pilots corresponding to all codebooks may be smaller than the maximum number of terminal devices accessed by each subframe.
  • the codebook may be randomly selected from the at least one codebook, and The pilot is randomly selected from the pilot corresponding to the randomly selected codebook, and the uplink code is performed by using the randomly selected codebook and the pilot.
  • the network device performs blind detection on the unlicensed resource group in each subframe by using at least one codebook and a pilot corresponding to each codebook in the at least one codebook, where the network device can adopt each codebook and poll Detecting a pilot corresponding to each codebook to perform blind detection; determining, according to the result of the blind detection, a first pilot set, wherein blind detection by using the pilot in the first pilot set and the corresponding codebook cannot be obtained Correcting terminal data; and determining a second pilot set from the first pilot set, wherein the pilot in the second pilot set is a pilot that has been sent by the terminal device in the first pilot set; specifically
  • the network device may determine the pilot that has been transmitted by the terminal device according to the signal strength of each pilot in the first pilot set.
  • the network device can also record the number of times that at least different terminal devices use the same codebook in each subframe.
  • the network device determines a time period T (the time period corresponding to the N subframes), and the terminal device selects the same number of subframes S of the same (codebook*pilot) combination, that is, the second pilot corresponding to each codebook. The number of subframes when the collection is empty.
  • the network device changes the to-be-transmitted mode of the terminal device, where the modified spectrum multiplexing rate corresponding to the to-be-transmitted mode is smaller than the spectrum multiplexing rate corresponding to the current transmission mode, and is sent to the terminal.
  • the device sends a notification message to indicate that the subsequent transmission of the terminal device adopts the changed mode to be transmitted.
  • the network device records the number of times that the different terminal devices use the same codebook in each subframe, the total number of times that the at least different terminal devices in the S and N subframes use the same codebook may be used to jointly determine the to-be-transmitted.
  • the mode for example, reduces the spectrum reuse rate if S is greater than or equal to a certain threshold and W is less than or equal to a certain threshold.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the system capacity can be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the number of codebooks and/or pilots is reduced. Reducing the interference on the same time-frequency resource block can improve the decoding rate by a certain program, thereby providing a better channel environment in the case of a small number of terminal devices, thereby improving spectrum utilization.
  • FIG. 7 is a schematic block diagram of a network device 500 in accordance with an embodiment of the present invention. As shown in FIG. 7, the network device 500 includes:
  • the blind detection unit 510 is configured to perform blind detection on each of the N subframes by using at least one codebook and a pilot corresponding to each codebook in the at least one codebook, where the N is a positive integer;
  • the first determining unit 520 is configured to determine, according to the blind detection result acquired by the blind detecting unit 510, a first pilot set corresponding to each codebook in each subframe, where a guide in the first pilot set is adopted Blind detection of the frequency and the corresponding codebook cannot obtain correct terminal data;
  • the second determining unit 530 is configured to determine, according to the first pilot set corresponding to each codebook in each subframe determined by the first determining unit 520, that each codebook in each subframe corresponds to the second pilot a set, where the pilot in the second pilot set is a pilot that has been sent by the terminal device in the first pilot set;
  • the third determining unit 540 is configured to determine, according to the second pilot set corresponding to each codebook in each subframe determined by the second determining unit 530, a mode to be transmitted of the terminal device, where different transmission modes correspond to Different spectrum reuse rates.
  • the terminal device in each subframe, does not request resources from the network device, but directly uses the codebook corresponding to the codebook and the codebook in at least one codebook to perform uplink transmission on the unlicensed resource.
  • the network device performs blind detection on the unlicensed resource by using at least one codebook and the pilot corresponding to each codebook in the at least one codebook; since each terminal device cannot know the selection of the other terminal device Codebook and pilot, different terminal devices may select the same codebook and the same pilot, so that the network device cannot detect the data sent by the different terminal device, or if a certain codebook and its corresponding one The pilot device is not selected by the terminal device, and the network device cannot decode the terminal data through the codebook and the pilot; for the above two cases, the network device cannot obtain the correct terminal data, and at this time, the network device can determine each The first pilot set corresponding to the codebook is blindly detected by the pilot in the first pilot set and the corresponding codebook, and the correct end cannot be obtained
  • the network device may determine, from the first pilot set corresponding to each codebook in each subframe, a pilot set of pilots corresponding to each codebook in each subframe that has been sent by the terminal device, that is,
  • the second set of pilots can also be understood as a pilot set of pilots that are simultaneously selected by at least two terminal devices for each pilot; and the mode of the terminal device to be transmitted is determined according to the second set of pilots, wherein different transmissions are performed.
  • the modes correspond to different spectrum reuse rates.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the pilot can be allocated to a plurality of terminal devices, and the product of the number of codebooks available for selection by the terminal device and the number of pilots corresponding to all codebooks at this time is smaller than the number of connected terminal devices.
  • the system capacity may be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the codebook is reduced. / or the number of pilots to reduce interference on the same time-frequency resource block, can improve the decoding rate programmatically, thereby providing a better channel environment in the case of fewer terminal devices, thereby improving spectrum utilization.
  • the spectrum multiplexing rate corresponding to the transmission mode of the terminal device may refer to the relationship between the number of resource elements (REs) and the number of terminal devices that multiplex the number of REs, where spectrum multiplexing The rate can be determined by the number of codebooks and/or pilots.
  • REs resource elements
  • the rate can be determined by the number of codebooks and/or pilots.
  • the third determining unit 540 is specifically configured to:
  • the third determining unit 540 may determine that the mode to be transmitted of the terminal device is the first transmission mode when the sum of the pilot numbers of the second pilot sets corresponding to all the codebooks in the N subframes is greater than or equal to the first threshold.
  • the spectrum multiplexing rate corresponding to the first transmission mode is greater than the spectrum multiplexing rate corresponding to the current transmission mode of the terminal device.
  • the sum of the pilot numbers of the second pilot sets corresponding to all the codebooks in the N subframes can be considered as the total occurrence of the same (codebook*pilot) combination in different terminal devices in the N subframes.
  • the network device 500 further includes a first notification unit 550, configured to send a first notification message to the terminal device, where the first notification message is used to indicate that the terminal device adopts the first A transmission mode for data transmission.
  • the third determining unit 540 may determine that the mode to be transmitted of the terminal device is the second transmission mode when the number of the subframes when the second pilot set corresponding to each codebook is an empty set is greater than or equal to the second threshold.
  • the spectrum multiplexing rate corresponding to the second transmission mode is smaller than the spectrum multiplexing rate corresponding to the current transmission mode of the terminal device.
  • the number of subframes when the second pilot set corresponding to each codebook is an empty set can be considered to be the same in the number of subframes, and there are no two different terminal devices selected (codebook* Frequency case, if the number of these subframes is greater than or equal to a certain threshold, then The transmission mode of the terminal device can be changed, for example, a transmission mode in which the spectrum multiplexing rate is 300% is changed to a transmission mode in which the spectrum multiplexing rate is 150%.
  • the network device 500 further includes a first notification unit 560, configured to send a second notification message to the terminal device, where the second notification message is used to indicate that the terminal device adopts the first The second transmission mode performs data transmission.
  • the mode of transmission of the terminal device is not limited to the above description. For example, when the total number of pilots of the second pilot set corresponding to all the codebooks in the N subframes is less than or equal to a certain threshold, and the second pilot set corresponding to each codebook is an empty set, the number of subframes is greater than When the threshold is equal to a certain threshold, the mode of the to-be-transmitted mode of the terminal device is reduced; or, the sum of the pilot numbers of the second pilot set corresponding to all the codebooks in the N subframes is greater than or equal to a certain threshold and the corresponding number of each codebook When the number of subframes when the two pilot sets are both empty sets is less than or equal to a certain threshold, the mode of the terminal device to be transmitted is improved.
  • the second determining unit 530 is specifically configured to:
  • the terminal may not use the codebook and the pilot for uplink transmission, or have different terminals.
  • the device uses the codebook and the pilot; in order to determine which situation, the signal strength of the pilot can be detected, and if the signal strength of the pilot is greater than a certain threshold, it is considered that there are different terminal devices.
  • the use of the pilot results in incorrect decoding; wherein the threshold can be simply set to zero.
  • the network device 500 further includes a third notification unit 570, configured to: before the blind detection unit performs blind detection on each of the N subframes, The terminal device sends a third notification message, where the third notification message is used to indicate a transmission mode adopted by the terminal device in the N subframes, where the transmission mode adopted in the N subframes is used to indicate the At least one codebook and a pilot corresponding to each codebook in the at least one codebook.
  • a third notification unit 570 configured to: before the blind detection unit performs blind detection on each of the N subframes, The terminal device sends a third notification message, where the third notification message is used to indicate a transmission mode adopted by the terminal device in the N subframes, where the transmission mode adopted in the N subframes is used to indicate the At least one codebook and a pilot corresponding to each codebook in the at least one codebook.
  • the network device 500 further includes:
  • the fourth determining unit 580 is configured to determine, according to the blind detection result, the number of times that the plurality of terminal devices in the N subframes use the same codebook;
  • the third determining unit 540 is specifically configured to:
  • the mode to be transmitted of the terminal device is determined according to the number of times that the plurality of terminal devices use the same codebook in the N subframes and the second pilot set corresponding to each codebook in each subframe.
  • the transmission mode corresponding to the transmission mode of the terminal device includes 150% and 300%.
  • the network device 500 is a base station.
  • the network device 500 in the embodiment of the present invention may correspond to the network device in the methods 200 to 400, and the corresponding functions of the network device in the methods 200 to 400 may be implemented. For brevity, details are not described herein again.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the system capacity can be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the number of codebooks and/or pilots is reduced. Reducing the interference on the same time-frequency resource block can improve the decoding rate by a certain program, thereby providing a better channel environment in the case of a small number of terminal devices, thereby improving spectrum utilization.
  • FIG. 9 is a schematic block diagram of a network device 600 in accordance with an embodiment of the present invention.
  • the network device 600 includes a processor 610, a memory 620, a bus 640 system, and a transceiver 630, wherein the processor 610, the memory 620, and the transceiver 630 pass through the bus 640.
  • the system is connected, the memory 620 is for storing instructions, the transceiver is for receiving data sent by the terminal device, and the processor 610 calls the instructions in the memory 620 to perform the following operations:
  • the pilot is a pilot that has been sent by the terminal device in the first pilot set;
  • the terminal device in each subframe, does not request resources from the network device, but directly uses the codebook corresponding to the codebook and the codebook in at least one codebook to perform uplink transmission on the unlicensed resource.
  • the network device performs blind detection on the unlicensed resource by using at least one codebook and the pilot corresponding to each codebook in the at least one codebook; since each terminal device cannot know the selection of the other terminal device Codebook and pilot, different terminal devices may select the same codebook and the same pilot, so that the network device cannot detect the data sent by the different terminal device, or if a certain codebook and its corresponding one The pilot device is not selected by the terminal device, and the network device cannot decode the terminal data through the codebook and the pilot; for the above two cases, the network device cannot obtain the correct terminal data, and at this time, the network device can determine each The first pilot set corresponding to the codebook is blindly detected by the pilot in the first pilot set and the corresponding codebook, and the correct end cannot be obtained
  • the network device may determine, from the first pilot set corresponding to each codebook in each subframe, a pilot set of pilots corresponding to each codebook in each subframe that has been sent by the terminal device, that is,
  • the second set of pilots can also be understood as a pilot set of pilots that are simultaneously selected by at least two terminal devices for each pilot; and the mode of the terminal device to be transmitted is determined according to the second set of pilots, wherein different transmissions are performed.
  • the modes correspond to different spectrum reuse rates.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the arrival frequency of the service packets is much smaller than the transmission frequency of the air interface frames, so the number of accesses of the terminal devices is increased. From the perspective, the same (codebook*pilot) can be allocated to multiple terminal devices, and the product of the number of codebooks available for selection by the terminal device and the number of pilots corresponding to all codebooks is less than the access. The number of terminal devices.
  • the system capacity may be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the codebook is reduced. / or the number of pilots to reduce interference on the same time-frequency resource block, can improve the decoding rate programmatically, thereby providing a better channel environment in the case of fewer terminal devices, thereby improving spectrum utilization.
  • the processor 610 invokes an instruction in the memory 620 to determine a mode to be transmitted of the terminal device according to the second pilot set corresponding to each codebook in each subframe.
  • the processor 610 specifically performs the following operations:
  • the processor 610 when the processor 610 invokes an instruction in the memory 620 to determine a mode to be transmitted of the terminal device, the processor 610 specifically performs the following operations:
  • the processor 610 calls the instructions in the memory 620 to also perform the following operations:
  • the first notification message is sent to the terminal device by the transceiver 630, where the first notification message is used to instruct the terminal device to perform data transmission by using the first transmission mode.
  • the processor 610 when the processor 610 invokes an instruction in the memory 620 to determine a mode to be transmitted of the terminal device, the processor 610 specifically performs the following operations:
  • the processor 610 calls the instructions in the memory 620 to also perform the following operations:
  • the processor 610 when the processor 610 invokes an instruction in the memory 620 to determine that each codebook in each subframe corresponds to a second pilot set, the processor 610 Specifically do the following:
  • the processor 610 before performing blind detection on each of the N subframes, calls the instruction in the memory 620 to perform the following operations:
  • the transmission mode is used to indicate the pilot corresponding to each codebook in the at least one codebook and the at least one codebook.
  • the processor 610 calls the instruction in the memory 620 to further perform the following operations:
  • the processor 610 invokes an instruction in the memory 620 to determine a mode to be transmitted of the terminal device according to a second pilot set corresponding to each codebook in each subframe, and the processor 610 Specifically do the following:
  • the network device 600 is a base station.
  • the network device 600 in the embodiment of the present invention may correspond to the network devices in the methods 200 to 400, and the corresponding functions of the network devices in the methods 200 to 400 may be implemented. I will not repeat them here.
  • a second pilot set corresponding to each codebook in each of the N subframes is determined, where the second pilot set is corresponding to each codebook in each subframe.
  • a pilot set of pilots selected by the two terminal devices, according to the second pilot set determining a mode to be transmitted of the terminal device, where different transmission modes correspond to different spectrum multiplexing rates, that is, according to N
  • the system capacity can be increased by increasing the number of terminal devices; or, in the case of the same number of terminal devices, the number of codebooks and/or pilots is reduced. Reducing the interference on the same time-frequency resource block can improve the decoding rate by a certain program, thereby providing a better channel environment in the case of a small number of terminal devices, thereby improving spectrum utilization.
  • the disclosed systems, devices, and methods may be implemented in other manners.
  • the device embodiments described above are merely illustrative.
  • the division of the unit is only a logical function division.
  • there may be another division manner for example, multiple units or components may be combined or Can be integrated into another system, or some features can be ignored or not executed.
  • the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be in an electrical, mechanical or other form.
  • the unit described as a separate component may or may not be physically separated, and the component displayed as a unit may or may not be a physical unit, that is, may be located in one place. Or it can be distributed to multiple network elements. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
  • each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
  • the functions may be stored in a computer readable storage medium if implemented in the form of a software functional unit and sold or used as a standalone product.
  • the technical solution of the present invention which is essential or contributes to the prior art, or a part of the technical solution, may be embodied in the form of a software product, which is stored in a storage medium, including
  • the instructions are used to cause a computer device (which may be a personal computer, server, or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention.
  • the foregoing storage medium includes: a U disk, a mobile hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk, and the like. .

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Abstract

本发明实施例提供一种用于调度终端设备的方法和网络设备。该方法包括:利用至少一个码本以及码本对应的导频,对N个子帧进行盲检测,根据盲检测结果,确定每个子帧中每个码本对应的第一导频集合,通过第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;根据每个码本对应的第一导频集合,确定每个码本对应第二导频集合,第二导频集合中的导频为第一导频集合中终端设备已发送的导频;根据每个子帧中每个码本对应的第二导频集合,确定待传输模式,不同的传输模式对应不同的频谱复用率。本发明兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同码本和导频而产生的碰撞问题。

Description

用于调度终端设备的方法和网络设备 技术领域
本发明涉及通信领域,并且更具体地,涉及一种用于调度终端设备的方法和网络设备。
背景技术
随着无线蜂窝网络的持续演进,广泛应用于第三代(3rd-Generation,简称为“3G”)和第四代(4th-Generation,简称为“4G”)移动通信系统的正交多址接入技术,如码分多址(Code Division Multiple Access,简称为“CDMA”)技术和正交频分多址(Orthogonal Frequency Multiple Access,简称为“OFDMA”)技术,已经逐渐无法满足人们对蜂窝网络日益提升的容量需求,如海量接入和频谱效率的持续提升等。与此同时,非正交的多址接入技术的研究和应用正逐渐引起业界和学术界越来越多的关注,人们希望未来的无线蜂窝网络,如第五代(5th-Generation,简称为“5G”)移动通信系统,能够借助非正交的多址接入技术有效的解决容量提升的问题。
稀疏码多址接入(Sparse Code Multiple Access,简称为“SCMA”)技术是一种典型的非正交多址接入和传输技术,当然该SCMA技术在通信领域还可以被称为其他名称。该类技术将来自一个或多个终端的M(M为不小于1的整数)个数据流叠加到N(N为不小于1的整数)个子载波上进行发送,其中每个数据流的每个数据都通过稀疏扩频的方式扩展到N个子载波上。当M的取值大于N时,该类技术可以有效地提升网络容量,包括系统可接入终端数和频谱效率等。因此,SCMA技术作为一种重要的非正交接入技术,已经引起越来越多的关注,并成为未来无线蜂窝网络演进的重要备选接入技术。
免授权(Grant free)是SCMA技术中一项用于小数据包传输的特殊调度机制,可以减少频繁的调度请求带来的开销和冗余。对于上行信道,Grant free终端不再请求资源,而是直接使用至少一个码本中的码本以及码本对应的导频,在免授权资源上进行上行传输,基站利用至少一个码本以及码本对应的导频,对免授权资源进行盲检测。
对于上行而言,这种Grant free的调度方式可以减少上行资源请求信令, 从而减少数据的传输时延,节约带宽。
然而,现有并没有涉及在该种传输机制如何提高,网络容量,即频谱复用率的相关技术。
发明内容
本发明实施例提供一种用于调度终端设备的方法和网络设备,可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
第一方面,提供了一种用于调度终端设备的方法,包括:
利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
根据盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
根据所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
结合第一方面,在第一方面的第一种可能的实现方式中,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
结合第一方面或第一方面的第一种可能的实现方式,在第一方面的第二种可能的实现方式中,所述根据所述每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式,包括:
根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
结合第一方面的第二种可能的实现方式,在第一方面的第三种可能的实现方式中,所述确定终端设备的待传输模式,包括:
在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于 等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
所述方法还包括:
向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
结合第一方面的第二种或第三种可能的实现方式,在第一方面的第四种可能的实现方式中,所述确定终端设备的待传输模式,包括:
在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
所述方法还包括:
向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
结合第一方面或其上述任一种可能的实现方式,在第一方面的第五种可能的实现方式中,所述确定所述每个子帧中每个码本对应第二导频集合,包括:
确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
结合第一方面或其上述任一种可能的实现方式,在第一方面的第六种可能的实现方式中,所述对N个子帧中每个子帧进行盲检测之前,所述方法还包括:
向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
结合第一方面或其上述任一种可能的实现方式,在第一方面的第七种可 能的实现方式中,所述方法还包括:
根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;
所述根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,包括:
根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
结合第一方面或其上述任一种可能的实现方式,在第一方面的第八种可能的实现方式中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
第二方面,提供了一种网络设备,包括:
盲检测单元,用于利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
第一确定单元,用于根据所述盲检测单元获取的盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
第二确定单元,用于根据所述第一确定单元确定的所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
第三确定单元,用于根据所述第二确定单元确定的所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
结合第二方面,在第二方面的第一种可能的实现方式中,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
结合第二方面或第二方面的第一种可能的实现方式,在第二方面的第二种可能的实现方式中,所述第三确定单元具体用于:
根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
结合第二方面的第二种可能的实现方式,在第二方面的第三种可能的实现方式中,所述第三确定单元具体用于:
在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
所述网络设备还包括:
第一通知单元,用于向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
结合第二方面的第二种或第三种可能的实现方式,在第二方面的第四种可能的实现方式中,所述第三确定单元具体用于:
在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
所述网络设备还包括:
第二通知单元,用于向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
结合第二方面或其上述任一种可能的实现方式,在第二方面的第五种可能的实现方式中,所述第二确定单元具体用于:
确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
结合第二方面或其上述任一种可能的实现方式,在第二方面的第六种可能的实现方式中,所述网络设备还包括第三通知单元,用于在所述盲检测单元对N个子帧中每个子帧进行盲检测之前,向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
结合第二方面或其上述任一种可能的实现方式,在第二方面的第七种可能的实现方式中,所述网络设备还包括:
第四确定单元,用于根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;其中,
所述第三确定单元具体用于:
根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
结合第二方面或其上述任一种可能的实现方式,在第二方面的第八种可能的实现方式中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
结合第二方面或其上述任一种可能的实现方式,在第二方面的第九种可能的实现方式中,所述网络设备为基站。
第三方面,提供了一种网络设备,包括:处理器、存储器、总线系统和收发器,其中,所述处理器、所述存储器和所述收发器通过所述总线系统相连,所述存储器用于存储指令,所述收发器用于接收终端设备发送的数据,所述处理器调用所述存储器中的指令执行以下操作:
根据至少一个码本以及至少一个码本中每个码本对应的导频,利用所述收发器接收的数据对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
根据盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
根据所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
结合第三方面,在第三方面的第一种可能的实现方式中,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
结合第三方面或第三方面的第一种可能的实现方式,在第三方面的第二 种可能的实现方式中,所述处理器调用所述存储器中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
结合第三方面的第二种可能的实现方式,在第三方面的第三种可能的实现方式中,所述处理器调用所述存储器中的指令确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
所述处理器调用所述存储器中的指令还执行以下操作:
通过所述收发器向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
结合第三方面的第二种或第三种可能的实现方式,在第三方面的第四种可能的实现方式中,所述处理器调用所述存储器中的指令确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
所述处理器调用所述存储器中的指令还执行以下操作:
通过所述收发器向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
结合第三方面或其上述任一种可能的实现方式,在第三方面的第五种可能的实现方式中,所述处理器调用所述存储器中的指令确定所述每个子帧中每个码本对应第二导频集合的过程中,所述处理器具体执行以下操作:
确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
结合第三方面或其上述任一种可能的实现方式,在第三方面的第六种可能的实现方式中,对N个子帧中每个子帧进行盲检测之前,所述处理器调用所述存储器中的指令还执行以下操作:
向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
结合第三方面或其上述任一种可能的实现方式,在第三方面的第七种可能的实现方式中,所述处理器调用所述存储器中的指令还执行以下操作:
根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;
所述处理器调用所述存储器中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
结合第三方面或其上述任一种可能的实现方式,在第三方面的第八种可能的实现方式中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
结合第三方面或其上述任一种可能的实现方式,在第三方面的第九种可能的实现方式中,所述网络设备为基站。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终 端设备选择相同的码本和导频而产生的碰撞问题。
附图说明
为了更清楚地说明本发明实施例的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。
图1是根据本发明实施例的应用场景图100。
图2是根据本发明实施例的SCMA的编码原理图。
图3是根据本发明实施例的用于调度终端设备的方法200的示意性流程图。
图4是根据本发明实施例的频谱复用率举例示意性图。
图5是根据本发明实施例的用于调度终端设备的方法300的示意性流程图。
图6是根据本发明实施例的用于调度终端设备的方法400的示意性流程图。
图7是根据本发明实施例的网络设备500的示意性框图。
图8是根据本发明实施例的网络设备500的另一示意性框图。
图9是根据本发明实施例的网络设备600的示意性框图。
具体实施方式
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例是本发明一部分实施例,而不是全部的实施例。基于本发明中的实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的范围。
在本发明实施例中,终端设备可以经无线接入网(Radio Access Network,简称为“RAN”)与一个或多个核心网进行通信,该终端设备可称为接入终端、用户设备(User Equipment,简称为“UE”)、用户单元、用户站、移动站、移动台、远方站、远程终端、移动设备、用户终端、终端、无线通信设备、用户代理或用户装置。接入终端可以是蜂窝电话、无绳电话、会话启动协议(Session Initiation Protocol,简称为“SIP”)电话、无线本地环路(Wireless  Local Loop,简称为“WLL”)站、个人数字处理(Personal Digital Assistant,简称为“PDA”)、具有无线通信功能的手持设备、计算设备或连接到无线调制解调器的其它处理设备、车载设备、可穿戴设备以及未来5G网络中的终端设备。
在本发明实施例中,网络设备可用于与终端设备通信,该网络设备可以是全球移动通讯(Global System of Mobile communication,简称为“GSM”)系统或码分多址(Code Division Multiple Access,简称为“CDMA”)中的基站(Base Transceiver Station,简称为“BTS”),也可以是宽带码分多址(Wideband Code Division Multiple Access,简称为“WCDMA”)系统中的基站(NodeB,简称为“NB”),还可以是长期演进(Long Term Evolution,简称为“LTE”)系统中的演进型基站(Evolutional Node B,简称为“eNB”或“eNodeB”),或者该网络设备可以为中继站、接入点、车载设备、可穿戴设备以及未来5G网络中的基站设备等。
图1是使用本发明的用于调度终端设备的方法的通信系统的示意图。如图1所示,该通信系统100包括网络设备102,网络设备102可包括多个天线组。每个天线组可以包括一个或多个天线,例如,一个天线组可包括天线104和106,另一个天线组可包括天线108和110,附加组可包括天线112和114。图1中对于每个天线组示出了2个天线,然而可对于每个组使用更多或更少的天线。网络设备102可附加地包括发射机链和接收机链,本领域普通技术人员可以理解,它们均可包括与信号发送和接收相关的多个部件(例如处理器、调制器、复用器、解调器、解复用器或天线等)。
网络设备102可以与多个终端设备(例如终端设备116和终端设备122)通信。然而,可以理解,网络设备102可以与类似于终端设备116或122的任意数目的终端设备通信。终端设备116和122可以是例如蜂窝电话、智能电话、便携式电脑、手持通信设备、手持计算设备、卫星无线电装置、全球定位系统、PDA和/或用于在无线通信系统100上通信的任意其它适合设备。
如图1所示,终端设备116与天线112和114通信,其中天线112和114通过前向链路118向终端设备116发送信息,并通过反向链路120从终端设备116接收信息。此外,终端设备122与天线104和106通信,其中天线104和106通过前向链路124向终端设备122发送信息,并通过反向链路126从终端设备122接收信息。
例如,在频分双工(FDD,Frequency Division Duplex)系统中,例如,前向链路118可利用与反向链路120所使用的不同频带,前向链路124可利用与反向链路126所使用的不同频带。
再例如,在时分双工(TDD,Time Division Duplex)系统和全双工(Full Duplex)系统中,前向链路118和反向链路120可使用共同频带,前向链路124和反向链路126可使用共同频带。
被设计用于通信的每组天线和/或区域称为网络设备102的扇区。例如,可将天线组设计为与网络设备102覆盖区域的扇区中的终端设备通信。在网络设备102通过前向链路118和124分别与终端设备116和122进行通信的过程中,网络设备102的发射天线可利用波束成形来改善前向链路118和124的信噪比。此外,与网络设备通过单个天线向它所有的终端设备发送信号的方式相比,在网络设备102利用波束成形向相关覆盖区域中随机分散的终端设备116和122发送信号时,相邻小区中的移动设备会受到较少的干扰。
在给定时间,网络设备102、终端设备116或终端设备122可以是无线通信发送装置和/或无线通信接收装置。当发送数据时,无线通信发送装置可对数据进行编码以用于传输。具体地,无线通信发送装置可获取(例如生成、从其它通信装置接收、或在存储器中保存等)要通过信道发送至无线通信接收装置的一定数目的数据比特。这种数据比特可包含在数据的传输块(或多个传输块)中。
可选地,在使用本发明实施例的用于调度终端设备的方法和装置的通信系统100中,在同一时段,多个终端设备复用同一时频资源与网络设备进行数据传输,并且,作为上述同一时频资源,例如,在以资源单元(RE,Resource Element)为单位的时频资源划分方式下,上述时频资源可以是由多个RE组成的时频资源块(也可以称为时频资源组)。
可选地,该通信系统为稀疏码分多址通信系统,以及,该时频资源为包括至少两个资源单元RE的时频资源块。
具体地说,稀疏码分多址(SCMA,Sparse Code Multiple Access)是一种新的多址接入方式,当然本领域技术人员也可以不把这个技术称之为SCMA,也可以称为其他技术名称。在该接入方式中,多个终端复用同一个时频资源块进行数据传输。每个资源块由若干资源RE组成,这里的RE可以是OFDM技术中的子载波-符号单元,也可以是其它空口技术中时域或频 域的资源单元。例如,在一个包含K个终端设备的SCMA系统中,可用资源分成若干正交的时频资源块,每个资源块含有L个RE,其中,该L个RE可以是在时域上的位置相同。当终端设备#k发送数据时,首先将待发送数据分成S比特大小的数据块,通过查找终端设备#k的码本(由网络设备确定并下发给该终端设备)将每个数据块映射成一组调制符号X#k={X#k1,X#k2,…,X#kL},每个调制符号对应资源块中一个RE,然后根据调制符号生成信号波形。对于S比特大小的数据块,每个码本含有2S个不同的调制符号组,对应2S种可能的数据块。
另外,在SCMA中,每个终端设备所对应的组调制符号X#k={X#k1,X#k2,…,X#kL}中,至少一个符号为零符号,并且,至少一个符号为非零符号。即,针对一个终端设备的数据,在L个RE中,只有部分RE(至少一个RE)承载有该终端设备的数据。
码字可以表示为多维复数向量,其维数为两维或两维以上,用于表示数据与两个或两个以上调制符号之间的映射关系,该调制符号包括至少一个零调制符号和至少一个非零调制符号,零调制符号和非零调制符号的关系可以为零调制符号个数不少于非零调制符号个数,数据可以为二进制比特数据或者多元数据。码本由两个或两个以上的码字组成。码本可以表示一定长度的数据的可能的数据组合与码本中码字的映射关系。SCMA技术通过将数据流中的数据按照一定的映射关系直接映射为码本中的码字即多维复数向量,实现数据在多个资源单元上的扩展发送。这里的数据可以是二进制比特数据也可以是多元数据,多个资源单元可以是时域、频域、空域、时频域、时空域、时频空域的资源单元。
SCMA的编码原理也可以用图2所示的二分图进行阐释:
上述二分图给出的是6个数据流复用4个资源单元的示例。其中,数据流也可以被称之为变量节点,资源单元也可被称之为功能节点,其中,6个数据流组成一个分组,4个资源单元组成一个编码单元。一个资源单元可以为一个资源单元,或者为一个资源粒子(英文为:Resource Element,英文缩写为:RE),或者为一个天线端口。二分图中,数据流和资源单元之间有连线表示至少存在该数据流的一种数据组合经码字映射后会在该资源单元上发送非零的调制符号,而数据流和资源单元之间没有连线则表示该数据流的所有可能的数据组合经码字映射后在该资源单元上发送的调制符号都为 零。数据流的数据组合可以按照如下阐述进行理解,例如,二进制比特数据流中,00、01、10、11为所有可能的两比特数据组合。为了描述方便,用s1至s6依次表示二分图中6个数据流待发送的数据组合,用x1至x4依次表示二分图中4个资源单元上发送的符号。从二分图中可以看出,每个数据流的数据经码字映射后会在两个或两个以上的资源单元上发送调制符号,同时,每个资源单元发送的符号是来自两个或两个以上的数据流的数据经各自码字映射后的调制符号的叠加。例如数据流3的待发送数据组合s3经码字映射后可能会在资源单元1和资源单元2上发送非零的调制符号,而资源单元3发送的数据x3是数据流2、数据流4和数据流6的待发送数据组合s2、s4和s6分别经各自码字映射后得到的非零调制符号的叠加。由于数据流的数量可以大于资源单元的数量,因而该SCMA系统可以有效地提升网络容量,包括系统的可接入用户数和频谱效率等。
结合以上关于码本和二分图的描述,码本中的码字通常具有如下形式:
Figure PCTCN2015073571-appb-000001
而相应的码本通常具有如下形式:
Figure PCTCN2015073571-appb-000002
其中,N为大于1的正整数,可以表示为一个编码单元所包含的资源单元数量,也可以理解为码字的长度;Qm为大于1的正整数,表示码本中包含的码字数量,与调制阶数对应,如四相相移键控(Quadrature Phase Shift Keying简称为“QPSK”)或4阶调制时,Qm为4;q正整数,且1≤q≤Qm。码本和码字所包含的元素cn,q为复数,数学上可以表示为cn,q=α*exp(j*β),1≤n≤N,1≤q≤Qmα β可以为任意实数。码本中的码字与数据流的数据组合可以形成一定映射关系,例如码本中的码字可以与二进制数据流的两比特数据组合形成如下映 射关系:“00”可以映射为码字
Figure PCTCN2015073571-appb-000003
“01”映射为码字
Figure PCTCN2015073571-appb-000004
“10”映射为码字
Figure PCTCN2015073571-appb-000005
“11”映射为码字
Figure PCTCN2015073571-appb-000006
结合上述二分图,当数据流与资源单元之间有连线时,数据流对应的码本和码本中的码字应具有如下特点:码本中至少存在一个码字在相应的资源单元上发送非零的调制符号,例如,数据流3和资源单元1之间有连线,则数据流3对应的码本至少有一个码字满足c1,q≠0,1≤q≤Qm,;当数据流与资源单元之间没有连线时,数据流对应的码本和码本中的码字应具有如下特征:码本中所有码字在相应的资源单元上发送为零的调制符号,例如,数据流3和资源单元3之间没有连线,则数据流3对应的码本中的任意码字满足c3,q=0,1≤q≤Qm。综上所述,当调制阶数为QPSK时,上述二分图中数据流3对应的码本可以具有如下形式和特征:
Figure PCTCN2015073571-appb-000007
其中cn,q=α*exp(j*β),1≤n≤2,1≤q≤4,α和β可以为任意实数,对任意q,1≤q≤4,c1,q和c2,q不同时为零,且至少存在一组q1和q2, 1≤q1,q2≤4,使得
Figure PCTCN2015073571-appb-000008
Figure PCTCN2015073571-appb-000009
举例地,如果数据流3的数据组合s3为“10”,则根据前述映射规则,该数据组合映射为码字即4维复数向量
Figure PCTCN2015073571-appb-000010
应理解,以上列举的SCMA系统仅为适用本发明的用于调度终端设备的方法和装置的通信系统的一例,本发明并不限定于此,其他的能够使终端设备在同一时段复用相同的时频资源进行数据传输的通信系统均落入本发明的保护范围内。
图3是根据本发明实施例的用于调度终端设备的方法200的示意性流程图。如图3所示,该方法200包括:
210,利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,N为正整数;
220,根据盲检测结果,确定该每个子帧中每个码本对应的第一导频集合,其中,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;
230,根据该每个子帧中每个码本对应的该第一导频集合,确定该每个子帧中每个码本对应第二导频集合,其中,该第二导频集合中的导频为该第一导频集合中终端设备已发送的导频;
240,根据该每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
具体地说,上行传输时,在各个子帧,终端设备不向网络设备请求资源,而是直接使用至少一个码本中的码本和码本对应的导频,在免授权资源上进行上行传输;在各个子帧,网络设备利用至少一个码本以及至少一个码本中每个码本对应的导频,在免授权资源上进行盲检测;由于每个终端设备无法获知其他终端设备所选择的码本和导频,不同的终端设备可能会选择相同的码本和相同的导频,这样网络设备无法检测到该不同终端设备发送的数据,或者,如果某一码本和其对应的某一导频没有被终端设备选择,则网络设备也无法通过该码本和导频解码到终端数据;对于上述两种情况,网络设备均 不能得到正确的终端数据,此时,网络设备可以确定每个码本对应的第一导频集合,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;网络设备可以从该每个子帧中每个码本对应的该第一导频集合中,确定每个子帧中每个码本对应的已经被终端设备发送的导频的导频集合,即第二导频集合,也可以理解为每个导频同时被至少两个终端设备选择的导频的导频集合;根据第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
在本发明实施例中,所述至少一个码本包括多个终端设备在其复用的某一时频资源进行上行传输时所采用的码本;每个码本可以对应至少一个导频,每个码本可以对应的不同的导频,其中该导频可以为解调参考信号(De Modulation Reference Signal,DMRS)。
由于在通常情况下,一个终端设备不可能无时无刻在发送业务,业务包的到达频率要远远小于空口帧的传输频率,所以从提高终端设备接入数量的角度上来看,相同的(码本*导频)可以分配给多个终端设备,则此时可供终端设备选择的码本的数量与所有码本对应的导频的数量的乘积小于接入的终端设备的数量。
可选地,在本发明实施例中,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
在本发明实施例中,终端设备的传输模式对应的频谱复用率可以是指资源单元(Resource Element,RE)的数量与复用该数量RE的终端设备的数 量的关系,其中,频谱复用率可以由码本和/或导频的数量确定。
例如,如果6个终端设备共同复用4个RE资源,其频谱的复用率为150%;如果12个终端设备共同复用4个RE资源,那么频谱的复用率为300%。例如,如图3所示,共有6个终端设备使用6个码本(图4中从左到右依次为码本1,码本2,码本3,码本4,码本5和码本6);其中,图中(10),(01),(11),(00)表示要编码的数据,箭头表示针对不同的数据,选择码本中不同的码块,例如,对于数据(11),终端设备1可以采用码本1中的第四个码块进行编码,终端设备6采用码本6中的第四个码块进行编码。应理解,6个终端设备共同复用4个RE,是指某一时刻可以实现最多6个终端设备来复用4个RE,而非必须由6个终端设备来复用4个RE,以及当前接入的终端设备的数量也可以多于6个。
可选地,230中,所述确定该每个子帧中每个码本对应第二导频集合,包括:
确定该每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据该每个子帧中每个码本对应的该第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
具体地说,如果网络设备通过某一码本以及该码本对应的某一导频不能不能得到正确的终端数据,则可能没有终端利用该码本和该导频进行上行传输,或者有不同终端设备均采用了该码本和该导频;为了判断是哪种情况,可以通过检测该导频的信号强度来实现,如果该导频的信号强度大于某一阈值,则认为有不同的终端设备使用了该导频导致不能正确译码;其中,该阈值可以简单设置为0。
在本发明实施例中,240中,根据该每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式,包括:
根据该N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定该终端设备的待传输模式。
具体地说,网络设备可以在该N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定终端设备的待传输模式为第一传 输模式,其中,该第一传输模式对应的频谱复用率大于终端设备的当前传输模式对应的频谱复用率。换句话说,N个子帧中所有码本对应的第二导频集合的导频数量总和可以认为在该N个子帧中不同的终端设备选择相同的(码本*导频)组合所发生的总次数,即终端设备间发生碰撞的总次数,如果该中次数大于某一阈值,则认为当前网络负载过高(指接入的终端设备不能正常通信,是由码本和/或导频的数量不能满足终端设备的需要而造成的终端设备之间的碰撞导致的),则可以改变终端设备的传输模式,例如,将从频谱复用率为150%的传输模式更改为频谱复用率为300%的传输模式。
或者,网络设备可以在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率。换句话说,每个码本对应的第二导频集合均为空集时子帧的数量可以认为在这些数量的子帧中,不存在两个不同的终端设备选择相同的(码本*导频)情况,如果这些子帧的数量大于等于某一阈值,则可以改变终端设备的传输模式,例如,将从频谱复用率为300%的传输模式更改为频谱复用率为150%的传输模式。
应理解,如何确定终端设备的待传输模式不限于上述描述。例如,在该N个子帧中所有码本对应的第二导频集合的导频数量总和小于等于某一阈值且每个码本对应的第二导频集合均为空集时子帧的数量大于等于某一阈值时,降低终端设备的待传输模式;或者,在该N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于某一阈值且每个码本对应的第二导频集合均为空集时子帧的数量小于等于某一阈值时,提高终端设备的待传输模式。再例如,可以根据这样的子帧数量来确定,在该子帧中,第二导频集合为空集数量大于等于某一阈值,该阈值可以小于码本的总数量。
在本发明实施例中,在网络设备确定的终端设备的待传输模式不同于当前传输模式时,可以通过广播信道或者控制信道向终端设备发送通知消息,以指示终端设备使用更改后的传输模式进行上行传输,其中,该传输模式可以指示终端设备所采用的至少一个码本和每个码本对应的导频。
可选地,在本发明实施例中,在210,对N个子帧中每个子帧进行盲检测之前,该方法还包括:
向终端设备发送通知消息,其中,该通知消息用于指示终端设备的在该 N个子帧中采用的传输模式,其中,该在该N个子帧中采用的传输模式用于指示该至少一个码本和该至少一个码本中每个码本对应的导频。
可选地,在本发明实施例中,网络设备还可以根据盲检测结果,确定该N个子帧中多个终端设备使用相同码本的次数;则网络设备可以根据该N个子帧中多个终端设备使用相同码本的次数以及该每个子帧中每个码本对应的第二导频集合,确定该终端设备的待传输模式。
为了更加清楚地理解本发明,以下将结合图5和图6详细描述本发明。
图5是根据本发明实施例中的用于调度终端设备的方法300的示意性流程图。如图5所示,该方法300包括:
301,网络设备为免授权区域分配免授权资源组,在该免授权资源组上进行上行传输所采用的至少一个码本和至少一个码本中每个码本对应的导频,并通过广播信道或是控制信道发送给多个UE。其中,可供终端设备选择的码本的数量与所有码本对应的导频的数量的乘积可以小于该每个子帧接入的最多终端设备的数量。
302,属于该免授权区域的终端设备接收到网络设备通过广播信道或控制信道发送的通知消息之后,如果在某一子帧需要进行上行传输,可以从至少一个码本中随机选择码本,并从该随机选择的码本对应的导频中随机选择导频,并利用该随机选择的码本和导频进行上行编码。
303,进行上行编码的终端设备编码结束之后进行上行传输。
304,网络设备在各个子帧利用至少一个码本和至少一个码本中每个码本对应的导频对免授权资源组进行盲检测,其中,网络设备可以采用每个码本,并轮询检测每个码本对应的导频,来进行盲检测;根据盲检测结果,确定第一导频集合,其中,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;并从第一导频集合中确定第二导频集合,其中,该第二导频集合中的导频为该第一导频集合中终端设备已发送的导频;具体地,网络设备可以根据第一导频集合中每个导频的信号强度来来确定已被终端设备发送的导频。网络设备也可以记录各个子帧至少两个终端设备采用相同码本的次数。
305,网络设备确定一段时间T内(N个子帧对应的时间段)不同终端设备在同一子帧选择相同(码本*导频)组合的次数M,即N个子帧中所有码本对应的第二导频集合中导频的总数量。
306,如果该M大于等于某一阈值,网络设备则更改终端设备的待传输模式,其中,更改后的待传输模式对应的频谱复用率大于当前传输模式对应的频谱复用率,并向终端设备发送通知消息,以指示终端设备后续传输采用更改后的该待传输模式。可选地,如果网络设备记录了各个子帧至少不同终端设备采用相同码本的次数,则可以结合该M和N个子帧中至少不同终端设备采用相同码本的次数总和W来共同确定待传输模式,例如,如果M大于等于某一阈值以及W大于等于某一阈值,则提高频谱复用率。
图6是根据本发明实施例的用于调度终端设备的方法400的示意性流程图。如图6所示,该方法400包括:
401,网络设备为免授权区域分配免授权资源组,在该免授权资源组上进行上行传输所采用的至少一个码本和至少一个码本中每个码本对应的导频,并通过广播信道或是控制信道发送给多个UE。其中,可供终端设备选择的码本的数量与所有码本对应的导频的数量的乘积可以小于该每个子帧接入的最多终端设备的数量。
402,属于该免授权区域的终端设备接收到网络设备通过广播信道或控制信道发送的通知消息之后,如果在某一子帧需要进行上行传输,可以从至少一个码本中随机选择码本,并从该随机选择的码本对应的导频中随机选择导频,并利用该随机选择的码本和导频进行上行编码。
403,进行上行编码的终端设备编码结束之后进行上行传输。
404,网络设备在各个子帧利用至少一个码本和至少一个码本中每个码本对应的导频对免授权资源组进行盲检测,其中,网络设备可以采用每个码本,并轮询检测每个码本对应的导频,来进行盲检测;根据盲检测结果,确定第一导频集合,其中,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;并从第一导频集合中确定第二导频集合,其中,该第二导频集合中的导频为该第一导频集合中终端设备已发送的导频;具体地,网络设备可以根据第一导频集合中每个导频的信号强度来来确定已被终端设备发送的导频。网络设备也可以记录各个子帧至少不同终端设备采用相同码本的次数。
405,网络设备确定一段时间T内(N个子帧对应的时间段),无终端设备选择相同(码本*导频)组合的子帧个数S,即每个码本对应的第二导频集合均为空集时子帧的数量。
406,如果该S大于等于某一阈值,网络设备则更改终端设备的待传输模式,其中,更改后的待传输模式对应的频谱复用率小于当前传输模式对应的频谱复用率,并向终端设备发送通知消息,以指示终端设备后续传输采用更改后的该待传输模式。可选地,如果网络设备记录了各个子帧至少不同终端设备采用相同码本的次数,则可以结合该S和N个子帧中至少不同终端设备采用相同码本的次数总和W来共同确定待传输模式,例如,如果S大于等于某一阈值以及W小于等于某一阈值,则降低频谱复用率。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
并且进一步地,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
图7是根据本发明实施例的网络设备500的示意性框图。如图7所示,该网络设备500包括:
盲检测单元510,用于利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,该N为正整数;
第一确定单元520,用于根据该盲检测单元510获取的盲检测结果,确定该每个子帧中每个码本对应的第一导频集合,其中,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;
第二确定单元530,用于根据该第一确定单元520确定的该每个子帧中每个码本对应的该第一导频集合,确定该每个子帧中每个码本对应第二导频集合,其中,该第二导频集合中的导频为该第一导频集合中该终端设备已发送的导频;
第三确定单元540,用于根据该第二确定单元530确定的该每个子帧中每个码本对应的第二导频集合,确定该终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
具体地说,上行传输时,在各个子帧,终端设备不向网络设备请求资源,而是直接使用至少一个码本中的码本和码本对应的导频,在免授权资源上进行上行传输;在各个子帧,网络设备利用至少一个码本以及至少一个码本中每个码本对应的导频,在免授权资源上进行盲检测;由于每个终端设备无法获知其他终端设备所选择的码本和导频,不同的终端设备可能会选择相同的码本和相同的导频,这样网络设备无法检测到该不同终端设备发送的数据,或者,如果某一码本和其对应的某一导频没有被终端设备选择,则网络设备也无法通过该码本和导频解码到终端数据;对于上述两种情况,网络设备均不能得到正确的终端数据,此时,网络设备可以确定每个码本对应的第一导频集合,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;网络设备可以从该每个子帧中每个码本对应的该第一导频集合中,确定每个子帧中每个码本对应的已经被终端设备发送的导频的导频集合,即第二导频集合,也可以理解为每个导频同时被至少两个终端设备选择的导频的导频集合;根据第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
由于在通常情况下,一个终端设备不可能无时无刻在发送业务,业务包的到达频率要远远小于空口帧的传输频率,所以从提高终端设备接入数量的角度上来看,相同的(码本*导频)可以分配给多个终端设备,则此时可供终端设备选择的码本的数量与所有码本对应的导频的数量的乘积小于接入的终端设备的数量。
可选地,在本发明实施例中,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
在本发明实施例中,终端设备的传输模式对应的频谱复用率可以是指资源单元(Resource Element,RE)的数量与复用该数量RE的终端设备的数量的关系,其中,频谱复用率可以由码本和/或导频的数量确定。
可选地,在本发明实施例中,该第三确定单元540具体用于:
根据该N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定该终端设备的待传输模式。
具体地说,第三确定单元540可以在该N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定终端设备的待传输模式为第一传输模式,其中,该第一传输模式对应的频谱复用率大于终端设备的当前传输模式对应的频谱复用率。换句话说,N个子帧中所有码本对应的第二导频集合的导频数量总和可以认为在该N个子帧中不同的终端设备选择相同的(码本*导频)组合所发生的总次数,即终端设备间发生碰撞的总次数,如果该中次数大于某一阈值,则认为当前网络负载过高(指接入的终端设备不能正常通信,是由码本和/或导频的数量不能满足终端设备的需要而造成的终端设备之间的碰撞导致的),则可以改变终端设备的传输模式,例如,将从频谱复用率为150%的传输模式更改为频谱复用率为300%的传输模式。可选地,如图8所示,该网络设备500还包括第一通知单元550,用于向该终端设备发送第一通知消息,其中,该第一通知消息用于指示该终端设备采用该第一传输模式进行数据传输。
或者,第三确定单元540可以在该每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定终端设备的待传输模式为第二传输模式,其中,该第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率。换句话说,每个码本对应的第二导频集合均为空集时子帧的数量可以认为在这些数量的子帧中,不存在两个不同的终端设备选择相同的(码本*导频)情况,如果这些子帧的数量大于等于某一阈值,则 可以改变终端设备的传输模式,例如,将从频谱复用率为300%的传输模式更改为频谱复用率为150%的传输模式。可选地,如图8所示,该网络设备500还包括第一通知单元560,用于向该终端设备发送第二通知消息,其中,该第二通知消息用于指示该终端设备采用该第二传输模式进行数据传输。
应理解,如何确定终端设备的待传输模式不限于上述描述。例如,在该N个子帧中所有码本对应的第二导频集合的导频数量总和小于等于某一阈值且每个码本对应的第二导频集合均为空集时子帧的数量大于等于某一阈值时,降低终端设备的待传输模式;或者,在该N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于某一阈值且每个码本对应的第二导频集合均为空集时子帧的数量小于等于某一阈值时,提高终端设备的待传输模式。
可选地,在本发明实施例中,该第二确定单元530具体用于:
确定该每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据该每个子帧中每个码本对应的该第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
具体地说,如果网络设备通过某一码本以及该码本对应的某一导频不能不能得到正确的终端数据,则可能没有终端利用该码本和该导频进行上行传输,或者有不同终端设备均采用了该码本和该导频;为了判断是哪种情况,可以通过检测该导频的信号强度来实现,如果该导频的信号强度大于某一阈值,则认为有不同的终端设备使用了该导频导致不能正确译码;其中,该阈值可以简单设置为0。
可选地,在本发明实施例中,如图8所示,该网络设备500还包括第三通知单元570,用于在该盲检测单元对N个子帧中每个子帧进行盲检测之前,向该终端设备发送第三通知消息,其中,该第三通知消息用于指示该终端设备在该N个子帧中采用的传输模式,其中,该在该N个子帧中采用的传输模式用于指示该至少一个码本和该至少一个码本中每个码本对应的导频。
可选地,如图8所示,该网络设备500还包括:
第四确定单元580,用于根据该盲检测结果,确定该N个子帧中多个终端设备使用相同码本的次数;其中,
该第三确定单元540具体用于:
根据该N个子帧中多个终端设备使用相同码本的次数以及该每个子帧中每个码本对应的第二导频集合,确定该终端设备的待传输模式。
可选地,该终端设备的传输模式对应的频谱复用率包括150%和300%。
可选地,该网络设备500为基站。
应理解,本发明实施例中的网络设备500可以对应于方法200至400中的网络设备,可以实现方法200至400中的网络设备的相应功能,为了简洁,在此不再赘述。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
并且进一步地,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
图9是根据本发明实施例的网络设备600的示意性框图。如图9所示,该网络设备600包括:处理器610、存储器620、总线640系统和收发器630,其中,所述处理器610、所述存储器620和所述收发器630通过所述总线640系统相连,所述存储器620用于存储指令,所述收发器用于接收终端设备发送的数据,所述处理器610调用所述存储器620中的指令执行以下操作:
根据至少一个码本以及至少一个码本中每个码本对应的导频,利用所述收发器630接收的数据对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
根据盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,通过所述第一导频集合中的导频以及对应的码本进行盲检测不能得到 正确的终端数据;
根据所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
具体地说,上行传输时,在各个子帧,终端设备不向网络设备请求资源,而是直接使用至少一个码本中的码本和码本对应的导频,在免授权资源上进行上行传输;在各个子帧,网络设备利用至少一个码本以及至少一个码本中每个码本对应的导频,在免授权资源上进行盲检测;由于每个终端设备无法获知其他终端设备所选择的码本和导频,不同的终端设备可能会选择相同的码本和相同的导频,这样网络设备无法检测到该不同终端设备发送的数据,或者,如果某一码本和其对应的某一导频没有被终端设备选择,则网络设备也无法通过该码本和导频解码到终端数据;对于上述两种情况,网络设备均不能得到正确的终端数据,此时,网络设备可以确定每个码本对应的第一导频集合,通过该第一导频集合中的导频以及对应的码本进行盲检测不能得到正确的终端数据;网络设备可以从该每个子帧中每个码本对应的该第一导频集合中,确定每个子帧中每个码本对应的已经被终端设备发送的导频的导频集合,即第二导频集合,也可以理解为每个导频同时被至少两个终端设备选择的导频的导频集合;根据第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
由于在通常情况下,一个终端设备不可能无时无刻在发送业务,业务包的到达频率要远远小于空口帧的传输频率,所以从提高终端设备接入数量的 角度上来看,相同的(码本*导频)可以分配给多个终端设备,则此时可供终端设备选择的码本的数量与所有码本对应的导频的数量的乘积小于接入的终端设备的数量。
可选地,在本发明实施例中,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
可选地,在本发明实施例中,所述处理器610调用所述存储器620中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式的过程中,所述处理器610具体执行以下操作:
根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
可选地,在本发明实施例中,所述处理器610调用所述存储器620中的指令确定终端设备的待传输模式的过程中,所述处理器610具体执行以下操作:
在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
所述处理器610调用所述存储器620中的指令还执行以下操作:
通过所述收发器630向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
可选地,在本发明实施例中,所述处理器610调用所述存储器620中的指令确定终端设备的待传输模式的过程中,所述处理器610具体执行以下操作:
在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
所述处理器610调用所述存储器620中的指令还执行以下操作:
通过所述收发器630向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
可选地,在本发明实施例中,所述处理器610调用所述存储器620中的指令确定所述每个子帧中每个码本对应第二导频集合的过程中,所述处理器610具体执行以下操作:
确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
可选地,在本发明实施例中,对N个子帧中每个子帧进行盲检测之前,所述处理器610调用所述存储器620中的指令还执行以下操作:
向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
可选地,在本发明实施例中,所述处理器610调用所述存储器620中的指令还执行以下操作:
根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;
所述处理器610调用所述存储器620中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式的过程中,所述处理器610具体执行以下操作:
根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
可选地,在本发明实施例中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
可选地,在本发明实施例中,所述网络设备600为基站。
应理解,本发明实施例中的网络设备600可以对应于方法200至400中的网络设备,可以实现方法200至400中的网络设备的相应功能,为了简洁, 在此不再赘述。
从而,在本发明实施例中,确定N个子帧中每个子帧中每个码本对应的第二导频集合,其中,第二导频集合为每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,根据该第二导频集合,确定终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率,也就是说,可以根据N个子帧中每个子帧中每个码本对应的被至少两个终端设备选择的导频的导频集合,来灵活选择频谱复用率,从而可以兼容考虑提高频谱复用率带来的网络设备解码复杂的问题,以及降低频谱复用率带来的至少两个终端设备选择相同的码本和导频而产生的碰撞问题。
并且进一步地,在相同码本和/或导频的情况下,可以通过增加终端设备的数量增加系统容量;或者,在相同终端设备数量的情况下,减少码本和/或导频的数量来减少相同时频资源块上的干扰,可以一定程序上提升译码率,从而在终端设备数较少的情况下,提供更好的信道环境,从而提升频谱利用率。
本领域普通技术人员可以意识到,结合本文中所公开的实施例描述的各示例的单元及算法步骤,能够以电子硬件、或者计算机软件和电子硬件的结合来实现。这些功能究竟以硬件还是软件方式来执行,取决于技术方案的特定应用和设计约束条件。专业技术人员可以对每个特定的应用来使用不同方法来实现所描述的功能,但是这种实现不应认为超出本发明的范围。
所属领域的技术人员可以清楚地了解到,为描述的方便和简洁,上述描述的系统、装置和单元的具体工作过程,可以参考前述方法实施例中的对应过程,在此不再赘述。
在本申请所提供的几个实施例中,应该理解到,所揭露的系统、装置和方法,可以通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如,所述单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方, 或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。
另外,在本发明各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。
所述功能如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本发明各个实施例所述方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等各种可以存储程序代码的介质。
以上所述,仅为本发明的具体实施方式,但本发明的保护范围并不局限于此,任何熟悉本技术领域的技术人员在本发明揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本发明的保护范围之内。因此,本发明的保护范围应所述以权利要求的保护范围为准。

Claims (29)

  1. 一种用于调度终端设备的方法,其特征在于,包括:
    利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
    根据盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
    根据所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
    根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
  2. 根据权利要求1所述的方法,其特征在于,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
  3. 根据权利要求1或2所述的方法,其特征在于,所述根据所述每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式,包括:
    根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
  4. 根据权利要求3所述的方法,其特征在于,所述确定终端设备的待传输模式,包括:
    在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
    所述方法还包括:
    向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
  5. 根据权利要求3或4所述的方法,其特征在于,所述确定终端设备 的待传输模式,包括:
    在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
    所述方法还包括:
    向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
  6. 根据权利要求1至5中任一项所述的方法,其特征在于,所述确定所述每个子帧中每个码本对应第二导频集合,包括:
    确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
    根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
  7. 根据权利要求1至6中任一项所述的方法,其特征在于,所述对N个子帧中每个子帧进行盲检测之前,所述方法还包括:
    向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
  8. 根据权利要求1至7中任一项所述的方法,其特征在于,所述方法还包括:
    根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;
    所述根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,包括:
    根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
  9. 根据权利要求1至8中任一项所述的方法,其中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
  10. 一种网络设备,其特征在于,包括:
    盲检测单元,用于利用至少一个码本以及至少一个码本中每个码本对应的导频,对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
    第一确定单元,用于根据所述盲检测单元获取的盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
    第二确定单元,用于根据所述第一确定单元确定的所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
    第三确定单元,用于根据所述第二确定单元确定的所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
  11. 根据权利要求10所述的网络设备,其特征在于,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
  12. 根据权利要求10或11所述的网络设备,其特征在于,所述第三确定单元具体用于:
    根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
  13. 根据权利要求12所述的网络设备,其特征在于,所述第三确定单元具体用于:
    在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对应的频谱复用率;
    所述网络设备还包括:
    第一通知单元,用于向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
  14. 根据权利要求12或13所述的网络设备,其特征在于,所述第三确 定单元具体用于:
    在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
    所述网络设备还包括:
    第二通知单元,用于向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
  15. 根据权利要求10至14中任一项所述的网络设备,其特征在于,所述第二确定单元具体用于:
    确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
    根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
  16. 根据权利要求10至15中任一项所述的网络设备,其特征在于,所述网络设备还包括第三通知单元,用于在所述盲检测单元对N个子帧中每个子帧进行盲检测之前,向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
  17. 根据权利要求10至16中任一项所述的网络设备,其特征在于,所述网络设备还包括:
    第四确定单元,用于根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;其中,
    所述第三确定单元具体用于:
    根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
  18. 根据权利要求10至17中任一项所述的网络设备,其中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
  19. 根据权利要求10至18中任一项所述的网络设备,其特征在于,所 述网络设备为基站。
  20. 一种网络设备,其特征在于,包括:处理器、存储器、总线系统和收发器,其中,所述处理器、所述存储器和所述收发器通过所述总线系统相连,所述存储器用于存储指令,所述收发器用于接收终端设备发送的数据,所述处理器调用所述存储器中的指令执行以下操作:
    根据至少一个码本以及至少一个码本中每个码本对应的导频,利用所述收发器接收的数据对N个子帧中每个子帧进行盲检测,其中,所述N为正整数;
    根据盲检测结果,确定所述每个子帧中每个码本对应的第一导频集合,其中,所述第一导频集合中的导频为结合对应的码本进行盲检测不能得到正确的终端数据的导频;
    根据所述每个子帧中每个码本对应的所述第一导频集合,确定所述每个子帧中每个码本对应第二导频集合,其中,所述第二导频集合中的导频为所述第一导频集合中所述终端设备已发送的导频;
    根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式,其中,不同的传输模式对应不同的频谱复用率。
  21. 根据权利要求20所述的网络设备,其特征在于,所述至少一个码本中码本的数量与码本对应的导频的数量的乘积小于所述每个子帧接入的终端设备的数量。
  22. 根据权利要求20或21所述的网络设备,其特征在于,所述处理器调用所述存储器中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
    根据所述N个子帧中所有码本对应的第二导频集合的导频数量总和,以及每个码本对应的第二导频集合均为空集时子帧的数量中的至少一种,确定所述终端设备的待传输模式。
  23. 根据权利要求22所述的网络设备,其特征在于,所述处理器调用所述存储器中的指令确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
    在所述N个子帧中所有码本对应的第二导频集合的导频数量总和大于等于第一阈值时,确定所述终端设备的待传输模式为第一传输模式,其中,所述第一传输模式对应的频谱复用率大于所述终端设备的当前传输模式对 应的频谱复用率;
    所述处理器调用所述存储器中的指令还执行以下操作:
    通过所述收发器向所述终端设备发送第一通知消息,其中,所述第一通知消息用于指示所述终端设备采用所述第一传输模式进行数据传输。
  24. 根据权利要求22或23所述的网络设备,其特征在于,所述处理器调用所述存储器中的指令确定终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
    在所述每个码本对应的第二导频集合均为空集时子帧的数量大于等于第二阈值时,确定所述终端设备的待传输模式为第二传输模式,其中,所述第二传输模式对应的频谱复用率小于终端设备的当前传输模式对应的频谱复用率;
    所述处理器调用所述存储器中的指令还执行以下操作:
    通过所述收发器向所述终端设备发送第二通知消息,其中,所述第二通知消息用于指示所述终端设备采用所述第二传输模式进行数据传输。
  25. 根据权利要求20至24中任一项所述的网络设备,其特征在于,所述处理器调用所述存储器中的指令确定所述每个子帧中每个码本对应第二导频集合的过程中,所述处理器具体执行以下操作:
    确定所述每个子帧中每个码本对应的第一导频集合中每个导频的信号强度;
    根据所述每个子帧中每个码本对应的所述第一导频集合中每个导频的信号强度,确定每个子帧中每个码本对应的第二导频集合,其中,第二导频集合中每个导频的信号强度大于等于第三阈值。
  26. 根据权利要求20至25中任一项所述的网络设备,其特征在于,对N个子帧中每个子帧进行盲检测之前,所述处理器调用所述存储器中的指令还执行以下操作:
    向所述终端设备发送第三通知消息,其中,所述第三通知消息用于指示所述终端设备在所述N个子帧中采用的传输模式,其中,所述在所述N个子帧中采用的传输模式用于指示所述至少一个码本和所述至少一个码本中每个码本对应的导频。
  27. 根据权利要求20至26中任一项所述的网络设备,其特征在于,所述处理器调用所述存储器中的指令还执行以下操作:
    根据所述盲检测结果,确定所述N个子帧中多个终端设备使用相同码本的次数;
    所述处理器调用所述存储器中的指令根据所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式的过程中,所述处理器具体执行以下操作:
    根据所述N个子帧中多个终端设备使用相同码本的次数以及所述每个子帧中每个码本对应的第二导频集合,确定所述终端设备的待传输模式。
  28. 根据权利要求20至27中任一项所述的网络设备,其中,所述终端设备的传输模式对应的频谱复用率包括150%和300%。
  29. 根据权利要求20至28中任一项所述的网络设备,其特征在于,所述网络设备为基站。
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