WO2017045585A1 - Procédé et dispositif d'attribution de ressource - Google Patents

Procédé et dispositif d'attribution de ressource Download PDF

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Publication number
WO2017045585A1
WO2017045585A1 PCT/CN2016/098861 CN2016098861W WO2017045585A1 WO 2017045585 A1 WO2017045585 A1 WO 2017045585A1 CN 2016098861 W CN2016098861 W CN 2016098861W WO 2017045585 A1 WO2017045585 A1 WO 2017045585A1
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Prior art keywords
resource
bit
resource block
block
frequency domain
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PCT/CN2016/098861
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English (en)
Chinese (zh)
Inventor
淦明
郭宇宸
刘乐
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华为技术有限公司
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Priority claimed from CN201510642610.6A external-priority patent/CN106559897B/zh
Application filed by 华为技术有限公司 filed Critical 华为技术有限公司
Publication of WO2017045585A1 publication Critical patent/WO2017045585A1/fr

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/12Wireless traffic scheduling

Definitions

  • the present invention relates to the field of communications, and in particular, to a method and apparatus for resource allocation.
  • frequency domain resources of different bandwidths can be divided into at least one resource block, and scheduling information corresponding to the divided resource blocks is indicated (for example, indication MU-MIMO (Multi-User Multiple-Input Multiple-Output) transmission can be performed on which resource block.
  • 802.11ax is an 802.11 wireless LAN communication standard, which transmits through the 5G frequency band, which is a subsequent upgrade version of 802.11ac.
  • MU-MIMO is a technology that allows a router to communicate with multiple devices at the same time.
  • the existing resource allocation method adopts a resource block-based bitmap indication manner to inform the receiving end of the resource allocation mode on the current transmission bandwidth.
  • the bitmap indication mode uses a continuous sequence of “1” or “0” to indicate resource blocks allocated to the same station, and jumps from “1” to “0” or “0” to “1”. "To indicate that a resource block is assigned to another site. Therefore, the number of bits used to indicate the resource allocation pattern on the current transmission bandwidth is equal to the number of resource blocks on the current transmission bandwidth. For example, as shown in FIG. 1, there are nine 1*26 resource blocks on a bandwidth of 20 MHz, and then the number of bits used to indicate the resource allocation pattern on the current transmission bandwidth is equal to 9 bits.
  • the receiving end receives a bitmap indication sequence of "110010000", then it can be known that the first and second resource blocks are allocated to the station 1, the third and the fourth resource block are allocated to the station 2. The fifth resource block is allocated to station 3, and the remaining four resource blocks are allocated to station 4. It should be noted that the bitmap indication sequence received by the receiving end indicates that the resource block actually divided is corresponding to the following station information. For example, the bitmap indicated by the resource block in FIG. 1 is "110010000", Site 1 information, Site 2 information, Site 3 information, and Site 4 information. Each site information contains a site identity, which is used to identify the site and is the identity of the site.
  • the number of bits used to indicate the resource allocation mode on the current transmission bandwidth is equal to the number of resource blocks on the current transmission bandwidth, instead of the current transmission bandwidth being actually The number of resource blocks divided. For a bandwidth of 80 megahertz or a bandwidth of 160 megahertz, the number of resource blocks that may be divided is large, so the number of bits used to indicate the resource allocation pattern on the current transmission bandwidth is also increased.
  • An embodiment of the present invention provides a resource allocation method and apparatus, which can reduce a signaling overhead by indicating at least one resource block in which a frequency domain resource is divided by a resource allocation bit sequence.
  • an embodiment of the present invention provides a resource allocation method, including:
  • the sending end generates resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • the sending end sends the resource scheduling information to the receiving end.
  • an embodiment of the present invention provides a resource allocation method, including:
  • the receiving end receives the resource scheduling information sent by the sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • the receiving end parses the resource scheduling information.
  • an embodiment of the present invention provides a sending end, including:
  • a generating module configured to generate resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • a sending module configured to send the resource scheduling information to the receiving end after the generating module generates the resource scheduling information.
  • the embodiment of the present invention further provides a receiving end, including:
  • a receiving module configured to receive resource scheduling information sent by the sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • the parsing module is configured to parse the resource scheduling information after the receiving module receives the resource scheduling information sent by the sending end.
  • An embodiment of the present invention provides a resource allocation method and apparatus, where resource scheduling information is generated by a transmitting end, where the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the sender sends resource scheduling information to receive end.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • FIG. 1 is a schematic diagram of dividing a frequency domain resource of a 20 MHz bandwidth by using a resource block based bitmap indication manner
  • FIG. 2 is a schematic diagram of a packet structure of an 802.11ax according to an embodiment of the present invention
  • FIG. 3 is a schematic structural diagram of a HE-SIG-B according to an embodiment of the present invention.
  • FIG. 4 is a schematic diagram of subcarrier division of a frequency domain resource with a bandwidth of 20 MHz according to an embodiment of the present invention
  • FIG. 5 is a schematic flowchart of a resource allocation method according to Embodiment 1 of the present invention.
  • FIG. 6 is a schematic flowchart diagram of another resource allocation method according to Embodiment 2 of the present invention.
  • FIG. 7 is a schematic diagram of default resource blocks of a frequency domain resource of 20 MHz bandwidth according to Embodiment 3 of the present invention.
  • FIG. 8 is a schematic diagram 1 of a resource block position in which a frequency domain resource of 20 MHz bandwidth may be divided according to Embodiment 3 of the present invention
  • FIG. 9 is a second schematic diagram of a resource block location in which a frequency domain resource of 20 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • FIG. 10 is a third schematic diagram of a resource block location in which a frequency domain resource of 20 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • 11 is a first example of resource blocks in which frequency domain resources of 20 MHz bandwidth are divided according to Embodiment 3 of the present invention.
  • FIG. 13 is a schematic diagram 1 of a resource block position in which a frequency domain resource of 40 MHz bandwidth may be divided according to Embodiment 3 of the present invention
  • FIG. 14 is a second schematic diagram of a resource block location in which a frequency domain resource of 40 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • FIG. 15 is a third schematic diagram of a resource block location in which a frequency domain resource of 40 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • 16 is an example of resource blocks in which frequency domain resources of 40 MHz bandwidth are divided according to Embodiment 3 of the present invention.
  • FIG. 17 is a schematic diagram 1 of a resource block position in which a frequency domain resource of an 80 MHz bandwidth may be divided according to Embodiment 3 of the present invention
  • FIG. 18 is a second schematic diagram of a resource block position in which a frequency domain resource of an 80 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • FIG. 19 is a schematic diagram 3 of a resource block position in which a frequency domain resource of an 80 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • FIG. 21 is a schematic diagram 1 of a resource block position in which a frequency domain resource of 160 MHz bandwidth may be divided according to Embodiment 3 of the present invention
  • FIG. 22 is a second schematic diagram of resource block locations in which frequency domain resources of 160 MHz bandwidth may be divided according to Embodiment 3 of the present invention.
  • FIG. 23 is a third schematic diagram of a resource block location of a 160 MHz bandwidth frequency domain resource according to Embodiment 3 of the present invention.
  • FIG. 24 is a schematic flowchart diagram of a method for generating resource scheduling information according to Embodiment 3 of the present invention.
  • 25 is an example of a resource allocation bit sequence of a spectrum resource of a 20 MHz bandwidth according to Embodiment 3 of the present invention.
  • 26 is an example of a resource allocation bit sequence of a 40 MHz bandwidth spectrum resource according to Embodiment 3 of the present invention.
  • FIG. 29 is a schematic structural diagram of a spectrum resource using a baffle method according to Embodiment 4 of the present invention.
  • FIG. 30 is a first example of a resource allocation bit sequence of a spectrum resource of 20 MHz bandwidth according to Embodiment 4 of the present invention.
  • FIG. 31 is a second example of a resource allocation bit sequence of a spectrum resource of 20 MHz bandwidth according to Embodiment 4 of the present invention.
  • FIG. 33 is a diagram showing an example of a resource allocation bit sequence of a 40 MHz bandwidth spectrum resource according to Embodiment 4 of the present invention.
  • FIG. 34 is a diagram showing an example of a resource allocation bit sequence of a spectrum resource of an 80 MHz bandwidth according to Embodiment 4 of the present invention.
  • FIG. 36 is a schematic diagram of another HE-SIG-B coding method according to Embodiment 5 of the present invention.
  • FIG. 37 is a schematic structural diagram of a transmitting end according to Embodiment 6 of the present invention.
  • FIG. 40 is a schematic structural diagram of a receiving end according to Embodiment 9 of the present invention.
  • 41a, 41b, and 41c are schematic diagrams showing the working principle of generating (transmitting) or parsing (receiving) resource allocation bit sequences according to an embodiment of the present invention.
  • the embodiment of the present invention is applied to a WLAN system, and 802.11ax is taken as an example.
  • the packet structure of 802.11ax is as shown in FIG. 2, wherein the preamble portion includes an L-preamble (Legacy preamble) and is associated with the L-preamble. Neighbor HE (High Efficient).
  • the L-preamble includes an L-STF (Legacy Shorting Training Field), an L-LTF (Legacy Long Training Field), and an L-SIG (Legacy Signal Field).
  • the HE preamble includes RL-SIG (Rpeated Legacy Signal Field), HE-SIGA (High Efficient Signal Field A), and HE-SIGB (High Efficient Signal Field B).
  • B HE-STF (High Efficient Shorting Training Field) and HE-LTF (High Efficient Long Training Field).
  • the packet structure of the WLAN system may further include DATA (Data Field).
  • the HE-SIG-B includes public information parameters and respective scheduled user site information.
  • the public information parameter includes a resource allocation indication, and each scheduled user site information includes a corresponding site identifier.
  • the public information parameter optionally includes a guard interval used for data transmission, OFMDA (Orthogonal Frequency Division Multiple Access)/MU-MIMO indication, HE-LTF number and mode, and may also include uplink / Downstream indication, whether there are parameters such as the regular HE-SIGB.
  • the user site information may also include the number of spatial streams of the site, the MCS (Modulation and Coding Scheme) used for data transmission, the coding type, whether to use the space-time code indication, and whether to use the beamforming technology indication.
  • MCS Modulation and Coding Scheme
  • the coding type whether to use the space-time code indication, and whether to use the beamforming technology indication.
  • some of the parameters of the public information parameters can also be carried in the HE-SIGA.
  • the resource block size is divided into 26 resource units by using 26 subcarriers.
  • the number of discrete Fourier transform/discrete Fourier transform points in the data symbol portion of the WLAN system is 256, that is, there are 256 subcarriers, where subcarriers- 1, 0, 1 is DC (Direct Current, DC component), left subcarrier-122 to subcarrier-2 and right subcarrier 2 to subcarrier 122 are used to carry data information, that is, 242 subcarriers are used to carry data. information.
  • Subcarrier-128 to subcarrier-123 and subcarrier 123 to subcarrier 128 are guard bands.
  • the 242 subcarriers that are typically used to carry data information are divided into 9 sub-resource blocks, each sub-resource block including 26 sub-carriers, and the remaining 8 unused sub-carriers.
  • the sub-resource block located at the center of the bandwidth spans the DC (ie, includes sub-carriers -1, 0, 1), and the method of the embodiment of the present invention mainly relates to the allocation of 242 sub-carriers for carrying data information.
  • next-generation protocols followed by WLANs stipulate possible resource block locations for various frequency domain resources to be allocated (20 MHz, 40 MHz, 80 MHz, or 160 MHz).
  • a resource block in which a frequency domain resource of 20 MHz bandwidth may be divided is a 1*26 resource block, a 2*26 resource block, a 4*26 resource block, or a 242 resource block, where 1*26
  • the resource block indicates that 26 subcarriers are used as one resource block
  • 2*26 resource blocks indicate 52 subcarriers as one resource block
  • 4*26 resource blocks indicate 106 subcarriers as one resource block
  • 242 resource blocks represent 242 subcarriers.
  • a frequency domain resource of 20 MHz bandwidth can be composed of the above several resource blocks.
  • a resource block that may be divided into frequency domain resources of 40 MHz bandwidth is 1*26 resource block, 2*26 resource block, 4*26 resource block, 242 resource block or 2*.
  • the 80MHz bandwidth frequency domain resource may be divided into 1*26 resource block, 2*26 resource block, 4*26 resource block, 242 resource block, 2*242 resource block or one or more resources in the 996 resource block.
  • a 160 MHz bandwidth frequency domain resource may be divided into 1*26 resource blocks, 2*26 resource blocks, 4*26 resource blocks, 242 resource blocks, 2*242 resource blocks, 996 resource blocks, or 2*996 resource blocks.
  • An embodiment of the present invention provides a resource allocation method. As shown in FIG. 5, the method includes:
  • the sending end generates resource scheduling information.
  • the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the resource scheduling information further includes site information, where the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the meaning of the resource allocation bit sequence may specifically include:
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission of the first resource block. Type and number of sites using the first resource block.
  • the second bit to the fourth bit of the resource allocation bit sequence is 000,000 For indicating that the first resource block performs single-user transmission; or, the second bit to the fourth bit of the resource allocation bit sequence is 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU - MIMO transmission, and the number of stations using the first resource block is 2; or, the second bit to the fourth bit of the resource allocation bit sequence is 010, 010 is used to indicate that the first resource block is multi-user The number of stations using the first resource block is 3; or the second bit to the fourth bit of the resource allocation bit sequence is 011, 011 is used to indicate the first resource.
  • the block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4; or the second bit to the fourth bit of the resource allocation bit sequence is 100, 100 Instructing the first resource block to perform multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block is 5; or, the second bit to the fourth bit of the resource allocation bit sequence 101, 101 is used to indicate the first resource Multi-user MIMO-MIMO transmission is performed, and the number of stations using the first resource block is 6; or the second bit to the fourth bit of the resource allocation bit sequence is 110, 110 Instructing the first resource block to perform multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block is 7; or, the second bit to the fourth bit of the resource allocation bit sequence is 111, 111 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block
  • the first bit is the second identifier, it indicates that the first resource block is not a 4*26 resource block, and the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resources. Piece.
  • the first bit indicates that the first resource block is not a 4*26 resource block; if the second bit is a second identifier, it indicates that the size of the first resource block is smaller than 4*26 resource blocks, and resource allocation
  • the third bit and the fourth bit of the bit sequence are used to indicate the type of the first N resource blocks into which the frequency domain resources are divided, where N is 2, 3 or 4.
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00, which is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or, the resource allocation bit sequence
  • the third bit and the fourth bit are 01, 01 are used to indicate that the first three resource blocks to which the frequency domain resources are divided are 1*26 resource blocks, 1*26 resource blocks, and 2*26 resource blocks in sequence;
  • the third bit and the fourth bit of the resource allocation bit sequence are 10, 10 for indicating the frequency domain
  • the first three resource blocks to which the resources are divided are 2*26 resource blocks, 1*26 resource blocks, and 1*26 resource blocks; or the third bit and the fourth bit of the resource allocation bit sequence are 11, 11 is used to indicate that the first two resource blocks in which the frequency domain resources are divided are 2*26 resource blocks.
  • the first bit indicates that the first resource block is not a 4*26 resource block; if the second bit is the first identifier, it indicates that the size of the first resource block is greater than 4*26 resource blocks, and resource allocation
  • the third bit and the fourth bit of the bit sequence are used to indicate the type of the first resource block, the fifth bit of the resource allocation bit sequence is the reserved bit, and the sixth bit of the resource allocation bit sequence
  • the eighth bit is used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the first step the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or the third bit of the resource allocation bit sequence is The bit and the fourth bit are 01, 01 is used to indicate that the first resource block is a 2*242 resource block; or the third bit and the fourth bit of the resource allocation bit sequence are 10, 10 for indicating The first resource block is a 996 resource block; or the third bit and the fourth bit of the resource allocation bit sequence are 11, 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the second step: the fifth bit of the resource allocation bit sequence is a reserved bit.
  • the third step: the sixth bit to the eighth bit of the resource allocation bit sequence is 000,000 for indicating the first resource block for single-user transmission; or the sixth bit of the resource allocation bit sequence to the
  • the eight bits are 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or, the sixth of the resource allocation bit sequence
  • the number of bits to the eighth bit is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 3; or, resource allocation
  • the sixth bit to the eighth bit of the bit sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4
  • the sixth bit to the eighth bit of the resource allocation bit sequence is 100, 100 is used to indicate that the first resource block performs multi-user multiple
  • the number of sites is 5; or, resource allocation
  • the sixth bit to the eighth bit of the special sequence is 101, 101 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 6
  • the sixth bit to the eighth bit of the resource allocation bit sequence 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 7; or the sixth bit of the resource allocation bit sequence is
  • the eighth bit is 111, 111 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block is 8.
  • the meaning of the resource allocation bit sequence may specifically include:
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the resource allocation bit sequence is the first identifier, and the second bit and the third bit are the second identifier, the first three resource blocks that are allocated by the frequency domain resource are 2*26 resources in sequence. Block, 1*26 resource block, and 1*26 resource block; or,
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • the fourth bit to the sixth bit of the resource allocation bit sequence is 000,000 for indicating that the first resource block performs single-user transmission; or, the resource is divided into
  • the fourth bit to the sixth bit of the bit sequence is 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or, the fourth bit to the sixth bit of the resource allocation bit sequence is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and uses the first resource block.
  • the number of stations is 3; or the fourth bit to the sixth bit of the resource allocation bit sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and The number of stations using the first resource block is 4; or the fourth bit to the sixth bit of the resource allocation bit sequence is 100, 100 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU - MIMO transmission, and the number of stations using the first resource block is 5; or, the fourth to sixth bits of the resource allocation bit sequence are 101, 101 is used to indicate that the first resource block is multi-user Incoming multi-technology MU-MIMO transmission, and using the first capital
  • the number of stations of the block is 6; or the fourth bit to the sixth bit of the resource allocation bit sequence is 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, And the number of stations using the first resource block is 7; or the fourth bit to the sixth bit of the resource allocation bit sequence is
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • the sending end sends the resource scheduling information to the receiving end.
  • the transmitting end sends the generated resource scheduling information to the receiving end, so that the receiving end parses the resource scheduling information, and learns the specific situation in which the frequency domain resources are divided according to the resource allocation bit sequence in the resource scheduling information.
  • the embodiment of the present invention provides a resource allocation method, where the resource scheduling information is generated by the transmitting end, where the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided; Send resource scheduling information to the receiving end.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • the special resource allocation sequence additionally indicates which resource block performs MU-MIMO transmission and the number of stations transmitted on each resource block.
  • An embodiment of the present invention provides a resource allocation method. As shown in FIG. 6, the method includes:
  • the receiving end receives resource scheduling information sent by the sending end.
  • the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the resource scheduling information further includes site information, and the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the receiving end parses resource scheduling information.
  • the meaning of the resource allocation bit sequence may specifically include:
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission of the first resource block. Type and number of sites using the first resource block.
  • the second bit to the fourth bit of the resource allocation bit sequence is 000,000 for indicating that the first resource block performs single-user transmission; or the second bit of the resource allocation bit sequence is to the fourth bit.
  • the number of bits is 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or the second of the resource allocation bit sequence
  • the bit to the fourth bit is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 3; or, resource allocation bits
  • the second bit to the fourth bit of the sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4;
  • the second bit to the fourth bit of the resource allocation bit sequence is 100, 100 is used to indicate that the first resource block performs multi-user
  • the second bit to the fourth bit of the sequence is 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 7;
  • the second bit to the fourth bit of the resource allocation bit sequence is 111, 111 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and the station that uses the first resource block The number is 8.
  • the first bit is the second identifier, it indicates that the first resource block is not a 4*26 resource block, and the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resources. Piece.
  • the first bit indicates that the first resource block is not a 4*26 resource block; if the second bit is a second identifier, it indicates that the size of the first resource block is smaller than 4*26 resource blocks, and resource allocation
  • the third bit and the fourth bit of the bit sequence are used to indicate the type of the first N resource blocks into which the frequency domain resources are divided, where N is 2, 3 or 4.
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00, which is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or, the resource allocation bit sequence
  • the third bit and the fourth bit are 01, 01 are used to indicate that the first three resource blocks to which the frequency domain resources are divided are 1*26 resource blocks, 1*26 resource blocks, and 2*26 resource blocks in sequence;
  • the third bit and the fourth bit of the resource allocation bit sequence are 10, 10 are used to indicate that the first three resource blocks into which the frequency domain resources are divided are 2*26 resource blocks, 1*26 resource blocks, and 1*26 resource block; or, the third bit and the fourth bit of the resource allocation bit sequence are 11, 11 for indicating that the first two resource blocks into which the frequency domain resource is divided are 2*26 resource blocks.
  • the first bit indicates that the first resource block is not a 4*26 resource block; if the second bit is the first identifier, it indicates that the size of the first resource block is greater than 4*26 resource blocks, and resource allocation
  • the third bit and the fourth bit of the bit sequence are used to indicate the type of the first resource block, the fifth bit of the resource allocation bit sequence is the reserved bit, and the sixth bit of the resource allocation bit sequence
  • the eighth bit is used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the first step the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or the third bit of the resource allocation bit sequence is The bit and the fourth bit are 01, 01 is used to indicate that the first resource block is a 2*242 resource block; Or, the third bit and the fourth bit of the resource allocation bit sequence are 10, 10 is used to indicate that the first resource block is a 996 resource block; or the third bit and the fourth bit of the resource allocation bit sequence are The bit is 11, 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the second step: the fifth bit of the resource allocation bit sequence is a reserved bit.
  • the third step: the sixth bit to the eighth bit of the resource allocation bit sequence is 000,000 for indicating the first resource block for single-user transmission; or the sixth bit of the resource allocation bit sequence to the
  • the eight bits are 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or, the sixth of the resource allocation bit sequence
  • the number of bits to the eighth bit is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 3; or, resource allocation
  • the sixth bit to the eighth bit of the bit sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4
  • the sixth bit to the eighth bit of the resource allocation bit sequence is 100, 100 is used to indicate that the first resource block performs multi-user multiple
  • the number of sites is 5; or, resource allocation
  • the sixth bit to the eighth bit of the special sequence is 101, 101 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 6
  • the sixth bit to the eighth bit of the resource allocation bit sequence is 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and uses the first resource block.
  • the meaning of the resource allocation bit sequence may specifically include:
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the resource allocation bit sequence is the first identifier, and the second bit and the third bit are the second identifier, the first three resource blocks that are allocated by the frequency domain resource are 2*26 resources in sequence. Block, 1*26 resource block, and 1*26 resource block; or,
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • the fourth bit to the sixth bit of the resource allocation bit sequence is 000,000 for indicating that the first resource block performs single-user transmission; or the fourth bit of the resource allocation bit sequence is to the sixth bit.
  • the number of bits is 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or the fourth of the resource allocation bit sequence
  • the bit to the sixth bit is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 3; or, resource allocation bits
  • the fourth bit to the sixth bit of the sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4;
  • the fourth bit to the sixth bit of the resource allocation bit sequence is 100, 100 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the first resource block is used.
  • the fourth bit to the sixth bit of the special sequence is 101, 101 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 6
  • the fourth bit to the sixth bit of the resource allocation bit sequence is 110, 110 is used to refer to
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • the process in which the receiving end parses the resource scheduling information corresponds to the process in which the sending end generates the resource scheduling information, which is not limited in the present invention.
  • the embodiment of the present invention provides a resource allocation method, where the receiving end receives the resource scheduling information sent by the sending end, where the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource in which the frequency domain resource is divided. Block; the receiving end parses the resource scheduling information.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • the embodiment of the present invention provides a resource allocation method.
  • the resource block location that the frequency domain resource to be allocated may be divided includes a default location, where the resource block corresponding to the default location is a resource block that is not specified by the bit sequence and is specified in the next generation protocol.
  • 1 bit may be used to indicate whether the resource block of the default location is allocated for use by the user.
  • the frequency domain resource of the 20 MHz bandwidth may include a default resource block located at the center (ie, a resource block located at a default location), and the default resource block may be a resource block of a type 1*26, that is, A resource block that spans DC (subcarrier-1, 0, 1) and includes 26 subcarriers.
  • the default resource block exists in the communication system by default, and is independently allocated, that is, each resource of 20 MHz bandwidth to be allocated is divided into a default resource block of type 1*26 at its central location, and the default resource block is independently assigned to one.
  • the receiving end, and the receiving end to which the default resource block is allocated and the default resource may be the same or different, and the present invention is not particularly limited.
  • For a frequency domain resource of 20 MHz bandwidth when the receiving end to which the default resource block is allocated is the same as the receiving end to which the resource block adjacent to the left or right side of the default resource block is allocated, the frequency domain resource of the 20 MHz bandwidth is indicated. Only assigned to one user. Otherwise, the receiving end to which the default resource block is assigned is different from the receiving end to which the resource block adjacent to the left or right side of the default resource block is allocated.
  • the frequency domain resources of the 20 MHz bandwidth also include the following four types of resource blocks respectively located on the left or right side of the default resource block of the 20 MHz frequency domain resource center, namely:
  • 1*26 resource block the smallest resource block that may be divided in the frequency domain resource of 20 MHz bandwidth, indicating that one resource block is composed of one sub resource block (ie, 26 subcarriers).
  • a 2*26 resource block indicates that one resource block is composed of two sub-resource blocks (ie, 2*26 subcarriers).
  • a 4*26 resource block indicates that one resource block is composed of four sub-resource blocks (ie, 4*26 subcarriers).
  • 242 resource block the largest resource block that may be divided in the frequency domain resource of 20 MHz bandwidth, indicating that one resource block is composed of 242 subcarriers.
  • the 4*26 resource block includes 106 subcarriers, that is, 102 data subcarriers and 4 pilot subcarriers.
  • 106 subcarriers that is, 102 data subcarriers and 4 pilot subcarriers.
  • the frequency domain resource of 20 MHz bandwidth may be divided into four layers:
  • the first layer is a distribution map of 1*26 resource blocks and default resource blocks (ie, 1*26 resource blocks located at the center of the frequency domain resource of 20 MHz bandwidth), and there are 4 on the left and right sides of the default resource block located at the center respectively.
  • a 1*26 resource block that is, a resource block located at resource block position #7 to position #10 and position #11 to position #14 shown in FIG.
  • the second layer is a distribution map of the 2*26 resource block and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource of the 20 MHz bandwidth), and there are 2 on the left and right sides of the default resource block located at the center, respectively.
  • a 2*26 resource block that is, a resource block located at position #1 to position #4 shown in FIG.
  • the third layer is a distribution map of the 4*26 resource block and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource of the 20 MHz bandwidth), and has 1 on the left and right sides of the default resource block located at the center.
  • a 4*26 resource block that is, a resource block located at position #5 and position #6 shown in FIG.
  • the fourth layer is 242 resource blocks.
  • the 242 resource block includes the subcarrier in which the aforementioned symmetric center is located.
  • the frequency domain resource of the 20 MHz bandwidth includes 242 subcarriers, which may be divided into any resource blocks in the first layer to the third layer in FIG. 8, and the divided resource blocks are allocated to multiple users. Also, each user can only allocate one of the divided resource blocks.
  • the frequency domain resource spectrum of the 20 MHz bandwidth may be divided into resource blocks in the fourth layer.
  • the frequency domain resource of the 20 MHz bandwidth is allocated to one user, and the bandwidth indication information and the bandwidth information described later may be used.
  • the single user transmission indication bit indicates the case of resource allocation.
  • the frequency spectrum resource spectrum of the 20 MHz bandwidth may be divided into resource blocks in the fourth layer.
  • the frequency domain resource of the 20 MHz bandwidth is allocated to multiple users for MU-MIMO transmission, and The case of resource allocation is indicated by the bandwidth indication information and the multi-user transmission indication bit described later.
  • the resource allocation method provided by the embodiment of the present invention mainly relates to a case where a frequency domain resource of a 20 MHz bandwidth is composed of any one of the first to third layers and is allocated to multiple users.
  • the frequency domain resource of the 20 MHz bandwidth is any combination of resource blocks in the first layer to the third layer in the first to third layers, and the size of all the resource blocks is combined.
  • the sum is 20 MHz, as shown in the shaded portion of Figure 9 or Figure 10.
  • FIG. 11 shows a resource allocation method of a frequency domain resource of a 20 MHz bandwidth.
  • the frequency domain resources in order from left to right in FIG. 11 are divided into two 2*. 26 resource blocks (ie, resource block #1 and resource block #2 in FIG. 10), a 1*26 resource block (ie, resource block #0 in FIG. 10, which is a default resource block), and a 4*26 resource block ( That is, resource block #3) in FIG.
  • FIG. 12 shows another resource allocation method of a frequency domain resource of 20 MHz bandwidth.
  • the frequency domain resources in order from left to right in FIG. 12 are divided into one.
  • *26 resource block ie, resource block #1 in FIG. 10
  • three 1*26 resource blocks ie, resource block #9, resource block #10, and resource block #11 in FIG. 10, where resource block #11 It is composed of a default resource block
  • resource block #11 It is composed of a default resource block
  • a 4*26 resource block ie, resource block #6 in FIG. 10
  • the frequency domain resource to be allocated includes a symmetric center.
  • the frequency domain resource of the 20 MHz bandwidth includes a resource block located at the center (ie, the resource block of the default location), and the resource blocks on both sides of the resource block located at the center are symmetrically distributed, that is, The centrally located resource block can serve as a symmetric center for frequency domain resources of 20 MHz bandwidth.
  • the frequency domain resource of 40 MHz bandwidth can be regarded as composed of two frequency domain resources of 20 MHz bandwidth.
  • the frequency domain resources of each 20 MHz bandwidth may include a default resource block located in the frequency domain resource center of the 20 MHz bandwidth (ie, the default resource block)
  • the resource block of the location), and the configuration and allocation manner of the default resource block (two in total) in the frequency domain resource of the 40 MHz bandwidth is similar to the configuration and allocation mode of the default resource block in the frequency domain resource of the 20 MHz bandwidth.
  • a detailed description thereof will be omitted.
  • the frequency domain resources of the 40 MHz bandwidth further include the following five types of resource blocks to the left or right of the center frequency of the frequency domain resources of the 40 MHz bandwidth, namely:
  • 1*26 resource block the smallest resource block that may be divided in the frequency domain resource of 40 MHz bandwidth, indicating that one resource block is composed of one sub resource block (ie, 26 subcarriers).
  • a 2*26 resource block indicates that one resource block is composed of two sub-resource blocks (ie, 2*26 subcarriers).
  • a 4*26 resource block indicates that one resource block is composed of four sub-resource blocks (ie, 4*26 subcarriers).
  • 242 resource blocks indicating that one resource block is composed of 242 subcarriers.
  • 2*242 resource block the largest resource block that may be divided in the frequency domain resource of 40 MHz bandwidth, indicating that one resource block is composed of 2*242 subcarriers.
  • the frequency domain resources of 40 MHz bandwidth may be divided into five layers:
  • the first layer is a distribution map of 1*26 resource blocks and default resource blocks (ie, 1*26 resource blocks located at the center of the frequency domain resource for each 20 MHz bandwidth), at the left of the default resource block located at each center.
  • On the right side there are 4 1*26 resource blocks respectively, wherein the distribution of 8 1*26 resource blocks in the frequency domain resources per 20 MHz bandwidth is the same as the 1*26 resource blocks shown in the first layer in FIG.
  • the distribution is similar, and the detailed description thereof is omitted here to avoid redundancy.
  • the second layer is a distribution map of 2*26 resource blocks and default resource blocks (ie, 1*26 resource blocks each located in the center of the frequency domain resource of 20MHz bandwidth), on the left and right sides of the default resource block located in each center.
  • There are two 2*26 resource blocks for example, position #E and position #F in FIG. 13), wherein the distribution of four 2*26 resource blocks per 20 MHz bandwidth is the same as the second layer in FIG.
  • the distribution of the 2*26 resource blocks shown is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the third layer is a distribution map of the 4*26 resource block and the default resource block (ie, 1*26 resource blocks located at the center of the frequency domain resource of each 20 MHz bandwidth), on the left and right sides of the default resource block located in each center.
  • There are 1 4*26 resource blocks for example, position #C and position #D in FIG. 13), wherein the distribution of 4*26 resource blocks per 20 MHz bandwidth is shown in the third layer of FIG.
  • the distribution of 4*26 resource blocks is similar.
  • in order to avoid redundancy detailed description thereof will be omitted.
  • the fourth layer is a 242 resource block distribution map.
  • the fifth layer is a 2*242 resource block distribution map.
  • the frequency domain resource of the 40 MHz bandwidth includes 484 subcarriers, and may be divided into any resource blocks in the first layer to the fourth layer in FIG. 13, and the divided resource blocks are allocated to multiple users. Also, each user can only allocate one of the divided resource blocks.
  • the frequency domain resource spectrum of the 40 MHz bandwidth may be divided into resource blocks in the fifth layer.
  • the frequency domain resource of the 40 MHz bandwidth is allocated to one user, and the bandwidth indication information and the following may be used.
  • the single user transmission indication bit indicates the case of resource allocation.
  • the exemplary frequency domain resource spectrum of the 40 MHz bandwidth may be divided into resource blocks in the fifth layer.
  • the frequency domain resource of the 40 MHz bandwidth is allocated to multiple users for MU-MIMO transmission, and The case of resource allocation is indicated by the bandwidth indication information and the multi-user transmission indication bit described later.
  • the resource allocation method provided by the embodiment of the present invention mainly relates to a case where a frequency domain resource of a 40 MHz bandwidth is composed of any one of the first to fourth layers and is allocated to multiple users.
  • the frequency domain resource of the 40 MHz bandwidth is any combination of the resource blocks of the first layer to the fourth layer in the first layer to the fourth layer, and the size of all the resource blocks is combined.
  • the sum is 40 MHz, as shown in the shaded portion of Figure 14 or Figure 15.
  • FIG. 16 shows a resource allocation method of frequency domain resources of 40 MHz bandwidth.
  • the frequency domain resources (in order from left to right in FIG. 16) are divided into two 2*. 26 resource blocks (ie, resource block #E and resource block #F in FIG. 13), a 1*26 resource block (ie, resource block #0), which is a default resource block), and a 4*26 resource block (ie, FIG. 13) Resource block #D) and a 242 resource block (ie, resource block #B in Figure 13).
  • the frequency domain resource to be allocated includes a symmetric center.
  • the resource blocks on both sides of the frequency domain resource center frequency of the 40 MHz bandwidth are symmetrically distributed, that is, the center frequency point can serve as a symmetric center of the frequency domain resource of 40 MHz bandwidth.
  • the resource block location that the to-be-assigned frequency domain resource may be divided includes a default location, where the resource block corresponding to the default location is a resource block that is not specified by the bit sequence and is specified in the next-generation protocol.
  • 5 bits are respectively used to indicate whether resource blocks of the five default locations under the bandwidth are allocated for use by the user.
  • the frequency domain resource of the 80 MHz bandwidth may include a default resource block located at the center (ie, a resource block located at a default location), and the default resource block may be a 1*26 resource block, that is, a cross-DC. (Subcarrier-1, 0, 1) and includes resource blocks of 26 subcarriers.
  • the default resource block exists by default in the communication system, and is independently allocated, that is, each resource of the 80 MHz bandwidth to be allocated is divided into a default resource block of 1*26 size at its central location, and the default resource block is independently assigned to one.
  • the receiving end, and the receiving end to which the default resource block is allocated and the resource block to which the resource block adjacent to the left or the right side of the default resource block is allocated may be the same or different, and the present invention is not particularly limited.
  • For a frequency domain resource of 80 MHz bandwidth when the receiving end allocated by the default resource block is the same as the receiving end to which the resource block adjacent to the left or right side of the default resource block is allocated, the frequency domain resource of the 80 MHz bandwidth is indicated. Only assigned to one user. Otherwise, the receiving end to which the default resource block is assigned is different from the receiving end to which the resource block adjacent to the left or right side of the default resource block is allocated.
  • the frequency domain resource of the 80 MHz bandwidth can be regarded as consisting of two frequency domain resources of 40 MHz bandwidth and one default resource block located at the symmetric center, and each frequency domain resource of 40 MHz bandwidth can be regarded as a frequency domain of two 20 MHz bandwidths.
  • the resource composition correspondingly, the frequency domain resource of each 20 MHz bandwidth may include a default resource block (ie, a resource block located at a default location) located in the frequency domain resource center of the 20 MHz bandwidth.
  • the frequency domain resources of the 80 MHz bandwidth include the following six types of resource blocks to the left or right of the default resource block of the frequency domain resource center of the 80 MHz bandwidth, namely:
  • 1*26 resource block the smallest resource block that may be divided among frequency domain resources of 80 MHz bandwidth, indicating that one resource block is composed of one sub resource block (ie, 26 subcarriers).
  • a 2*26 resource block indicates that one resource block is composed of two sub-resource blocks (ie, 2*26 subcarriers).
  • a 4*26 resource block indicates that one resource block is composed of four sub-resource blocks (ie, 4*26 subcarriers).
  • 242 resource blocks indicating that one resource block is composed of 242 subcarriers.
  • a 2*242 resource block indicates that one resource block is composed of 2*242 subcarriers.
  • 996 resource block the largest resource block that may be divided in the frequency domain resource of 80 MHz bandwidth, indicating that one resource block is composed of 996 subcarriers.
  • the frequency domain resources of the 80 MHz bandwidth may be divided into six layers:
  • the first layer is a distribution map of 1*26 resource blocks and default resource blocks (ie, 1*26 resource blocks located at the center of the frequency domain resource of each 20 MHz bandwidth and 1*26 resource blocks located at the center of the 80 MHz bandwidth).
  • the distribution of the 1*26 resource block shown in the first layer in FIG. 8 is similar, and the detailed description thereof will be omitted herein to avoid redundancy.
  • the second layer is a 2*26 resource block and a default resource block (ie, 1*26 resource blocks located at the center of the frequency domain resource of the 20 MHz bandwidth and 1*26 resource blocks located at the center of the frequency domain resource of the 80 MHz bandwidth).
  • Distribution map, the left and right of the default resource block of the frequency domain resource center location per 20MHz bandwidth There are two 2*26 resource blocks on the side, respectively, wherein the distribution of four 2*26 resource blocks in each 20MHz bandwidth is similar to the distribution of the 2*26 resource blocks shown in the second layer in Figure 8, here, in order to avoid The details are omitted.
  • the third layer is a 4*26 resource block and a default resource block (ie, 1*26 resource block located at the center of the frequency domain resource of each 20 MHz bandwidth and 1*26 resource block located at the center of the frequency domain resource of the 80 MHz bandwidth)
  • the distribution map has a 4*26 resource block on each of the left and right sides of the default resource block of the frequency domain resource center position of each 20 MHz bandwidth, wherein the distribution of 4*26 resource blocks in each 20 MHz bandwidth is the same as that in FIG.
  • the distribution of the 4*26 resource blocks shown in the third layer is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the fourth layer is a distribution map of the 242 resource block distribution map and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource of the 80 MHz bandwidth), and is located at the center frequency of the frequency domain resource located in each 40 MHz bandwidth.
  • the distribution of the 242 resource blocks shown in the layer is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the fifth layer is a distribution map of the 2*242 resource block distribution map and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource of the 80 MHz bandwidth), and the default resource at the center of the frequency domain resource located in the 80 MHz bandwidth.
  • the distribution of the 242 resource blocks shown in the fifth layer is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the sixth layer is the 996 resource block distribution map.
  • the frequency domain resource of the 80 MHz bandwidth includes 996 subcarriers, and may be divided into any resource blocks in the first layer to the fifth layer in FIG. 17, and the divided resource blocks are allocated to multiple users. Also, each user can only allocate one of the divided resource blocks.
  • the frequency domain resource spectrum of the 80 MHz bandwidth may be divided into resource blocks in the sixth layer.
  • the frequency domain resource of the 80 MHz bandwidth is allocated to one user, and the bandwidth indication information and the following may be used.
  • the single user transmission indication bit indicates the case of resource allocation.
  • the frequency domain resource spectrum of the 80 MHz bandwidth can be divided into the resources in the sixth layer.
  • the source block, in this case, the frequency domain resource of the 80 MHz bandwidth is allocated to a plurality of users for MU-MIMO transmission, and the resource allocation may be indicated by the bandwidth indication information and the multi-user transmission indication bit described later.
  • the resource allocation method provided by the embodiment of the present invention mainly relates to a case where a frequency domain resource of an 80 MHz bandwidth is composed of any one of the first to fifth layers and is allocated to multiple users.
  • the frequency domain resource of the 80 MHz bandwidth is any combination of resource blocks in the first layer to the fifth layer in the first to fifth layers, and the size of all the resource blocks is combined.
  • the sum is 80 MHz, as shown in the shaded portion in Fig. 18 or Fig. 19.
  • FIG. 20 shows a resource allocation method of frequency domain resources of 80 MHz bandwidth.
  • the frequency domain resources (in order from left to right in FIG. 20) are divided into one 4*26.
  • the frequency domain resource to be allocated includes a symmetric center.
  • the frequency domain resource of the 80 MHz bandwidth includes a resource block located at the center (ie, the resource block of the default location), and the resource blocks on both sides of the resource block located at the center are symmetrically distributed. That is, the centrally located resource block can serve as a symmetric center of the frequency domain resource of the 80 MHz bandwidth.
  • the 160MHz bandwidth frequency domain resource can be regarded as composed of two 80MHz bandwidth frequency domain resources.
  • each 80MHz bandwidth frequency domain resource may include a default resource block located in the frequency domain resource center of the 80MHz bandwidth (ie, the default resource block).
  • the resource block of the location), and the frequency domain resource of each 20 MHz bandwidth in the 160 MHz bandwidth frequency domain resource may include a default resource block (ie, a resource block located at a default location) located in the frequency domain resource center of the 20 MHz bandwidth.
  • 10 bits are respectively used to indicate whether resource blocks of the 10 default locations in the bandwidth are respectively allocated to the user.
  • the 160MHz bandwidth frequency domain resources also include the following seven types of resource blocks located to the left or right of the 160MHz frequency domain resource center frequency point, namely:
  • 1*26 resource block the smallest resource block that may be divided among frequency domain resources of 160 MHz bandwidth, Indicates that a resource block consists of one sub-resource block (ie, 26 sub-carriers).
  • a 2*26 resource block indicates that one resource block is composed of two sub-resource blocks (ie, 2*26 subcarriers).
  • a 4*26 resource block indicates that one resource block is composed of four sub-resource blocks (ie, 4*26 subcarriers).
  • 242 resource blocks indicating that one resource block is composed of 242 subcarriers.
  • a 2*242 resource block indicates that one resource block is composed of 2*242 subcarriers.
  • a 996 resource block indicates that one resource block is composed of 996 subcarriers.
  • 2*996 resource block the largest resource block that may be divided among 160 MHz frequency domain resources, indicating that one resource block is composed of 2*996 subcarriers.
  • a frequency domain resource of 160 MHz bandwidth may be divided into seven layers:
  • the first layer is a distribution map of 1*26 resource blocks and default resource blocks (ie, 1*26 resource blocks located at the center of the frequency domain resource per 20 MHz bandwidth and 1*26 resource blocks located at the center of each 80 MHz bandwidth).
  • the distribution of the 1*26 resource blocks shown in the first layer is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the second layer is a 2*26 resource block and a default resource block (ie, 1*26 resource block located at the center of the frequency domain resource per 20 MHz bandwidth and 1*26 resource block located at the center of the frequency domain resource per 80 MHz bandwidth) Distribution map, there are two 2*26 resource blocks on the left and right sides of the default resource block of the frequency domain resource center position per 20MHz bandwidth, wherein the distribution and graph of 2*26 resource blocks in the frequency domain resources per 20MHz bandwidth.
  • the distribution of the 2*26 resource blocks shown in the second layer in 8 is similar, and a detailed description thereof will be omitted herein to avoid redundancy.
  • the third layer is a 4*26 resource block and a default resource block (ie, 1*26 resource block located at the center of the frequency domain resource per 20 MHz bandwidth and 1*26 resource block located at the center of the frequency domain resource per 80 MHz bandwidth)
  • the distribution map has a 4*26 resource block on each of the left and right sides of the default resource block of the frequency domain resource center location of each 20 MHz bandwidth, wherein the distribution of 4*26 resource blocks in the frequency domain resource per 20 MHz bandwidth is
  • the distribution of 4*26 resource blocks shown in the third layer in Figure 8 is similar, here, to avoid The detailed description is omitted.
  • the fourth layer is a distribution map of the 242 resource block distribution map and the default resource block (ie, 1*26 resource blocks located at the center of the frequency domain resource per 80 MHz bandwidth), at the frequency center of the frequency domain resource located at each 40 MHz bandwidth.
  • the detailed description is omitted.
  • the fifth layer is a distribution map of the 2*242 resource block distribution map and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource per 80 MHz bandwidth), and is the default at the center of the frequency domain resource located in the 80 MHz bandwidth.
  • the detailed description is omitted.
  • the sixth layer is a distribution map of the 996 resource block distribution map and the default resource block (ie, 1*26 resource block located at the center of the frequency domain resource per 80 MHz bandwidth), and the left and right of the frequency domain resource center point located in the 160 MHz bandwidth.
  • detailed description thereof is omitted. .
  • the seventh layer is a 2*996 resource block distribution map.
  • the frequency domain resource of 160 MHz bandwidth includes 2*996 subcarriers, and may be divided into any resource blocks from the first layer to the sixth layer, and the divided resource blocks are allocated to multiple users, and Each user can only allocate one of the divided resource blocks.
  • the frequency domain resource spectrum of the 160 MHz bandwidth may be divided into resource blocks in the seventh layer.
  • the 160 MHz bandwidth frequency domain resource is allocated to one user, and the bandwidth indication information and the following may be used.
  • the single user transmission indication bit indicates the case of resource allocation.
  • the frequency spectrum resource spectrum of the 160 MHz bandwidth may be divided into resource blocks in the seventh layer.
  • the 160 MHz bandwidth frequency domain resource is allocated to multiple users for MU-MIMO transmission, and The case of resource allocation is indicated by the bandwidth indication information and the multi-user transmission indication bit described later.
  • the resource allocation method provided by the embodiment of the present invention mainly relates to a case where a frequency domain resource of a 160 MHz bandwidth is composed of any one of the first to sixth layers and is allocated to multiple users.
  • the frequency domain resource of the 160 MHz bandwidth is any combination of the resource blocks of the first layer to the third layer in the first layer to the sixth layer, and the size of all the resource blocks is combined.
  • the sum is 160 MHz, as shown in the shaded portions in Figures 22 and 23.
  • the frequency domain resource to be allocated includes a symmetric center.
  • the resource blocks on the left and right sides of the center frequency point of the frequency domain resource of the 160 MHz bandwidth are symmetrically distributed, that is, the center frequency point can serve as a symmetric center of the frequency domain resource of 160 MHz bandwidth.
  • the above describes the resource block positions in which various frequency domain resources to be allocated may be divided.
  • the following describes the process of generating resource scheduling information based on the resource block positions that may be divided.
  • the number of stations actually divided into resource blocks is 1, and if it is MU-MIMO transmission, the resource blocks actually divided into The maximum number of sites is 8 and the minimum is 2.
  • the minimum resource block for performing MU-MIMO transmission is 4*26 type, so the number of stations whose resource block size is smaller than 4*26 resource blocks defaults to 1, and the number of stations greater than or equal to 4*26 resource blocks is The number is uncertain, the minimum is 1 and the maximum is 8.
  • the method for generating resource scheduling information by using the first identifier is 1 and the second identifier is 0.
  • the method includes:
  • the sender acquires at least one resource block in which the frequency domain resource is divided.
  • the sending end determines whether the first resource block is a 4*26 resource block, where the first resource block is the first resource block into which the frequency domain resource is divided.
  • the frequency domain resource with a bandwidth of 20 MHz and the first resource block are the leftmost first resource block, and the frequency domain resource of the 20 MHz bandwidth can be a symmetric center with 1*26 resource blocks.
  • the block division is described.
  • the first bit indicates whether the resource block actually divided is a 4*26 resource block.
  • the sending end sets the first bit of the resource allocation bit sequence as the first identifier, and sets the second bit to the fourth bit of the resource allocation bit sequence. Bit.
  • the sender sets a resource allocation bit sequence.
  • the second bit to the fourth bit is 000,000 for indicating the first resource block for single-user transmission; or, the transmitting end sets the second bit to the fourth bit of the resource allocation bit sequence 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 2; or, the transmitting end sets the second bit of the resource allocation bit sequence
  • the bit to the fourth bit is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 3; or, the sender sets resources.
  • the second bit to the fourth bit of the allocated bit sequence is 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 4; or, the sender sets the second bit of the resource allocation bit sequence to the fourth bit is 100, 100 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and uses the The number of sites in a resource block is 5 Or, the sending end sets the second bit to the fourth bit of the resource allocation bit sequence to be 101, 101 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and uses the first resource.
  • the number of stations of the block is 6; or, the sender sets the second bit of the resource allocation bit sequence to the fourth bit is 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU- MIMO transmission, and the number of stations using the first resource block is 7; or, the transmitting end sets the second bit to the fourth bit of the resource allocation bit sequence to be 111, 111 is used to indicate that the first resource block is more
  • the user multi-input and multi-technology MU-MIMO transmission, and the number of stations using the first resource block is 8.
  • the sending end sets the first bit of the resource allocation bit sequence as the second identifier, and determines whether the size of the first resource block is greater than the 4*26 resource block.
  • the sending end sets the second bit of the resource allocation bit sequence as the second identifier, and sets the third bit and the fourth of the resource allocation bit sequence. Bits.
  • the resource block actually divided is not a 4*26 resource block
  • the second bit indicates whether the size of the actually divided resource block is greater than 4*26 resource blocks.
  • the resource block that is actually divided can be determined by using Table 1.
  • the third bit and the fourth bit of the resource allocation bit sequence are set by the transmitting end to be 00, 00, which is used to indicate that the frequency domain resource is divided before Four resource blocks are 1*26 a resource block; or, the third bit and the fourth bit of the resource allocation bit sequence are set to 01, 01 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 1*26 resource blocks, 1*26 resource block and 2*26 resource block; or, the third bit and the fourth bit of the resource allocation bit sequence set by the transmitting end are 10, 10 are used to indicate the first three resources in which the frequency domain resource is divided.
  • the block is 2*26 resource block, 1*26 resource block and 1*26 resource block in turn; or the third bit and the fourth bit of the resource allocation bit sequence are set at the transmitting end to be 11, 11 for indicating frequency
  • the first two resource blocks to which the domain resource is divided are 2*26 resource blocks.
  • the order of the resource blocks that are actually divided above may also be from right to left, and the present invention is not limited. It can be understood that the bit sequence corresponding to the resource block actually divided in the present invention can also be swapped.
  • the spectrum on the right side of the symmetric center 1*26 resource block is indicated by the resource bit sequence indication method in which the left spectrum resource is actually divided.
  • the sending end sets the second bit of the resource allocation bit sequence as the first identifier, and sets the third bit of the resource allocation bit sequence to the eighth. Bits.
  • the resource block actually divided can be determined by Table 2.
  • the third bit and the fourth bit of the sequence are 10, 10 is used to indicate that the first resource block is a 996 resource block; or the third bit and the fourth bit of the resource allocation bit sequence are set by the transmitting end. 11,11 is used to indicate that the first resource block is a 2*996 resource block. It can be understood that the bit sequence corresponding to the resource block actually divided in the present invention can also be swapped.
  • the second bit "1" indicates that the size of the resource block actually divided is larger than 4*26 resource blocks.
  • the resource blocks that are actually divided can also be represented by logical bits, and no table needs to be stored.
  • the third bit indicates whether the resource block actually divided is a 996 resource block, and when the third bit "0" indicates that the actually partitioned resource block is not a 996 resource block, the fourth bit indicates whether the actually partitioned resource block is 2 or not *242 resource blocks.
  • the spectrum resource on the right side of the symmetric center 1*26 resource block is also divided, so the symmetric center 1*26 resource
  • the 4 bits to the right of the block can be used to indicate the number of stations transmitted on the actually partitioned resource block.
  • the fifth bit of the resource allocation bit sequence is set by the transmitting end as a reserved bit.
  • the transmitting end sets the sixth bit to the eighth bit of the resource allocation bit sequence to 000,000 for indicating the first resource block for single-user transmission; or the transmitting end sets the sixth bit of the resource allocation bit sequence.
  • the eighth bit is 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 2; or, the sender sets resource allocation
  • the sixth bit to the eighth bit of the bit sequence is 010, 010 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 3
  • the transmitting end sets the sixth bit to the eighth bit of the resource allocation bit sequence to be 011, 011 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and uses the first The number of stations of the resource block is 4; or the sender sets the sixth bit to the eighth bit of the resource allocation bit sequence to be 100, 100 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU - MIMO transmission, and Number of sites using the first resource block 5; or, the sender sets the sixth bit to the eighth bit of the
  • the number of stations in the MU-MIMO transmission and using the first resource block is 7; or the sixth bit to the eighth bit of the resource allocation bit sequence is set to 111, 111 is used to indicate the first resource.
  • the block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 8.
  • the 8 bits of the resource allocation bit sequence and the actual partitioned resource blocks indicated thereby can be simply represented in a table. As shown in Table 3 below, 8 bits collectively indicate 256 resource allocation bit sequences.
  • the number of transmitted stations is n; 2x996(n) indicates 2*996 resource blocks, and the number of stations transmitted on the resource is n.
  • the resource allocation sequence indicating the resource blocks that are actually divided is the resource allocation bit sequence 1 in the following table. If the first identifier of the 5th bit is 0, the second identifier is 1, and all other bits are 1 with the first identifier and the second identifier is 0, indicating that the resource allocation sequence of the actually partitioned resource block is The shaded resource allocation bit sequence of the table 2. It can be understood that the first identifier and the second identifier of each bit have different values, indicating that the resource allocation sequence of the actually divided resource blocks is a different sequence, and the corresponding table is also different.
  • the present invention is not limited to the resource allocation bit sequence 1 and the resource allocation bit sequence 2 in the table.
  • the value of the first identifier and the second identifier of the fifth reserved bit (referring to the fifth bit when the second bit is the first value) also causes the resource allocation bit sequence in the table to be different.
  • the resource allocation bit sequence 1 and the resource allocation bit sequence 2 are both adopted: when the fifth bit reserved bit is 1, the sixth bit to the eighth bit are reserved bits; when the fifth bit is pre- When the reserved bit is 0, the sixth bit to the eighth bit indicate the number of stations transmitted on the first resource block.
  • the resource allocation bit sequence generated by dividing the spectrum resource block of the 20 MHz bandwidth is “1010 1000”, and the meaning of the resource allocation bit sequence is illustrated by taking the first 4 bits “1010” as an example.
  • the bit "1” indicates that the spectrum resource on the left side of the symmetric center 1*26 resource block is actually divided into 4*26 resource blocks, and the last three bits "010" indicate that the number of stations transmitted on the 4*26 resource block is three.
  • the resource allocation bit sequence generated after the division of the spectrum resource block shown in FIG. 25 is 129 of the resource allocation bit sequence 1 in Table 3, and the resource allocation bit sequence generated after the division of the spectrum resource block is indicated as “1010 1000”.
  • the spectrum resource block is actually divided into symmetric centers.
  • the spectrum resources on the left side of the resource block are actually divided into 4*26 resource blocks, and the number of stations transmitted on the resource block is 3, which is MU-MIMO transmission, symmetric center.
  • the spectrum resource on the left side of the 1*26 resource block is actually divided into 4*26 resource blocks, and the number of stations transmitted on the resource block is 1.
  • the resource allocation bit sequence generated by the spectrum resources of the first 20 MHz and the second 20 MHz bandwidth after the spectrum resource of the 40 MHz bandwidth is divided is “0101Y110”, where Y represents the reserved bit. .
  • the first bit “0” indicates that the spectrum resource on the left side of the symmetric center 1*26 resource block is actually divided into non-4*26 resource blocks, and the second bit “1” indicates that the spectrum resource on the left side of the symmetric center 1*26 resource block is actually divided. More than 4*26 resource blocks.
  • the 3rd to 4th bits "01" indicate that the spectrum resource on the left side of the symmetric center 1*26 resource block is actually divided into 2*242 resource blocks.
  • the last three bits "110" indicate that the number of stations actually transmitted on the 2*242 resource block is 7.
  • the resource allocation bit sequence generated after the first 20 MHz and the second 20 MHz spectrum resource block shown in FIG. 26 is divided into 55 in the resource allocation bit sequence 1 in the table, indicating the resource generated after the spectrum resource block is divided.
  • the allocation bit sequence is "0010 0110", and the two 20M spectrum resource blocks are actually divided into 2*242 resource blocks (also referred to as 484 resource blocks), and the number of stations transmitted on the resource block is 7.
  • the spectrum resource block of the 80 MHz bandwidth is actually divided into resource blocks, and the resource allocation bit sequence generated by the first 20 MHz bandwidth spectrum resource is “1000 1000”, and the second 20 MHz bandwidth
  • the resource allocation bit sequence generated by the spectrum resource is “0100 Y 000”, and the resource allocation bit sequence generated by the spectrum resources of the third and fourth 20 MHz bandwidths is “0101 Y 101”.
  • the resource allocation bit sequence generated after the first 20 MHz spectrum resource block shown in FIG. 27 is divided into 97 in the resource allocation bit sequence 1 in the table, indicating that the resource allocation bit sequence generated after the spectrum resource block is divided is “ 1000 1000”, the spectrum resource block is actually divided into 4*26 resource blocks, 1*26 resource blocks and 4*26 resource blocks (from left to right), and the number of stations transmitted on two 4*26 resource blocks Both are 1.
  • the resource allocation bit sequence generated after the second 20 MHz spectrum resource block is divided into 33 in the resource allocation bit sequence 1 in the table, indicating that the resource allocation bit sequence generated after the spectrum resource block is divided is “0100 0000”,
  • the spectrum resource block is actually divided into 242 resource blocks, and the number of stations transmitted on the resource block is 1.
  • the resource allocation bit sequence generated after the third 20 MHz and the fourth 20 MHz spectrum resource block are divided is 54 of the resource allocation bit sequence 1 in the table, indicating that the resource allocation bit sequence generated after the spectrum resource block is divided is “ 0101 0101", the two 20M spectrum resource blocks are actually divided into 2*242 resource blocks, and the number of stations transmitted on the resource block is 6.
  • the resource block 2x996 resource block (also referred to as 2*996 resource block) corresponding to the maximum bandwidth of 160 MHz may be indicated in the HE-SIGA field, and the sequence numbers in Table 3 are 81 to 88 as a reserved sequence, for a total of 8. At this time, there are 124 reserved sequence numbers, that is, 132 resource allocation bit sequences indicating that the spectrum resource block is actually divided, wherein the resource block indicating that the spectrum resource block is actually divided has a bit sequence of the intermediate 1*26 resource block. There are 108, and the resource block indicating that the spectrum resource block is actually divided does not contain the intermediate 1*26 resource block. There are 32 kinds of 242(n), 484(n), and 996(n) in Table 3.
  • the present invention uses a reserved bit to indicate whether a 1*26 resource block is used (whether or not it is allocated to a station), since the resource block in which the indicated spectrum resource block is actually divided has 108 bit sequences of intermediate 1*26 resource blocks, so corresponding 108 reserved bits are required to indicate the actual division of the spectrum in 108 above.
  • the intermediate resource block 1*26 resource block in the case is not used.
  • a separate "x" in the table indicates that the intermediate resource block 1*26 resource block is not used.
  • the resource allocation bit sequence 1 and the resource allocation bit sequence 2 are the same as the table 3, but the reserved sequence is used to indicate that the intermediate resource block 1*26 resource block in the case where the spectrum is actually divided is not used, wherein the actual division of the spectrum
  • the case where the intermediate resource block 1*26 resource block in the case is not used is the shaded portion of the "resource block (from left to right) actually divided" in Table 4.
  • the resource allocation bit sequence 1 and the resource allocation bit sequence 2 in Table 3 or Table 4 are both selected, that is, the protocol specifies or one of the resource allocation bit sequences stored in the product should be stored. , or other possible deformations. For a resource block that is actually divided, only one resource allocation bit sequence (or sequence) is associated with it, so that the receiving end can learn the actual divided resource block according to the resource allocation bit sequence.
  • the reserved bits in Table 3 or Table 4 can also be used to indicate the HE-SIGB site information load balancing special case on the HE-SIG-B20M, such as the resource allocation bit sequence reserved by the sequence number 81 ( Another resource allocation special sequence indicating the 484 resource block indicates that the number of station information corresponding to the resource allocation bit sequence in the 20M HE-SIGB where the reserved resource allocation bit sequence is located is 0, and the reserved number is 82.
  • the resource allocation bit sequence (the special sequence for assigning another resource to the 996 resource block) indicates that the number of site information corresponding to the resource allocation bit sequence in the 20-M HE-SIGB where the reserved resource allocation bit sequence is located is 0;
  • the reserved bits in Table 3 or Table 4 may also be other available cases, and the invention is not limited thereto.
  • the 8 bits of the resource allocation bit sequence and the actually divided resource blocks indicated thereby may also be generated by using the working principle diagrams (flowcharts) of FIGS. 41a, 41b and 41c to generate a resource allocation bit sequence or Parse the resource allocation bit sequence.
  • 26 indicates a 1*26 resource block
  • 52 indicates a 2*26 resource block
  • 106 indicates a 4*26 resource block
  • 242 indicates a 242 resource block
  • 484 indicates a 2*242 resource block
  • 996 indicates a 996 resource.
  • Block, 2x996 indicates 2*996 resource blocks.
  • Figure 41a is a process of generating or parsing the first 4 bits of an 8-bit resource allocation bit sequence, where "x" represents the bit to be generated or parsed in the first 4 bits, "-" represents the last 4 bits, and there are 2 in the flowchart Exit: 1.
  • the resource block is greater than 106 resource blocks; 2. Generate or read the 5th to 8th bit resource indication (indicating the right resource block).
  • Fig. 41b the second exit of Fig. 41a is used as an entry, illustrating the generation or parsing process of the last 4 bits, where "x" represents the bit to be generated or parsed in the last 4 bits, and "-" represents the first 4 bits.
  • Fig. 41c the first exit of Fig. 41a is used as an entry, illustrating the generation or parsing process of the last 4 bits, where "x" represents the bit to be generated or parsed in the last 4 bits, and "-" represents the first 4 bits.
  • a reserved sequence is a reserved sequence, wherein the reserved sequence can be used to indicate retention
  • a source allocation bit sequence (such as a special resource allocation sequence indicating a 484 resource block or a special resource allocation sequence indicating a 996 resource block) carries the site information corresponding to the resource allocation bit sequence in the 20M HE-SIGB in which the resource allocation bit sequence is located. The number is 0. If you use '0111, 0yyy', the reserved sequence can be used to indicate retention.
  • Figs. 41a, 41b and 41c are one of the examples. If the first identifier and the second identifier of each bit in the resource allocation sequence are different, the corresponding value of the flowchart will be changed accordingly, similar to the possible variant of the resource allocation sequence in Table 3 or Table 4.
  • the first identifier of the fifth bit takes the value 0 and the second identifier takes the value 1.
  • the first bit of the other bit takes the value 1 and the second identifier takes the value 0.
  • the resource allocation bit sequence generated after the spectrum resource block is divided is a table.
  • the resource allocation bit sequence 2 in 3; the first identifier of all the bits takes the value 1 and the second identifier takes the value 0, and the resource allocation bit sequence generated after the spectrum resource block is divided is the resource allocation bit sequence 1 in Table 3.
  • the number of stations that are actually divided into resource blocks is 1. If it is MU-MIMO transmission, the number of stations that are actually divided into resource blocks is at most 8, and the minimum is 2.
  • the minimum resource block for performing MU-MIMO transmission is 242 resource blocks, so the number of stations whose resource block size is smaller than 242 resource blocks defaults to 1, and the number of resource blocks greater than or equal to 4*26 is uncertain and minimum. It is 1, and the maximum is 8.
  • the method for generating resource scheduling information by using the first identifier is 1 and the second identifier is 0, and the method includes:
  • the sender acquires at least one resource block in which the frequency domain resource is divided.
  • the transmitting end generates a resource allocation bit sequence according to at least one resource block that is divided by the frequency domain resource.
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block; or If the first bit and the third bit of the resource allocation bit sequence are the first identifier, the second ratio If the special bit is the second identifier, the first two resource blocks in which the frequency domain resource is divided are 2*26 resource blocks; or, if the first bit of the resource allocation bit sequence is the first identifier, the second bit and The third bit is the second identifier, and the first three resource blocks that are divided into frequency domain resources are 2*26 resource blocks, 1*26 resource blocks, and 1*26 resource blocks in turn; or, if the resource allocation bit sequence The first bit and the second bit are the second identifier, and the third bit is the first identifier, and the first three resource blocks that are divided into the frequency domain resources are 1*26 resource blocks and 1*26 resources in sequence.
  • the first resource block is a 2*242 resource block; or, if the resource allocation bit sequence is 010, Then, the first resource block in which the frequency domain resource is divided is 996 resource blocks.
  • the transmitting end sets the fourth bit to the sixth bit of the resource allocation bit sequence to 000,000 for indicating the first resource block for single-user transmission.
  • the transmitting end sets the fourth bit to the sixth bit of the resource allocation bit sequence to 001, 001 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and uses the first The number of stations of the resource block is 2; or, the sender sets the fourth bit to the sixth bit of the resource allocation bit sequence to be 010, 010, which is used to indicate that the first resource block performs multi-user MIMO technology.
  • the transmitting end sets the fourth bit to the sixth bit of the resource allocation bit sequence to 011, 011 is used to indicate the first resource block Multi-user MIMO-MIMO transmission, and the number of stations using the first resource block is 4; or, the transmitter sets the fourth bit to the sixth bit of the resource allocation bit sequence to 100,100.
  • the transmitting end Used to indicate a resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 5; or, the transmitting end sets the fourth bit to the sixth bit of the resource allocation bit sequence 101, 101 is used to indicate that the first resource block performs multi-user multiple input multiple-output technology MU-MIMO transmission, and the number of stations using the first resource block is 6; or, the transmitting end sets the fourth of the resource allocation bit sequence
  • the bit to the sixth bit is 110, 110 is used to indicate that the first resource block performs multi-user multiple input multiple output technology MU-MIMO transmission, and the number of stations using the first resource block is 7; or, the sender setting Resource
  • the fourth bit to the sixth bit of the allocated bit sequence is 111, 111 is used to indicate that the first resource block performs multi-user multiple input multiple output MU-MIMO transmission, and the number of stations using the first resource block is 8.
  • a frequency resource of 20 MHz bandwidth may be divided into nine 1*26 resource blocks.
  • the present invention proposes to use a baffle method to indicate a combination of frequency resource division.
  • the positions of the corresponding six arrows in FIG. 29 are respectively set to 1 bit. When the bit is "1", it indicates that two adjacent resource blocks are connected. Together, it can be combined into a larger resource block than the 1*26 resource block; when the bit is "0", it means that the adjacent two resource blocks are separated.
  • the intermediate 1*26 resource block may not be combined with other resource blocks into other resources, so that there is no arrow on the side of the resource block 2.
  • the resource allocation information is indicated as “111 111”, indicating that the first 1*26 resource blocks on the left side of the intermediate 1*26 resource block are combined into a 4*26 resource block, and the middle 1*26 resource block is right. Four 1*26 resource blocks are combined to form a 4 ⁇ 26 resource block.
  • the resource allocation information is indicated as “101 111”, indicating that two 1*26 resource blocks on the left side of the intermediate 1*26 resource block are combined into a 2*26 resource block, and the next two 1*s are 26 resource blocks are grouped together into 2*26 resource blocks, and the first 1*26 resource blocks on the right side of the middle 1*26 resource block are combined to form a 4*26 resource block.
  • the resource allocation information is indicated as “101 000”, indicating that two 1*26 resource blocks on the left side of the intermediate 1*26 resource block are combined to form a 2*26 resource block, followed by two 1*s. 26 resource blocks are grouped together into 2*26 resource blocks, and the first 1*26 resource blocks on the right side of the middle 1*26 resource block are not connected together and are divided into independent 1*26 resource blocks.
  • the indication bit to the left or right of the intermediate resource block may not be “011", “110” or “010".
  • the left bit of the intermediate resource block indicates the bit "110”
  • these special indicator bits to indicate other meanings.
  • the frequency domain resource of the 20 MHz bandwidth is divided into 242 resource blocks by using "011XXX", wherein a 3-bit binary number "X” is used to indicate the number of stations transmitted on the 242 resource block, and "000” indicates the number of stations. Is 1, "001" means the number of sites is 2, and so on.
  • frequency domain resources with a bandwidth greater than 20 MHz such as frequency domain resources of 40 MHz bandwidth
  • the frequency domain resources into two 20 MHz bandwidths are respectively indicated by the actually divided resource blocks, but one more resource block type that may be divided, such as a 2*242 resource block.
  • a special indication bit is used to indicate the situation, such as "110XXX” indicating that the 20MHz bandwidth frequency domain resource is combined with the adjacent 20MHz bandwidth frequency domain resource into 2*242 resource blocks.
  • the "010XXX” indicates that the 20MHz bandwidth frequency domain resource is combined with the adjacent two 20MHz bandwidth frequency domain resources into one 996 resource block.
  • the frequency domain resource of 40 MHz bandwidth is actually divided.
  • the frequency domain resource indication bit sequence of the first 20 MHz bandwidth is “011 001”, and the frequency domain resource of the second 20 MHz bandwidth is shown.
  • the indication bit sequence is also "011 001".
  • the frequency domain resource of the 80 MHz bandwidth is actually divided.
  • the frequency domain resource indication bit sequence of the first 20 MHz bandwidth is “111 111”, and the frequency domain resource of the second 20 MHz bandwidth is shown.
  • the bit sequence "110 011" is indicated, the frequency domain resource indication bit sequence of the third 20 MHz bandwidth is "011 000”, and the frequency domain resource indication bit sequence of the fourth 20 MHz bandwidth is also "011 000".
  • the first identifier provided by the embodiment of the present invention is 1, and the second identifier is 0, and the first identifier is 0, the second identifier is 1, and may be an identifier that is agreed by any receiving end and the sending end.
  • the invention is not limited.
  • the site information is not included. That is to say, which resource blocks are not included for the MU-MIMO transmission indication, and which resources are used for the single-user transmission indication.
  • the smallest resource block in which MU-MIMO transmission is considered here is a 4*26 resource block.
  • the embodiment of the present invention proposes to additionally add a bit to indicate the number of stations transmitted on the resource block, and put it in the site information.
  • the encoding method of HE-SIG-B is separately coded for the information of K stations.
  • the public parameters are partially coded independently, and the information of each K site is encoded separately, as shown in FIG.
  • Another way is that the public parameters are encoded together with the information of the former K site, and the information of each K site is encoded separately, as shown in FIG.
  • Each of the site information groups contains a fixed number of bits and is equal.
  • the public information parameter group may have the same size as the site information group, or may be different, but the receiving end is known.
  • the value of K is any positive integer and can be 3 or 4.
  • the embodiment of the present invention proposes that, in addition to the first independent coding block, optionally adding 3 bits in a specified coding block indicates that the transmission is actually performed on a 4*26 resource block or a larger resource block.
  • the number of sites, where the bit position is not limited, is better placed before the code block. For example, 000 means that 1 site participates in transmission, 001 means 2 sites participate in transmission, and so on. More than one station participates in the transmission, indicating that MU-MIMO transmission is performed on the resource block, that is, 3-bit bits "001-111" indicate MU-MIMO transmission, and "000" indicates single-site transmission.
  • the bits indicating the number of stations transmitted on the 4*26 resource block or the larger resource block are placed in the designated coding block, so that the receiver can know how many bits each block has, so that it can be correctly decoded.
  • the number of stations in the specified coding block in the 20M is increased by 6 bits to indicate the number of stations on the resource block.
  • 20M contains one 4*26 resource block or 242 resources.
  • the block or the adjacent 20 MHz bandwidth frequency domain resources are combined into a larger resource block, and the number of stations on the resource block is indicated by adding 3 bits in the coded block within the frequency domain resource of the 20 MHz bandwidth.
  • the frequency domain resource of the 20 MHz bandwidth is divided into two 4*26 resource blocks, and each resource block needs to add 3 bits to indicate the number of stations transmitted on the resource block.
  • the transmitting end places the 6 bits. The front of the second code block.
  • the receiving end first decodes the first block of coded blocks (the number of bits included in the first block of coded blocks is known), and the resource information of the first block of codes is used to learn that there are two 4*26 resource blocks. Therefore, the receiver knows that the second block of code blocks is additionally increased by 6 bits, so that it can be effectively decoded.
  • the frequency domain resource of the 20 MHz bandwidth is divided into one 4*26 resource block, and three bits need to be added to indicate the number of stations transmitted on the resource block.
  • the sender places the 3 bits into the second code. The front inside the block.
  • the receiving end first decodes the first block of coded blocks (the number of bits included in the first block of coded blocks is known), and the resource information of the first block of codes is known to contain one 4*26 resource block. Therefore, the receiver knows that the second block of code blocks is additionally increased by 3 bits, so that it can be effectively decoded.
  • the frequency domain resource of the 80 MHz bandwidth is divided into: the first 20 MHz bandwidth frequency domain resource contains two 4*26 resource blocks, and the transmitting end places the 6 bits in the first 20 MHz bandwidth frequency domain resource.
  • the frequency domain resource of the second 20 MHz bandwidth divided contains one 242 resource block, and the transmitting end places the three bits in front of the second coding block in the frequency domain resource of the second 20 MHz bandwidth.
  • the frequency domain resource of the third 20 MHz bandwidth divided and the frequency domain resources of the adjacent 20 MHz bandwidth are divided into 2*484 resource blocks, and the transmitting end places the 3 bits in the frequency domain resource of the third 20 MHz bandwidth.
  • the frequency domain resource of 20 MHz bandwidth is divided into 2*484 resource blocks together with the adjacent frequency domain resources of 20 MHz bandwidth, and the transmitting end places the 3 bits into the second coding block in the frequency domain resource of the fourth 20 MHz bandwidth.
  • the front is divided into 2*484 resource blocks together with the adjacent frequency domain resources of 20 MHz bandwidth, and the transmitting end places the 3 bits into the second coding block in the frequency domain resource of the fourth 20 MHz bandwidth.
  • the receiving end first decodes the first block of coding blocks in the frequency domain resource of each 20 MHz bandwidth (the number of bits included in the first block of coding blocks is known), and the resource allocation information of the first block is used to learn that the resource block contains 4*26 resources. And the number of larger resource blocks. Therefore, the receiver knows how many extra bits are added to the second block of code blocks, so that it can be effectively decoded.
  • the above embodiment is not limited to adding bit information indicating the number of stations on the 4*26 resource block and the larger resource block in the second coding block. It can also be in other coded blocks, but it needs to be known at the receiving end.
  • the embodiment of the present invention provides a sending end. As shown in FIG. 37, the sending end includes:
  • the generating module 10 is configured to generate resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, and the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the sending module 11 is configured to send the resource scheduling information to the receiving end after the generating module 10 generates the resource scheduling information.
  • the resource scheduling information further includes site information, and the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first bit indicates that the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and use the first resource. The number of sites in the block.
  • the first bit indicates that the first resource block is not a 4*26 resource block
  • the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resource blocks.
  • the resource allocation bit sequence The three bits and the fourth bit are used to indicate the first N resource blocks in which the frequency domain resources are divided. Type, where N is 2, 3 or 4;
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and the resource allocation bit sequence
  • the fifth bit is a reserved bit
  • the sixth bit to the eighth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first N resource blocks in which the frequency domain resource is divided, where N is 2, 3 or 4, and specifically includes:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or
  • 01 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 1*26 resource block, 1*26 resource block, and 2 *26 resource blocks; or,
  • 10 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 2*26 resource blocks, 1*26 resource blocks, and 1 *26 resource blocks; or,
  • the third bit and the fourth bit of the resource allocation bit sequence are 11, 11, the first two resource blocks used to indicate that the frequency domain resource is divided are 2*26 resource blocks.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and specifically include:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or
  • 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the first bit is the first identifier, and the first resource block to which the frequency domain resource is divided is the 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the resource allocation bit sequence is the first identifier, and the second bit and the third bit are the second identifier, the first three resource blocks that are allocated by the frequency domain resource are 2*26 resources in sequence. Block, 1*26 resource block, and 1*26 resource block; or,
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • An embodiment of the present invention provides a transmitting end, including a generating module, configured to generate resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • the sending module is configured to send the resource scheduling information to the receiving end after the generating module generates the resource scheduling information.
  • the transmitting end can Generating resource scheduling information including a resource allocation bit sequence, wherein a resource allocation bit sequence indicating that a frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and a conventional resource block based bitmap indication method (per The division of frequency domain resources of 20 MHz bandwidth requires 9 bits to represent) compared to the signaling overhead.
  • An embodiment of the present invention provides a receiving end. As shown in FIG. 38, the receiving end includes:
  • the receiving module 20 is configured to receive resource scheduling information sent by the sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the parsing module 21 is configured to parse the resource scheduling information after the receiving module 20 receives the resource scheduling information sent by the sending end.
  • the resource scheduling information further includes site information, and the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first bit indicates that the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and use the first resource. The number of sites in the block.
  • the first bit indicates that the first resource block is not a 4*26 resource block
  • the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resource blocks.
  • the resource allocation bit sequence The three bits and the fourth bit are used to indicate the type of the first N resource blocks into which the frequency domain resources are divided, where N is 2, 3 or 4;
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and the resource allocation bit sequence
  • the fifth bit is a reserved bit
  • the sixth bit to the eighth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first N resource blocks in which the frequency domain resource is divided, where N is 2, 3 or 4, and specifically includes:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or
  • 01 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 1*26 resource block, 1*26 resource block, and 2 *26 resource blocks; or,
  • 10 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 2*26 resource blocks, 1*26 resource blocks, and 1 *26 resource blocks; or,
  • the third bit and the fourth bit of the resource allocation bit sequence are 11, 11, the first two resource blocks used to indicate that the frequency domain resource is divided are 2*26 resource blocks.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and specifically include:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or
  • 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the frequency domain resource is divided into 2*26 resource block, 1*26 resource block and 1*26 resource block; or
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • An embodiment of the present invention provides a receiving end, including a receiving module, configured to receive resource scheduling information sent by a sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate that at least the frequency domain resource is divided. a resource block; a parsing module, configured to parse the resource scheduling information after the receiving module receives the resource scheduling information sent by the sending end.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • the embodiment of the present invention provides a sending end. As shown in FIG. 39, the sending end includes:
  • the processor 30 is configured to generate resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the transmitter 31 is configured to send the resource scheduling information to the receiving end after the processor 30 generates the resource scheduling information.
  • the resource scheduling information further includes site information, and the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first bit indicates that the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and use the first resource. The number of sites in the block.
  • the first bit indicates that the first resource block is not a 4*26 resource block
  • the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resource blocks.
  • the resource allocation bit sequence The three bits and the fourth bit are used to indicate the type of the first N resource blocks into which the frequency domain resources are divided, where N is 2, 3 or 4;
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and the resource allocation bit sequence
  • the fifth bit is a reserved bit
  • the sixth bit to the eighth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first N resource blocks in which the frequency domain resource is divided, where N is 2, 3 or 4, and specifically includes:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or
  • 01 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 1*26 resource block, 1*26 resource block, and 2 *26 resource blocks; or,
  • 10 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 2*26 resource blocks, 1*26 resource blocks, and 1 *26 resource blocks; or,
  • the third bit and the fourth bit of the resource allocation bit sequence are 11, 11, the first two resource blocks used to indicate that the frequency domain resource is divided are 2*26 resource blocks.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and specifically include:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or
  • 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the resource allocation bit sequence is the first identifier, and the second bit and the third bit are the second identifier, the first three resource blocks that are allocated by the frequency domain resource are 2*26 resources in sequence. Block, 1*26 resource block, and 1*26 resource block; or,
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • An embodiment of the present invention provides a transmitting end, including a processor, configured to generate resource scheduling information, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided;
  • the transmitter is configured to send the resource scheduling information to the receiving end after the processor generates the resource scheduling information.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • the embodiment of the present invention provides a receiving end. As shown in FIG. 40, the receiving end includes:
  • the receiver 40 is configured to receive resource scheduling information sent by the sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate at least one resource block in which the frequency domain resource is divided.
  • the processor 41 is configured to parse the resource scheduling information after the receiver 40 receives the resource scheduling information sent by the sending end.
  • the resource scheduling information further includes site information, and the site information corresponds to at least one resource block in which the frequency domain resource is divided.
  • the first bit of the resource allocation bit sequence is used to indicate whether the first resource block is a 4*26 resource block, and the first resource block is the first resource block into which the frequency domain resource is divided.
  • the first bit indicates that the first resource block is a 4*26 resource block
  • the second bit to the fourth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and use the first resource. The number of sites in the block.
  • the first bit indicates that the first resource block is not a 4*26 resource block
  • the second bit of the resource allocation bit sequence is used to indicate whether the size of the first resource block is greater than 4*26 resource blocks.
  • the resource allocation bit sequence The three bits and the fourth bit are used to indicate the type of the first N resource blocks into which the frequency domain resources are divided, where N is 2, 3 or 4;
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first resource block, and the resource allocation bit sequence
  • the fifth bit is a reserved bit
  • the sixth bit to the eighth bit of the resource allocation bit sequence are used to indicate the transmission type of the first resource block and the number of stations using the first resource block.
  • the third bit and the fourth bit of the resource allocation bit sequence are used to indicate the type of the first N resource blocks in which the frequency domain resource is divided, where N is 2, 3 or 4, and specifically includes:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first four resource blocks into which the frequency domain resource is divided are 1*26 resource blocks; or
  • 01 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 1*26 resource block, 1*26 resource block, and 2 *26 resource blocks; or,
  • 10 is used to indicate that the first three resource blocks into which the frequency domain resource is divided are 2*26 resource blocks, 1*26 resource blocks, and 1 *26 resource blocks; or,
  • the third bit and the fourth bit of the resource allocation bit sequence are 11, 11, the first two resource blocks used to indicate that the frequency domain resource is divided are 2*26 resource blocks.
  • the type of the first resource block specifically includes:
  • the third bit and the fourth bit of the resource allocation bit sequence are 00, 00 is used to indicate that the first resource block is 242 resource blocks; or
  • 11 is used to indicate that the first resource block is a 2*996 resource block.
  • the first resource block to which the frequency domain resource is divided is a 4*26 resource block;
  • the first bit and the third bit of the resource allocation bit sequence are the first identifier and the second bit is the second identifier, the first two resource blocks of the frequency domain resource are divided into 2*26 resource blocks. ;or,
  • the first bit of the resource allocation bit sequence is the first identifier, and the second bit and the third bit are the second identifier, the first three resource blocks that are allocated by the frequency domain resource are 2*26 resources in sequence. Block, 1*26 resource block, and 1*26 resource block; or,
  • the first three resource blocks that are allocated by the frequency domain resource are 1*26 resources in sequence. Block, 1*26 resource block, and 2*26 resource block; or,
  • the first four resource blocks that are allocated by the frequency domain resource are 1*26 resource blocks;
  • the first resource block to which the frequency domain resource is divided is 242 resource blocks;
  • the first resource block to which the frequency domain resource is divided is a 2*242 resource block;
  • the first resource block to which the frequency domain resource is divided is 996 resource blocks.
  • the fourth bit to the sixth bit of the resource allocation bit sequence are used to indicate the frequency domain resource.
  • first identifier is 1 and the second identifier is 0; or the first identifier is 0, and the second identifier is 1.
  • An embodiment of the present invention provides a receiving end, including a receiver, configured to receive resource scheduling information sent by a sending end, where the resource scheduling information includes a resource allocation bit sequence, where the resource allocation bit sequence is used to indicate that at least the frequency domain resource is divided.
  • a resource block configured to parse the resource scheduling information after the receiver receives the resource scheduling information sent by the sending end.
  • the transmitting end is capable of generating resource scheduling information including a resource allocation bit sequence, wherein the resource allocation bit sequence indicating that the frequency domain resource per 20 MHz bandwidth is divided requires only 8 bits or less, and the conventional Compared to the resource block-based bitmap indication method (the division of frequency domain resources per 20 MHz bandwidth requires 9 bits to represent), the signaling overhead is reduced.
  • the disclosed apparatus and method may be implemented in other manners.
  • the device embodiments described above are merely illustrative.
  • the division of the modules or units is only a logical function division.
  • there may be another division manner for example, multiple units or components may be used. Combinations 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 units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. You can choose some of them according to actual needs or All units are used to achieve the objectives of the solution of this 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 above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
  • the integrated unit if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable storage medium.
  • the technical solution of the present invention which is essential or contributes to the prior art, or all or part of the technical solution, may be embodied in the form of a software product stored in a storage medium.
  • a number of instructions are included to cause a computer device (which may be a personal computer, server, or network device, etc.) or a processor 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

Un mode de réalisation de la présente invention concerne un procédé et un dispositif d'attribution de ressource. L'invention appartient au domaine de la communication et peut indiquer au moins un bloc de ressource divisé d'une ressource dans le domaine fréquentiel au moyen d'une séquence binaire d'attribution de ressource de sorte à réduire le surdébit de signalisation. Dans le procédé d'attribution de ressource, une extrémité de transmission : génère les informations de programmation de ressource comprenant la séquence binaire d'attribution de ressources qui est utilisée pour indiquer au moins un bloc de ressource divisé de la ressource dans le domaine fréquentiel ; et envoie les informations de programmation de ressource à une extrémité de réception.
PCT/CN2016/098861 2015-09-17 2016-09-13 Procédé et dispositif d'attribution de ressource WO2017045585A1 (fr)

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