CN101378289A - Method and apparatus for denoting physical resource - Google Patents

Abstract

The invention discloses expression methods and a device of a physical resource, wherein, one of the methods comprises the steps of utilizing continuous virtual resource blocks with limited length to express the physical resource position of semi-static dispatching data. By the technical proposal, the bit overhead of physical resource expression of semi-static dispatching data is reduced, and the saved bits are used for a virtual CRC, thus effectively improving the detection performance of physical downlink control channel.

Description

Physical resource representation method and device

Technical Field

The present invention relates to the field of communications, and in particular, to a method and apparatus for representing physical resources.

Background

A Long Term Evolution (Long Term Evolution, LTE for short) system is an important project of the third generation partnership organization, and fig. 1 shows a schematic diagram of a basic frame structure in the LTE system, as shown in fig. 1, the frame structure may be divided into four levels of radio frames, half frames, subframes, slots and symbols, wherein a length of a radio frame is 10ms, and a radio frame is composed of two half frames, each half frame is 5ms in length, a half frame is composed of 5 subframes, each subframe is 1ms in length, one subframe is composed of two slots, and each slot is 0.5ms in length.

When the LTE system employs a conventional cyclic prefix, one slot may contain 7 uplink/downlink symbols with a length of 66.7us, where the cyclic prefix length of the first symbol is 5.21us and the cyclic prefix length of the other 6 symbols is 4.69 us.

When the LTE system employs an extended cyclic prefix, one slot contains 6 uplink/downlink symbols with a length of 66.7us, where the cyclic prefix length of each symbol is 16.67 us.

Generally, one Resource Element (RE) is one subcarrier in one Orthogonal Frequency Division Multiplexing (OFDM) symbol, and one downlink Resource Block (RB) is composed of 12 consecutive subcarriers and 7 consecutive OFDM symbols (6 OFDM symbols in case of long CP), and is 180kHz in frequency domain and a time length of one general slot in time domain, fig. 2 is a schematic structural diagram of a Resource Block with a bandwidth of 5MHz in the LTE system, as shown in fig. 2, when Resource allocation is performed, Resource blocks are allocated by using the Resource Block as a basic unit, a black frame is one Resource Block (12 × 7), and a grid-shaped small grid inside the black frame is one Resource Element.

In the LTE system, semi-persistent scheduling (SPS) data, such as Voice over IP (VoIP) data, does not permanently occupy physical resources, but semi-statically changes the transmission position of the physical resources. Currently, a physical Resource representation method of semi-persistent scheduling data adopts a continuous Virtual Resource Block (VRB) representation method and a bitmap (bitmap) representation method.

Currently, Physical Resource allocation indication in LTE uses Physical Resource Block (PRB) as a unit in uplink and Virtual Resource Block (VRB) as a unit in downlink, and currently, there are three types of Resource location indication methods, namely Type0, Type1 and Type2, where Type0 and Type1 are discontinuous (non-compact) allocation modes and Type2 is continuous (compact) allocation modes.

If the Resource position indication method of Type0 is adopted, the resources are firstly grouped, and then Resource Block group (RBG for short) is adopted as a unitThe bitmap (bitmap) indicates (1-bit header is used to distinguish Type0 from Type1), and the RBGs are formed by consecutive PRBs, and the size of the number of PRBs (RBG size) P included in each RBG is determined by the system bandwidth, as shown in table 1. The minimum unit of resource allocation is RBG, given the system bandwidth

In total can be divided into

An RBG and need

One bit is used for bitmap indication, as shown in table 1:

TABLE 1 RBG size definition

For example, when the system is 50 PRBs, the resource location indication method adopting Type0 may be divided into 17 RBGs, where one RBG only includes 2 consecutive PRBs, and at this time, the corresponding bitmap size is 17 bits, and each bit in the bitmap corresponds to whether 1 corresponding RBG is allocated or not.

In addition, with the resource location indication method of Type1, all resources need to be firstly divided into several subsets (subset), and then indicated in a bitmap manner inside the subset (where 1-bit header is used to distinguish Type0 from Type 1). The minimum unit of resource allocation is PRB, and the total resource allocation can be divided into PRB according to the system bandwidth and RBG size

RBGs (divided into P subsets by REG at the same time), and Type1 is the same as Type0, and used togetherOne bit is used for allocation of PRBs within a subset. The number of subsets is also equal to P, i.e. there is subset0, subsett1，...，subset^P-1(Subset selection requiresOne bit indication) so that only one bit remainsOne bit is used as a bitmap for the selection indication of PRBs within each subset.

type1 divides subsets with RBG size as the minimum unit, the starting position of the 1 st RBG in each subset is equal to nP, n is 0, 1, and P-1 represents the subset number, after the starting position is determined, the RBGs in each subset are selected at equal intervals of P multiplied by P PRBs, and the number of the corresponding PRBs in each subset is z₀，z₁，...，z_P-1. Required to remove (shift) z in each subset₀-y，z₁-y，...，z_P-1Y PRBs that can be shifted from the leftmost or the rightmost end, which requires 1 bit to indicate whether it is the leftmost or the rightmost end. This means that the number of PRBs available for selection in each subset is only y, and their allocation is indicated by the bitmap selection.

For example, when the system is 50 PRBs, and P is 3, the resource location indication method can be divided into 17 RBGs and 3 subsets, at this time, 2 bits need to be left for selection of the subsets, and 1 bit needs to be used for removing redundant PRBs from the leftmost end or the rightmost end, and only 14 bits are used as bitmap to select PRBs in each subset. The starting position of subset0 is 0, the starting position of subset1 is P, the starting position of subset2 is 2P, the corresponding subset0 includes 18 PRBs, the subset1 includes 17 PRBs, the subset2 includes 15 PRBs, and 4 PRBs, 3 PRBs and 1 PRB need to be shifted respectively, as shown in fig. 3.

Type2 (the compact method described above) is used to allocate consecutive PRBs (uplink 0) or VRBs (downlink 1a) and to indicate resources in a tree structure, where RIV indicates the location RB of the RIV from the starting RB_startAnd the length L of the continuous RB_CRBsCommon determination, wherein each resource indication constitutes a tree structureA node of (2). To ensure the allocation of contiguous resources at any starting location, adjacent parent nodes in the tree have a common child node.

Indicating the number of downlink available resource blocks. To be provided with $N_{\mathrm{RB}}^{\mathrm{DL}}=10$ For example, a tree graph as shown in FIG. 4 may be generated. The definition of resource indication RIV is:

when in use

When the temperature of the water is higher than the set temperature, $\mathrm{RIV}=N_{\mathrm{RB}}^{\mathrm{DL}}(L_{\mathrm{CRBs}}-1)+{\mathrm{RB}}_{\mathrm{start}},$ wherein, <math> <mrow> <msub> <mi>RB</mi> <mi>start</mi> </msub> <mo>&Element;</mo> <mrow> <mo>[</mo> <mn>0,1</mn> <mo>,</mo> <mo>.</mo> <mo>.</mo> <mo>.</mo> <mo>,</mo> <mrow> <mo>(</mo> <msubsup> <mi>N</mi> <mi>RB</mi> <mi>DL</mi> </msubsup> <mo>-</mo> <msub> <mi>L</mi> <mi>CRBs</mi> </msub> <mo>)</mo> </mrow> <mo>]</mo> </mrow> <mo>,</mo> </mrow></math> if not, then, $\mathrm{RIV}=N_{\mathrm{RB}}^{\mathrm{DL}}({N_{\mathrm{RB}}^{\mathrm{DL}}-L}_{\mathrm{CRBs}}+1)+(N_{\mathrm{RB}}^{\mathrm{DL}}-1-{\mathrm{RB}}_{\mathrm{start}}).$

in the related art, Downlink Control Information (DCI) is transmitted through a Physical Downlink Control channel (PDCCH for short) 1, and a terminal (User Equipment, UE for short) performs blind detection through Cyclic Redundancy Check (CRC) of the DCI to determine a PDCCH position addressed to the terminal, but the length of the CRC is limited, and therefore, in order to improve the detection performance of the Physical Downlink Control channel, some bits need to be saved from a resource representation signaling for virtual CRC. However, no technical solution to solve the above problems has been proposed.

Disclosure of Invention

The present invention is made in view of the problem that the bit overhead of the physical resource representation of the semi-persistent scheduling data is large at present, and therefore, the present invention is to provide a physical resource representation method and apparatus to solve the above problems in the related art.

According to one aspect of the invention, a method for representing physical resources is provided for representing the location of physical resources for semi-static data.

The method for representing the physical resource comprises the following steps: the physical resource location of the semi-static scheduling data is represented by using continuous virtual resource blocks with limited length.

Wherein the half is represented using continuous virtual resource blocks of limited lengthThe specific processing of the physical resource position of the static scheduling data is as follows: number of consecutive virtual resource blocks L limited by length allocated to semi-persistent scheduling data_CRBsAnd starting position RB of continuous virtual resource block allocated to semi-static scheduling data_STARTDetermining the physical resource position of semi-static scheduling data, and counting the number L of continuous virtual resource blocks according to a predetermined mode_CRBsAnd starting position RB of continuous virtual resource block_STARTAnd coding to obtain the resource representation signaling of the semi-static scheduling data.

The specific processing of encoding according to the predetermined mode is as follows: when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START) Wherein L is_CRBsIndicating the number of consecutive virtual resource blocks, RBs, allocated to semi-persistent scheduling data_STARTIndicating the starting position of consecutive virtual resource blocks allocated to semi-persistent scheduling data, RIV being the resource indication signalling of semi-persistent scheduling data, N_RBRepresenting the total number of available resource blocks on the bandwidth.

Wherein, the bit number of the resource representation signaling of the semi-persistent scheduling data is:

where k represents the number of bits saved.

Wherein the maximum length of the continuous virtual resource block is

Wherein, the value of the saved bit number k is as follows: when N is present_RB>When H, k is 2; when N is present_RBWhen the ratio is less than or equal to H, k is 1, wherein H is a positive integer.

According to another aspect of the present invention, a method for representing physical resources is provided for representation of physical resource locations for semi-static data.

The method for representing the physical resource comprises the following steps: the physical resource locations of the semi-static scheduling data are represented using length-limited bitmaps.

The processing of the physical resource location representing the semi-static scheduling data is specifically as follows: and representing the physical resource position of the semi-static scheduling data by using the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by an identifier and a resource indication bit map.

Wherein, the identifier and the resource indication bitmap represent a resource representation signaling of the semi-static scheduling data, and the method comprises: sequentially grouping after sequentially numbering all available resource blocks, wherein the number of resource blocks contained in each group except the last group is P, the number of resource blocks contained in the last group is less than or equal to P, and the total number of resource groups is

Wherein P represents the number of resource blocks contained in one resource group, and P is a positive integer, wherein N is_RBRepresenting the total number of available resource blocks, N, over the bandwidth_RBGRepresenting the total number of resource groups; according toDetermining the size of a resource indication bitmap, wherein k represents the saved bit number, each bit in the resource indication bitmap corresponds to one resource group, and represents whether all resource blocks in the resource group are allocated to a target user or not; the starting position of the resource indication bitmap is represented by an identifier, or whether the offset of the resource indication bitmap relative to the starting resource block is triggered or not is represented by the identifier, or N is represented by the current resource indication bitmap_RBGFirst N in a resource group_SPSWhether individual resource group is next N_SPSA set of resources.

The processing of the physical resource location representing the semi-static scheduling data is specifically as follows: and the resource representation signaling of the semi-static scheduling data is used for representing the physical resource position of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by 1-bit identification, a subset index and an intra-subset bitmap indication, and the 1-bit identification represents the resource representation signaling of the leftmost end or the rightmost end represented by the intra-subset bitmap indication.

Wherein the bit number indicated by the bitmap in the subset is

Where k represents the number of bits saved, P represents the number of resource blocks contained in a resource group,

indicating the number of downlink available resource blocks.

Wherein, the value of the saved bit number k is as follows: when N is present_RB>When H, k is 2; when N is present_RBWhen the ratio is less than or equal to H, k is 1, wherein H is a positive integer.

According to still another aspect of the present invention, there is provided a representation apparatus of physical resources for representation of physical resource locations of semi-static data.

The representation device of the physical resource according to the invention comprises: the first representation module is used for representing the physical resource position of the semi-static scheduling data by using a continuous virtual resource block with limited length; and/or a second representation module for representing physical resource locations of the semi-static scheduling data using the length-limited bitmap.

By means of the technical scheme, the physical resource position of the semi-static scheduling data is represented by using the continuous virtual resource block or bitmap with limited length, bit overhead represented by the physical resource of the semi-static scheduling data is reduced, and the saved bits are used as virtual CRC, so that the detection performance of the physical downlink control channel is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a diagram of a basic frame structure of an LTE system in the related art;

fig. 2 is a diagram illustrating a resource block with a bandwidth of 5MHz in an LTE system according to the related art;

FIG. 3 is a diagram illustrating resource allocation using type1 for resource location indication in the related art;

FIG. 4 is a diagram illustrating resource allocation using type2 for resource location indication in the related art;

FIG. 5 is a flow chart of a method for representing physical resources according to a first embodiment of the method of the present invention;

FIG. 6 is a flow chart of a method of representing physical resources according to a second embodiment of the method of the present invention;

fig. 7 is a block diagram of a representation apparatus of physical resources according to an embodiment of the present invention.

Detailed Description

Overview of the function

In the related art, there are three types of resource location indication methods, namely Type0, Type1 and Type2, where Type0 and Type1 use a bitmap (bitmap) representation method, and Type2 uses a continuous virtual resource block representation method. The difference between Type0 and Type1 is that Type0 is indicated by adopting bitmap in the unit of RBG, and Type1 is indicated by firstly dividing all resources into a plurality of subsets (subset) and then indicating by bitmap inside the subset. Because the UE performs blind detection through the CRC of the DCI to determine the PDCCH location addressed to the UE, however, since the length of the CRC is limited, a problem that the terminal is prone to error when performing the CRC blind detection occurs may occur, and therefore, in order to improve the detection performance of the PDCCH, some bits need to be saved from the resource indication signaling for the virtual CRC.

Therefore, the invention provides a physical resource representation method of semi-static scheduling data, which uses continuous virtual resource blocks with limited length and bitmaps to represent the physical resource position of the semi-static scheduling data. Compared with the existing resource representation method, the method has smaller signaling overhead, thereby saving some bits and being used as virtual CRC to improve the detection performance of the physical downlink control channel. Specifically, for Type0, the resource representation signaling of the semi-static scheduling data is represented by using the identifier and the resource indication bitmap, for Type1, the resource representation signaling of the semi-static scheduling data is represented by using the 1-bit identifier, the subset index and the intra-subset bitmap, and for Type2, the length of the continuous virtual resource block is reduced.

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Method embodiment one

According to an embodiment of the present invention, a method for representing physical resources is provided for representing the location of physical resources of semi-static data. Fig. 5 is a flowchart of a method for representing physical resources according to a first embodiment of the present invention, and as shown in fig. 5, the method includes the following processes:

step S502, the physical resource position of the semi-static scheduling data is represented by using the continuous virtual resource block with limited length.

In step S502, the specific process of using the continuous virtual resource blocks with limited length to represent the physical resource locations of the semi-persistent scheduling data is as follows: number of consecutive virtual resource blocks L limited by length allocated to semi-persistent scheduling data_CRBsAnd starting position RB of continuous virtual resource block allocated to semi-static scheduling data_STARTDetermining the physical resource position of semi-static scheduling data, and counting the number L of continuous virtual resource blocks according to a predetermined mode_CRBsAnd starting position RB of continuous virtual resource block_STARTAnd coding to obtain the resource representation signaling of the semi-static scheduling data.

The predetermined encoding method specifically includes: when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START) Wherein L is_CRBsIndicating the number of consecutive virtual resource blocks, RBs, allocated to semi-persistent scheduling data_STARTIndicating the starting position of consecutive virtual resource blocks allocated to semi-persistent scheduling data, RIV being the resource indication signalling of semi-persistent scheduling data, N_RBRepresenting the total number of available resource blocks on the bandwidth.

In step S502, the number of bits of the resource indication signaling of the semi-persistent scheduling data is:

wherein k represents the total number of saved bits, and the maximum length of continuous virtual resource blocks is

Wherein H is a positive integer, when N is_RB>When H, k is 2; when N is present_RBWhen the content is less than or equal to H, k is 1.

In step S504, the saved bits (k) are used for the virtual CRC.

The above technical solution will be described in detail with reference to specific examples.

Example 1, the physical resource location of uplink semi-persistent scheduling data is represented by a length-limited continuous virtual resource block representation method.

The physical resource position of the uplink semi-static scheduling data is determined by the number L of virtual resource blocks allocated to the uplink semi-static scheduling data_CRBsAnd starting position RB of virtual resource block allocated to uplink semi-static scheduling data_STARTDetermination of L_CRBsAnd RB_STARTEncoding is performed in such a way that RIV represents L_CRBsAnd RB_STARTThe coded result, namely the resource of the uplink semi-static scheduling data represents signaling;

L_CRBsand RB_STARTThe coding method comprises the following steps: when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START)。

In addition, the maximum number of continuous virtual resource blocks of the uplink semi-static scheduling data physical resource is

y represents the number of bits of physical resource signaling of uplink semi-persistent scheduling data,

k represents the total number of saved bits, N_RBRepresenting the total number of available resource blocks in the uplink bandwidth; the value of k is: when N is present_RB>When H, k is 2, when N_RBWhen the sum is less than or equal to H, k is 1, H can be 0, 20, 49 and 110, and the saved k bits are used as virtual CRC;

through the processing, the bit overhead represented by the physical resource of the uplink semi-static scheduling data is reduced, and the saved bits are used as the virtual CRC, so that the detection performance of the physical downlink control channel is improved.

Example 2, the physical resource location of the downlink semi-persistent scheduling data is represented by a length-limited continuous virtual resource block representation method.

The physical resource position of the downlink semi-static scheduling data is determined by the number L of virtual resource blocks allocated to the downlink semi-static scheduling data_CRBsAnd the starting position RB of the virtual resource block allocated to the downlink semi-static scheduling data_STARTDetermination of L_CRBsAnd RB_STARTEncoding is performed in such a way that RIV represents L_CRBsAnd RB_STARTThe coded result, namely the resource of the downlink semi-static scheduling data represents signaling;

wherein L is_CRBsAnd RB_STARTThe coding method specifically comprises the following steps: when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START)。

The maximum number of continuous virtual resource blocks of the physical resources of the downlink semi-static scheduling data isy represents the bit number of physical resource signaling of the downlink semi-persistent scheduling data,

k represents the total number of saved bits, N_RBRepresenting the total number of available resource blocks in the downlink bandwidth;

when N is present_RB>When H, k is 2, when N_RBWhen the ratio is less than or equal to H, k is 1, and H can be 0, 20, 49 or 110; finally, the saved k bits are used as virtual CRC;

through the processing, the bit overhead represented by the physical resource of the downlink semi-static scheduling data is reduced, and the saved bits are used as the virtual CRC, so that the detection performance of the physical downlink control channel is improved.

Method embodiment two

According to an embodiment of the present invention, a method for representing physical resources is provided for representing the location of physical resources of semi-static data. Fig. 6 is a flowchart of a method for representing physical resources according to a second embodiment of the method of the present invention, as shown in fig. 6, including the following processes:

step S602, using the length-limited bitmap to represent the physical resource location of the semi-static scheduling data.

For Type0, in step S602, the processing for indicating the physical resource location of the semi-persistent scheduling data specifically includes: and representing the physical resource position of the semi-static scheduling data by using the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by an identifier and a resource indication bit map.

Specifically, the manner of the identifier and the resource indication bitmap representing resource representation signaling of the semi-persistent scheduling data includes:

1. sequentially grouping after sequentially numbering all available resource blocks, wherein the number of resource blocks contained in each group except the last group is P, the number of resource blocks contained in the last group is less than or equal to P, and the total number of resource groups is

Wherein P represents the number of resource blocks contained in one resource group, and P is a positive integer, wherein N is_RBRepresenting the total number of available resource blocks, N, over the bandwidth_RBGRepresenting the total number of resource groups;

2. according to

Determining the size of a resource indication bitmap, wherein k represents the number of saved bits, each bit in the resource indication bitmap corresponds to one resource group, and represents whether all resource blocks in the resource group are allocated to a target user or not;

the value of k is: when in useN_RB>When H, k is 2, when N_RBWhen the ratio is less than or equal to H, k is 1, and H is a positive integer.

3. The starting position of the resource indication bitmap is represented by an identifier, or whether the offset of the resource indication bitmap relative to the starting resource block is triggered or not is represented by the identifier, or N is represented by the current resource indication bitmap_RBGFirst N in a resource group_SPSWhether individual resource group is next N_SPSA set of resources.

In addition, regarding Type1, in step S602, the processing indicating the physical resource location of the semi-persistent scheduling data is specifically: and the resource representation signaling of the semi-static scheduling data is used for representing the physical resource position of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by 1-bit identification, a subset index and an intra-subset bitmap indication, and the 1-bit identification represents the resource representation signaling of the leftmost end or the rightmost end represented by the intra-subset bitmap indication.

Wherein the bit number indicated by the bitmap in the subset is

Wherein k represents the number of saved bits, P represents the number of resource blocks contained in one resource group,

indicating the number of downlink available resource blocks.

The value of k is: when N is present_RB>When H, k is 2, when N_RBWhen the ratio is less than or equal to H, k is 1, and H is a positive integer.

In step S604, the saved bits (k) are used for the virtual CRC.

The above-described embodiments will be described below by way of example.

Example 3 for Type0, the physical resource location of the semi-static scheduling data is represented using a length-limited bitmap.

The resource representation signaling of the semi-static scheduling data is represented by an identifier and a resource indication bitmap; wherein the identifier indicates a starting position of the bitmap, or the identifier indicates an offset of the bitmap with respect to a starting resource block, or the identifier indicates whether the bitmap is shifted;

all available resource blocks are numbered sequentially, then the resource blocks are grouped sequentially, the number of the resource blocks contained in each group is P, finally, the remaining resource blocks are divided into one group, the number of the resource blocks contained in the group is less than or equal to P, each group corresponds to one bit, 1 represents that all the resource blocks in the group are allocated to a target user, 0 represents that all the resource blocks in the group are not allocated to the target user, and P is a positive integer. The total number of resource groups which can be divided is

In addition, the size of the bitmap

Wherein P represents the number of resource blocks included in one resource group, and k represents the number of bits saved for use as a virtual CRC;

that is, each bit in the bitmap corresponds to whether a resource group is allocated, but since the total number of bitmaps is smaller than the total number of resource groups, each time the resource representation bitmap can only represent the first N resource groups_SPSAllocation of individual resource groups, or, last N_SPSAllocation of individual resource groups, in particular top N_SPSIs also last N_SPSOne, determined by the identifier bits; finally, when N is_RB>When H, k is 2, when N_RBWhen the sum is less than or equal to H, k is 1, H can be 0, 20, 49 and 110, and the saved k bits are used as virtual CRC;

through the processing, the bit overhead represented by the physical resource of the semi-static scheduling data is reduced, and the saved bits are used as the virtual CRC, so that the detection performance of the physical downlink control channel is improved.

Example 4 for Type1, the physical resource location of semi-static scheduling data is represented using a length-limited bitmap.

All resources are divided into a plurality of subsets (subset), and then indicated in a bitmap mode inside the subset (1-bit header is used for distinguishing Type0 and Type1), wherein the minimum unit of resource allocation is PRB, and the total resource allocation can be divided into PRB according to the system bandwidth and RBG size

RBGs (divided into P subsets by REG), Type1 and Type0

One bit is used for allocation of PRBs within a subset. The number of subsets is also equal to P, i.e., there are subset0, subset1^P-1(Subset selection requires

One bit indication) so that only one bit remains

One bit is used as a bitmap for the selection indication of PRBs within each subset. 1 bit indicates whether it is the leftmost or rightmost end. This means that the number of PRBs available for selection in each subset is only y, and their allocation is indicated by the bitmap selection. k represents the number of bits saved;

type1 divides subsets with RBG size as the minimum unit, the starting position of the 1 st RBG in each subset is equal to nP, n is 0, 1, and P-1 represents the subset number, after the starting position is determined, the RBGs in each subset are selected at equal intervals of P multiplied by P PRBs, and the number of the corresponding PRBs in each subset is z₀，z₁，...，z_P-1. Shift is required to drop z in each subset₀-y，z₁-y，...，z_P-1Y PRBs that can be shifted from the leftmost or the rightmost end, which requires 1 bit to indicate whether it is the leftmost or the rightmost end. This means that the number of PRBs available for selection in each subset is only y, and their allocation is indicated by the bitmap selection. Finally, the saved k bits are used as a virtual CRC.

Device embodiment

According to an embodiment of the present invention, a representation apparatus of a physical resource is provided for representation of a physical resource location of semi-static data. Fig. 7 is a block diagram of a representation apparatus of physical resources according to an embodiment of the present invention, as shown in fig. 7, including a first representation module 70 and/or a second representation module 72, it should be noted that, in practical applications, the first representation module 70 and the second representation module 72 may also be arranged in a unified manner, but in order to clearly illustrate the technical solution of the present invention, a separately arranged solution is adopted here to illustrate the technical solution of the present invention. The above-described modules will be described in detail below.

A first representation module 70, configured to represent physical resource locations of semi-static scheduling data using continuous virtual resource blocks with limited length;

specifically, the specific process that the first representation module 70 uses the continuous virtual resource blocks with limited length to represent the physical resource positions of the semi-static scheduling data is as follows: the first representation module 70 uses a limited number L of consecutive virtual resource blocks of length allocated to semi-persistent scheduling data_CRBsAnd starting position RB of continuous virtual resource block allocated to semi-static scheduling data_STARTDetermining the physical resource position of semi-static scheduling data, and counting the number L of continuous virtual resource blocks according to a predetermined mode_CRBsAnd starting position RB of continuous virtual resource block_STARTAnd coding to obtain the resource representation signaling of the semi-static scheduling data.

The specific process of the first representation module 70 performing encoding according to the predetermined manner is as follows: when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START) Wherein L is_CRBsIndicating the number of consecutive virtual resource blocks, RBs, allocated to semi-persistent scheduling data_STARTRepresenting the start of consecutive virtual resource blocks allocated to semi-persistent scheduling dataLocation, RIV is resource representation signaling of semi-persistent scheduling data, N_RBRepresenting the total number of available resource blocks on the bandwidth.

The bit number of the resource representation signaling of the semi-persistent scheduling data is as follows:

wherein k represents the total number of saved bits, and the maximum length of continuous virtual resource blocks is

Wherein H is a positive integer, when N is_RB>When H, k is 2; when N is present_RBWhen the content is less than or equal to H, k is 1.

A second representing module 72, configured to represent the physical resource location of the semi-static scheduling data using a length-limited bitmap.

For Type0, the second representing module 72 represents that the processing of the physical resource location of the semi-persistent scheduling data specifically is: the second representing module 72 represents the physical resource location of the semi-static scheduling data by using the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by the identifier and the resource indication bit map.

Specifically, the manner of resource representation signaling that the identifier and the resource indication bitmap represent semi-static scheduling data includes:

1. sequentially grouping after sequentially numbering all available resource blocks, wherein the number of resource blocks contained in each group except the last group is P, the number of resource blocks contained in the last group is less than or equal to P, and the total number of resource groups is

Wherein P represents the number of resource blocks contained in one resource group, and P is a positive integer, wherein N is_RBRepresenting the total number of available resource blocks, N, over the bandwidth_RBGRepresenting the total number of resource groups;

2. according to

Determining the size of a resource indication bitmap, wherein k represents the number of bits saved for serving as virtual CRC, each bit in the resource indication bitmap corresponds to one resource group, and represents whether all resource blocks in the resource group are allocated to a target user;

3. the starting position of the resource indication bitmap is represented by an identifier, or whether the offset of the resource indication bitmap relative to the starting resource block is triggered or not is represented by the identifier, or N is represented by the current resource indication bitmap_RBGFirst N in a resource group_SPSWhether individual resource group is next N_SPSA set of resources.

For Type1, the second representing module 72 represents that the processing of the physical resource location of the semi-persistent scheduling data specifically is: the second representing module 72 represents the physical resource location of the semi-static scheduling data by using the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by a 1-bit identifier, a subset index, and an intra-subset bitmap indication, wherein the 1-bit identifier represents whether the intra-subset bitmap indication represents the leftmost or rightmost resource representation signaling.

Wherein the bit number indicated by the bitmap in the subset is

Wherein k represents the number of saved bits, P represents the number of resource blocks contained in one resource group,

indicating the number of downlink available resource blocks.

When N is present_RB>When H, k is 2, when N_RBWhen the sum is less than or equal to H, k is 1, H can be 0, 20, 49 and 110, and the saved k bits are used as virtual CRC;

in summary, with the technical solution of the present invention, the physical resource position of the semi-persistent scheduling data is represented by using the continuous virtual resource block or bitmap with a limited length, so as to reduce the bit overhead represented by the physical resource of the semi-persistent scheduling data, and use the saved bits as the virtual CRC, thereby improving the detection performance of the physical downlink control channel.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (13)

1. A method for representing physical resources for use in the representation of physical resource locations for semi-static data, the method comprising:

the physical resource location of the semi-static scheduling data is represented by using continuous virtual resource blocks with limited length.

2. The method of claim 1, wherein the specific process of using the continuous virtual resource blocks with limited length to represent the physical resource locations of semi-static scheduling data is as follows:

number L of consecutive virtual resource blocks limited by the length allocated to the semi-persistent scheduling data_CRBsAnd a starting position RB of the continuous virtual resource blocks allocated to the semi-persistent scheduling data_STARTDetermining the physical resource position of the semi-static scheduling data, and counting the number L of the continuous virtual resource blocks according to a preset mode_CRBsAnd starting position RB of the continuous virtual resource block_STARTAnd coding to obtain the resource representation signaling of the semi-static scheduling data.

3. The method according to claim 2, wherein the specific process of encoding in the predetermined manner is:

when in use

When RIV is equal to N_RB(L_CRBs-1)+RB_START(ii) a Otherwise, RIV ═ N_RB(N_RB-L_CRBs+1)+(N_RB-1-RB_START) Wherein L is_CRBsRepresenting the number of consecutive virtual resource blocks, RBs, allocated to said semi-persistent scheduling data_STARTRepresenting the starting position of consecutive virtual resource blocks allocated to said semi-persistent scheduling data, RIV representing signalling for the resources of said semi-persistent scheduling data, N_RBRepresenting the total number of available resource blocks on the bandwidth.

4. The method of claim 3, wherein the number of bits of the resource representation signaling of the semi-persistent scheduling data is:

where k represents the number of bits saved.

5. The method of claim 4, wherein the continuous virtual resource block maximum length is

6. The method of claim 5, wherein the saved number of bits k is selected from the group consisting of:

when N is present_RB>When H, k is 2; when N is present_RBWhen the ratio is less than or equal to H, k is 1, wherein H is a positive integer.

7. A method for representing physical resources for use in the representation of physical resource locations for semi-static data, the method comprising:

the physical resource locations of the semi-static scheduling data are represented using length-limited bitmaps.

8. The method according to claim 7, wherein the processing for indicating the physical resource location of the semi-persistent scheduling data is specifically:

and representing the physical resource position of the semi-static scheduling data by utilizing the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by an identifier and a resource indication bit map.

9. The method of claim 8, wherein the identifier and the resource indication bitmap represent a manner of resource representation signaling for the semi-static scheduling data comprises:

sequentially grouping after sequentially numbering all available resource blocks, wherein the number of resource blocks contained in each group except the last group is P, the number of resource blocks contained in the last group is less than or equal to P, and the total number of resource groups is PWherein P represents the number of resource blocks contained in one resource group, and P is a positive integer, wherein N is_RBRepresenting the total number of available resource blocks, N, over the bandwidth_RBGRepresenting the total number of resource groups;

according toDetermining the size of the resource indication bitmap, wherein k represents the saved bit number, each bit in the resource indication bitmap corresponds to one resource group, and represents whether all resource blocks in the resource group are allocated to a target user or not;

representing the starting position of the resource indication bitmap by the identifier, or representing whether the offset of the resource indication bitmap relative to the starting resource block is triggered, or representing that the current resource indication bitmap represents N by the identifier_RBGFirst N in a resource group_SPSWhether individual resource group is next N_SPSA set of resources.

10. The method according to claim 7, wherein the processing for indicating the physical resource location of the semi-persistent scheduling data is specifically:

and representing the physical resource position of the semi-static scheduling data by using the resource representation signaling of the semi-static scheduling data, wherein the resource representation signaling of the semi-static scheduling data is represented by a 1-bit identifier, a subset index and an intra-subset bitmap indication, and the 1-bit identifier represents the resource representation signaling of the leftmost end or the rightmost end represented by the intra-subset bitmap indication.

11. The method of claim 10, wherein the number of bits indicated by the bitmap within the subset is equal to

Where k represents the number of bits saved, P represents the number of resource blocks contained in a resource group,indicating the number of downlink available resource blocks.

12. The method according to claim 9 or 11, wherein the saved number of bits k takes the following values:

when N is present_RB>When H, k is 2; when N is present_RBWhen the ratio is less than or equal to H, k is 1, wherein H is a positive integer.

13. An apparatus for representing physical resources for use in the representation of physical resource locations for semi-static data, the apparatus comprising:

the first representation module is used for representing the physical resource position of the semi-static scheduling data by using a continuous virtual resource block with limited length; and/or

And a second representation module, configured to represent physical resource locations of the semi-static scheduling data using the length-limited bitmap.

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