KR20110098755A - Method, base station and terminal for sending and receiving hs-scch - Google Patents

Abstract

The present invention provides a method for transmitting and receiving a shared control channel (HS-SCCH) of a high speed downlink shared channel, a base station and a terminal, and uses HS-SCCH signaling of the same length under conditions for setting each functional demand. Among them, in the above method, the base station determines the channelization code information corresponding to the current functional demand based on the correspondence between the preset channelization code information and the functional demand, and includes the determined channelization code information for the terminal. Send HS-SCCH signaling, wherein the functional demand includes a multiple input / output (MIMO) function or a continuous packet connection (CPC) function. The present invention can compose the MIMO function and the CPC function, and prevents the terminal from blind detection or blind decoding for the HS-SCCH.

Description

METHOOD, BASE STATION AND TERMINAL FOR SENDING AND RECEIVING HS-SCCH}

TECHNICAL FIELD The present invention relates to mobile communication technology, and more particularly, to a method, a base station and a terminal for sending and receiving a shared control channel (HS-SCCH) of a high speed downlink shared channel.

In High Speed Package Access (HSPA) technology, the high speed downlink shared channel is shared before the base station sends downlink data to the mobile station (UE) through the high speed physical downlink shared channel (HS-PDSCH). The HS-PDSCH control information allocated to the UE should be transmitted to the UE through the control channel (HS-SCCH). Among them, HS-SCCH signaling included in HS-SCCH includes channelization code set identifier, time slot information, modulation method (Mod) information, data block size (TBS) information, and mixed automatic retransmission request (HARQ). Information, HS-SCCH cyclic sequence number (HCSN), UE ID and the like. Wherein the channelization code set ID includes a start code and a termination code indicating the start code channel information and the end code channel information in which the HS-PDSCH is located; The HARQ information includes HARQ process information (HAP), incremental redundancy version number (RV) and new data indication (NDI). 1 shows a conventional HS-SCCH signaling structure of the prior art, wherein the length of the conventional HS-SCCH signaling is 46 bits.

In the study of reinforced HSPA, multiple input multiple output (MIMO) technology was introduced. MIMO technology can improve the downlink data transmission speed and capacity of the system by sending a plurality of data streams to the UE through the base station. In consideration of problems such as hardware realization and cost consumption of the UE, the general MIMO scheme can support single stream and dual stream transmission of the downlink. Therefore, when performing single stream transmission, control information of a single stream must be sent to the UE through HS-SCCH, and when performing dual stream transmission, control information of dual stream must be sent to the UE through HS-SCCH. . In the prior art, the transmission scheme of the HS-SCCH already exists and can carry control information of MIMO single stream or dual stream. HS-SCCH signaling in such a transmission method includes channelization code set ID, time slot position information, single or dual stream data block size information, modulation information, HARQ information, HS-SCCH cyclic sequence number, UE ID, and the like. do.

In addition, continuous packet connectivity (CPC) technology was introduced in the research of enhanced HSPA. In order to reduce the overhead of the control channel, a semi-persistent scheduling technique has been proposed, that is, the base station can send a HS-SCCH once and allocate periodic semi-persistent resources to the UE. The base station may send data to the UE using the semi-persistent resource, and there is no need to perform resource scheduling every time until the base station reallocates the semi-persistent resource to the UE via the HS-SCCH. Such semi-persistent resource allocation and reallocation may be broadly referred to as semi-persistent resource allocation type. In addition, when there is new data or the UE does not correctly receive the data transmission, the base station may schedule downlink physical resources other than semi-persistent resources to the UE via the HS-SCCH, which is called a temporary scheduling resource type. . In the prior art, a transmission scheme of the HS-SCCH already exists and can carry control information of a semi-persistent resource allocation type or a temporary scheduling resource type.

However, since the lengths of the HS-SCCH signaling supporting the MIMO function and the CPC function are different, in order to avoid the UE performing blind detect or blind decoding on the HS-SCCH. The HS-SCCH transmission scheme of the technology can support either the MIMO function or the CPC function. That is, the corresponding HS-SCCH transmission method is provided to mount single stream control information in MIMO, dual stream control information is loaded, or the corresponding HS-SCCH transmission method is provided to load control information of CPC semi-persistent resources or The MIPC function and the CPC function cannot be complied with only the control information loading of the CPC temporary scheduling resource.

In view of these problems, the present invention provides a method for sending and receiving an HS-SCCH, a base station and a terminal to enable the MIMO function and the CPC function to be blind so that the UE detects blind or decodes the HS-SCCH. prevent.

In the method of sending the HS-SCCH using the same length of HS-SCCH signaling under the condition of setting each functional demand,

The base station determines the channelization code information corresponding to the current functional demand based on the correspondence between the preset channelization code information and the functional demand, and sends the HS-SCCH signaling including the determined channelization code information to the terminal. Wherein the functional demand includes a multiple input / output MIMO function or a continuous packet connection CPC function.

In the method for receiving the HS-SCCH using the same length of HS-SCCH signaling under the condition of setting each functional demand,

After receiving the HS-SCCH signaling, the terminal determines the functional demand corresponding to the channelization code information in the received HS-SCCH signaling based on the correspondence between the preset channelization code information and the functional demand. The HS-SCCH signaling is decoded according to the requested functional demand, wherein the functional demand includes a MIMO function or a CPC function.

A base station applied to a communication system using HS-SCCH signaling of the same length under each functional demand condition,

The base station includes a channelization code confirmation unit and a signaling sending unit,

The channelization code determination unit determines the channelization code information corresponding to the current functional demand based on the correspondence between the preset channelization code information and the functional demand,

The signaling sending unit sends HS-SCCH signaling including channelization code information determined by the channelization code determination unit to the terminal.

Among them, the functional demand includes a MIMO function or a CPC function.

A terminal applied to a communication system using the same length of HS-SCCH signaling under each functional demand condition,

The terminal includes a signaling accepting unit, a function confirming unit and a signaling decoding unit,

The signaling reception unit receives HS-SCCH signaling,

The function confirmation unit determines the function demand corresponding to the channelization code information of HS-SCCH signaling received by the signaling accepting unit based on the correspondence between the preset channelization code information and the function demand,

The signaling decoding unit decodes the HS-SCCH signaling according to the function demand determined by the function determination unit,

Among them, the functional demand includes a MIMO function or a CPC function.

As can be seen from the above description, the present invention is set to use the same length of HS-SCCH signaling under the MIMO function and the CPC function, and the base station is currently in accordance with the correspondence between the preset channelization code information and the functional demand The channelization code information corresponding to the functional demand of the terminal is determined, and the terminal sends the HS-SCCH signaling including the determined channelization code information. In other words, the base station provided by the present invention supports the MIMO function or the CPC function by sending HS-SCCH signaling including corresponding channelization code information based on the current functional demand, and correspondingly, the terminal receives Based on the channelization code information in one HS-SCCH signaling, the function demand corresponding to the current HS-SCCH signaling is determined and then the corresponding decoding process is performed. That is, the present invention composes the MIMO function and the CPC function, and sets the HS-SCCH signaling under the MIMO function and the CPC function to be the same length, thereby preventing the UE from blind detection or blind decoding for the HS-SCCH.

1 is a diagram for a conventional HS-SCCH signaling structure in the prior art.
FIG. 2 is a diagram illustrating a structure of HS-SCCH signaling for loading MIMO single stream transmission resource control information at 46 bits in length according to an embodiment of the present invention.
3 is a diagram illustrating a structure of HS-SCCH signaling for loading MIMO dual stream transmission resource control information in 46-bit length according to an embodiment of the present invention.
4 is a structural diagram of channelization code information in the structure of FIG.
5 is a diagram illustrating a structure of HS-SCCH signaling of semi-persistent resource allocation type for CPC function in 46-bit length according to an embodiment of the present invention.
6 is a structure diagram of channelization code information in the structure of FIG.
FIG. 7 illustrates a structure of HS-SCCH signaling of a temporary scheduling resource type for a CPC function at 46 bits in length according to an embodiment of the present invention.
8 illustrates a structure of HS-SCCH signaling for a MIMO function at 54 bits in length according to an embodiment of the present invention.
9 illustrates an HS-SCCH structure of a semi-persistent resource allocation type for the CPC function in a 54 bit length according to an embodiment of the present invention.
FIG. 10 illustrates an HS-SCCH structure of a temporary scheduling resource type for a CPC function in a 54 bit length according to an embodiment of the present invention.
FIG. 11 illustrates a structure of HS-SCCH signaling for a MIMO function at 52 bits in length according to an embodiment of the present invention.
12 is a structural diagram of a base station according to an embodiment of the present invention.
13 is a structural diagram of a terminal according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments in order to clarify the objectives, technical solutions, and advantages of the present invention.

According to an embodiment of the present invention, HS-SCCH signaling of the same length is used when setting various functional demands; Based on the correspondence between the channelization code information and the functional demand in the preset HS-SCCH signaling, the channelization code information corresponding to the current functional demand is determined, and the HS-SCCH signaling including the channelization code information. Send; Among them, the functional demand includes a MIMO function or a CPC function.

In addition, when the current functional demand is a MIMO function, the channelization code information corresponding to the current resource type is determined based on the correspondence between the channelization code information and the resource type, and the sent HS-SCCH signaling The channelization code information included in the channelization code information satisfies the current functional demand and at the same time the current resource type, wherein the resource type under the MIMO function is a MIMO single stream transmission resource or a MIMO dual stream transmission resource. Alternatively, if the current resource type is a MIMO single stream transmission resource, the TBS region of any one of the data streams is set to invalid, and if the current resource type is a MIMO dual stream transmission resource, two data streams are provided. Set all TBS fields in to valid.

If the current functional demand is a CPC function, the resource allocation cycle information corresponding to the current resource type is determined based on the correspondence between the resource allocation cycle information and the resource type, and the corresponding HS-SCCH signaling is applied. The determined resource allocation cycle information is further included, wherein the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.

Hereinafter, the method will be described in detail by combining specific embodiments. The method according to the present invention can be mainly divided into two cases according to the length of HS-SCCH signaling.

In the first case, under each functional requirement, a signaling structure of 46 bits is used, which is the same length as that of normal HS-SCCH signaling.

Single stream transmission of MIMO requires 16 HARQ processes, but in the conventional HS-SCCH signaling structure, since the HAP region indicating the number of HARQ processes is only 3 bits, only a maximum of 8 HARQ processes can be indicated. Signaling HS-SCCH cannot be used for transmission of MIMO single stream. Herein, the present invention newly presents an HS-SCCH signaling structure for 46-bit length and carrying MIMO single stream transmission resource control information. In the structure, the HAP region occupies 4 bits, eliminates the NDI region originally occupying 1 bit, and / or adjusts the RV region originally occupying 3 bits to 2 bits. For example, the HS-SCCH signaling structure shown in FIG. 2 can be used. In the structure shown in FIG. 2, the HAP region can find 16 bits and support 16 HARQ processes. Since it does not include the NDI area, RV area does not need to explicitly indicate the redundancy version, and defines the correspondence between the redundancy version and the RV value in advance so that one RV value is fixed to indicate new data transmission and the rest May indicate retransmission. Each other region can be made identical to the structure of conventional HS-SCCH signaling. This structure can also be used for scheduling initial data transmission or retransmission of non-persistent resources in the CPC. In the channelization code information of the structure, if the start code value is less than or equal to the end code value, the spread spectrum factor (SF) is 16. If the start code is 15 and the end code is 0, SF is 1; do.

In the prior art, the 46-bit long HS-SCCH signaling structure is already used to carry MIMO dual stream transmission resource control information. In the present invention, the HS-SCCH signaling structure can be directly introduced. 3 illustrates a structure of HS-SCCH signaling for loading MIMO dual stream transmission resource control information at 46 bits in length according to an embodiment of the present invention. As shown in Fig. 3, the structure is compared with conventional HS-SCCH signaling, and includes RV regions of two data streams each occupying two bits, and does not include NDI information. Here, the content of the channelization code information is different from the normal HS-SCCH signaling, including 2-bit MIMO ID information, 1-bit second data stream modulation information (Mod 2), and second data for the first data stream. It includes 5 bits of TBS size offset information of the stream, and the structure of the channelization code information is shown in FIG. Among them, the first bit and the fifth bit take fixed values as MIMO ID information to indicate that the HS-SCCH is used for MIMO dual stream transmission. In other words, if the channelization code information is 1xxx0xxx, it means that the corresponding HS-SCCH carries MIMO dual stream transmission resource control information, and x takes an arbitrary value. However, when the HS-SCCH of the structure carries MIMO dual stream transmission resource control information, only the state in which SF is 1 is supported.

In the prior art, the 46-bit long HS-SCCH signaling structure is already used for the semi-persistent resource allocation type or the temporary signaling resource type under the CPC function, but this can be distinguished from the conventional HS-SCCH signaling only. Can not be distinguished from HS-SCCH signaling under the MIMO function. Accordingly, the present invention provides an HS-SCCH signaling structure used for the semi-persistent resource allocation type under the CPC function and an HS-SCCH signaling structure used for the temporary signaling resource type under the CPC function, respectively.

FIG. 5 illustrates the structure of HS-SCCH signaling of semi-persistent resource allocation type for CPC function in 46 bit length according to an embodiment of the present invention. HS-SCCH signaling of this structure includes 12 bits of channelization code information, 5 bits of TS, 1 bit of Mod, 3 bits of HCSN, 5 bits of semi-persistent resource valid time, 2 bits of HS-SICH indication, 2 Bit-BS, CRC and UE ID, wherein the semi-persistent resource valid time indicates which TTI the semi-persistent resource allocated by the base station is valid from, and the HS-SICH indication indicates that the UE Indicates the HS-SICH used for feeding back information after decoding data received from the persistent resource. Among them, the channelization code information is improved compared to the structure of the prior art, and includes a 4-bit CPC ID, a 2-bit resource allocation period, and 6-bit code channel information (CCS). As shown in Fig. 6, the first, second, fifth, and sixth bits of the channelization code information indicate that the CPC ID is used for the CPC function by taking a fixed value.

That is, when the channelization code information is 11xx10xxxxxx, it indicates that the HS-SCCH is used for the CPC function, where x takes an arbitrary value. Among them, CCS indicates allocated code channel information, but the minimum granularity is a code channel having two SFs of 16, and the first 3 bits of the CCS area may be the start code, and the last 3 bits may be the end code. Is 7 and the termination code is 0, indicating that SF is 1.

7 illustrates a structure of HS-SCCH signaling of a temporary scheduling resource type for a CPC function at 46 bits in length according to an embodiment of the present invention. HS-SCCH signaling of the structure may include 12 bits of channelization code information, 5 bits of TS, 1 bit of Mod, 3 bits of HCSN, 2 bits of TBS, 2 bits of RV, and 4 bits of PTR. . The PTR indicates the interval, i.e., the number of TTIs, between the current retransmission and the first transmission of the data packet. Here, the format of the channelization code information is as shown in FIG. That is, the first, second, fifth, and sixth bits of the channelization code information are CPC IDs and take a fixed value to indicate that they are used for the CPC function. That is, when the channelization code information is 11xx10xxxxxx, it indicates that the HS-SCCH is used for the CPC function, where x may take an arbitrary value. CCS indicates allocated code channel information, but the minimum granularity is a code channel having two SFs of 16.

In the CPC function, the resource allocation period information in the channelization code information may be used to determine whether the HS-SCCH signaling is used for the semi-persistent resource allocation type or the temporary scheduling resource type. For example, 00 may indicate that only one TTI physical resource is allocated, i.e., that HS-SCCH signaling is used for the temporary scheduling resource type, and 01 indicates a 20-ms semi-persistent physical resource. It can indicate that it allocates, allocates a semi-persistent physical resource of 80 ms cycles by 10, and allocates a semi-persistent physical resource of 160 ms cycles by 11, that is, the HS-SCCH signaling is semi- Indicates that the resource is used for persistent resource allocation types.

In the first situation, i.e., when using 46-bit HS-SCCH signaling, when the base station determines that the current functional demand is a MIMO function, the HS-SCCH signaling structure corresponding to the MIMO function is sent and the HS-SCCH signaling is performed. The channelization code information is the channelization code information corresponding to the MIMO function. Specifically, in the transmission control information of the MIMO single stream, the value taken by the start code in the channelization code information is made equal to or smaller than the value taken by the termination code, for example, the HS-SCCH is assigned to the MIMO single stream using 0xxx1xxx. Indicating that, where x can take any value, or take the value of the start code as 15 and the value of the end code as 0. In the transmission control information of the MIMO dual stream, the first bit in the channelization code information takes 1 and the fifth bit takes 0.

When the base station determines that the current functional demand is a CPC function, it sends an HS-SCCH signaling structure corresponding to the CPC function, and the channelization code information in the HS-SCCH signaling is channelization code information corresponding to the CPC function. Specifically, the first, second, fifth, and sixth bits of the channelization code information take 1, 1, 1, and 0, respectively, and the channelization code information has resource allocation period information corresponding to the current resource type. have.

Correspondingly, after receiving the HS-SCCH, the UE acquires the channelization code information in the HS-SCCH, and based on the correspondence between the channelization code information in the HS-SCCH signaling and the function demand, the HS-SCCH. -Determine whether SCCH signaling will be used for MIMO function or CPC function. If used in the MIMO function, it is further determined based on the correspondence between the channelization code information and the resource type, whether the corresponding HS-SCCH signaling is MIMO single stream transmission resource control information or MIMO dual stream transmission resource control information. do. Specifically, if the value taken by the start code in the channelization code information is less than or equal to the value taken by the end code, for example, using 0xxx1xxx indicates that the HS-SCCH is used for the MIMO single stream, where x is It can take any value. Or if the start code takes 15 and the end code takes 0, it is determined that the HS-SCCH signaling carries MIMO single stream transmission resource control information, and according to the corresponding form, MIMO single stream transmission from the HS-SCCH signaling. Decode resource control information. If the first bit of the channelization code information takes 1 and the fifth bit takes 0, it is determined that the HS-SCCH signaling carries MIMO dual stream transmission resource control information, and according to the corresponding form, the HS- Decode MIMO dual stream transmission resource control information from SCCH signaling. If the first, second, fifth, and sixth bits of the channelization code information take 1, 1, 1, and 0, respectively, confirm that the HS-SCCH signaling carries CPC function control information, and furthermore, the channelization code information. It is possible to determine whether the HS-SCCH signaling is used for the semi-persistent resource allocation type or the temporary scheduling resource type through the resource allocation period information.

In the second case, an extended signaling structure is used than conventional HS-SCCH signaling, i.e., the length is larger than 46 bits.

There are several HS-SCCH signaling structures used for MIMO single-stream or dual-stream transmission in the conventional technology, and in the present invention, MIMO single-stream transmission resource control information using HS-SCCH having such a structure is directly used. Alternatively, the MIMO dual stream transmission resource control information may be loaded. However, since the length of the HS-SCCH signaling used for the CPC function existing in the prior art is 46 bits, in this situation, the method provided by the present invention mainly extends the HS-SCCH signaling under the CPC function and extends the length of the HS-SCCH signaling under the MIMO function. It provides a method to be equal to the length of -SCCH signaling and to use the corresponding HS-SCCH signaling according to the current functional demand. Correspondingly, the terminal may perform functional classification on the received HS-SCCH.

The HS-SCCH signaling may also use various lengths based on different settings of the channelization code information and the modulation information length. Some exemplary lengths will now be described, respectively, with some embodiments.

1) When the length of the HS-SCCH signaling is 54 bits, the channelization code information of the HS-SCCH signaling under the MIMO function is 8 bits, the HAP is 4 bits, and the structure may be as shown in FIG. Among them, Mod, TBS and RV information of two data streams are included, respectively. Under the MIMO function, the start code in the channelization code information takes a value less than or equal to the end code, or the value taken by the start code is greater than any specified value in the end code to indicate that SF is one. For example, the start code and the end code may be reversed as specific values indicating that SF is one. The start code takes the maximum value and the end code takes the minimum value. The following description is a description of all such examples, and will not be described below. At 54 bits, the value of the start code indicating that SF is 1 is 15 and the value of the termination code is 0. In the MIMO single stream transmission, if the TBS area of one of the data streams is set to 0, correspondingly, the Mod area and the RV area of the data stream are invalidated. For example, TBS2 may be set to 0, and correspondingly, Mod2 region and RV2 region may be set to 0. In MIMO dual stream transmission, both TBS regions to which two data streams correspond are valid.

Since the length of the HS-SCCH signaling under the conventional CPC function is 46 bits, the length of the HS-SCCH signaling under the CPC function must also be set to 54 bits to prevent the blind detection of the UE. In this case, by adding an 8-bit CPC ID in front of the HS-SCCH signaling form under the original CPC function, the channelization code information may be configured together with the original start code and the end code, and the structure of the remaining information is the same as in the prior art. It is composed. Among them, the HS-SCCH structure used for the semi-persistent resource allocation distribution type under the CPC function is shown in FIG. 9, and the HS-SCCH structure used for the temporary scheduling resource type is shown in FIG.

In the channelization code information for the MIMO function at this size, the HS- of the MIMO function is because the value taken by the start code is less than or equal to the termination code, or the value taken by the start code is 15 and the value taken by the termination code is 0. In order to indicate the CPC function separately from SCCH, the value set by the first 4 bits in the 8-bit CPC ID is set to be larger than the last 4 bits, and the first 4 bits and the last 4 bits are not set to take 15 and 0 at the same time. For example, the CPC ID may be set to any one of 11xx10xx, 11xx01xx, 10xx01xx, or 01xx00xx, and the x ID may be used as a bit that takes an arbitrary value or leaves it in advance.

2) When the length of the HS-SCCH signaling is 53 bits, the HS-SCCH signaling structure under the MIMO function is almost the same as the structure shown in FIG. 8, and the difference is that the HAP is 3 bits. In this case, the HS-SCCH signaling structure under the CPC function may use the structures shown in FIGS. 9 and 10, respectively. If different, the CPC ID added to the channelization code information is 7 bits. To distinguish it from HS-SCCH signaling under the MIMO function, the value taken by the first four bits of the channelization code information is greater than the next four bits contiguous and the first four bits and the next four bits contiguous do not simultaneously take 15 and 0, respectively. Should be. At this time, the CPC ID may be set to any one of 11xx10x, 11xx01x, 10xx00x, 10xx01x, or 01xx00x, and x ID may be used as a bit that takes an arbitrary value or leaves it in advance. In addition, one bit of the two bits previously left in the HS-SCCH signaling may be added to the CPC ID to form the same CPC eye as shown in FIGS. 9 and 10.

3) When the length of the HS-SCCH signaling is 52 bits, the HS-SCCH signaling structure under the MIMO function is almost the same as the structure shown in FIG. 8, and the difference is that the channelization code information is 6 bits. The HS-SCCH signaling structure having a length of 52 bits and used for the MIMO function may be as shown in FIG. Since the channelization code information is reduced to 6 bits, the first 3 bits are the start code and the last 3 bits are the end code. At this time, the code channel granularity allocated is increased from one code channel with SF 16 to two code channels with SF 16 when compared with the structure shown in FIG. In this case, the HS-SCCH signaling structure under the CPC function can also use the structures shown in FIGS. 9 and 10, respectively. If different, the CPC ID added to the channelization code information is 6 bits. To distinguish it from HS-SCCH signaling under the MIMO function, the value taken by the first 3 bits of the channelization code information is larger than the value taken by the next adjacent 3 bits, and the values taken by the first 3 bits and the next adjacent 3 bits are simultaneously. It should not be 7 and 0. At this time, the CPC ID may be set to any one of 11x10x, 11x01x, 10x00x, 10x01x, or 01x00x, and x ID may be used as a bit that takes an arbitrary value or is left in advance.

4) When the length of the HS-SCCH signaling is 51 bits, the structure of the HS-SCCH signaling under the MIMO function is almost the same as that shown in FIG. 11, and the difference is that the HAP is 3 bits. In this case, the HS-SCCH signaling structure under the CPC function may use the structures shown in FIGS. 9 and 10, respectively. If different, the CPC ID added to the channelization code information is 5 bits. To distinguish it from HS-SCCH signaling under the MIMO function, the value taken by the first three ratios in the channelization code information is also greater than the value taken by the next adjacent three bits, and the first three bits and the next adjacent three bits are simultaneously 7 and 0, respectively. Do not take it. At this time, the CPC ID may take any one of 11x10, 11x01, 10x00, 10x01, or 01x00, and x ID may be used as a bit that takes an arbitrary value or is left in advance. In addition, one bit of the two bits originally left in the HS-SCCH signaling may be added to the CPC ID.

In the second situation, in addition to the four lengths of HS-SCCH signaling, HS-SCCH signaling under the MIMO function may take 50 bits and 49 bits as the length of the channelization code information and the HAP is different. When 50 bits are taken, a specific value indicating that SF is 1 in the channelization code information under the MIMO function is set to 0 and 1 for the first and second bits of the start code, and 1 and 2 bits for the termination code, respectively. Can be taken as 0 and 0 respectively. For example, 0100 can be taken. Correspondingly, under the CPC function, the CPC ID included in the channelization code information of the HS-SCCH signaling may be set to 4 bits and 3 bits, respectively. If the CPC ID is 4 bits, it can be set to any one of 1110, 1101, 1000, 1001, or 0100. If the CPC ID is 3 bits, it can be set to 100. Detailed examples thereof will not be described here.

In addition, HS-SCCH signaling under the MIMO function may take 48 bits and 47 bits. In this case, 2 bits and 1 bit can be added to the HS-SCCH signaling, respectively, and 2 bits left in advance in the HS-SCCH signaling can be moved to the front to form a 4 bit and 3 bit CPC ID together with the added bit. have. That is, if the HS-SCCH signaling under the MIMO function is 48 bits, the channelization code of the HS-SCCH signaling under the corresponding CPC function includes a 4-bit CPC ID, and is any one of 1110, 1101, 1000, 1001, or 0100. Can be set to display CPC functions. When the HS-SCCH signaling under the MIMO function is 47 bits, the channelization code of the HS-SCCH signaling includes the 3-bit CPC ID under the corresponding CPC function, and may be set to 100 to indicate the CPC function.

In the second situation, the HS-SCCH signaling under the CPC function also distinguishes whether to use the semi-persistent resource allocation type or the temporary scheduling resource type through the resource allocation period information.

In addition, the reserved space in the HS-SCCH signaling may be further used for the portable code channel allocation scheme information. For example, by using two bits left in advance, it is possible to indicate whether to use a code channel allocation method in which 1 SF is 1, a code channel allocation method in which 16 SFs are 16, or another code channel allocation method. have. Specifically, the first group allocation scheme or the second group allocation scheme may be indicated by one bit thereof. In the case of the first group allocation scheme, the second bit specifically indicates whether to use a code channel allocation scheme in which 1 SF is 1 or the code channel allocation scheme in which 16 SFs are 16. In the case of the second group allocation scheme, the second bit specifically indicates that a different code channel allocation scheme in which SF is 16 is used.

In the embodiment of the method, the length of the HS-SCCH signaling used by the base station and the terminal may be preset. That is, the base station and the terminal contract the length of HS-SCCH signaling to be used and perform transmission of HS-SCCH signaling according to the determined length. The network side (eg, the wireless network controller) may also use the length of the HS-SCCH signaling corresponding to the capability state of the terminal based on the capability state of the terminal, and use the HS-SCCH signaling length information through higher layer signaling. Transmit to base station and terminal. The base station performs the sending of the HS-SCCH signaling according to the length of the HS-SCCH signaling, and the terminal performs the reception of the HS-SCCH signaling according to the length of the HS-SCCH signaling. Among them, the HS-SCCH signaling length information sent by the network side may be carried in higher layer signaling in an explicit manner. More preferably, parameter information of the HS-SCCH signaling length can be implicitly carried in higher layer signaling. The base station and the terminal determine corresponding HS-SCCH signaling length information through parameter information carried by higher layer signaling.

For example, if the terminal reports to the radio network controller that its capability supports a resource whose SF is 1, then the radio network controller confirms to use 46-bit long HS-SCCH signaling and 46-bit through higher layer signaling. Transmits the information to the base station and the terminal. After receiving the higher layer signaling, the base station sends the HS-SCCH corresponding to the current functional demand according to the 46-bit HS-SCCH, and the terminal receives the higher layer signaling and then HS according to the length of 46 bits. Decode for SCCH. If the terminal reports to the radio network controller that its capability can support a resource with an SF of 1 and can also support a resource with an SF of 16, the radio network controller can transmit a 46-bit length to the base station and the terminal through higher layer signaling. It is possible to inform the base station and the terminal to use the HS-SCCH signaling structure that is greater than 46 bits in length. The base station sends the HS-SCCH according to the indication of the higher layer signaling, and the terminal decodes the HS-SCCH of the corresponding length according to the indication of the higher layer.

The method provided by the present invention has been described in detail above, and the base station and the terminal provided by the present invention will be described in detail below. 12 is a structural diagram of a base station according to an embodiment of the present invention. The base station is applied to a communication system using HS-SCCH signaling of the same length under each functional demand condition. As shown in Fig. 12, the base station may include a channelization code determination unit 1201 and a signaling sending unit 1202.

The channelization code determination unit 1201 determines the channelization code information corresponding to the current functional demand based on the correspondence between the preset channelization code information and the functional demand.

The signaling sending unit 1202 sends HS-SCCH signaling including the channelization code information determined by the channelization code determination unit 1201 to the terminal.

Among them, the functional demand includes a MIMO function or a CPC function.

In addition, the base station may further include a signaling length determination unit 1203 for determining the preset HS-SCCH signaling length information or for obtaining the used HS-SCCH signaling length information from the received higher layer signaling.

The channelization code determination unit 1201 determines the channelization code information corresponding to the current functional demand at the length determined by the signaling length determination unit 1203.

The signaling sending unit 1202 sends HS-SCCH signaling according to the length information determined by the signaling length determining unit 1203.

More preferably, when the current resource type is determined to be a MIMO function, the channelization code determination unit 1201 performs channelization corresponding to the current resource type based on the correspondence between the channelization code information and the resource type. The code information can be confirmed, and the signaling sending unit 1202 provides channelization code information corresponding to the current functional demand and corresponding to the current resource type.

This structure refers to the 46-bit HS-SCCH structure, and other structures may be used for the HS-SCCH structure larger than 46 bits. At this time, the base station, if the channelization code determination unit 1201 determines that the current resource type is a MIMO function, if the current resource type is a MIMO single stream transmission resource, the HS- signal sent by the signaling sending unit 1202 If the TBS region of any data stream of SCCH signaling is set to invalid and if the current resource type is a MIMO dual stream transmission resource, the TBS region of two data streams of the HS-SCCH signaling sent by the signaling sending unit 1202 is set. It may further include a TBS region setting unit 1204 for setting all to be valid.

In addition, when the channelization code determination unit 1201 determines that the current resource type is a CPC function, the system allocates a resource corresponding to the current resource type to the HS-SCCH signaling sent by the channel sending unit 1202. The apparatus may further include a period setting unit 1205 for carrying the period information. Among them, the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.

13 is a structural diagram of a terminal according to an embodiment of the present invention. The terminal is also applied to a communication system using HS-SCCH signaling of the same length under each functional requirement. As shown in Fig. 13, the terminal may include a signaling reception unit 1301, a function determination unit 1302, and a signaling decoding unit 1303.

The signaling reception unit 1301 receives HS-SCCH signaling.

The function confirmation unit 1302 determines the function demand corresponding to the channelization code information in the HS-SCCH signaling received by the signaling reception unit 1301 based on the correspondence between the preset channelization code information and the function demand. do.

The signaling decoding unit 1303 decodes the HS-SCCH signaling according to the function demand determined by the function determination unit 1302.

Among them, the functional demand includes a MIMO function or a CPC function.

In addition, the terminal may further include a signaling length determination unit 1304 for determining the preset HS-SCCH signaling length information or for acquiring the HS-SCCH signaling length information from the received higher layer signaling.

The function confirmation unit 1302 determines the function demand corresponding to the channelization code information of the HS-SCCH signaling under the length information determined by the signaling length decision unit 1304.

The signaling decoding unit 1303 decodes the HS-SCCH signaling according to the length information determined by the signaling length determination unit 1304.

More preferably, when the function determination unit 1302 determines that the current functional demand is a MIMO function, the terminal determines the channelization code of the HS-SCCH signaling based on the correspondence between the channelization code information and the resource type. The method may further include a first resource type determination unit 1305 for determining a resource type corresponding to the information. Among them, the resource type under the MIMO function is a MIMO single stream transmission resource or a MIMO dual stream transmission resource.

The signaling decoding unit 1303 performs a decoding operation according to the functional demand determined by the function determination unit 1302 and the resource type determined by the first resource type determination unit 1305.

The first resource type determination unit 1305 refers to 46-bit long HS-SCCH signaling, and another structure may be used for HS-SCCH signaling larger than 46 bits long. That is, when the function determination unit 1302 determines that the current function demand is a MIMO function, the terminal determines the current resource type based on the TBS region information included in the received HS-SCCH signaling. If the TBS region of the two data streams is set to invalid, determine the current resource type as a MIMO single stream transmission resource. If the TBS regions of the two data streams are set to all valid, set the current resource type to the MIMO dual stream transmission resource. A second resource type determination unit 1306 may be further included for determining.

The signaling decoding unit 1303 performs a decoding operation according to the functional demand determined by the function determination unit 1302 and the resource type determined by the second resource type determination unit 1305.

In addition, when the function determination unit 1302 determines that the current function demand is a CPC function, the terminal determines resource allocation period information included in the HS-SCCH signaling based on the correspondence between the resource allocation period information and the resource type. The apparatus may further include a third resource type determination unit 1307 for determining a resource type corresponding to.

The signaling decoding unit 1303 performs a decoding operation according to the functional demand determined by the function determination unit 1302 and the resource type determined by the third resource type determination unit 1307.

Among them, the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.

The base station and the terminal provided in the above embodiment can realize the corresponding function of each unit by using the specific scheme provided in the method embodiment.

As can be seen from the above description, the present invention uses HS-SCCH signaling of the same length under the condition of setting the MIMO function and the CPC function, and thus the base station is based on the correspondence between the preset channelization code information and the functional demand. After confirming the channelization code information corresponding to the current functional demand, the terminal sends the HS-SCCH signaling including the determined channelization code information. In other words, the base station provided by the present invention supports the MIMO function or the CPC function by sending HS-SCCH signaling including corresponding channelization code information based on the current functional demand, and correspondingly, the terminal receives After the functional demand corresponding to the current HS-SCCH signaling is determined using the channelization code information in the HS-SCCH signaling, a corresponding decoding process is performed. That is, the present invention composes the MIMO function and the CPC function, and sets the HS-SCCH signaling under the MIMO function and the CPC function to use the same length, thereby preventing the UE from blind detection or blind decoding for the HS-SCCH. .

The foregoing descriptions are merely preferred embodiments of the present invention, but do not limit the present invention. All changes, equivalent substitutions and improvements made within the spirit and principles of the present invention shall be included within the scope of the present invention.

Explanation of symbols on the main parts of the drawings
1201: channelization code confirmation unit 1202: signaling sending unit
1203: signaling length determination unit 1204: TBS region setting unit
1205: cycle setting unit

Claims (30)

In the method for sending the shared control channel HS-SCCH of the high-speed downlink shared channel using the same length of HS-SCCH signaling under the condition of setting each functional demand,
The base station determines the channelization code information corresponding to the current functional demand based on the correspondence between the preset channelization code information and the functional demand, and sends the HS-SCCH signaling including the determined channelization code information to the terminal. And wherein the functional demand includes a multiple input / output MIMO function or a continuous packet connection CPC function.
The method of claim 1,
The used HS-SCCH signaling length information is preset in the base station and the terminal, or the network side transmits the HS-SCCH signaling length information to the base station and the terminal through higher layer signaling. To send the shared control channel HS-SCCH.
The method of claim 1,
If the current functional demand is a MIMO function, the base station further determines channelization code information corresponding to the current resource type based on the correspondence between the channelization code information and the resource type, but the HS sent by the base station. The channelization code information included in the SCCH signaling is channelization code information corresponding to the current resource type while corresponding to the current functional demand, wherein the resource type under the MIMO function is a MIMO single stream transmission resource or a MIMO dual stream transmission resource. Is or
Further, if the current resource type is a MIMO single stream transmission resource, the base station further sets the size TBS region of the data block of one of the data streams to be invalid in the HS-SCCH signaling to be sent, and the current resource type is set to invalid. In the case of a MIMO dual stream transmission resource, a method for transmitting a shared control channel HS-SCCH of a high speed downlink shared channel, characterized in that the TBS region of both data streams is set to be valid in the HS-SCCH signaling.
The method of claim 1,
If the current functional demand is a CPC function, the base station further determines resource allocation period information corresponding to the current resource type based on the correspondence between the resource allocation period information and the resource type, and the HS sent by the base station. The SCCH signaling further includes the determined resource allocation period information, wherein the resource type under the CPC function includes a semi-persistent resource allocation type or a temporary scheduling resource type. How to ship HS-SCCH.
The method of claim 2,
The used HS-SCCH signaling length information indicates that the length of HS-SCCH signaling is greater than 46 bits or 46 bits.
The method of claim 5, wherein
If the length of HS-SCCH signaling used is 46 bits,
For the MIMO single stream transmission resource under the MIMO function, the HS-SCCH signaling includes 4-bit mixed automatic retransmission request process HAP information, and the determined channelization code information is a value that the start code takes and the end code takes. Less than or equal to, or start code takes 15 and end code takes 0,
For the MIMO dual stream transmission resource under the MIMO function, the first and fifth bits of the determined channelization code information are 1 and 0, respectively, and the channelization code information includes modulation information and second data of a second data stream. The stream further includes TBS size offset information for the first data stream,
For a semi-persistent resource allocation type or temporary scheduling resource type under the CPC function, the first, second, fifth and sixth bits of the determined channelization code information take 1, 1, 1 and 0, respectively, and the channelization code The method further comprises resource allocation period information. The method for sending a shared control channel HS-SCCH of the fast downlink shared channel.
The method according to claim 6,
For the MIMO single stream transmission resource under the MIMO function, the first and fifth bits of the determined channelization code information take 0 and 1, respectively. How to ship.
The method of claim 5, wherein
If the length of the used HS-SCCH signaling is greater than 46 bits,
For the MIMO single stream transmission resource under the MIMO function, the determined channelization code information is that the value taken by the start code is less than or equal to the value taken by the termination code, or the start code and the termination code are the band spreading factor SF is 1; Taking a predetermined value to be displayed and setting the TBS region of one of the data streams carried in the HS-SCCH signaling to invalid;
For the MIMO dual stream transmission resource under the MIMO function, the determined channelization code information is intended to indicate that the value taken by the start code is less than or equal to the value taken by the end code, or the start code and the end code indicate that SF is 1 Taking a value and setting all of the TBS regions of the two data streams carried in the HS-SCCH signaling to be valid;
For a semi-persistent resource allocation type or temporary scheduling resource type under the CPC function, the determined channelization code information includes a CPC ID of N-46 bits or N-46 + M bits length, where N is the HS used. The length of SCCH signaling and M is the length of bits left in advance during HS-SCCH signaling, and the value taken by the CPC ID is taken by the first N-46 bits or the first N-46 + M bits of channelization code information under the MIMO function. A method for sending a shared control channel HS-SCCH of a high speed downlink shared channel, characterized in that it is a value other than a value.
The method of claim 8,
When the length of the HS-SCCH signaling used is 50 bits, the first bit and the second bit of the start code take 0 and 1, respectively, in a predetermined value indicating that SF taken by the start code and the end code is 1; And a first bit and a second bit of the code take zeros and zeros, respectively.
The method of claim 8,
For the semi-persistent resource allocation type or the temporary scheduling resource type under the CPC function, sharing of the high speed downlink shared channel further comprises carrying code channel allocation scheme information in the reserved bits of the HS-SCCH or the CPC ID. Method of sending control channel HS-SCCH.
In a method for receiving an HS-SCCH using HS-SCCH signaling of the same length under the conditions for setting each functional demand,
After receiving the HS-SCCH signaling, the terminal determines the functional demand corresponding to the channelization code information in the received HS-SCCH signaling based on the correspondence between the preset channelization code information and the functional demand. Decoding the HS-SCCH signaling according to the demand for the function, wherein the demand for the function includes a MIMO function or a CPC function.
The method of claim 11,
And the used HS-SCCH signaling length information is obtained from higher layer signaling previously set or received in the terminal.
The method of claim 11,
When the terminal determines that the functional demand is a MIMO function, the terminal further determines the resource type corresponding to the received channelization code information of the HS-SCCH signaling based on the correspondence between the channelization code information and the resource type. Performing the decoding step according to a determined resource type, wherein the resource type under the MIMO function is a MIMO single stream transmission resource or a MIMO dual stream transmission resource, or
Further, the current resource type is determined based on the received TBS region information included in the HS-SCCH signaling. If the TBS region of one data stream is set to invalid, the current resource type is MIMO. The decoding step is performed in a manner corresponding to the MIMO single stream transmission resource by determining that it is a single stream transmission resource. If both TBS regions of the two data streams are set to be valid, the current resource type is the MIMO dual stream transmission resource. And deciding to perform the decoding step in a manner corresponding to a MIMO dual stream transmission resource.
The method of claim 11,
If the terminal determines that the functional demand is a CPC function, the terminal further corresponds to the resource allocation period information included in the HS-SCCH signaling received based on the correspondence between the resource allocation period information and the resource type. Determining a resource type and performing the decoding step according to the determined resource type, wherein the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.
The method of claim 12,
The used HS-SCCH signaling length information indicates that the length of the HS-SCCH signaling is 46 bits or greater than 46 bits.
The method of claim 15,
If the length of HS-SCCH signaling used is 46 bits,
If the value taken by the start code of the channelization code information is less than or equal to the value taken by the end code, or if the start code takes 15 and the end code takes 0, the terminal indicates that the current functional demand is a MIMO function. And the HS-SCCH signaling carries control information of a MIMO single stream transmission resource.
If the first bit and the fifth bit of the channelization code information are 1 and 0, respectively, the terminal determines that the current functional demand is a MIMO function, and the HS-SCCH signaling provides control information of the MIMO dual stream transmission resource. Mounted,
If the first, second, fifth, and sixth bits of the channelization code information take 1, 1, 1, and 0, respectively, the terminal determines that the current functional demand is a CPC function. How to receive.
17. The method of claim 16,
If the first and fifth bits of the channelization code information take 0 and 1, respectively, the terminal determines that the current functional demand is a MIMO function, and the HS-SCCH signaling controls the MIMO single stream transmission resource. A method for receiving an HS-SCCH, characterized by mounting information.
The method of claim 15,
If the length of the used HS-SCCH signaling is greater than 46 bits,
If the value taken by the start code in the channelization code information is less than or equal to the value taken by the end code, or the start code and the end code take a predetermined value indicating that the spread spectrum factor SF is 1, then the current function. To confirm that demand is a MIMO feature,
The channelization code information includes a CPC ID of N-46 bits or N-46 + M bits, wherein the CPC ID is the first N-46 bits or the first N-46 + M bits of the channelization code information under the MIMO function. If it takes a value other than the value taken, it is determined that the current functional demand is a CPC function, wherein N is the length of the used HS-SCCH signaling and M is the length of the bits left in advance of the HS-SCCH signaling. How to file an HS-SCCH.
The method of claim 18,
After determining that the current functional demand is a MIMO function, if the TBS region of one of the data streams carried by the HS-SCCH signaling is set to invalid, the terminal indicates that the HS-SCCH signaling is a MIMO single stream transmission resource. Determining that the control information is loaded, and performing the decoding step in a manner corresponding to a MIMO single stream transmission resource, and if both TBS regions of the two data streams carried by the HS-SCCH signaling are set to be valid, The terminal determines that the HS-SCCH signaling includes control information of a MIMO dual stream transmission resource, and performs the decoding step in a manner corresponding to the MIMO dual stream transmission resource.
The method according to any one of claims 18 or 19,
If the length of the used HS-SCCH signaling is 50 bits, the predetermined value indicating that the SF taken by the start code and the end code is 1, the first bit and the second bit of the start code take 0 and 1, respectively, and terminate And a first bit and a second bit of the code take zeros and zeros, respectively.
A base station applied to a communication system using HS-SCCH signaling of the same length under each functional demand condition,
The base station includes a channelization code confirmation unit and a signaling sending unit,
The channelization code determination unit determines the channelization code information corresponding to the current functional demand based on the predetermined relationship between the channelization code information and the functional demand, and the signaling sending unit determines the channelization code to the terminal. Send HS-SCCH signaling including channelization code information determined by the unit,
Wherein the functional demand includes a MIMO function or a CPC function.
The method of claim 21,
The base station further includes a signaling length determination unit for determining preset HS-SCCH signaling length information or for obtaining the used HS-SCCH signaling length from the received higher layer signaling,
The channelization code determination unit determines channelization code information corresponding to a current functional demand under a length determined by the signaling length determination unit,
And the signaling sending unit sends HS-SCCH signaling according to the length information determined by the signaling length determining unit.
The method of claim 21 or 22,
The channelization code determination unit, when determining that the current resource type is a MIMO function, determines the channelization code information corresponding to the current resource type based on the correspondence between the channelization code information and the resource type. And channelization code information corresponding to a current resource type to the signaling sending unit corresponding to the functional demand of the base station.
The method of claim 21 or 22,
If the channelization code determination unit determines that the current resource type is a MIMO function, if the current resource type is a MIMO single stream transmission resource, any one of HS-SCCH signaling sent by the signaling sending unit TBS for setting the TBS area of the stream to invalid and for setting both TBS areas of two data streams of HS-SCCH signaling sent by the signaling sending unit if the current resource type is a MIMO dual stream transmission resource. The base station further comprises a region setting unit.
The method of claim 21 or 22,
A period setting unit for carrying the resource allocation period information corresponding to the current resource type in the HS-SCCH signaling sent by the channel sending unit when the channelization code determination unit determines that the current resource type is a CPC function More,
Wherein the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.
A terminal applied to a communication system using the same length of HS-SCCH signaling under each functional demand condition,
The terminal includes a signaling accepting unit, a function confirming unit and a signaling decoding unit,
The signaling reception unit receives HS-SCCH signaling,
The function confirmation unit determines the function demand corresponding to the channelization code information of HS-SCCH signaling received by the signaling accepting unit based on the correspondence between the preset channelization code information and the function demand,
The signaling decoding unit decodes the HS-SCCH signaling according to the function demand determined by the function determination unit,
Wherein said functional demand includes a MIMO function or a CPC function.
The method of claim 26,
The terminal further includes a signaling length determination unit for determining preset HS-SCCH signaling length information or for acquiring the HS-SCCH signaling length information from the received higher layer signaling.
The function confirmation unit determines the function demand corresponding to the channelization code information in the HS-SCCH signaling under the length information determined by the signaling length decision unit,
And the signaling decoding unit decodes the HS-SCCH signaling according to the length information determined by the signaling length determination unit.
The method of claim 26 or 27, wherein
The terminal, when the function determination unit determines that the current functional demand is a MIMO function, the resource type corresponding to the channelization code information of the HS-SCCH signaling based on the correspondence between the channelization code information and the resource type. Further comprising a first resource type determination unit for determining
The signaling decoding unit performs the decoding operation according to the functional demand determined by the function determination unit and the resource type determined by the first resource type determination unit,
Wherein the resource type under the MIMO function is a MIMO single stream transmission resource or a MIMO dual stream transmission resource.
The method of claim 26 or 27, wherein
The terminal, when the function determination unit determines that the current functional demand is a MIMO function, determines the current resource type based on the TBS region information included in the received HS-SCCH signaling, if one of the data If the TBS area of the stream is set to invalid, it is determined that the current resource type is a MIMO single stream transmission resource. If the TBS area of both data streams is set to be valid, the current resource type is determined to be a MIMO dual stream transmission resource Further comprising a second resource type determination unit for
And the signaling decoding unit performs the decoding operation according to the function demand determined by the function determination unit and the resource type determined by the second resource type determination unit.
The method of claim 26 or 27, wherein
When the function determination unit determines that the current function demand is a CPC function, the terminal corresponds to the resource allocation period information included in the HS-SCCH signaling based on the correspondence between the resource allocation period information and the resource type. Further comprising a third resource type determination unit for determining a resource type,
The signaling decoding unit performs the decoding operation according to the functional demand determined by the function determination unit and the resource type determined by the third resource type determination unit,
Wherein, the resource type under the CPC function is a semi-persistent resource allocation type or a temporary scheduling resource type.

Images