RU2642516C2 - Method and device for shared use of code resource of associated individual physical channel - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method for sharing a code resource of an associated dedicated physical channel (A-DPCH) includes the following receiving a request to establish a radio link (RL-request); it is estimated whether the RL request is an RL request for data only transmission or not; if the RL-request is an RL-request for the transfer of only data, from the used A-DPCH code resource for allocation to the A-DPCH according to the type of the RL-request service, a code resource, corresponding to an available SOFF offset (Symbol chipOffset), in which the offset SOFF is a time difference rounded off by 2560 chips between the DPCH 0 slot (DCH) and the Primary Common Pilot Channel (PCPICH) header, is selected.

EFFECT: reduction of the use of code resources of the associated dedicated physical channel of the cell with an increased number of users.

11 cl, 7 dwg, 1 tbl

Description

Technical field

This invention relates to the field of mobile communications, in particular to a method and device for sharing a code resource of an associated dedicated physical channel (A-DPCH, Associated-Dedicated Physical Channel).

BACKGROUND OF THE INVENTION

To perform the High Speed Downlink Packet Access (HSDPA) service in addition to the High Speed Downlink Shared Channel (HS-PDSCH, High-Speed Physical Downlink Shared Channel), High Speed Shared Signaling Control Channel (HS-SCCH , High Speed-Shared Signaling Control Channel) and high-speed dedicated physical control channel on the uplink (HS-DPCCH, High Speed-Uplink Dedicated Physical Control Channel), the channel A-DPCH is required, and, as a rule, A-DPCH is configured to signaling radio channel transmission (SRB, Signaling Radio Bearer).

Typically, the A-DPCH Spreading Factor (SF) is 256 (which corresponds to the SRB 3.4k data rate, the most common version, while SF can be 128-32, which corresponds to the channel data rate SRB 13.6k and above), for each user of the HSDPA protocol, one A-DPCH channel must be provided, and every 16 A-DPCH channels can use the SF16 code resource. Typically, the HSDPA and A-DPCH services have only 13 code resources with SF16 (the other three are used by common channels and other R99 channels). If there are 96 HSDPA users per cell, then only A-DPCH channels can use 96 code resources with SF256, which are converted into 6 code resources with SF16, and only 7 code resources SF16 are allocated to the HSDPA reference service. To improve the capabilities of the air interface, one cell can receive up to 192 HSDPA users, and at the moment only A-DPCH channels can use 12 SF16 code resources, then the HSDPA data service can use only one SF16 code resource and, therefore, the cell is difficult to transmit data due to lack of code resources.

Code resources are the most important logical resources of the cell on the downlink, and to solve the problem of using code resources with A-DPCH channels, the 3GPP protocol (Partnership Project of the Third Generation) includes the technology of partial dedicated physical channels (F-DPCH, Fractional Dedicated Physical Channel) for R6 SRB is transmitted over a high-speed shared channel on the downlink (HS-DSCH, High-Speed Downlink Shared Channel), the F-DPC channel only transmits transmission power control commands (TPC, Transmission Power Control), and transmission power control commands 10 pol callers are compressed to F-DPCH with SF256, thereby significantly reducing the use of code resources.

However, most terminals of existing commercial networks do not support the F-DPCH protocol, so the problem of excessive use of the code resources of the A-DPCH cells with an increased number of users does not yet have a satisfactory solution.

SUMMARY OF THE INVENTION

An embodiment of the invention of a method and apparatus for sharing the code resource of the A-DPCH channel is proposed, which will significantly reduce the use of the code resource of the A-DPCH.

To solve the technical side of the issue, the following technical solutions are implemented in accordance with an embodiment of the invention.

A method for sharing an A-DPCH code resource is proposed, which may include the following:

receiving a request to establish a radio link (RL-request);

evaluates whether the RL request is an RL request to transmit only data or not;

if the RL request is an RL request to transmit only data, from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available offset SOFF (Symbol chipOffset) is selected, where SOFF is this is the time difference rounded taking into account 2560 chips between slot 0 of the dedicated physical channel (DPCH, Dedicated Physical Channel) and the frame header of the primary common pilot channel (PCPICH, Primary Common Pilot Channel).

In a preferred embodiment, the step of selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH depending on the type of RL request service may include the following:

if the RL request is a locally generated initial RL request, then the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH, and the default offset value (DOFF, Default Offset) is generated in according to the selected available SOFF offset;

if the RL request is an RL request with a soft handover, then the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH.

In a preferred embodiment, the step of selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH and generating a DOFF in accordance with the selected available SOFF offset can include the following:

the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values, then the code resource corresponding to the first available SOFF offset found is allocated to A-DPCH, and DOFF is generated in accordance with the available SOFF offset;

if there are no available SOFF offsets in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH channel, and the corresponding DOFF is equal to 0.

In a preferred embodiment, the step of selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH may include the following:

the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values, and the code resource corresponding to the first available SOFF offset equal to the SOFF offset of the A-DPCH is allocated to the A-DPCH;

if the available SOFF offsets equal to the SOFF of the A-DPCH are not found in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH.

In a preferred embodiment, the step in which the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values may include the following:

if in the used A-DPCH code resource, the SOFF N offset is allocated to the A-DPCH, the following three SOFF offsets in the A-DPCH code resource are defined as inaccessible: N, N + 2 mod 10, N + 8 mod 10.

In another embodiment of the invention, there is provided an A-DPCH channel resource sharing apparatus, which may include:

a receiving module configured to receive an RL request;

an analytical module evaluating whether the RL request is an RL request to transmit only data or not;

a processing module configured to select, from the used A-DPCH code resource for distribution on the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available SOFF offset if the RL request is an RL request to transmit only data to where the offset SOFF is the time difference rounded taking into account 2560 chips between slot 0 of the DPCH and the frame header of the PCPICH.

In a preferred embodiment, the processing module may include:

a DOFF offset submodule of the initial radio link and code resource allocation, configured to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset, if the RL request is a locally generated initial RL request, and generate DOFF offsets according to the selected available SOFF offsets;

soft handover radio resource code resource distribution submodule adapted to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset if the RL request is an RL request with soft handover.

In a preferred embodiment, the DOFF offset submodule of the initial radio link and code resource allocation may include:

a DOFF bias unit of the initial radio link and code resource allocation, configured to search available SOFF from small to large SF values in the used A-DPCH code resources;

an initial radio link establishment interface unit configured to allocate an A-DPCH code resource corresponding to the first detected available SOFF offset and generate a DOFF in accordance with the available SOFF offset;

the DOFF offset block of the initial radio link and code resource allocation can be further configured to distribute the free SF256 code resource with the smallest SF value to the A-DPCH and equate the corresponding DOFF to 0 if no available SOFF offsets are found in the used A-DPCH code resource.

In a preferred embodiment, the soft-radio link code resource allocation unit is specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the SOFF N offset in the used A-DPCH code resource is allocated to a specific A-DPCH: N , N + 2 mod 10, N + 8 mod 10.

In a preferred embodiment, the soft resource handover radio resource code resource distribution submodule may include:

a soft handover radio resource code resource allocation unit, configured to search available SOFFs from small to large SF values in the used A-DPCH code resources;

a soft handoff radio link establishment interface unit configured to distribute on the A-DPCH a code resource corresponding to the first detected available SOFF offset equal to the SOFF of the A-DPCH;

the soft resource handover radio resource code resource allocation unit may further be configured to distribute the free code resource SF256 with the smallest SF value to the A-DPCH if no available SOFF offsets equal to SOFF of the A-DPCH are found in the used A-DPCH code resource .

In a preferred embodiment, the soft-radio link code resource allocation unit may be specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the SOFF N offset is allocated to a specific A-DPCH in the used A-DPCH code resource : N, N + 2 mod 10, N + 8 mod 10.

The following positive effects of an embodiment of the invention are distinguished.

Since the downlink SRB can be transmitted on the HS-DSCH, only the TPC field and the slot format pilot field adopted for the downlink of the A-DPCH are effective, code resource SF256 can be shared between several A-DPCHs; in the solutions described above, where the RL request is an RL request to transmit only data, from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, the available SOFF offset code resource is selected so that Reduce the use of A-DPCH code resource regardless of F-DPCH technology.

Brief Description of the Drawings

In FIG. 1 depicts an algorithm of a method for sharing an A-DPCH code resource in one embodiment of the invention.

In FIG. 2 is a diagram of time sequences of slots on the downlink of a universal format.

In FIG. 3 shows a graph of the interdependence of the share of soft handover, user code, and degree of sharing of the A-DPCH code resource.

In FIG. 4 shows a connection diagram of an apparatus for sharing an A-DPCH code resource in a mobile communication system in one embodiment of the invention.

In FIG. 5 shows a diagram of an apparatus for sharing an A-DPCH code resource in one embodiment of the invention.

In FIG. 6 depicts yet another flowchart of an A-DPCH code resource sharing method in one embodiment of the invention.

In FIG. 7 is a diagram of sharing a code resource A-DPCH on the downlink when slot format No. 2 is adopted.

Detailed Description of Embodiments

To clarify the technical side of the issue, the interpretation of technical solutions and advantages of embodiments of the invention, their detailed description is given below with reference to the drawings and specific embodiments of the invention.

To solve the problem of overloading the code resources of the A-DPCH channel of a cell with an increased number of users, an embodiment of the invention of a method and apparatus for sharing the code resource of the A-DPCH channel is proposed, which will significantly reduce the use of the A-DPCH code resource regardless of F-DPCH technologies.

In FIG. 1 depicts an algorithm of a method for sharing an A-DPCH code resource in one embodiment of the invention. According to FIG. 1, this embodiment of the invention includes:

step a: receiving an RL request;

step b: it is evaluated whether the RL request is an RL request to transmit only data or not;

step c: from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available SOFF offset is selected if the RL request is an RL request to transmit only data, where SOFF is time difference rounded off taking into account 2560 chips between slot 0 of the DPCH and the frame header of the PCPICH.

Since the downlink SRB can be transmitted on the HS-DSCH, only the TPC field and the slot format pilot field adopted for the downlink of the A-DPCH are effective, code resource SF256 can be shared between several A-DPCHs; in the solution described above, where the RL request is an RL request to transmit only data, from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, the available SOFF offset code resource is selected so that it significantly reduce the use of A-DPCH code resource regardless of F-DPCH technology.

In another preferred embodiment of the invention, based on steps (a) to (c), a step is selected from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, the code resource corresponding to the available SOFF bias includes the following:

if the RL request is a locally generated initial RL request, then the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH, and the DOFF offset value is generated in accordance with the selected available SOFF offset;

if the RL request is an RL request with a soft handover, then the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH.

In another preferred embodiment of the invention, based on steps (a) to (c), a step is selected from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset and DOFF generated in accordance with SOFF selected, includes the following:

the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values, then the code resource corresponding to the first available SOFF offset found is allocated to A-DPCH, and DOFF is generated in accordance with the selected SOFF;

if there are no available SOFF offsets in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH channel, and the corresponding DOFF is equal to 0.

In another preferred embodiment of the invention, based on steps (a) to (c), a step in which a code resource corresponding to an available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH includes:

the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values, then the code resource corresponding to the first detected SOFF offset equal to the AFF DP channel SOFF is allocated to the A-DPCH;

if the available SOFF offsets equal to the SOFF of the A-DPCH are not found in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH.

In another preferred embodiment of the invention, based on steps (a) to (c), the step in which the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values includes the following:

if in the used A-DPCH code resource, the SOFF offset N is allocated to a specific A-DPCH, the following three SOFF offsets in the A-DPCH code resource are defined as inaccessible: N, N + 2 mod 10, N + 8 mod 10.

In another embodiment of the invention, there is provided an A-DPCH channel resource sharing apparatus, which may include:

a receiving module configured to receive RL requests;

an analytical module evaluating whether the RL request is an RL request to transmit only data or not;

a processing module configured to select, from the used A-DPCH code resource for distribution on the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available SOFF offset if the RL request is an RL request to transmit only data, where SOFF is the time difference rounded to 2,560 chips between slot 0 of the DPCH and the frame header of the PCPICH.

Since the downlink SRB can be transmitted on the HS-DSCH, only the TPC field and the slot format pilot field adopted for the downlink of the A-DPCH are effective, code resource SF256 can be shared between several A-DPCHs; in the solution described above, where the RL request is an RL request to transmit only data, from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, the available SOFF offset code resource is selected so that it significantly reduce the use of A-DPCH code resource regardless of F-DPCH technology.

In a preferred embodiment, the processing module includes:

a DOFF offset submodule of the initial radio link and code resource allocation, configured to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset, if the RL request is a locally generated initial RL request, and generate DOFF offsets according to the selected available SOFF offsets;

soft handover radio resource code resource allocation submodule, adapted to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset.

In a preferred embodiment, the DOFF offset submodule of the initial radio link and code resource allocation includes:

a DOFF bias unit of the initial radio link and code resource allocation, configured to search available SOFF from small to large SF values in the used A-DPCH code resources;

an initial radio link establishment interface unit configured to allocate an A-DPCH code resource corresponding to the first detected available SOFF offset and generate a DOFF in accordance with the available SOFF offset;

the DOFF offset block of the initial radio link and the code resource allocation is configured to further allocate the free code resource SF256 with the lowest SF value to the A-DPCH and equate the corresponding DOFF to 0 if no available SOFF offsets are found in the used A-DPCH code resource.

In a preferred embodiment, the soft-radio link code resource allocation unit is specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the SOFF N offset in the used A-DPCH code resource is allocated to a specific A-DPCH: N , N + 2 mod 10, N + 8 mod 10.

In a preferred embodiment, the soft resource handover radio resource code resource distribution submodule includes:

a soft handover radio resource code resource allocation unit, configured to search available SOFFs from small to large SF values in the used A-DPCH code resources;

a soft handoff radio link establishment interface unit configured to distribute on the A-DPCH a code resource corresponding to the first detected available SOFF offset equal to the SOFF of the A-DPCH;

the soft handover radio resource code resource allocation unit is further configured to distribute the free code resource SF256 with the smallest SF value to the A-DPCH channel if no SOFF offsets equal to the SOFF of the A-DPCH channel are found in the used A-DPCH code resource.

In a preferred embodiment, the soft-radio link code resource allocation unit is specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the SOFF N offset in the used A-DPCH code resource is allocated to a specific A-DPCH: N , N + 2 mod 10, N + 8 mod 10.

The following is a detailed description of the invention of a method and apparatus for sharing an A-DPCH code resource with reference to the accompanying drawings.

In FIG. 2 is a diagram of the time sequences of the downlink slots of the universal format defined by the 3GPP protocol, and the downlink DPCH channel, as a rule, consists of the following parts according to the sending sequence:

field Data 1 and field Data 2, configured to transmit data, while if the data is not sent, the fields do not generate energy;

the TPC field configured to transmit the TPC command uplink, the field having a fixed size of 2 bits and is required to be filled;

the field of the transport format combination indicator (TFCI, Transport Format Combination Indicator), configured to indicate the transport format of the data currently being sent and to facilitate decryption of data on user equipment, while this field is not required for some slot formats, format No. is preferred for the invention 2 downlink slots, but no TFCI field;

a pilot field configured to transmit a pilot bit for channel analysis of the user equipment, the field is required.

Table 1 provides a brief description of some of the downlink slot formats defined by 3GPP.

Moreover, in the present invention, it is preferable to use the format No. 2 of the slots, where SF = 256, with a total volume of 20 bits, in which the bit numbers of any field are assigned respectively as follows: the Data1 field contains 2 bits; the Data2 field contains 14 bits; the TPC field contains 2 bits; TFCI field contains 0 bits and is empty; the pilot field contains 2 bits.

When transmitting only DPCH data, it generally only supports SRB and is called A-DPCH. For the present invention, it is preferable to use the format No. 2 of the slots on the A-DPCH, with the SRB being tied to the HS-DSCH, as a result of which the Data1 and Data2 fields can practically not send data, and in general there is no data transmission in time with respect to these two fields ; the TPC field takes 2 bits, transmits the TPC command uplink and performs continuous data transmission; the pilot field takes 2 bits, is configured to analyze the channel of the user equipment and provides continuous data transmission; the TFCI field occupies 0 bits, and since the SRB is not transmitted via A-DPCH and there is no data transmission either, the TFCI field is not required, i.e. this field does not exist;

the format No. 2 of the slots contains 20 bits, the TPC field and the pilot field together occupy 4 bits, data is not transmitted in time corresponding to the remaining 16 bits, that is, code resources occupied by A-DPCH can be used by other users in time corresponding to 16 the bits, therefore, the SF256 code resource can be shared by several A-DPCHs, as long as the TPC fields and the pilot fields of such users are completely spaced apart in time sequence. For example, in the No. 2 format of the downlink slots, a maximum of 4 A-DPCHs can share code resource SF256.

In FIG. 4 shows an apparatus for sharing an A-DPCH code resource as an embodiment of the invention installed in a radio network controller (RNC) of a universal mobile telecommunication system (UMTS).

In FIG. 5 shows a diagram of an apparatus for sharing an A-DPCH code resource in one embodiment of the invention, and the functions of each block are described below.

Initial radio link establishment interface unit:

the initial radio link refers to the radio link installed by the generating equipment of the user in the cell, in addition to the code resource, the DOFF parameter must be distributed on the downlink, and the interface unit only creates an interface for the distribution of the code resource and the DOFF parameter for the initial radio link;

DOFF offset block of the initial radio link and code resource allocation:

the DOFF parameter and the code resource are allocated to the radio link to transmit only the data originally set in the cell to avoid conflicts in the code resources of the A-DPCH channels and to obtain the maximum reuse factor;

soft handoff radio interface setup unit:

the rounded value of the chipOffset of the soft handoff radio link is random, only the downlink code resource is allocated, and the interface unit only creates an interface for allocating the code resource of the soft handover radio link;

soft handoff radio resource code resource allocation unit:

for a data-only radio link with a soft handover, a code resource is allocated to avoid conflicts in the code resources of the A-DPCH channels and to obtain a maximum reuse factor.

In FIG. 6 shows an algorithm for a method of sharing an A-DPCH code resource in one embodiment of the invention, including the following steps:

step 101: receiving an RL request to transmit only data.

For an RL request for transmitting only data, an A-DPCH code resource sharing method is used as an embodiment of the invention. If the DPCH channel transmits speech, then the method described in this invention is not recommended, since the data is transmitted in parts of Data1 and Data2 in the format of the downlink slots corresponding to such conditions.

Step 102: if the RL request is a locally generated initial RL request, a “DOFF offset of the initial radio link and code resource allocation” process is performed; if, however, the RL request is an RL request with a soft handover, then the process of “distributing the code resource of a radio link with a soft handover” is performed.

Step 103: in a preferred embodiment, the “DOFF offset of the initial radio link and code resource allocation” process is performed:

here SOFF is the time difference rounded taking into account 2560 chips between slot 0 of the DPCH channel and the frame header of the PCPICH channel, the value is in the range 0 ~ 9, and the practical step length is 256 chips.

3GPP defines the PCPICH of a cell as a reference time sequence of all downlink physical channels. The frame header offset of all DPCHs relative to the PCPICH frame header is defined as the chip offset (in the range 0 ~ 38,399 chips); according to the 3GPP protocol, in the case of a chip offset, the nodeB station must round up a multiple of 256 chips, and the rounding result is referred to as RchipOffset for brevity. For example, if the chip offset (chipoffset) is 305 chips, then the corresponding RchipOffset value will be 256 chips; if the chip offset is 501 chips, the corresponding RchipOffset value is 512 chips.

For a DPCH corresponding to a radio link locally installed by user equipment, the RNC can distribute DOFF indicating the time difference between the DPCH and PCPICH frame headers, as well as the DOFF range: (Resolution: 512 chips; Range: 0 ... 599)

RchipOffset = DOFF * 512 mod 38400.

The ratio of DOFF and SOFF:

SOFF = (DOFF * 512 mod 2560) / 256.

The practical value of chipoffset for a soft handoff radio line is random; therefore, the value of RchipOffset is also random. The ratio of RchipOffset and SOFF:

SOFF = (RchipOffset mod 2560) / 256.

For example, in accordance with FIG. 7:

The SOFF offset corresponding to UE1 is 0; the SOFF offset corresponding to UE2 is 1; the SOFF offset corresponding to UE3 is 4; and the SOFF offset corresponding to UE4 is 5.

For a locally generated initial RL request, “the used A-DPCH code resource” is examined for “available SOFF offsets” from small to large SF values, then the first “available SOFF offset” is found, for the A-DPCH the code resource corresponding to the “available offset SOFF ", and DOFF is generated according to the" available SOFF offset ";

if “available SOFF offsets” are not found in the “used A-DPCH code resource”, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH channel, and the corresponding DOFF is 0.

Lowest SF value:

In the code tree of the cell, the available code resources in SF256 are sequentially numbered from 0 to 255 from left to right, and the used code resources SF256 with the lowest value are preferable for reuse within the framework of the present invention in order to increase the reuse factor and reduce the fragmentation of the code resource.

A preferred method for determining whether the reused “A-DPCH code resource” is used by another A-DPCH is as follows:

before use, the SF256 code resource is mapped to 10 “available SOFF offsets,” 0 to 9, respectively; if the code resource is allocated to a specific A-DPC channel, and the offset A-DPCH SOFF is N, then the following code resource offsets SOFF cannot be reused:

N, N + 2 mod 10, N + 8 mod 10;

if the SOFF offset of the other A-DPCH is equal to one of these three values, the TPC fields or pilot fields of the two A-DPCs overlap each other within the time sequence.

For example, in accordance with FIG. 7:

The "available SOFF offsets" of a particular code resource initially have values from 0 to 9;

after the first user UE1 has taken the offset SOFF 0, there remain “available offsets SOFF”: 1, 3, 4, 5, 6, 7, and 9;

after the second user of UE2 has taken the offset SOFF 1, there remain “available SOFF offsets”: 4, 5, 6 and 7;

after the third user of UE3 has taken the SOFF 4 offset, there are “available SOFF offsets”: 5 and 7;

after the fourth user of UE4 has taken SOFF offset 5, there are no more “available SOFF offsets”.

Step 104: a “distribution of the code resource of the soft handoff radio link” is performed.

The step is similar to step 103 with the difference that there is no DOFF offset distribution process since the SOFF offset of the A-DPCH is not randomly allocated to the RNC user with a soft handover.

“The used A-DPCH code resource” is examined for “available SOFF offsets from small to large SF values, the first“ available SOFF offset ”is found, the“ available SOFF offset ”of the code resource is equal to the SOFF offset of the A-DPCH channel, for A-DPCH it is distributed code resource corresponding to “available SOFF offset”.

If there are no “available SOFF offsets” in the “used code resource A-ORCH”, while the “available SOFF offset” is equal to the SOFF offset of the A-DPCH channel, the free code resource SF256 with the lowest SF value is allocated.

Using the technical solutions described in this invention, it is possible to significantly reduce the use of the A-DPCH code resource regardless of the F-DPCH technology and, theoretically, any terminals that support HSDPA configurations within this technology.

In FIG. 3 shows a graph of the interdependence of the share of soft handover, user code, and degree of sharing of the A-DPCH code resource. In FIG. 3, the horizontal axis indicates the number of users of one cell; the vertical axis indicates the degree of sharing of the code resource, all in FIG. 3 three curves, which successively from top to bottom show the conditions for changing the share of soft handover equal to 0%, 40% and 100%. The proportion of soft handover for an outdoor station is usually 40%, and as can be seen from FIG. 3, with a share of soft handover of 40%, the degree of sharing of the code resource quickly reaches 4 times the theoretical maximum, if the number of users in one cell exceeds 30.

Evaluation subject to the degree of sharing of the code resource 3.6 times shows that approximately every 22 users can reduce the code resource SF16 after the implementation of this invention. If the number of HSDPA users in one cell reaches 96, the available code resources for the HS-DSCH service of the cell increase by about 62%, while the cell power gain is significant.

The preferred implementation mode of the present invention is described above, it should be noted that those skilled in the art can make several improvements and improvements without deviating from the basic principles of the invention, and all these improvements and improvements fall within the scope of protection of the present invention.

Industrial applicability

The technical solutions proposed in the embodiments of the invention can be used for sharing the A-DPCH code resource for wireless communications, while from the used A-DPCH code resource for distribution to A-DPC, depending on the type of RL request service, a code resource is selected corresponding to the available SOFF offset, thereby significantly reducing the use of A-DPCH code resource regardless of F-DPCH technology.

Claims (32)

1. A method for sharing a code resource of an associated dedicated physical channel (A-DPCH), comprising: receiving a request to establish a radio link (RL-request); an assessment of whether the RL request is an RL request to transmit only data or not; if the RL request is an RL request to transmit only data, from the used A-DPCH code resource for distribution to the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available offset SOFF (Symbol chipOffset) is selected, where SOFF is this is the time difference rounded taking into account 2560 chips between slot 0 of the dedicated physical channel (DPCH, Dedicated Physical Channel) and the frame header of the primary common pilot channel (PCPICH, Primary Common Pilot Channel). 2. The method of sharing the code resource of the A-DPCH channel according to claim 1, wherein selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH depending on the type of RL request service contains following: when the RL request is a locally generated initial RL request, the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH, and the default offset value (DOFF, Default Offset) is generated in according to the selected available SOFF offset; when the RL request is an RL request with a soft handover, the code resource corresponding to the available SOFF offset is selected from the used A-DPCH code resource for distribution to the A-DPCH. 3. The method of sharing the code resource of the A-DPCH channel according to claim 2, wherein selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH, and generating a DOFF offset in accordance with the selected available offset SOFF contains the following: the used A-DPCH code resource is examined for available SOFF offsets from small to large values of the expansion coefficient (SF), the code resource corresponding to the first detected SOFF offset is allocated to the A-DPCH and generated DOFF in accordance with the available SOFF offset; if there are no available SOFF offsets in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH channel, and the corresponding DOFF is equal to 0. 4. The method of sharing the code resource of the A-DPCH channel according to claim 2, wherein selecting a code resource corresponding to the available SOFF offset from the used A-DPCH code resource for distribution to the A-DPCH comprises the following: the used A-DPCH code resource is examined for available SOFF offsets from small to large SF values, and the code resource corresponding to the first available SOFF offset equal to the SOFF offset of the A-DPCH is allocated to the A-DPCH; if the available SOFF offsets equal to the SOFF offset of the A-DPCH are not detected in the used A-DPCH code resource, then the free code resource SF256 with the lowest SF value is allocated to the A-DPCH. 5. A method for sharing an A-DPCH code resource according to claim 3 or 4, wherein examining the A-DPCH code resource used for available SOFF offsets from small to large SF values comprises the following: if in the used A-DPCH code resource, the SOFF N offset is allocated to a specific A-DPCH, the following three SOFF offsets in the A-DPCH code resource are defined as inaccessible: N, N + 2 mod 10, N + 8 mod 10. 6. An apparatus for sharing a code resource of an associated dedicated physical channel (A-DPCH), comprising: a receiving module configured to receive a request for establishing a radio link (RL request); an analytical module evaluating whether the RL request is an RL request to transmit only data or not; a processing module configured to select, from the used A-DPCH code resource for distribution on the A-DPCH, depending on the type of RL request service, a code resource corresponding to the available offset SOFF (Symbol chipOffset) if the RL request is an RL transfer request only data in which the SOFF offset is the time difference rounded taking into account 2560 chips between slot 0 of the dedicated physical channel (DPCH, Dedicated Physical Channel) and the frame header of the Primary Common Pilot Channel (PCPICH). 7. The A-DPCH code resource sharing device according to claim 6, wherein the processing module comprises: a default offset submodule (DOFF) of the initial radio link and code resource allocation, adapted to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset when the RL request is a locally generated initial RL- requesting and generating a DOFF offset in accordance with the selected available SOFF offset; soft handover radio resource code resource distribution submodule adapted to select from the used A-DPCH code resource for distribution to the A-DPCH a code resource corresponding to the available SOFF offset if the RL request is a locally generated initial RL request. 8. The A-DPCH code resource sharing device according to claim 7, wherein the DOFF offset submodule of the initial radio link and code resource distribution contains: a DOFF offset unit of the initial radio link and code resource allocation, configured to search available SOFF from small to large values of the spreading coefficient (SF) in the used A-DPCH code resources; an initial radio link establishment interface unit configured to allocate an A-DPCH code resource corresponding to the first detected available SOFF offset and generate a DOFF in accordance with the available SOFF offset; the DOFF offset unit of the initial radio link and code resource allocation, further configured to allocate the free code resource SF256 with the smallest SF value to the A-DPCH and equate the corresponding DOFF to 0 when no available SOFF offsets are found in the used A-DPCH code resource. 9. The A-DPCH code resource sharing device according to claim 8, wherein the soft-handover radio resource code resource allocation unit is specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the A- The DPCH offset SOFF N is allocated to a specific A-DPCH channel: N, N + 2 mod 10, N + 8 mod 10. 10. The device sharing the code resource A-DPCH according to claim 7, in which the submodule of the distribution of the code resource of the radio link with soft handover contains: a soft handover radio resource code resource allocation unit, configured to search available SOFFs from small to large SF values in the used A-DPCH code resources; a soft handoff radio link establishment interface unit configured to distribute on the A-DPCH a code resource corresponding to the first detected available SOFF offset equal to the SOFF of the A-DPCH; the soft handover radio resource code resource allocation unit is further configured to distribute the free code resource SF256 with the lowest SF value to the A-DPCH when no available SOFF offsets equal to SOFF of the A-DPCH are found in the used A-DPCH code resource. 11. The A-DPCH code resource sharing apparatus according to claim 10, wherein the soft-handover radio resource code resource allocation unit is specifically configured to determine the following three SOFF offsets in the A-DPCH code resource as unavailable if the A- The DPCH offset SOFF N is allocated to a specific A-DPCH channel: N, N + 2 mod 10, N + 8 mod 10.

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