KR100311529B1 - Base-station searching method, and apparatus for the method - Google Patents

Abstract

The present invention relates to a next generation mobile communication system, and more particularly, to a method for searching for a base station and an apparatus therefor in a next generation mobile communication system using an asynchronous broadband code division multiple access scheme (hereinafter, abbreviated as W-CDMA).

To this end, the present invention provides a transmitter and receiver with a simplified hardware configuration used for base station discovery in the next generation mobile communication system of asynchronous W-CDMA, and provides a method for searching a base station faster using such apparatuses. .

Description

Base-station searching method, and apparatus for the method

The present invention relates to a next generation mobile communication system, and more particularly, to a method and apparatus for searching for a base station in a next generation mobile communication system using asynchronous W-CDMA.

Currently, W-CDMA describes and defines a common downlink physical channel.

Among these common downlink physical channels, there are primary common control physical channels (PCCPCHs). The primary common control physical channels (PCCPCHs) include 10-bit data and control information required for correlation detection. Only common pilot bits of the bits are transmitted. In particular, no information is transmitted during the 256-chip period at the beginning of each slot of the primary common control physical channel (PCCPCH). Instead, during the 256-chip period, the primary SCH (SCH1) and the secondary synchronization channel ( secondary SCH) (SCH2) is transmitted.

FIG. 1 is a diagram illustrating a structure of a synchronization channel (SCH) according to a 3GPP radio access network (RAN) and a transmission timing relationship with a primary common control physical channel (PCCPCH).

Referring to FIG. 1, a symbol of a primary synchronization channel SCH1 having a value of '1' is spread by a primary synchronization code (C _P ) and then a primary common control physical channel (PCCPCH) is spread. It is sent once in every slot during the period of no transmission. This primary synchronization channel (SCH1) is spread using the same code for all base stations, and is used in the process of detecting the slot start time during the procedure of searching the base stations of the system.

Also, a symbol of the secondary synchronization channel SCH2 having a value of '1' may be a secondary synchronization code ( After being spread by the primary synchronization code, the first common control physical channel (PCCPCH) is transmitted in parallel with the above-described primary synchronization channel (SCH1) in every slot during the period in which it is not transmitted. Where i is a group number and k is a slot number.

Where the secondary sync code for each slot ( ) Is selected from the pre-assigned secondary synchronization code table in Table 1 for base station discovery. ) Sequence represents one of 32 different downlink scrambling codes, so each of 16 secondary synchronization codes ( 32 different scrambling codegroups are included, and the secondary synchronization channel SCH2 is used to identify a code group in a procedure of searching base stations of a system. At this time, if the code group is identified, the starting point of the frame can be detected.

Code group Secondary sync code 0 C ₁ , C ₁ , C ₂ , C ₁₁ , C ₆ , C ₃ , C ₁₅ , C ₇ , C ₈ , C ₈ , C ₇ , C ₁₅ , C ₃ , C ₆ , C ₁₁ , C ₂ One C ₁ , C ₂ , C ₉ , C ₃ , C ₁₀ , C ₁₁ , C ₁₃ , C ₁₃ , C ₁₁ , C ₁₀ , C ₃ , C ₉ , C ₂ , C ₁ , C ₁₆ , C ₁₆ ... ... 31 C ₂ , C ₅ , C ₇ , C ₅ , C ₂ , C ₁₁ , C ₁₀ , C ₉ , C ₁ , C ₁₅ , C ₁₃ , C ₁₅ , C ₁ , C ₉ , C ₁₀ , C ₁₁

2 is a block diagram illustrating a configuration of a transmitter for explaining a general base station discovery procedure.

The transmitting apparatus of FIG. 2 transmits a primary common control physical channel (PCCPCH) in every slot, and there is no information transmission through the primary common control physical channel (PCCPCH) for a 256-chip period at the initial time of every slot.

Instead, the primary sync channel SCH1 and the secondary sync channel SCH2 are transmitted during this 256 chip period.

In this manner, in addition to transmitting the primary common control physical channel (PCCPCH), the transmitting device may transmit various channels such as a secondary common control physical channel (SCCPCH) and a dedicated physical channel (DPCH). send. (In addition, although the transmitting apparatus performs various operations, this is general, and since there is no big relation with the gist of the present invention, the detailed operation description will be omitted.)

3 is a block diagram illustrating a configuration of a receiving apparatus for explaining a general base station discovery procedure.

First, a general base station discovery procedure will be described before the description of FIG. 3.

The first step of the base station discovery procedure detects the starting point of the slot. This step involves correlating the transmitted primary synchronization code (C _P ) to find the starting point of any one of the 16 slots per frame and observing the correlation output of the matched filter. Get the slot timing, or masking timing.

Subsequently, in the second step, the code group of the base station is identified based on the masking timing found in the first base station discovery process and the start point of the frame is detected. This is the secondary sync code sent ( ) And the 17 codes of the code set are correlated, and the frame timing can be obtained when the maximum correlation value is confirmed.

In the third step, the primary scrambling code is identified through correlation between all codes and symbols of the primary common control physical channel (PCCPCH) in the code group found in the second base station discovery process. The primary common control physical channel (PCCPCH) is detected after the primary scrambling code is identified. As a result, super frame synchronization can be obtained and the broadcast channel (BCH) is more obvious to the base station because the primary common control physical channel (PCCPCH) is a downlink physical channel used to carry a broadcast channel (BCH). Can get information

The configuration and operation of a receiving apparatus for the above-described base station discovery procedure will be described with reference to FIG. 3.

The operation of the reception device for slot synchronization, which is the first step of the base station discovery procedure, first receives signals of the primary synchronization channel SCH1 spread by the primary synchronization code for 256 chip intervals in every slot. The received signal is divided into an I-channel signal and a Q-channel signal, and then a carrier wave is removed. Each I-channel signal and a Q-channel signal pass through the pulse shaping filters 10 and 11, respectively, and then match the filters 12 and 13 again. ).

The matched filters 12 and 13 use Orthogonal Gold Code C _P to correlate several received signals and send the results to the square portions 14 and 15, respectively.

Each correlation result squared in the squares 14 and 15 is summed and stored, and the procedure so far is repeatedly performed on a received signal delayed by one chip (or half chip), and thus a chip (or half chip). Each correlation result in units of) is stored in a slot sum block 16 in units of slots.

Thereafter, the first decision logic block 17 compares the correlation result values of the slot units stored in the slot summing block 16 with a predetermined threshold value, whereby a correlation result exceeding the threshold value is derived. The slot from which the maximum correlation result value is detected is determined as the slot start time of each frame. However, if the correlation result of the slot unit exceeding the threshold is not obtained, the first step is repeated.

Referring to the operation of the receiving apparatus for frame synchronization and code group identification, which is the second step of the next base station discovery procedure, the signals received through the secondary synchronization channel are separated into respective I channel signals and Q channel signals after the carrier is removed. Pass through the pulse shaping filters 10 and 11, respectively. It is then input to a Bank of 17 correlators 18, where the slot start time detected in the first step of base station discovery is provided to the 17 correlation banks 18.

Here, the 17 correlation banks 18 are different orthogonal gold codes ( 17 correlators (not shown) are used, and each of the correlators uses an orthogonal gold code assigned to each base station signal based on a provided slot start time. ) And sends the result to the third square portion 19 and the fourth square portion 20.

Each correlation result squared by the square units 19 and 20 is summed and stored. The procedure so far is repeated in 16 slots, that is, one frame unit, and the correlation result values of each slot unit are determined by a decision matrix block. (21) is stored in units of frames.

Correlation result values stored in the decision matrix block 21 are then provided to a second decision logic block 22, which is determined from the provided correlation results using a synchronization code table. Create a decision variable. At this time, the second decision logic block 22 identifies a code group from which the maximum value is derived and makes a frame start time point.

In the operation of the receiving apparatus for identifying the scrambling code, which is the third step of the base station discovery procedure, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH).

To this end, first, the symbol unit signal transmitted through the first common control physical channel (PCCPCH) is separated into each I channel signal and Q channel signal after the carrier is removed, and passes through the pulse shaping filters 10 and 11, respectively. Subsequently, an Orthogonal Variable Spreading Factor (hereinafter referred to as OVSF) code for distinguishing channels is input to a Bank of 16 correlators 23 at a start point of a frame already provided.

In this case, the 16 correlation banks 23 include 16 correlators (not shown) for each of 16 different code groups, and these correlators have an orthogonal gold code assigned to each signal input to themselves based on a provided frame start time. Are correlated in symbol units, and the correlation results are sent to square portions 24 and 25, respectively.

Each correlation result squared in the square units 24 and 25 is summed and stored in a symbol sum block 26 in symbol units.

The correlation result values in the unit of symbols stored in the symbol summing block 26 are compared with a specific preset threshold value, and the correlation result of the correlation result of the correlation result exceeding the threshold value is found. Can be.

Since each correlator uses any one of the 16 orthogonal gold codes of the code group found in the second step of base station discovery, knowing the correlator number, scrambling the orthogonal gold code corresponding to the detected correlator number among the 16 orthogonal gold codes. Know the base station to use as a code.

However, if no correlation result is obtained that exceeds the threshold, the third step for identifying the scrambling code is repeated.

As the primary scrambling code is identified through the symbol unit correlation, the primary common control physical channel (PCCPCH) is detected, and accurate broadcast channel (BCH) information is obtained for the corresponding base station.

In the third step of the conventional general base station discovery procedure described above, each signal of the primary common control physical channel (PCCPCH) input based on the starting point of the frame for each of 16 different code groups and the orthogonal gold code assigned to them are 16 correlators are used because they correlate symbolically.

As the 16 correlators are used as described above, the hardware of the receiving apparatus becomes complicated.

In order to solve this problem, if the number of correlators used is reduced, more searching time is required compared to the time of searching a base station using 16 correlators.

SUMMARY OF THE INVENTION An object of the present invention has been made in view of the above, and provides a transmission device and a reception device of a simplified hardware configuration used for base station discovery in the next generation mobile communication system of asynchronous W-CDMA. It provides a method for searching a base station faster.

A feature of the method for searching a base station according to the present invention for achieving the above object is that the transmitting side omits symbol transmission in at least one specific slot of a synchronization channel (SCH) every frame, and the receiving side transmits the symbol And identifying the scrambling code used at the transmitting side by using at least one correlator corresponding to the number of the omitted slot.

Preferably, in the step of omitting symbol transmission in the specific slot, symbol transmission is omitted in at least one or more specific slots of the primary synchronization channel SCH1 among the synchronization channels, and in another example, symbol transmission is omitted in the specific slot. In the step, symbol transmission is omitted in at least one specific slot of the primary synchronization channel SCH1 among the synchronization channels, and symbol transmission is omitted in at least one specific slot of the secondary synchronization channel SCH2 among the synchronization channels. .

The scrambling code identification may include correlating symbols of each slot of the synchronization channel, finding slots for which a minimum correlation value is detected in the correlation result, and correspondingly to the number of slots for which the minimum correlation value is detected. The correlation output of the correlator is observed, and the correlation outputs are compared with a predetermined threshold, and when the maximum correlation value is output, the orthogonal code given to the correlator is determined as the scrambling code.

Another feature of the base station discovery method according to the present invention for achieving the above object is that the transmitting side omits symbol transmission in at least one or more specific slots of the primary synchronization channel (SCH1), the primary synchronization channel (SCH1) Omission of symbol transmission in at least one or more specific slots of the secondary synchronization channel (SCH2) transmitted in parallel with the < RTI ID = 0.0 >), < / RTI > Detecting a slot start time of a frame, detecting a start time of the transmitting frame from a correlation result of a slot unit with respect to the secondary sync channel SCH2 at the receiving side, and Identifying a scrambling code used for the transmitting side from the correlation result for SCH1) and the correlation result for the secondary synchronization channel (SCH2).

Preferably, the slot start time detection step detects the slot start time of each received frame when the correlation result of the symbol unit for the primary synchronization channel SCH1 is maximum, and the primary synchronization channel SCH1. Information on a slot having a minimum correlation result in symbol units for is used for identifying the scrambling code.

In addition, when the frame start time detection step is the maximum correlation result of the slot unit for the secondary synchronization channel (SCH2) is the start time of the transmission frame is detected, and for the secondary synchronization channel (SCH2) Information on a slot having a minimum correlation result in units of slots is used for identifying the scrambling code.

1 is a diagram illustrating a structure of a synchronization channel (SCH) according to a 3GPP radio access network (RAN) and a transmission timing relationship with a primary common control physical channel (PCCPCH).

2 is a block diagram showing a configuration of a transmitting apparatus for explaining a general base station discovery procedure.

3 is a block diagram showing the configuration of a receiving apparatus for explaining a general base station discovery procedure.

4 illustrates a general sync channel structure.

5 is a diagram illustrating a synchronization channel structure for explaining a base station discovery procedure according to the first embodiment of the present invention.

6 is a diagram illustrating a synchronization channel structure for explaining a base station discovery procedure according to a second embodiment of the present invention.

7 is a block diagram showing the configuration of a transmitter for explaining a base station discovery procedure according to the present invention.

8 is a block diagram showing the configuration of a receiving apparatus for explaining a base station discovery procedure according to the present invention.

* Description of symbols on the main parts of the drawings *

100: serial-parallel conversion unit 110: index generator

200,210: pulse shaping filter 220,230: matching filter

240,250,310,320,410,420: Square

260: slot sum block 270: maximum value detector

300: 17 correlation bank 330: decision matrix block

340: decision logic block 400: 16 correlation bank

430: symbol summation block 440: minimum value detector

Hereinafter, a preferred embodiment of a method for searching a base station and an apparatus therefor according to the present invention will be described with reference to the accompanying drawings.

In the present invention, a symbol of a specific slot is not transmitted among all slots of each frame transmitted through the primary sync channel SCH1. In this case, the receiving device receiving the transmitted frame may know the slot number without the symbol transmission, and accordingly, the scrambling code used for the frame may be any one of 16 codes of a specific Orthogonal Gold Code Group (OGCG). It is easily identified.

In another embodiment of the present invention, in each frame of the primary synchronization channel SCH1 and the secondary synchronization channel SCH2 transmitted in parallel with each other, symbols of a specific slot of each synchronization channel of all slots are not transmitted. In this case, the receiving device that receives the transmitted frame can know the slot number of each frame without symbol transmission, and thus the scrambling code used for the frame can be easily selected from 16 codes of a specific orthogonal gold code group (OGCG). Are identified.

A more detailed description thereof will be described with reference to the following drawings.

4 is a diagram illustrating a general synchronization channel structure, in which a symbol of a primary synchronization channel (SCH1) is transmitted once during a 256-chip period in which a primary common control physical channel (PCCPCH) is not transmitted in every slot of a transmission frame.

In addition, in each slot of the transmission frame, the symbols of the secondary synchronization channel SCH2 are transmitted once in parallel with the primary synchronization channel SCH1 during the 256 chip period in which the primary common control physical channel PCCPCH is not transmitted. .

In the present invention, a symbol of a specific slot is not transmitted among all symbols of each synchronization channel (SCH) shown in FIG. 1. An embodiment thereof will be described below.

5 is a diagram illustrating a synchronization channel structure for explaining a base station discovery procedure according to the first embodiment of the present invention.

FIG. 5 illustrates a case in which a symbol of a specific slot is not transmitted among all slots of each frame transmitted through the primary synchronization channel (SCH1). FIG. 5A illustrates one symbol of the primary synchronization channel (SCH1) symbols of 16 slots. 5B illustrates a case in which one symbol of the first synchronization channel (SCH1) symbols of eight slots is not transmitted.

In FIG. 5A, the N th symbol of the SCH1 symbols transmitted through 16 slots per frame is not transmitted.

At this time, the receiving device receiving the transmitted frame can know the slot number without the symbol transmission. The slot number N without symbol transmission indicates that the scrambling code of the currently received frame is the Nth code among the 16 codes of the orthogonal gold code group (OGCG).

Therefore, the receiving device can use the information in the third step of the base station discovery to identify the corresponding scrambling code with only one correlator.

The following describes the base station discovery procedure for the case of FIG. 5A in more detail.

In this case, the first step of the base station discovery procedure detects the starting point of the slot. This step is to find the starting point of any one of 16 slots per frame by correlating slot-by-slot with respect to the transmitted primary synchronization code (C _P ), and by observing the correlation output of the matched filter Obtain slot timing of the base station, that is, masking timing.

Subsequently, in the second step, the code group of the base station is identified based on the masking timing found in the first base station discovery process and the start point of the frame is detected.

This is the secondary sync code sent ( ) And the 17 codes of the code set are correlated, and the frame timing can be obtained when the maximum correlation value is confirmed.

In this step, the correlation output of the matched filter used in the first step of the base station search is observed to find the slot where the minimum correlation value is detected. Then, the slot number where the minimum correlation value is detected is informed to the base station search third step.

In the third step of the base station discovery, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH) among the code groups found in the second base station discovery process.

In more detail, since the slot number without symbol transmission indicated in the second step of the base station discovery indicates that the scrambling code of the currently received frame is the number of the orthogonal gold codes of the code group, the third step is used for correlation processing. As long as the minimum correlation value among the 16 correlators provided corresponds to the slot number where the correlation is detected, only the correlator correlates the symbols of the primary common control physical channel (PCCPCH).

Then, it is observed whether the correlation result in this symbol unit exceeds a specific threshold, and when the correlation result at this time exceeds the threshold, the corresponding primary scrambling code is identified.

On the other hand, if the correlation result of the symbol unit does not exceed the threshold, another correlator corresponding to the corresponding slot number where the second minimum correlation value of the 16 slot unit correlation outputs of the matched filter is detected is detected. Repeat the third step of base station discovery.

In FIG. 5B, the primary synchronization channel (SCH1) symbols transmitted through 16 slots per frame are divided by eight slots, and the K-th symbol of the eight primary synchronization channel (SCH1) symbols is not transmitted.

At this time, the receiving device receiving the transmitted frame can know two slot numbers (K, 2K) without symbol transmission per frame. The slot number (K, 2K) without the symbol transmission indicates that the scrambling code of the currently received frame is the Kth code or the 2Kth code among the 16 codes of the orthogonal gold code group (OGCG).

Therefore, the receiving device can identify the scrambling code from the correlation result of the two correlators by using such information in the third step of the base station discovery.

The following describes the base station discovery procedure for the case of FIG. 5B in more detail.

In this case, the first step of the base station discovery procedure is the same as the case of FIG. 5A.

Subsequently, in the second step, the code group of the base station is identified based on the masking timing found in the first base station discovery process and the start point of the frame is detected.

This is the secondary sync code sent ( ) And the 17 codes of the code set are correlated, and the frame timing can be obtained when the maximum correlation value is confirmed.

In this step, the correlation output of the matched filter used in the first step of searching for the base station is observed every 8 slots to find two slots per frame for which the minimum correlation value is detected. Then, the slot number where the minimum correlation value is detected is informed to the base station search third step.

In the third step of the base station discovery, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH) among the code groups found in the second base station discovery process.

In more detail, the slot number without the symbol transmission indicated in the second step of the base station discovery indicates that the scrambling code of the currently received frame is the number and the number of orthogonal gold codes of the code group. Of the 16 correlators provided for processing, only the two correlators corresponding to the two slot numbers where the minimum correlation value is detected are correlated with the symbols of the primary common control physical channel (PCCPCH).

After that, it is observed whether the correlation result of this symbol unit exceeds a certain threshold. If the correlation result at this time exceeds the threshold, the orthogonal gold code given to the correlator for which the maximum correlation result of the two correlators is detected is 1; Primary scrambling code is identified.

In the case of FIG. 5B described so far, the success rate of scrambling code identification is much higher than that of FIG. 5A, so that the two correlation results in this symbol unit rarely exceed the threshold.

6 is a diagram illustrating a synchronization channel structure for explaining a base station discovery procedure according to a second embodiment of the present invention.

FIG. 6 illustrates a case in which symbols of a specific slot are not transmitted in each sync channel among all slots in each frame of the primary sync channel SCH1 and the secondary sync channel SCH2 transmitted in parallel with each other. In this case, one symbol of each symbol of the primary synchronization channel SCH1 and the secondary synchronization channel SCH2 is not transmitted. FIG. 6B shows the primary synchronization channel SCH1 and the secondary synchronization channel (8 slots) of eight slots. This is a case where one symbol of each symbol of SCH2) is not transmitted.

In FIG. 6A, the Nth symbol of each symbol of the primary synchronization channel SCH1 and the secondary synchronization channel SCH2 transmitted in parallel through 16 slots per frame is not transmitted.

At this time, the receiving device receiving the transmitted frame can know the slot number of each channel without symbol transmission. The slot number N without symbol transmission indicates that the scrambling code of the currently received frame is the Nth code among the 16 codes of the orthogonal gold code group (OGCG).

Therefore, the receiving device can use the information in the third step of the base station discovery to identify the corresponding scrambling code with only one correlator.

The following describes the base station discovery procedure for the case of FIG. 6A in more detail.

In this case, the first step of the base station discovery procedure detects the starting point of the slot. This step is to find the starting point of any one of 16 slots per frame by correlating slot-by-slot with respect to the transmitted primary synchronization code (C _P ), and by observing the correlation output of the matched filter Obtain slot timing of the base station, that is, masking timing.

Subsequently, in the second step, the code group of the base station is identified based on the masking timing found in the first base station discovery process and the start point of the frame is detected.

This is the secondary sync code sent ( ) And the 17 codes of the code set are correlated, and the frame timing can be obtained when the maximum correlation value is confirmed.

In this step, the correlation output of the matched filter used in the first step of the base station search is observed to find the slot where the minimum correlation value is detected, and the second synchronization in which the slot having the minimum correlation value is detected is transmitted. code( ) And whether the minimum correlation value among the correlation results using the 17 codes of the code set matches the detected slot.

If the two slots coincide with each other, this slot number is informed to the third step of the base station search.

In the third step of the base station discovery, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH) among the code groups found in the second base station discovery process.

In more detail, since the slot number without symbol transmission indicated in the second step of the base station discovery indicates that the scrambling code of the currently received frame is the number of the orthogonal gold codes of the code group, the third step is used for correlation processing. As long as the minimum correlation value among the 16 correlators provided corresponds to the slot number where the correlation is detected, only the correlator correlates the symbols of the primary common control physical channel (PCCPCH).

Then, it is observed whether the correlation result in this symbol unit exceeds a specific threshold, and when the correlation result at this time exceeds the threshold, the corresponding primary scrambling code is identified.

However, if the minimum correlation value is detected in the correlation output of the matched filter and the second synchronization code ( ) And the slot where the minimum correlation value is detected in the correlation result using the 17 codes of the code set do not match each other, the slot and the second order where the second minimum correlation value is detected in the correlation output of the matched filter. Sync code ( ) And the slot where the second minimum correlation value is detected in the correlation result using the 17 codes of the

Then, it is checked whether the slots in which the second minimum correlation value is detected by the correlation coincide with each other, or by the combination with these two slots, whether each of the two slots in which the minimum correlation value is detected by the correlation is identical with each other. .

At this time, the slot number corresponding to each other is informed to the third step of the base station search, and the third step of the base station search is repeated through another correlator corresponding to the slot number.

In FIG. 6B, the primary synchronization channel (SCH1) and the secondary synchronization channel (SCH2) symbols, which are transmitted in parallel through 16 slots per frame, are divided into eight slots, and eight primary synchronization channels (SCH1) and secondary are divided. The K-th symbol of the synchronization channel (SCH2) symbols is not transmitted.

At this time, the receiving device receiving the transmitted frame can know two slot numbers (K, 2K) without symbol transmission per frame. The slot number (K, 2K) without the symbol transmission indicates that the scrambling code of the currently received frame is the Kth code or the 2Kth code among the 16 codes of the orthogonal gold code group (OGCG).

Therefore, the receiving device can identify the scrambling code from the correlation result of the two correlators by using such information in the third step of the base station discovery.

The following describes the base station discovery procedure for the case of FIG. 6B in more detail.

In this case, the first step of the base station discovery procedure is the same as the case of FIG. 6A.

Subsequently, in the second step, the code group of the base station is identified based on the masking timing found in the first base station discovery process and the start point of the frame is detected.

This is the secondary sync code sent ( ) And the 17 codes of the code set are correlated, and the frame timing can be obtained when the maximum correlation value is confirmed.

In this step, we also observe the correlation output of the matched filter used in the first step of the base station search every 8 slots to find two slots per frame where the minimum correlation value is detected. The secondary sync code sent in this reminder ( ) And the minimum correlation value among the correlation results using the 17 codes of the code set matches the two slots detected.

At this time, two slot numbers matching each other are informed to the third step of the base station discovery.

In the third step of the base station discovery, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH) among the code groups found in the second base station discovery process.

In more detail, the slot number without the symbol transmission indicated in the second step of the base station discovery indicates that the scrambling code of the currently received frame is the number and the number of orthogonal gold codes of the code group. Of the 16 correlators provided for processing, only the two correlators corresponding to the two slot numbers where the minimum correlation value is detected are correlated with the symbols of the primary common control physical channel (PCCPCH).

Then, observe whether the correlation result of this symbol unit exceeds a certain threshold, and if the correlation result exceeds this threshold, the orthogonal gold code assigned to the correlator for which the maximum correlation result of the two correlators is detected is the corresponding first order. It is identified by the scrambling code.

The following describes the configuration and operation of a transmitter and a receiver for the base station discovery procedure.

7 is a block diagram showing the configuration of a transmission apparatus for explaining a base station discovery procedure according to the present invention.

The transmitting apparatus of FIG. 7 transmits a primary common control physical channel (PCCPCH) in every slot. There is no information transmission through the primary common control physical channel (PCCPCH) for a 256-chip period at an initial time point of each slot.

Instead, the primary synchronization channel SCH1 and the secondary synchronization channel SCH2 are transmitted during the 256-chip period, and the transmission apparatus of the present invention does not transmit a symbol of a specific slot among all slots in these synchronization channels SCH. Two switches SW1 and SW2 are provided.

These switches SW1 and SW2 are turned on at every slot boundary and are turned off after 256 chip intervals without information transmission through the primary common control physical channel (PCCPCH).

In addition to transmitting the primary common control physical channel (PCCPCH), the transmitting device of the present invention transmits several other channels such as a secondary common control physical channel (SCCPCH) and a dedicated physical channel (DPCH). Performs various operations, but detailed descriptions thereof will be omitted since they do not have much relation with the gist of the present invention.)

8 is a block diagram showing the configuration of a receiving apparatus for explaining a base station discovery procedure according to the present invention.

Referring to FIG. 8, the configuration and operation of the receiving apparatus for the above-described base station discovery procedure will be described.

The operation of the reception device for slot synchronization, which is the first step of the base station discovery procedure, first receives signals of the primary synchronization channel SCH1 spread by the primary synchronization code for 256 chip intervals in every slot. The received signal is divided into an I-channel signal and a Q-channel signal, and then carriers are removed. Each I-channel signal and Q-channel signal pass through the pulse shaping filters 200 and 210, respectively, and then pass through the matching filters 220 and 230. .

The matched filters 220 and 230 correlate various received signals using an orthogonal gold code C _P and send the results to the square units 240 and 250, respectively.

Each correlation result squared in the square units 240 and 250 is summed and stored, and the procedure up to now is repeatedly performed on a received signal delayed by one chip, and each correlation result value in units of chips is a slot sum block. sum) 260 is stored in units of slots.

Thereafter, the correlation result stored in the slot sum block 260 in units of slots is provided to the minimum value detector 440 which will be described later, and also transferred to the maximum value detector 270 to be used to find a slot start time.

The maximum value detector 270 compares the correlation result values of the slot units stored in the slot summing block 260 with a predetermined threshold value, and the maximum correlation result value is determined among the slots from which the correlation result exceeding the threshold value is derived. The detected slot is determined as the slot start time of each frame. However, if the correlation result of the slot unit exceeding the threshold is not obtained, the first step is repeated.

Referring to the operation of the receiving apparatus for frame synchronization and code group identification, which is the second step of the next base station discovery procedure, the signals received through the secondary synchronization channel are separated into respective I channel signals and Q channel signals after the carrier is removed. Pass through the pulse shaping filters 200 and 210, respectively. The bank is then input to a bank of 17 correlators 300, where the slot start time detected in the first step of base station discovery is provided to the 17 correlation bank 300.

Here, the 17 correlation banks 300 may have different orthogonal gold codes ( 17 correlators (not shown) are used, and each of the correlators uses an orthogonal gold code assigned to each base station signal based on a provided slot start time. ) And sends the result to the third square portion 310 and the fourth square portion 320.

Each correlation result squared in the squares 310 and 320 is summed and stored, and the procedure so far is repeated in 16 slots, that is, in units of one frame, and the correlation result values of each slot unit are determined by using a decision matrix ( 330 is stored in units of frames.

Correlation result values stored in the decision matrix block 330 are then provided to a decision logic block 340, which is determined from the provided correlation results using a synchronization code table. variable) At this time, the decision logic block 340 identifies the code group from which the maximum value is derived, and detects the start point of the frame.

Also, in the second step of searching for a base station according to the present invention, if there is no symbol transmission of a specific slot in the secondary synchronization channel (SCH2) as in the case of FIG. 6, among the correlation result values stored in the decision matrix block 330. The slot for which the minimum correlation value is detected is found. (In FIG. 5, since a symbol is transmitted in all slots of the secondary synchronization channel, this operation is omitted.)

Subsequently, in a first step of searching for a base station, a correlation result of the matching filters 220 and 230 stored in slot units in the slot sum block 260 is provided to the minimum value detector 440. As shown in FIG. 5, if there is no symbol transmission in a specific slot of the primary synchronization channel SCH1, the slot number where the minimum correlation value is detected is detected among the correlation results provided by the minimum value detector 440. It is provided to the bank 400.

However, as shown in FIG. 6, when there is no symbol transmission simultaneously in a specific slot of the primary synchronization channel SCH1 and the secondary synchronization channel SCH2, the minimum correlation value is detected by the decision matrix block 330. When the slot and the slot for which the minimum correlation value is detected by the minimum detector 440 match, the slot number is provided to the 16 correlation banks 400.

In the operation of the receiving apparatus for identifying the scrambling code, which is the third step of the base station discovery procedure, the primary scrambling code is identified through correlation between symbols of the primary common control physical channel (PCCPCH).

To this end, first, a symbol unit signal transmitted through a primary common control physical channel (PCCPCH) is separated into respective I channel signals and Q channel signals after the carrier is removed, and passes through the pulse shaping filters 200 and 210, respectively. Subsequently, the frame is multiplied by an OVSF code for channel division at a start point of a frame that is already provided, and is input to a bank of 16 correlators 400.

In this case, the 16 correlation banks 400 include 16 correlators (not shown) for each of 16 different code groups, and these correlators have an input orthogonal gold code assigned to each signal based on a provided frame start time. Are correlated in symbol units, and the correlation results are sent to the square units 410 and 420, respectively.

Each correlation result squared by the square units 410 and 420 is summed and stored in a symbol sum block 430 in symbol units.

The correlation result values of the symbol unit stored in the symbol summing block 430 are compared with a predetermined threshold value, and from the comparison result, the correlator number from which the maximum correlation result value is detected is detected. Can be.

Since each correlator uses any one of the 16 orthogonal gold codes of the code group found in the second step of base station discovery, knowing the correlator number, scrambling the orthogonal gold code corresponding to the detected correlator number among the 16 orthogonal gold codes. Know the base station to use as a code.

However, the present invention does not exceed two correlators required for the third step of the base station discovery. That is, when one symbol of the 16 slot primary synchronization channel (SCH1) symbols is not transmitted as in the case of FIG. 5A, and as in the case of FIG. When one symbol of each symbol of the synchronization channel SCH2 is not transmitted, only one of the 16 correlators provided in the 16 correlation banks 400 is used, and as shown in FIG. 5B, the primary synchronization channel of 8 slots is used. When one of the (SCH1) symbols is not transmitted, and as in the case of FIG. 6B, one symbol of each of the symbols of the primary synchronization channel SCH1 and the secondary synchronization channel SCH2 of 8 slots is not transmitted. If not, only two of the sixteen correlators included in the sixteen correlation banks 400 are used to identify the scrambling code.

5 and 6, if a primary scrambling code is identified through symbol unit correlation using only two or more correlators, the primary common control physical channel (PCCPCH) is detected. Obtain accurate broadcast channel (BCH) information for the base station.

As described above, using the method of searching for a base station and an apparatus therefor according to the present invention has the following effects.

In the present invention, the base station transmitting apparatus does not transmit a symbol of a specific slot in the primary synchronization channel SCH1 or the secondary synchronization channel SCH2 by switching, and the UE receiving apparatus confirms a slot without a symbol transmission in advance. Since it is applied to the scrambling code identification during the base station discovery procedure, the amount of calculation for correlation processing is reduced, thereby reducing the power consumption of the terminal.

In addition, it is possible to simplify the hardware configuration of the UE receiver in an asynchronous system where base station discovery is more complicated than synchronous.

In addition, since the base station transmitting apparatus does not transmit a symbol of a specific slot in the primary synchronization channel SCH1 or the secondary synchronization channel SCH2 by switching, the transmission amount per frame is reduced, thereby improving link performance.

Claims (3)

The transmitting side omitting symbol transmission in at least one specific slot of a synchronization channel (SCH) every frame; And identifying a scrambling code used at the transmitting side by using at least one correlator corresponding to the number of the slot where the symbol transmission is omitted at the receiving side. The method of claim 1, wherein omitting symbol transmission in the specific slot comprises: The symbol transmission method of the base station, characterized in that the symbol transmission is omitted in at least one specific slot of the primary synchronization channel (SCH1) of the synchronization channel. The method of claim 1, wherein omitting symbol transmission in the specific slot comprises: Symbol transmission is omitted in at least one specific slot of the primary synchronization channel SCH1 among the synchronization channels, and symbol transmission is omitted in at least one specific slot of the secondary synchronization channel SCH2 among the synchronization channels. A base station search method.