KR100566902B1 - Cell searching device in asynchronous mobile communication system and method thereof - Google Patents

Abstract

Disclosed are a cell search apparatus and a method of an asynchronous mobile communication system. The cell search apparatus of the asynchronous mobile communication system includes a normalizer, an accumulator, and a maximum detector. The normalizer selects a predetermined number of detected correlation values with respect to the received signal from a larger order, and normalizes the selected correlation values by dividing them by a predetermined value. The accumulator accumulates the normalized correlation value. The maximum detector detects a time offset of the sync code as the maximum correlation value among the accumulated normalized correlation values. According to the present invention, memory and power consumption can be saved during cell search, and the overall cell search time can be shortened.

Cell search, mobile communication, correlation, normalization, cumulative

Description

Cell searching device in asynchronous mobile communication system and method

1 is a diagram illustrating a synchronization channel structure of a forward link used in an asynchronous W-CDMA system;

2 is a flowchart for explaining a cell search method of a mobile station;

3 is a block diagram showing the internal structure of a conventional one-step cell search apparatus,

4 is a diagram illustrating an output example of the matched filter of FIG. 3;

5 is a block diagram showing an internal configuration of a first-stage cell search apparatus according to the present invention;

6 is an overall flowchart illustrating a process of acquiring a starting point of a slot for cell searching according to the present invention;

7 is a flowchart illustrating a cumulative step in the cell search method according to the present invention.

The present invention relates to an apparatus and method for cell search in an asynchronous mobile communication system. More specifically, the cell search is performed at high speed by normalizing a correlation value, which is an output value of a matched filter for a primary sync channel, in a cell search operation. A cell search apparatus and method in an asynchronous mobile communication system having reduced memory capacity.

The next generation International Mobile Telecommunication System (IMT-2000) is a wireless transmission technology that is currently being developed in many countries around the world. The IS-95 series base station synchronous CDMA-2000 method is being developed based on North America, and Europe and Japan. There is a base station asynchronous W-CDMA method under development in 3GPP (3rd Generation Partnership Project3C).

In the mobile communication system, when the power of the communication terminal device is turned on, when communication between the communication terminal device and the base station device is disconnected, and when the switching target base station device is specified at the time of handover, the communication terminal device currently has a certain base station device. Must be specified that is the closest and best for communicating. This is called cell search. If the communication terminal device is moving at high speed, or if there are many subscribers such as a large city and the base station devices are densely installed, the number of objects to be searched increases and the surrounding cell environment changes at high speed. , Cell search is required to be executed at high speed.

The asynchronous W-CDMA method, unlike the IS-95 series base station synchronous CDMA method in which all base stations operate in frame synchronization based on an external time reference such as a global positioning system (GPS), requires no frame synchronization between base stations. Its feature is that it can operate. While the IS-95 series base station synchronous CDMA scheme distinguishes each base station by using a phase difference with respect to the absolute time of one code sequence, the base station asynchronous W-CDMA scheme distinguishes base stations by different code sequences. Since the base station asynchronous W-CDMA scheme does not require a device such as a GPS receiver, a cell search time of a mobile station may be lengthened during initial call setup or handoff. In order to reduce the mobile station cell search time of the base station asynchronous W-CDMA, the base station asynchronous W-CDMA scheme adopts a grouping concept, and uses two synchronization channels in the forward link as shown in FIG. The base station search procedure consists of three steps.

The primary synchronization channel (P-SCH) is composed of a Generalized Hierarchical Golay (GHG) code having a 256-chip unmodulated length and is transmitted one slot at each slot (0.667 msec). In the 3GPP W-CDMA scheme, one frame is 10 msec and coincides with the scrambling code length. One P-SCH is repeatedly transmitted 15 times per frame, one in each slot, and all base stations of the system use the same code as the P-SCH. The mobile station cell search step 1 receives a first synchronization channel transmitted from the base station and synchronizes a slot time of the base station.

The second synchronization channel (S-SCH) also has a length of 256 chips, while different codes are transmitted in every slot. That is, the second synchronization channel is composed of 15 sequences of length 256 chips, and each sequence is aligned with the first synchronization channel code as shown in FIG. In step 2 of mobile station cell search, the mobile station, which is slot time-synchronized through the first synchronization channel, receives the second synchronization channel to obtain base station identification code information and information on a start point of a 10 msec frame.

In step 3 of the mobile station cell search, the mobile station determines the type of PN code of the base station by using the frame start point and base station identification code information obtained in step 2. That is, if 8 PN codes corresponding to the base station classification code group obtained in the second step are correlated from the start point of the frame obtained in the second step, and the maximum value exceeds the preset threshold, the mobile station determines the maximum. A PN code having a value is declared as a PN code used by the current base station for spread spectrum of the forward link. In this way, the mobile station acquires information on the frame synchronization and the PN code of the current base station.

In the cell search method of the mobile station, as shown in Fig. 2, each step procedure is sequentially performed to perform initial synchronization with the base station search. That is, after the synchronization of the slot time is found in the first step (S211), the frame time synchronization and the base station identification code information is searched in the second step (S212), the information on the frame synchronization and the PN code of the target base station in the third step (S213). Acquire a cell to complete the cell search. The above-described step cell search is performed in parallel.

By the way, the most important of the multi-step cell search procedure is to find slot time synchronization more quickly in the first step (S211). This is because if the slot time synchronization is not properly matched, the calculation for all the steps after the first step becomes useless.

3 is a block diagram showing the internal structure of a conventional one-step cell search apparatus.

As shown in FIG. 3, the conventional one-step cell search apparatus includes a matching filter 311, an accumulator 312, and a maximum correlation value detector 313.

The matched filter 311 inputs a received signal and detects a correlation of the signal. In this case, the process of detecting the correlation value is performed with respect to a time offset possible for the period in which the first synchronization channel is received, and the correlation value according to the time offset is accumulated and stored in the accumulator 312. Here, the time offset is 2560 because there are 2560 chips per slot. That is, the accumulator that stores correlation values needs space for storing 2560 pieces of data. In addition, the reason for accumulating the correlation value is performed to suppress the influence of noise and interference of the received signal. When the channel environment is poor, the power of the received signal is weak. Therefore, the cumulative frequency should be increased.

The maximum correlation detector 313 detects a maximum correlation value among the correlation values stored in the accumulator 312, detects a time offset of a synchronization code corresponding to the detected maximum correlation value, and detects the detected synchronization code. Synchronize the slot time with the base station with a time offset of.

However, when the influence of noise and interference is large, the power of the received signal is weak, and as shown in FIG. 4, the correlation between sidelobes such as (412) and (413) is accurate for the time offset due to the influence of noise and interference. Larger or similar to correlation 411. In this case, since the slot time synchronization is incorrect, the cumulative number of correlation values must be increased for accurate synchronization.

Increasing the cumulative number of times increases the time required for the first-stage cell search, resulting in a hardware load due to an increase in the cumulative number, thereby increasing power consumption to reduce power consumption of a mobile station that uses a limited power. There is a problem that increases further.

Therefore, in order to solve the above problem, the present invention can shorten the slot time synchronization time during the one-step cell search in the asynchronous W-CDMA mobile communication system, and the memory and power during the cell search. An object of the present invention is to provide a cell search apparatus and method for an asynchronous mobile communication system which can reduce consumption.

In order to achieve the above object, in a cell search apparatus of an asynchronous mobile communication system, a normalization unit selects a predetermined number from a large order of detected correlation values for a received signal, and normalizes the selected correlation values by dividing them by a predetermined value. ; An accumulator that receives and accumulates the normalized correlation value; And a maximum value detector which detects a time offset of a sync code with a maximum correlation value among the accumulated normalized correlation values.

In order to achieve the above another object, in the cell search method of an asynchronous mobile communication system, a normalization step of selecting a predetermined number from a large order of detected correlation values with respect to a received signal, and normalizing the selected correlation values by dividing them by predetermined values ; Accumulating and receiving the normalized correlation value; And a maximum value detecting step of detecting a time offset of a sync code as a maximum correlation value among the accumulated normalized correlation values. The cell search method of the asynchronous mobile communication system is provided.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram illustrating an internal configuration of a first stage cell search apparatus according to the present invention.

As shown in FIG. 5, the first-stage cell search apparatus according to the present invention includes a matched filter 511, a normalizer 512, an accumulator 513, and a maximum detector 514.

The matched filter 511 detects a correlation value with respect to the received signal Rx using a slot sync code. Here, the matched filter 511 detects a correlation value with respect to a time offset possible for the period in which the first synchronization channel is received, and outputs the result to the normalizer 52.

The normalizer 512 arranges the ₂₅₆₀ correlation values C ₁ , C ₂ ,..., C ₂₅₆₀ that are output values of the matching filter 511 in large order. The correlation values C ₁ , C ₂ ,..., C _M are selected from the sorted correlation values by a predetermined number M, M <2560, and the smallest correlation value C _M is selected from the selected correlation values. Divide the selected correlations C ₁ , C ₂ ,..., C _M. In this way, the normalized correlation values D ₁ , D ₂ ,..., D _M are output to the accumulation unit.

The accumulator 513 stores the normalized correlation values in a predetermined number of storage spaces (N, N <2560). The accumulator 513 first checks whether the slot starting point of the selected and normalized correlation values is the same as the previously stored normal values AC ₁ , AC ₂ ,..., AC _N , and accumulates the same. . In addition, the accumulator 513 compares the cumulative values stored in the accumulator 513 by comparing the cumulative values stored in the accumulator 513 with the accumulated correlation values stored in the accumulator 513. If it is larger, select and store it in order of size to fit the predetermined number. At this time, correlation values smaller than the accumulation values stored in the accumulation unit 513 are deleted.

The maximum value detector 514 selects the largest of a predetermined number (N) of data stored in the accumulator 513, selects a time offset thereof as a starting point of the slot, and transfers it to the cell search stage 2.

FIG. 6 is a flowchart illustrating a process for quickly acquiring a start point of a slot for fast cell search in a W-CDMA system operating asynchronously with a base station according to an exemplary embodiment of the present invention.

First, when the signal Rx is received and input to the matching filter 511, the correlation value is detected using the slot synchronization code, and the detected correlation value is output to the normalization unit 52.

In the normalization unit 512, 2560 correlation values C ₁ , C _{2 ,.} The correlation values C ₁ , C ₂ ,..., C _M are selected (step S611).

The selected correlation values C ₁ , C ₂ ,..., C _M are divided by the smallest correlation value C _M among the selected correlation values (step S612). In this way, the normalized correlation values D ₁ , D ₂ ,..., D _M are stored in the accumulation unit (step S613).

The maximum value is selected from the normalized correlation values stored in the accumulator, and is selected as the starting point of the slot, and transferred to the second stage cell search unit (step S614).

7 is a flowchart illustrating a cumulative step in the cell search method according to the present invention.

The cumulative step is the same as the first cumulative step 71 of comparing the time offsets of the normalized correlations with the time offsets of the correlations already stored in the accumulator, and accumulating the normalized correlations if there is the same. If not, the second cumulative step 72 of storing the normalized correlation value only when the normalized correlation value is larger than the correlation value stored in the accumulation part by comparing the normalized correlation value with the correlation values stored in the accumulation part. Include.

In the first accumulation step 71, the accumulation unit 513 inputs normalized correlation values D ₁ , D ₂ ,..., D _M from the normalization unit 512 (step S711).

In addition, time offsets of correlation values in which the input normalized correlation values ID _i : ID ₁ , ID ₂ ,..., ID _M are accumulated in the accumulation unit 513 (IAC _j : IAC ₁ , IAC _2). ,..., IAC _N ) (step S712).

If the time offset ID _i of the input normalized correlation values is the same as the time offset IAC _j of correlation values already stored in the accumulator 513, the same normalized correlation value is accumulated, and the normalization is performed. The correlated value D _i is removed (step S713). The input normalized correlation values are all examined (step S714).

In the second cumulative step 72, the accumulator 513 compares whether the normalized correlation values left after performing the first cumulative step 71 are greater than the correlation values stored in the accumulator 513 (step S715). ). If the normalized correlation value left in the first accumulation step 71 is larger than the correlation value stored in the accumulation unit 513 (D _i > AC _j ), the normalized correlation value is stored (step S716). All normalized correlations left in the first cumulative step 71 are examined (step S717).

As described above, by normalizing the correlation value selected from the correlation values that are the output values of the matching filter, the effect can be suppressed when the channel environment is poor.

In other words, if the received signal has a large noise and interference, the correlations of the sidelobes are larger or similar to the correlations for the correct time offset, and since the correlations of the large number of sidelobes have a large value, the normal values of the correlations are generally smaller. Will have

On the other hand, if the influence of noise and interference is small, the normal value for the correlation value for the accurate time offset will have a relatively large value than the normal value for the correlation of sidelobes. Therefore, slot synchronization can be achieved faster than conventionally accumulating correlation values and obtaining maximum values.

As described above, the present invention provides an output of a matched filter in order to minimize the influence of signal power degradation due to interference and noise of a first synchronous channel transmitted from a base station when performing cell search in an asynchronous W-CDMA mobile communication system. By performing the normalization operation, it is possible to reduce the cumulative number of slot time synchronizations during the one-step cell search, and it is possible to reduce the hardware load due to the reduction of the cumulative number.

It also normalizes the correlation and selects and stores only some of the 2560 possible time offsets, saving memory, and normalizing can be done as integers, reducing hardware load and performing to detect synchronous code time offsets. Since the number of slots is reduced, the power consumption is reduced.

Therefore, memory and power consumption can be saved during cell search, and the overall cell search time can be shortened.

Claims (8)

In the cell search device of the asynchronous mobile communication system, A normalizer which selects a predetermined number of detected correlation values with respect to the received signal from a larger order, and normalizes the selected correlations by dividing the selected correlation values by the smallest value among the selected correlation values; An accumulator for selecting and storing the normalized correlation values in order; A maximum value detector configured to detect a time offset of a sync code with a maximum correlation value among the accumulated normalized correlation values, The accumulator compares whether the time offsets of the normalized correlations are equal to the time offsets of the correlations already stored in the accumulator, and accumulates the normalized correlations if there is the same. Comparing the normalized correlation value with the correlation values stored in the accumulation unit and storing the normalized correlation value only when the normalized correlation value is larger than the correlation value stored in the accumulation unit. Cell Search Device. delete delete delete In the cell search method of the asynchronous mobile communication system, A normalization step of selecting a predetermined number of detected correlation values with respect to the received signal from a larger order and normalizing the selected correlation values by dividing them by the smallest value of the selected correlation values; A cumulative step of selecting and storing a predetermined number of the normalized correlation values in order; A maximum value detecting step of detecting a time offset of a sync code as a maximum correlation value among the accumulated normalized correlation values, The accumulating step compares whether the time offsets of the normalized correlation values are the same as the time offsets of the correlation values already stored in the accumulator, and accumulates the normalized correlation values when the same is present. If not, the second cumulative step of storing the normalized correlation value only when the normalized correlation value is greater than the correlation value stored in the accumulation part by comparing the normalized correlation value with the correlation values stored in the accumulation part. Cell search method of the asynchronous communication system comprising a. delete delete delete

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