KR100342562B1 - Apparatus and method for searching for pn sequence phase of multi-carrier cdma mobile communication system - Google Patents

Abstract

In the present invention, in a P-SE sequence phase search apparatus in a code division multiple access mobile communication system using multiple carriers, a received signal of at least two received signals received through different frequency bands is received and allocated. At least two P-en sequence phase searchers for performing P-en sequence phase search respectively according to different search conditions, and outputting P-en phase and energy information, and for each of the P-en sequence phase searchers. And a controller for assigning different search conditions and receiving the P-en phase and energy information to determine a minimum variation section.

Description

Apparatus and method for P-N sequence phase search in a multi-carrier code division multiple access method mobile communication system {APPARATUS AND METHOD FOR SEARCHING FOR PN SEQUENCE PHASE OF MULTI-CARRIER CDMA MOBILE COMMUNICATION SYSTEM}

The present invention relates to a peer-to-peer phase search apparatus and method of a code division multiple access mobile communication system, and more particularly, to a peer-to-peer phase search apparatus and a method of a code division multiple access mobile communication system using a multi-carrier.

The code division multiple access (hereinafter referred to as CDMA) mobile communication system has been developed from the standard for transmitting / receiving voice signals, and the IMT-2000 standard for high speed data transmission as well as voice is discussed. have. The IMT-2000 standard aims to provide services such as high quality voice, moving picture, and Internet search. As one of the IMT-2000 standards, a multi-carrier method for transmitting information to be transmitted to a plurality of carriers has been proposed. The multi-carrier method may be a method of modulating and transmitting information spread by the same pseudo-noise (PN) sequence to a plurality of different carriers.

The transmitter of the CDMA mobile communication system employing the multi-carrier scheme may use a method of dividing an information signal into a plurality of signals and spreading each of the divided signals into the same PN sequence. In this case, the transmitter modulates each of the plurality of spread signals into different carriers. As a result, data is transmitted through a plurality of different types of frequency bands. In addition, a transmitter divides an information signal into a plurality of frequency band signals in advance in a base band and each of the plurality of signals. Can be modulated into a radio frequency band by multiplying a single carrier corresponding to a center frequency. In order to demodulate the information signal for each frequency band, the receiving terminal demodulates the received signal by multiplying a local carrier corresponding to each of the frequency bands.

Meanwhile, in a CDMA mobile communication system employing a multi-carrier method, a base station generates a base station-generated PN sequence or a pilot signal of different types through a pilot channel for synchronization with mobile stations. Each carrier can be loaded on certain carriers. The mobile station can search the phase of each PN sequence for each of a plurality of carrier received signals transmitted from the base station by using a serial search method or a parallel search method.

That is, when the power is turned on, the mobile station first performs an operation of acquiring a pilot channel (Pilot Acquisition). The mobile station performs an initial PN sequence phase search operation that satisfies the threshold condition of the start position of the PN sequence generated at the base station and the start position of the PN sequence generated by the mobile station itself. In addition, when PN Reacquisition such as call disconnection is required, the mobile station performs a PN sequence phase search operation again.

The PN sequence phase search operation can be largely divided into four steps. The first operation is a step of calculating the detection energy according to the correlation during the predetermined integration section for the base station generated PN sequence received at an arbitrary time point and the mobile station generated PN sequence generated in the mobile station PN generator. The second operation is a step of repeating the first operation a predetermined number of times after shifting the phase (Phase) of the mobile station generated PN sequence. The third operation is a step of comparing the calculated detection energy with the threshold detection energy. The fourth operation is to perform the first to third operations again when the corresponding calculated detection energy is smaller than the threshold detection energy. In addition, the PN sequence phase search operation adjusts the search conditions such as the range of the integration section, the window size, the asynchronous cumulative section, and the corresponding PN phase information step by step, and adjusts the stability for each step. You can go higher. In this case, the names of the steps may be DETECT, DWELL, VERIFY, and the like. Thus, the PN sequence phase search operation can minimize the probability of failure of phase search. In addition, in the case of acquiring a reliable PN sequence phase that satisfies a certain condition, it is possible to continuously search for the variation in the PN sequence phase by determining the minimum variation period. In this case, the operation of continuously searching for the variation of the PN sequence phase by determining the minimum variation section may be PULLIN.

1 is a diagram illustrating an example of a PN sequence phase search apparatus using a serial detection method in a CDMA mobile communication system.

The controller 150 controls the overall operation of the PN sequence phase search apparatus of FIG. In addition, the controller 150 adjusts various parameters (range of integration section, window size, asynchronous accumulation section, etc.) and controls phase shift of the mobile station-generated PN sequence of the PN generator 160. The received signal may be a signal received by the mobile station and then processed by RF processing and digitization such as down conversion and input to the modem chip. In this case, the received signal includes a PN sequence generated from a predetermined base station.

The despreader 110 performs an operation of despreading by multiplying the PN sequence value from the PN generator 160 with the received signal input at an arbitrary time point. At this time, the phase search start point of the PN sequence generated in the mobile station is preset. For example, the phase search starting point may be from the PN offset '0'.

The sync accumulator 120 accumulates the output of the despreader 110 for a corresponding integration period. The energy calculator 130 calculates the detected energy according to the correlation between the base station generated PN sequence and the mobile station generated PN sequence based on the accumulated value of the synchronization accumulator 120. The comparator 140 performs an operation of comparing the detected energy calculated by the energy calculator 130 and the threshold energy to provide the comparison result to the controller 150. The threshold energy may be arbitrarily set by the controller 150. The controller 150 controls the phase shift of the PN sequence from the PN generator 160 according to the comparison result of the comparator 140. In addition, the controller 150 reports a reliable PN sequence phase that satisfies a certain condition to a higher processor (not shown). As a result, the mobile station performs a demodulation operation on received signals such as a synchronization channel and a paging channel.

After the PN sequence phase search operation is completed, the controller 150 inputs pilot offset information from the upper processor and adjusts various parameters to check reception strength of pilot signals of neighboring base stations and provides a current service. The operation of comparing the received signal strength of the pilot signal can be performed. In this case, the above operation may also be referred to as a set maintenance operation.

For example, in a CDMA mobile communication system, a mobile station currently manages various information about the base station to which it is registered and other base stations. In addition, the mobile station receives a neighbor base station list message including PN offset information of each base station through a paging channel, and measures the strength of each pilot signal of the neighbor base stations as a reference for handoff. The mobile station manages an active sector, a neighbor sector, a candy sector, and the like by measuring the strength of the pilot signals. The active sector corresponds to a base station to which a mobile station is currently transmitting / receiving messages, the neighbor sector corresponds to a base station that may be used for handoff in the future, and the candy date sector demodulates data although it is not currently used for data demodulation. Corresponds to a base station with a large enough energy to do so.

2 is a diagram illustrating another example of a PN sequence phase search apparatus using a serial detection method in a CDMA mobile communication system.

The multiplier 202 and the multiplier 206 provided in the carrier demodulator 210 input a received signal. And the multiplier 202 and the multiplier 206 are local carriers, respectively. And Multiplying by the received signal. Thus, the received signal is carrier demodulated and converted into an I channel (In Phase) signal and a Q channel (Quadrature) signal, respectively. The matched filter 204 and the matched filter 208 restore the waveforms of the I channel signal and the Q channel signal, respectively.

The despreader 220 inputs the PN code of the I channel and the PN code of the Q channel from a PN code generator (not shown) provided in the mobile station to despread the recovered I channel signal and the Q channel signal. The integrator 225 and the integrator 255 accumulate and add the despread I channel signal and the Q channel signal during a predetermined integration period. The energy detector 230 and the energy detector 260 square the result of the addition operation, and calculate the detected energy according to the correlation between the base station generated PN code and the mobile station generated PN code. The adder 235 performs an operation of adding the detection energy output from the energy detector 230 and the energy detector 260. The comparator 240 performs an operation of comparing the calculated detection energy with a threshold detection energy and provides the comparison result to the controller 250. The threshold detection energy may be arbitrarily set by the controller 250. The controller 250 outputs the corresponding PN phase control signal corresponding to the comparison result provided from the comparator 240 to the PN code generator.

As described above, the mobile station of the CDMA mobile communication system using the multi-carrier method can search the phase of the PN sequence of the plurality of carrier received signals transmitted from the base station by using the serial search method or the parallel search method.

However, in the CDMA mobile communication system using a multi-carrier, if a PN phase search is performed on signals of a plurality of different frequency bands by a serial search method, a single serial PN sequence search device may include a plurality of (eg, three) devices. PN sequences must be searched simultaneously. Therefore, there is a disadvantage in that the time required for PN sequence phase search and set management operation is longer, resulting in a significant decrease in reception performance. Particularly, when a hand off occurs in the serial search method, a single serial PN sequence search device does not respond quickly to a channel change rate in a situation where a channel change is fast and thus has a high probability of call drop. Will increase.

To solve this problem, there may be a method of increasing the speed of the serial PN sequence search apparatus and a method using a parallel PN sequence search apparatus. First of all, when performing a PN phase search for signals of a plurality of different frequency bands by a serial search method in a CDMA mobile communication system using a multi-carrier, a single serial PN sequence search device receives the received signal. It can operate N times as many as the number of signals. For example, a CDMA mobile communication system using three frequency bands may use a 24x PN phase sequence search device instead of an 8x PN phase sequence search device. In this case, the 24x PN phase sequence search apparatus can quickly process three frequency band PN sequences. However, in order to implement the 24x PN phase sequence search apparatus, there is a disadvantage in that the complexity of hardware design increases significantly.

Secondly, in the PN sequence phase search apparatus according to the parallel search method, the PN sequence phase search apparatus of the serial search method of FIGS. 1 to 2 may be connected in parallel. In this case, each PN sequence phase search apparatus performs a phase search operation of a PN sequence for respective signals among the received signals of the plurality of frequency bands. If each of the PN sequence phase search apparatus performs the PN sequence phase search operation from the same PN sequence phase search point for the received signal for each frequency band generated at a predetermined base station, the PN sequence for the same hypothesis for each frequency band To perform a phase search operation. Therefore, the time taken for the PN sequence phase search operation is not significantly different compared to the serial search method. However, since the performance of the PN sequence phase search apparatus is evaluated by reducing the average search time, when the parallel search method is applied in a CDMA mobile communication system using a multi-carrier method, a method for reducing the average search time is considered. Should be.

As is well known, an offset value of a pilot signal for identifying a specific base station in a CDMA mobile communication system is uniquely assigned to each base station. In addition, even in a multi-carrier system, pilot PN offset values included in signals of a plurality of different frequency bands transmitted from a specific base station are the same. At this time, since the signals of each frequency band do not go through the same fading environment due to the characteristics of the mobile communication environment, the base station carries the same corresponding pilot signal on each of the signals of each frequency band and transmits them. Meanwhile, the mobile station can perform the PN sequence search operation on the signals of all frequency bands. Therefore, in the parallel search method, if the serial PN sequence search apparatus performs the PN sequence search operation by generating the PN sequence from different phase search start points without generating the PN sequence from the same phase search start point, The time taken will be shortened. In addition, when the parallel PN sequence search device searches for phases of up to 32768 PN codes, the 32768 hypotheses are divided into N equal to the number of each serial PN sequence search device, and each serial PN sequence search device is divided into N equal phases. If the PN code is generated from the point of view, the time required for the PN sequence search operation may theoretically be N times faster.

On the other hand, in a multi-carrier CDMA mobile communication system, the PN offset of one base station is the same in each frequency band signal used by the base station, but the fading effect in each frequency band is different and the characteristics of the multi-pass are not the same. That is, there is no guarantee that the phases of the base station generated PN sequences in each frequency band received by the mobile station are the same. Therefore, in the multi-carrier CDMA mobile communication system, each PN sequence phase search operation should be performed on all received signals of different frequency bands.

However, each PN sequence phase search device performs a PN sequence phase search operation with respect to a received signal of an input frequency band under different search conditions, and a specific PN sequence phase search device performs a PN sequence search operation that satisfies a predetermined search condition. When the variation period of the minimum PN phase is completed and determined, the phase of the base station-generated PN sequence of the remaining other frequency bands will not be out of the phase variation period. As described above, since the serial PN sequence phase search apparatus performs the PN sequence phase search according to different search conditions until the variation period of the PN phase is determined, the time required for the PN sequence phase search operation is shortened on average. will be. In particular, since most of the time required for the PN sequence phase search operation is spent in the initial stage, i.e., determining the variation interval of the minimum PN phase (e.g., the Detect stage), the time required for the PN sequence phase search operation is 1/2 times to It could be reduced by one third.

In addition, when the variation period of the minimum PN phase is determined, in order to perform each PN sequence phase search operation on the received signal for each frequency band, each PN sequence phase search apparatus performs a PN sequence within the determined minimum PN phase variation period. You will need to perform a phase search operation.

Accordingly, an object of the present invention is to provide an apparatus and method for a P-PN phase search in a code division multiple access mobile communication system using a multi-carrier.

Another object of the present invention is to perform a PN sequence phase search operation under different search conditions for a frequency band received signal input to each PN sequence phase search device in a code division multiple access mobile communication system using a multi-carrier. In addition, the present invention provides an apparatus and a method for determining a variation interval of a minimum P-en phase and reducing an average time taken for a PN sequence phase search operation.

Another object of the present invention is to receive at least one of at least two received signals in which at least two P-N phase searchers are received through different frequency bands in a code division multiple access mobile communication system using a multi-carrier. A P-en sequence phase search is performed by receiving different signals and assigned different search conditions to output the P-en phase and energy information, and a controller controls the different search conditions for each of the P-en sequence phase searchers. The present invention provides an apparatus and a method for allocating and receiving the P-en phase and energy information to determine a minimum variation interval.

Another object of the present invention is to receive at least one of at least two received signals in which at least two P-N phase searchers are received through different frequency bands in a code division multiple access mobile communication system using a multi-carrier. A P-en sequence phase search is performed by receiving different signals and assigned different search conditions to output the P-en phase and energy information, and a controller controls the different search conditions for each of the P-en sequence phase searchers. Assigns and receives the P-en phase and energy information to determine a minimum variation section, and the at least two P-en sequence phase searchers perform a P-en sequence phase search within the minimum variation section determined by the controller. To provide an apparatus and method.

Another object of the present invention is to perform a PN sequence phase search operation from a different PN phase search start point of each PN sequence phase searcher corresponding to each frequency band received signal in a code division multiple access mobile communication system using a multi-carrier. It is to provide an apparatus and method capable of doing so.

The present invention for achieving the above objects is a P-N sequence phase search apparatus in a multi-carrier code division multiple access mobile communication system, the received signal of any one of at least two received signals received through different frequency bands At least two P-en sequence phase searchers for performing P-en sequence phase search according to different search conditions assigned to each other and outputting P-en phase and energy information, and the P-en sequence phase searcher And a control unit for allocating the different search conditions to each other and receiving the P-en phase and energy information to determine a minimum variation period.

In addition, the present invention provides a method of searching for a P-N sequence phase of at least two received signals received through different frequency bands in a multi-carrier code division multiple access mobile communication system. Performing a P-en sequence phase search of at least one of the received signals in parallel and outputting the P-en phase and energy information, and determining the minimum variation interval by receiving the P-en phase and energy information. It is characterized by including the process.

In addition, the present invention provides a method of searching for a P-N sequence phase of at least two received signals received through different frequency bands in a multi-carrier code division multiple access mobile communication system. Performing a P-en sequence phase search of at least one of the received signals in parallel and outputting the P-en phase and energy information, and performing the number of times of performing the P-en sequence phase search on the output energy information. Comparing each threshold with a variable which is changed by the step, re-performing the P-N sequence phase search if there is at least two pieces of energy information larger than the threshold value by the comparison; In the process of determining the minimum variation section based on the phase information corresponding to the energy information. Characterized in that made.

1 is a diagram illustrating an example of a PN sequence phase search apparatus using a serial detection method in a CDMA mobile communication system.

2 is a diagram illustrating another example of a PN sequence phase search apparatus using a serial detection method in a CDMA mobile communication system.

3 illustrates an example of different PN phase search starting points of each of the N serial PN sequence phase searchers according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

4 illustrates a PN sequence phase search apparatus according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

5 is a diagram illustrating a PN sequence phase search apparatus according to another embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

6 is a flowchart illustrating a PN sequence phase search method according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

7 is a flowchart illustrating a parallel PN sequence phase search method according to another embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

8A illustrates an example of different PN phase search start points of each PN sequence phase searcher according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

8B illustrates another example of different PN phase search start points of each PN sequence phase searcher according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

9A and 9B illustrate a PN sequence phase search process according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Specific details appear in the following description, which is provided to aid a more general understanding of the present invention, and it should be understood by those skilled in the art that the present invention may be practiced without these specific details. It will be self explanatory. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the present invention using a parallel search scheme in a code division multiple access mobile communication system using a multi-carrier, a plurality of PN sequence phase searchers receive at least one of at least two received signals received through different frequency bands. The PN sequence phase search is performed according to different search conditions. In this case, the different search conditions may be composed of a phase and a search section corresponding to the start point of the PN sequence phase search. As a result, each PN sequence phase search device may perform a PN sequence search operation by generating a PN sequence from different phase search start points without generating the PN sequence from the same phase search start point. Therefore, on average, the time taken for the PN sequence search operation is shortened.

For convenience of explanation, the concept of a PN circle will be described as follows. That is, in a CDMA mobile communication system, when a transmitter transmits a spread signal by multiplying an information signal by a PN sequence having a high data rate, the receiver synchronizes the PN sequence of the transmitter and multiplies the received signal to despread the received signal. It can be called a system for restoring a signal. In addition, in a CDMA mobile communication system, a channel-coded random data signal or symbol is multiplied by an orthogonal code for data transmission and orthogonally spread by an orthogonal spreading period. In addition, each sequence of the orthogonally spread data signal may be multiplied with a PN sequence having a transmission rate of 1.2288 MHz and the like to be PN spreaded and transmitted. In addition, the pilot signal may be a PN spread by multiplying an orthogonal code such as Walsh orthogonal code ω _{0 by a} non-modulated symbol consisting of consecutive '+ 1's and then multiplying by a PN sequence. That is, the above-mentioned unmodulated signal having a value of '+1' is orthogonally spread by being multiplied by an orthogonal code such as ω ₀ and the like. It becomes a signal.

In addition, the PN sequence may have a period of 2 ¹⁵ -1, and a value of '1' or '-1' is generated with a probability of 50%. The PN sequence has a unique PN sequence phase start point for each base station, and the mobile station searches for the corresponding PN sequence included in the pilot signal to synchronize with the base station. In general, a PN sequence having 32768 cycles is represented by a PN circle.

FIG. 3 is a diagram illustrating examples of different PN phase search start points of each of the N serial PN sequence phase searchers according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

Here, each scale of the PN circles 31 to 3N represents a PN sequence phase, and the intervals between the scales represent a PN chip section. In addition, the arrows provided in the PN circles mean different PN phase search starting points of the PN sequence phase searchers, that is, different PN sequence phases. In addition, it can be seen that each PN phase search start point divides the PN circle by N in accordance with the embodiment of the present invention.

4 is a diagram illustrating a PN sequence phase search apparatus according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

Referring to FIG. 4, the carrier demodulator 400 demodulates a reception signal for each frequency band by inputting a first frequency band reception signal to an Nth frequency band reception signal. In this case, the first multiplier 410 to the N-th multiplier 414 provided in the carrier demodulator 400 input a received signal of each frequency band, and multiply each of the first local carrier to the Nth local carrier, respectively, for the respective frequencies. Demodulate the received signal in the band. The matched filter 416 to the matched filter 420 included in the carrier demodulator 400 restore a waveform of the received signal of each demodulated frequency band.

The first PN sequence phase searcher 430 to the N-th PN sequence phase searcher 450 may have the configuration of FIG. 1 or FIG. 2. The first PN sequence phase searcher 430 to the N-th PN sequence phase searcher 450 may receive the first frequency band received signal corresponding to their own to the Nth frequency band according to different search conditions of the controller 460. PN sequence phase search is performed on the signal to output PN phase and energy information. In this case, the different search condition may be a PN phase and a search period corresponding to the start point of the PN sequence phase search. In addition, according to the different search conditions, the first PN sequence phase searcher 430 to the N-th PN sequence phase searcher 450 may perform an operation of searching for PN phases from different PN sequence phase search start points.

The controller 460 receives the PN phase and energy information to adjust and allocate a corresponding search condition to control operations of the first PN sequence phase searcher 430 to the Nth PN sequence phase searcher 450. . In addition, the controller 460 inputs the PN phase and energy information, allocates a corresponding search condition, and determines a minimum variation section by a predetermined PN sequence phase search algorithm. The controller 460 shares the information about the minimum variation interval with each of the PN sequence phase seekers 430 to 450 in order to perform each PN sequence phase search operation on the received signal for each frequency band. Let's do it. Thus, the first PN sequence phase searcher 430 to the N-th PN sequence phase searcher 450 perform a PN sequence phase search operation within the minimum variation section.

The controller 460 reports the PN phase to the higher processor (not shown) when the PN phase is captured within the set minimum variation period. This causes the mobile station (not shown) to demodulate the synchronization and paging channels and the like in the next step. In addition, the controller 460 performs the PN sequence phase search operation, inputs the pilot offset information from the upper processor, adjusts the search condition, etc., and then checks the reception strength of the pilot signals of neighboring base stations and provides the current service. Performs an operation to compare the reception strength of the pilot signal.

Meanwhile, when at least two or more of the corresponding energy information output from the respective PN sequence phase searchers satisfy predetermined thresholds, the controller 460 compares the corresponding energy information satisfying the predetermined thresholds and obtains the largest energy. Branch has energy information. The minimum variation may be determined according to the PN phase information corresponding to the output of the largest energy, and the minimum variation may be shared by the respective PN sequence phase seekers 430 to 450.

If at least two or more of the corresponding energy information output from the respective PN sequence phase seekers 430 to 450 satisfy predetermined thresholds, the control unit 460 meets the corresponding PN sequence phase searchers. A new corresponding search condition may be given to the PN sequence phase search operation to be performed again. And when the single corresponding energy information output as a result of the PN sequence phase search operation is larger than a threshold variable by the number of reruns, the control unit 460 determines the PN phase information corresponding to the output of the largest energy. In accordance with the present invention, the minimum variation may be determined and the minimum variation may be shared by the PN sequence phase seekers 430 to 450. In addition, the variable threshold may be adjusted step by step by the number of repetitions of the PN sequence phase search.

When at least two or more of the corresponding energy information output from the PN sequence phase searchers 430 to 450 satisfy predetermined thresholds, a new corresponding search condition is provided to the corresponding PN sequence phase searchers satisfying the predetermined thresholds. In the example of performing the PN sequence phase search operation again by applying a value, the stability of the PN sequence search operation and the probability of failure of the phase search can be further reduced.

On the other hand, in the embodiment of FIG. 4, each of the PN sequence phase seekers 430 to 450 performs a PN sequence phase search operation on a received signal of a frequency band corresponding to each of the PN sequence phase searchers 430 to 450, respectively, before the minimum variation period is determined. You can see that it is. However, this is an embodiment of the present invention, in which each of the PN sequence phase searchers 430 to 450 is assigned a different search condition to which any one of the frequency band received signals is allocated until the minimum variation interval is determined. According to the PN sequence phase search operation. Of course, after the minimum variation period is determined, each of the PN sequence phase searchers 430 to 450 must perform a PN sequence phase search operation on a received signal having a unique frequency band allocated thereto.

5 is a diagram illustrating a PN sequence phase search apparatus according to another embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

Referring to FIG. 5, the carrier demodulator 510 demodulates a reception signal for each frequency band by inputting a first frequency band reception signal to an Nth frequency band reception signal. The first PN sequence phase searcher 530 to the N-th PN sequence phase searcher 550 may have the configuration of FIG. 1 or FIG. 2. The first PN sequence phase searcher 530 to the N-th PN sequence phase searcher 550 may be provided with the first frequency band received signal output from the switch 520 under different search conditions of the controller 560. The PN sequence phase search is performed on one frequency band received signal among the Nth frequency band received signals to output PN phase and energy information. In this case, the different search condition may be a PN phase and a search period corresponding to the start point of the PN sequence phase search. In addition, according to the different search conditions, the first PN sequence phase searcher 530 to the N-th PN sequence phase searcher 550 may each perform an operation of searching for PN phases from different PN sequence phase search start points. have.

The controller 560 receives the PN phase and energy information to adjust and allocate a corresponding search condition to control operations of the first PN sequence phase searcher 530 to the Nth PN sequence phase searcher 550. .

The controller 560 inputs the PN phase and energy information, allocates a corresponding search condition, and determines a minimum variation section by a predetermined PN sequence phase search algorithm. In addition, in order to perform each PN sequence phase search operation on the received signals for each frequency band, the PN sequence phase searchers 430 to 450 share the information about the minimum variation section. As a result, the first PN sequence phase searcher 530 to the N-th PN sequence phase searcher 550 perform a PN sequence phase search operation on a received signal having a unique frequency band corresponding to the first PN sequence phase searcher 530. To perform.

The controller 560 reports the PN phase to the upper processor (not shown) when the PN phase is captured within the set minimum variation section. This causes the mobile station (not shown) to demodulate the synchronization and paging channels and the like in the next step.

In addition, the switch unit 520 may receive one of the frequency band reception signals from the first frequency band reception signal and the Nth frequency band reception signals until the minimum variation period is determined by the control of the control unit 560. Switch to the input terminal of the PN sequence phase searcher. The switch unit 520 is controlled by the controller 560, and after the minimum variation period is determined, the switch unit 520 may be configured to correspond to the first to Nth frequency band received signals. Switching to an input terminal of the first PN sequence phase searcher 530 to the N-th PN phase searcher 550 is performed.

6 is a flowchart illustrating a PN sequence phase search method according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers. Hereinafter, the control flow of FIG. 6 will be described with reference to the configuration shown in FIG. 5.

In step 610, the carrier demodulator 510 demodulates the input signals for each frequency band. In operation 615, the switch unit 520 switches the input terminals of the first PN sequence phase searchers 530 to the Nth PN sequence phase searchers 550 to a specific frequency band input signal under the control of the controller 560. In operation 620, each of the PN sequence phase searchers 530 to 550 performs a PN sequence phase search operation on the specific frequency band input signal according to different search conditions assigned by the controller 560 to perform a corresponding PN phase. And energy information, respectively.

In operation 625, the controller 560 examines the PN phase and energy information to determine whether a PN sequence phase that satisfies a specific condition is captured. If the PN sequence phase that satisfies the specific condition is not captured, the controller 560 allocates a new search condition to each of the PN sequence phase seekers 530 to 550 in step 630 and performs the control operation of step 625. Do it again. If the PN phase satisfying the specific condition is captured in step 625, the controller 560 determines the minimum PN phase shift period in step 635. In operation 640, the switch 520 controls the first PN sequence phase searcher 530 corresponding to each of the first frequency band input signal and the Nth frequency band input signals by the control of the controller 560. To switch to an input terminal of the N-th PN phase searcher 550.

In operation 645, each of the PN sequence phase searchers 530 to 550 is configured with respect to unique frequency band input signals assigned to each of the PN sequence phase seekers 530 to 550 according to a corresponding search condition corresponding to the minimum variation section from the controller 560. The PN sequence phase variation is searched within the minimum variation section. In operation 650, the controller 560 checks whether a PN sequence phase has been acquired for a specific number of frequency band input signals. If it is determined in step 650 that the PN sequence phase is captured, the controller 560 proceeds to step 655. In operation 655, the controller 560 provides corresponding PN phase information for each band to the higher processor. However, if the PN sequence phase is not captured, the process proceeds to step 630 and allocates a new search condition and returns to step 625.

On the other hand, a CDMA mobile communication system using multiple carriers must support compatibility with a CDMA mobile communication system using a previous single carrier. For example, the user can switch the operation mode of the mobile station according to the service type of the currently supported system, that is, whether it is multi-carrier or single carrier. In addition, when a mobile station currently set in a multi-carrier mode moves to or is powered on in a service area supporting a single carrier service, the mobile station detects this and automatically switches the operation mode.

Therefore, the parallel PN sequence phase search apparatus must also perform a PN sequence phase search operation on a received signal of a single carrier or frequency band. At this time, each PN sequence search device generates a PN sequence or PN code from a different phase search start point without receiving a PN sequence or PN code from a same phase search start point for a received signal of a single frequency band to perform a PN sequence search operation. If so, the time taken for the PN sequence search operation is reduced.

7 is a flowchart illustrating a parallel PN sequence phase search method according to another embodiment of the present invention in a CDMA mobile communication system using multiple carriers. Referring to FIG. 4, the control flow shown in FIG. Will be explained.

When the mobile station is powered on, in step 710, the controller 460 checks whether the operation mode of the current mobile station is a multi-carrier mode or a single carrier mode. At this time, the criterion of the inspection may be information on the operation mode of the current mobile station from the upper processor. The criterion of the test may be a result of channel demodulation by the current operation mode from the upper processor.

If the operation mode is a multi-carrier mode, in step 720, the carrier demodulator 400 performs carrier demodulation on a corresponding local carrier for each frequency band with respect to a received signal under the control of the controller 460 or the higher processor. . In operation 730, each of the PN sequence phase searchers 430 to 450 performs a PN sequence phase search operation from a different PN sequence phase search start point with respect to the received signal for each frequency band by the control of the controller 460. .

However, if the operation mode is not the multi-carrier mode, but is a single carrier mode, in step 740, the carrier demodulator 400 controls the received signal to a single local carrier under the control of the controller 460 or the higher processor. Perform demodulation. Accordingly, the input of each of the PN sequence phase seekers 430 to 450 becomes a single frequency band received signal. In operation 750, by the control of the controller 460, the PN sequence phase searchers 430 to 450 perform a PN sequence phase search operation from a different PN sequence phase search start point with respect to a single frequency band received signal. . In step 760, the controller 460 reports the captured PN phase information to the higher processor.

8A is a diagram illustrating an example of different PN phase search start points of each PN sequence phase searcher according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

In the embodiment of FIG. 8A, the number of PN sequence phase seekers is assumed to be three, and a PN sequence phase search start point is allocated to each PN sequence phase searcher by dividing a PN circle into three. 8A shows that each PN sequence phase searcher inputs a single frequency band received signal and performs a PN sequence phase search operation by covering a corresponding search window from the corresponding PN sequence phase search start point. Indicates.

8B is a diagram illustrating another example of a different PN phase search start point of each PN sequence phase searcher according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

In the embodiment of FIG. 8B, it is assumed that the number of PN sequence phase seekers is three, and the PN circle, that is, the PN sequence is divided into PN offset '0' and the search section of the set size, and then each PN sequence phase searcher is divided into two. This means that each divided search section is allocated in order.

9A and 9B illustrate a PN sequence phase search process according to an embodiment of the present invention in a CDMA mobile communication system using multiple carriers.

That is, in FIG. 9A, each PN sequence phase searcher performs a PN sequence phase search operation according to different search conditions assigned to a specific frequency band received signal, for example, a second frequency band received signal, and then, the reference numeral 11 is used. A process of determining the minimum variation section by outputting PN phase and energy information corresponding to the variation section is shown.

9B illustrates that the control unit determines the minimum variation section and provides information corresponding to the minimum variation section to a first PN sequence phase searcher to a third PN sequence phase searcher, so that each PN sequence phase searcher is configured to perform the minimum variation. A process of searching for a PN sequence phase shift in a section is shown.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, in the CDMA mobile communication system using multiple carriers, the present invention provides a PN sequence phase search operation under different search conditions for a frequency band received signal inputted by each PN sequence phase search device. The variation interval is determined. This has the advantage of reducing the time taken for the PN sequence phase search operation on average. In particular, the time required for the PN sequence phase search operation is generally 1/2 of the time since most of the time required for the PN sequence phase search operation is spent in the initial stage, i.e., determining the variation interval of the minimum PN phase (e.g., the Detect stage). It can be reduced by a factor of one to one third. In addition, there is an advantage that the initial PN phase acquisition and call recovery time is reduced when the mobile station is powered on or disconnected.

According to the present invention, when the variation range of the minimum PN phase is determined, each PN sequence phase search operation is performed on the received signals for each frequency band, so that the fading influence is not different in each frequency band and the characteristics of the multi-pass are not the same. For each frequency band received signal, there is an advantage in that the PN sequence phase search operation can be performed that is stable and can reduce the probability of failure of phase search.

Claims (19)

In the P-N sequence phase search apparatus in a multi-carrier code division multiple access mobile communication system, Receiving one of the at least two received signals received through different bands and performing the P-N sequence phase search according to different allocated search conditions to output the P-en phase and energy information. At least two P-N sequence phase finders, And a control unit for allocating the different search conditions to the P-en sequence phase searchers and receiving the P-en phase and energy information to determine a minimum variation period. P-N sequence phase search device in communication system. The method of claim 1, wherein the different search conditions, A P-N sequence phase search apparatus in a multi-carrier code division multiple access mobile communication system, comprising: phases and search intervals corresponding to P-N sequence phase search starting points. The method of claim 2, wherein the different search conditions, Multi-carrier code division multiple access characterized in that the P-N sequence phase search starting points of the at least two P-N sequence phase seekers are equally allocated to the P-N sequence by the number of the P-N sequence phase seekers. P-N sequence phase search device in mobile communication system. The method of claim 2, wherein the different search conditions, In the multi-carrier code division multiple access mobile communication system, the PN sequence is divided into intervals having a predetermined size and each partition is sequentially assigned to the at least two P-N sequence searchers. Device. The system of claim 1, wherein the at least two P-N sequence phase seekers are: And a P-N sequence phase search in a multi-carrier code division multiple access mobile communication system, characterized in that to perform a P-N sequence phase search within a minimum variation section determined by the controller. The method of claim 5, Switching so that any one of at least two received signals having different bands is provided to the P-N sequence phase searchers when the different search condition is provided by the control of the controller. In the multi-carrier code division multiple access mobile communication system, a switch for switching so that each received signal is provided to the corresponding P-N sequence phase searcher at the time when the minimum variation interval is determined. Sequence phase search. A method of searching for a P-N sequence phase of at least two received signals received through different bands in a multi-carrier code division multiple access mobile communication system, Outputting P-en phase and energy information by performing P-en sequence phase search of at least one of the received signals in parallel according to different search conditions assigned to each other; And receiving the P-en phase and energy information to determine a minimum variation section. 2. The method of claim 7, wherein the different search conditions, A P-N sequence phase search method in a multi-carrier code division multiple access mobile communication system, characterized in that it consists of phases and search intervals corresponding to P-N sequence phase search start points. The method of claim 8, wherein the different search conditions, Multi-carrier code division multiple access mobile communication system characterized by dividing a P-en sequence by the parallel number of performing the P-en sequence phase search and defining the corresponding phase by the equalization as starting points of the P-en sequence P-N sequence phase search in. The method of claim 8, wherein the different search conditions, A P-N sequence phase searching method in a multi-carrier code division multiple access mobile communication system, characterized by dividing a PN sequence into intervals of a predetermined size and assigning each divided search interval to each parallel P-N sequence phase search. . The method of claim 7, wherein the minimum variation interval, The P-N sequence phase search method of the multi-carrier code division multiple access mobile communication system, characterized in that determined by the phase information corresponding to the largest energy information of the provided energy information. The method according to claim 7 or 11, wherein When the minimum variation interval is determined, searching for the P-N sequence phase within the determined minimum variation interval for each of the received signals, and providing the P-N sequence phases acquired through the search to a higher processor. A P-N sequence phase search method in a multi-carrier code division multiple access mobile communication system, characterized in that it comprises. A method of searching for a P-N sequence phase of at least two received signals received through different bands in a multi-carrier code division multiple access mobile communication system, Outputting P-en phase and energy information by performing P-en sequence phase search of at least one of the received signals in parallel according to different search conditions assigned to each other; Comparing the output energy information with a threshold which is varied by the number of times of performing the P-en sequence phase search; Re-performing the P-N sequence phase search if there is at least two energy information larger than the threshold by the comparison; If there is only one energy information larger than the predetermined threshold, the P-N sequence phase searching method in the multi-carrier code division multiple access mobile communication system is characterized by determining a minimum variation section based on the phase information corresponding to the energy information. . The method of claim 13, wherein the threshold value, And up-regulating step by step by the number of times of performing the P-en sequence phase search. 14. The method of claim 13, wherein performing the P-N sequence phase search again comprises: And performing a P-N sequence phase search only for a search condition for outputting energy information larger than the threshold value. The method of claim 13, wherein the different search conditions, A P-N sequence phase search method in a multi-carrier code division multiple access mobile communication system, characterized in that it consists of phases and search intervals corresponding to P-N sequence phase search start points. The method of claim 16, wherein the different search conditions, Multi-carrier code division multiple access mobile communication system characterized by dividing a P-en sequence by the parallel number of performing the P-en sequence phase search and defining the corresponding phase by the equalization as starting points of the P-en sequence P-N sequence phase search in. The method of claim 16, wherein the different search conditions, A P-N sequence phase searching method in a multi-carrier code division multiple access mobile communication system, characterized by dividing a PN sequence into intervals of a predetermined size and assigning each divided search interval to each parallel P-N sequence phase search. . The method of claim 13, If the minimum fluctuation interval is determined, searching for the P-N sequence phase within the determined minimum fluctuation period for each of the received signals, and providing the P-N sequence phases acquired through the search to a higher processor. A P-N sequence phase search method in a multi-carrier code division multiple access mobile communication system, characterized in that it comprises.