KR100273644B1 - Apparatus and method for communicating channel using cmmon short code in asynchronous cdma basestation in a synchorouns - Google Patents

Abstract

A base station communication apparatus of an asynchronous code division multiple access communication system provides a start code of a spreading code and generates a common code commonly used by each base station, and the puncturing control period having a modulation pattern unique to the base station. And a modulator for modulating the common code by the modulation pattern, and a puncturer for puncturing the transmission signal of a spread spectrum specific common channel to the output of the modulator in the puncturing control period.

Description

Apparatus and method for base station channel communication of asynchronous code division multiple access communication system

The present invention relates to a base station communication apparatus and method for a code division multiple access communication system using an asynchronous method, and more particularly, to an apparatus and method for searching a base station at high speed using a common code.

In a communication system using a code division multiple access scheme, a communication system such as the IS-95 in which all base stations operate synchronously, each base station is synchronized in time to a Global Positioning System (GPS), and each base station has the same spreading code. By transmitting the code) to each unique value, the terminals can distinguish the base stations. However, the base station apparatuses of the code division multiple access communication system using the asynchronous method transmit a spreading code that is not synchronized with the GPS. In this case, before performing the communication, the terminals should search for a spreading code used in an optimal base station, that is, a base station signal having the largest reception power, and synchronize the code. Therefore, the time required for cell search in the asynchronous mobile terminal is the sum of the time required to find the spreading code and the time required to acquire the code synchronization. Therefore, in order to search the cell at high speed in the mobile terminal, it is very important to shorten the above two time periods, and therefore, the spreading code should be appropriately designed.

1 is a diagram illustrating a structure of a forward channel transmitter of base stations in a conventional code division multiple access communication system using an asynchronous scheme. The channel transmitter structure of the base station as shown in FIG. 1 is disclosed in "FAST CELL SEARCH ALGORITHM IN DS-CDMA MOBILE RADIO USING LONG SPREADING CODES" published by the K.Higuchi et al.

In the case of FIG. 1, the forward channel configuration includes a common channel commonly applied to all users in the base station and a dedicated channel assigned to each user. The common channel includes a pilot channel, a sync channel, a paging channel, a common control channel (CCH), and the like for transmitting voice and data to the dedicated channel. There is a traffic channel (TCH).

Each channel transmitter uses an orthogonal code to distinguish between its own channel and the channels of other channel transmitters. In this case, the orthogonal code generally uses Walsh code.

Subsequently, the base station devices scramble each channel transmission signal by using a long spreading code (hereinafter referred to as LSC) that is differently assigned to each base station so as to identify corresponding base station devices. In this case, a specific common channel among the common channels uses a spreading signal for identifying a base station and a common code periodically punctured in the LSC so that the terminal can quickly search for the base station. Herein, it is assumed that the specific common channel is a common control channel. Therefore, the common control channel scrambled with the LSC periodically punctures the CSC, which is a common code, to a mask control. The CSC is shorter in length than the LSC and is commonly used in all base stations, and the puncturing period is also the same in all base stations. The period of the LSC is to be an integer multiple of the CSC period.

The mobile terminal first searches for the CSC by the optimal base station, that is, the CSC received at the highest power, and extracts the correct period using the CSC matched receiver. Since the LSC period is an integer multiple of the CSC period, the mobile terminal searches for the LSC only at the position of the CSC which is periodically repeated. Therefore, as described above, the mobile terminal searches for the CSC of a specific common channel when searching for a base station, thereby reducing the time required for searching for the type and code synchronization of the LSC.

FIG. 2 is a diagram illustrating an example of a transmission signal of a common control channel punctured by a CSC transmitted from base station apparatuses having a forward channel structure as shown in FIG. 1. Since the common control channel signal is not transmitted while the CSC is punctured to the LSC as shown in FIG. 2, the control signal should be generated in consideration of this point in advance when generating the transmission signal of the common control channel. .

3A and 3B show examples of output signals of a plurality of base station common control channels using a common CSC in an inter-base station asynchronous system. Here, the output signal is one cycle of the LSC, and FIG. 3A illustrates an example in which CSC synchronization of a plurality of base station common control channel signals is not matched. FIG. 3B illustrates CSC synchronization of a plurality of base station common control channel signals. An example of the case is shown. In this case, as shown in FIG. 3A, since the CSC is not synchronized, the CSC is not canceled and there is no problem in the terminal searching for the base station.

However, since all the base stations puncture the same CSC with the same period, once the CSC is synchronized as shown in FIG. 3B, as shown in FIGS. 4A and 4B, the CSCs punctured in the common control channels of the multiple base stations exist repeatedly at the same time. Done. At this time, if the phases of the received CSCs are the same as in FIG. 4A, the mobile terminal does not have a problem finding the period of the CSC. However, if the phases of the received CSCs are different as shown in FIG. 4B, the received power is decreased to search for the CSC period. Becomes difficult. In particular, when the phases of the CSCs are reversed as shown in FIG. 4B, there is a problem that CSCs transmitted from two base stations cancel each other and thus cannot repeatedly search for CSCs.

Accordingly, an object of the present invention is to prevent the base station apparatus of a code division multiple access communication system using an asynchronous method from being continuously canceled by the common code of the other base station when the common code is punctured in the spread code on a specific common channel. An apparatus and method are provided.

It is another object of the present invention to modulate a common code according to a unique modulation pattern when a base station apparatus of a code division multiple access communication system using an asynchronous method modulates a common code on a specific common channel and then punctures a spreading code in a channel. It is an object of the present invention to provide an apparatus and a method capable of preventing a continuous cancellation due to a generated phase shift.

Generator for generating a common code used for each base station by the base station communication apparatus of the asynchronous type code division multiple access communication system according to an embodiment of the present invention for achieving the above object A modulator for storing a modulation pattern unique to the base station and modulating the common code by the modulation pattern in the puncturing control period, and puncturing the spread signal of a specific common channel spread in the puncturing control period to the output of the modulator in the puncturing control period. Characterized in that consisting of a perforator.

1 is a diagram illustrating a structure of a common channel and a traffic channel of each base station in a conventional code division multiple access communication system using an asynchronous scheme.

FIG. 2 is a diagram illustrating a signal form of a common channel in a base station apparatus having a channel structure as shown in FIG. 1.

3A is a diagram illustrating an example in which synchronization of a base station common code punctured by a plurality of base station common channel signals is not corrected, and FIG. 3B illustrates synchronization of a base station common code punctured by a plurality of base station common channel signals. Drawing showing an example of the fit

FIG. 4A is a diagram showing an example where the common code synchronization is correct and there is no phase difference for a plurality of base station common channel signals, and FIG. 4B is a diagram showing an example where the common code synchronization is correct and the phases are opposite in multiple common channel signals. drawing

5 is a diagram illustrating a channel structure for preventing continuous cancellation of a common code included in a common channel signal in a base station apparatus of a code division multiple access communication system using an asynchronous method according to an embodiment of the present invention.

6 is a view for explaining an operation of puncturing a common code in a common channel signal in a channel communication apparatus of a base station as shown in FIG.

7 illustrates an example of a common channel signal punctured by a common code modulated by a modulation pattern in a base station communication apparatus according to an embodiment of the present invention.

8 is a diagram illustrating a characteristic of preventing continuous cancellation of a common code when common code synchronization of two base station common channels is correct in a base station communication apparatus according to an embodiment of the present invention.

According to the present invention, when all base stations using a common carrier frequency are operated asynchronously in a direct spread code division multiple access (DS-CDMA) communication system, a common code of each base station is set to a spreading code of a specific common channel of a forward channel link. It transmits by puncturing in a period, and modulates and transmits in a specific pattern when puncturing the common code. This prevents the codes commonly assigned to all base stations from canceling each other by phase shift of a communication channel in the process of searching for a base station. do. That is, all of the base stations puncture the common CSC with the same period, which is to reduce the cell search time used in the mobile terminal, so that the CSC is modified for each base station while puncturing the spreading code while maintaining the structure using the common CSC. do. This prevents the common code from being continuously canceled even when the common codes of the base stations applied to the mobile terminal are completely synchronized.

FIG. 5 is a diagram illustrating a structure of a forward channel of a base station according to an embodiment of the present invention, and illustrates an example of configuring a specific common channel and traffic channel of each base station with a modulation pattern generator. Herein, it is assumed that a specific common channel is a common control channel (CCH), and an orthogonal code uses a Walsh code.

Referring to FIG. 5, the multiplier 511 multiplies orthogonally spreads the transmission signal of the common control channel by multiplying the transmission signal of the common control channel by the Walsh code assigned to the common control channel. A spread code generator 513 generates a spread code LSC having an N _LSC period for identifying a base station. The multiplier 515 multiplies the spread signal LSC by the transmission signal of the common control channel output from the multiplier 511 and spreads the bandwidth. The common code generator (CSC generator) 517 generates a common code CSC which is punctured and inserted into the transmission signal of the common control channel in N _CSC periods. The modulation pattern generator 519 stores the unique modulation pattern of the corresponding base station for preventing the common code CSC from continuous cancellation with the CSC of the other base station, and is activated at a predetermined period under the control of the puncturing controller 525 to output the modulation pattern. The multiplier 521 multiplies and outputs the common code CSC output from the common code generator 517 and the modulation pattern output from the modulation pattern generator 519. The puncturer 523 inputs the outputs of the multipliers 515 and 521. When the puncture control signal is generated by the puncture controller 525, the puncturer 523 punctures the modulated common code CSC output from the multiplier 521 to the transmission signal of the common control channel. The puncturing controller 525 generates the puncturing control signal for puncturing a common code in the common control channel at a predetermined period.

The multipliers 551-55N respectively input transmission signals of corresponding traffic channels and Walsh codes Walsh1-WalshN assigned to the corresponding traffic channels, and orthogonally spread transmission signals of the corresponding traffic channels. The multipliers 561-56N multiply the outputs of the corresponding multipliers 551-55N by the spreading codes of the spreading code generator 513 to spread the transmission signals of the corresponding traffic channels. The adder 571 adds and outputs the spread spectrum signals of each traffic channel output from the multipliers 561-56N. The adder 573 adds the transmission signal of the added traffic channel output from the adder 571 and the signal of the common control channel punctured by the common code to output the transmission signal of the corresponding base station.

FIG. 6 is a diagram for describing a process of puncturing a common code CSC modulated to a common control channel in FIG. 5.

Referring to FIG. 6, the common code CSC having an N _CSC period is punctured to a spreading code LSC having an N _LSC period, and the interval between the common code CSCs becomes an N _P (N _CSC / R _C ) chip period. . In the N _CSC period, the puncturing controller 525 simultaneously drives the modulation pattern generator 519 and the puncturing unit 523, so that the common code CSC modulated by the multiplier 521 is punctured and output on the common control channel CCH.

5 and 6, the transmission signals of the common control channel CCH and the traffic channel TCHs are orthogonally spread by corresponding Walsh codes, and channels are divided. The signals of each orthogonally spread channel are spread again. It is multiplied by the spreading code LSC generated by the generator 513 and scrambled.

The transmission signal of the common control channel CCH is applied to the puncturer 523. At this time, all base stations have the same common code generator 517 for puncturing a common code, and each base station has a CSC modulation pattern generator 519 consisting of + 1 / -1, which is different from other base stations. The modulation pattern is driven by a period of N _CSC in a section in which the common code CSC is output by the puncturing controller 525 and multiplied by the common code CSC. Accordingly, before the common code CSC common to each base station is punctured by the control of the puncturing controller 525, the common code CSC is multiplied by a modulation pattern uniquely assigned to the base station. It is punctured and output to the transmission signal of the common control channel CCH.

<Table 1> is a table showing an example of different modulation patterns applied to each base station, and FIG. 7 is a signal example of a common control channel punctured by a common code CSC modulated by a modulation pattern as shown in <Table 1>. It is shown.

Base station Modulation pattern Cell a +1 -1 +1 -1 +1 -1 +1 -1 Cell b +1 +1 -1 -1 +1 +1 -1 -1 Cell c +1 +1 -1 -1 -1 -1 +1 +1

Therefore, if the common code CSC is modulated using the modulation pattern as shown in Table 1, even if the common code CSC outputted through the common control channel CCH of the two base stations is consistent, as shown in FIG. The sign CSC is not canceled out.

8 shows each state when the common code CSC of the common control channel of the two base stations is synchronized. In this case, the hatched portion in FIG. 8 indicates a state in which the phases of the common code CSC of Cell A and Cell B are in the same phase, and the portion not shown indicates that the phases of the common code CSC of Cell A and Cell B are in opposite states. It is. In FIG. 8, for convenience of description, the case where the modulation pattern has a period of 5 is taken as an example. That is, assuming that five common code CSCs are perforated per spread code LSC cycle. In FIG. 8, a portion of the common control channel signal that is not punctured by the common code CSC is omitted.

The modulation pattern of Cell A used in FIG. 8 is (+1, +1, -1, -1, +1) and the modulation pattern of Cell B is (-1, +1, -1, +1, +1). )to be. In FIG. 8, reference numeral 812 denotes a puncturing state of the common code CSC of the common control channel of the cell A, and reference numerals 822 through 830 denote common codes of the common control channel of the cell A by the common code CSC of the common control channel of the cell B. All possible relative positions that can be located relative to the CSC are shown.

The hatched portion of the common control channel signal of the cell B shows a portion in phase with the common control channel signal of the cell A when a phase shift does not occur during transmission, and the remaining portions of the cell B and the cell are shown. The case where the common code CSC phase of B is reversed is shown. In this case, since the common code CSCs of the opposite phase phases cancel each other, but not repeatedly, the code synchronization of the spreading code LSC can be searched. In this case, if the phase of the common control channel signal of one base station changes by 180 degrees due to the phase shift generated during transmission, the phase of the hatched portion in FIG. 8 becomes the same, and in this case, code synchronization can be found. . Therefore, it is possible to prevent the case where the common code CSC cannot be repeatedly detected due to the phase difference even if a phase shift occurs or not during transmission.

As described above, the base station transmitter of the code division multiple access communication system using the asynchronous method punctures and transmits a common code in a spreading code period through a specific common channel, and the mobile terminals transmit the transmission signal of the specific common channel of the base station. In a system for searching for a base station, the common code of the base stations is punctured by a phase shift generated during transmission by puncturing a common code used by all base stations using the same modulation pattern of the base station. Even if the synchronization is correct, the common codes can be prevented from being continuously canceled, and thus, there is an advantage that the mobile terminal can perform the code synchronization by searching the base station at high speed.

Claims (13)

A base station communication apparatus of an asynchronous code division multiple access communication system, A generator for generating a common code used by each base station in common; A modulator having a modulation pattern unique to a base station, wherein the modulation pattern is repeated at regular intervals and modulates the common code by the modulation pattern; And a puncture inserter for puncturing a transmission signal of a specific common channel spread in the common code transmission section and inserting an output of the modulator. The method of claim 1, wherein the modulator, A modulation pattern generator having the modulation pattern; And a multiplier configured to multiply and modulate the modulation pattern and the common code. The base station communication apparatus according to claim 2, wherein the common code is punctured at the predetermined period in the spreading code interval and the spreading code is started at the end of the specific common code. The base station communication apparatus of claim 1, wherein the specific common channel is a common control channel. A base station communication apparatus of an asynchronous code division multiple access communication system, Generating a common code used by each base station in common; Having a modulation pattern unique to a base station, repeating the modulation pattern by a predetermined period, and modulating the common code by the modulation pattern; And puncturing the transmission signal of a specific common channel spread in the transmission period of the common code, and inserting an output of the modulator. A common code generator for generating a common code commonly used by a plurality of base stations, A pattern generator for generating a modulation pattern specific to each base station; A spreading code generator for generating a spreading code for identifying the base station at regular intervals; A specific channel transmitter for spreading and transmitting a transmission signal of a specific channel by the spreading code; And a common code inserter for modulating the common code into the modulation pattern and puncturing and inserting the modulated common codes into predetermined positions within a spreading code period of a transmission code of the common channel. Base station communication device. The method of claim 6, wherein the common code inserter, A multiplier for modulating by multiplying the common pattern with the modulation pattern; And a puncture inserter for puncturing a transmission signal of a specific channel spread by the spreading code in a predetermined section and inserting the modulated common code in the puncturing section. The base station communication apparatus according to claim 7, wherein the predetermined position is repeated in a predetermined interval unit in the spreading code interval, and the puncturing interval is a period of the common code. 8. The base station communication apparatus of claim 7, wherein the specific channel is a common control channel. In the base station communication method of a code division multiple access communication system of a spreading code for generating a spreading code for specifying a base station at regular intervals and spreading transmission of a transmission signal of a specific channel by the spreading code, Generating a common code commonly used by a plurality of base stations, and generating a modulation pattern specific to each base station; A base station communication method of an asynchronous code division multiple access communication system comprising the step of modulating the common code into the modulation pattern and puncture inserting the modulated common codes into a predetermined position within a spreading code period of a transmission code of the common channel. . The method of claim 6, wherein the common code inserting process comprises: Modulating by multiplying the common pattern with the modulation pattern; A base station communication method of an asynchronous code division multiple access communication system comprising puncturing a transmission signal of a specific channel spread by the spreading code in a set section and inserting the modulated common code in the punctured section. The method of claim 7, wherein the puncturing in the period of the spreading code is repeated in a predetermined period in the spreading code section and punctures the signal of the specific channel by the period of the common code, and the common in the puncturing section. A base station communication method of an asynchronous code division multiple access communication system in which a code is inserted. The method of claim 12, wherein the specific channel is a common control channel.