KR100424628B1 - Apparatus and method for generating spreading code in mobile communication system - Google Patents

Abstract

The apparatus for generating a Walsh code (walsh code) and an orthogonal variable spread factor (OVSF) code according to the present invention, if the input channel ID corresponds to the OVSF code, bit-inverting the input channel ID to the OVSF A bit inverse array for converting into a channel ID for generating a code, and the channel ID as it is if the input channel ID corresponds to the Walsh code, and a channel output from the bit inverse array if the channel ID corresponds to the OVSF code A multiplexer for selectively outputting an ID, a counter sequentially generating counter signals within a predetermined range determined according to the length of the input channel ID, a code ID from the multiplexer, and a counter signal from the counter. Characterized by including a code generator to generate The.

Description

Apparatus and method for generating spreading code in mobile communication system {APPARATUS AND METHOD FOR GENERATING SPREADING CODE IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to an apparatus and method for generating a spreading code, and more particularly, an apparatus for generating a Walsh code used in a synchronous system and an Orthogonal Variable Spread Factor (OVSF) code used in an asynchronous system through a single apparatus. It is about a method.

Currently, 3G Code Division Multiple Access (CDMA) cellular mobile communication is largely divided into a synchronous system and an asynchronous system.

The asynchronous system may be a universal mobile telecommunication system (UMTS) adopted in the European standard manner, and the synchronous system may be a CDMA2000 adopted in the US standard manner. Currently, the two systems are harmonized, and accordingly, various technologies for making the two systems compatible are required.

Generally, orthogonal codes are used for spreading channels and identifiers for distinguishing each channel in a mobile communication system. Here, the CDMA2000 system uses a Walsh code as the orthogonal code, and the UMTS system uses an OVSF code as the orthogonal code.

1 shows a channel transmitter of the synchronous system.

Referring to FIG. 1, Walsh code generators 111 through 11N generate predetermined Walsh codes. Then, each of the spreaders 101 to 10N multiplies and outputs the Walsh code generated by the Walsh code generator corresponding to the input user data. Thereafter, the adder 121 adds and outputs spread signals from the spreaders 101-10N. The multiplier 121 multiplies the output signal of the adder 121 by a carrier wave, converts the radio signal into a radio frequency (RF) signal, and outputs the result to an antenna.

2 shows a configuration of a receiver corresponding to the transmitter of FIG. 1.

Referring to FIG. 2, first, the multiplier 201 multiplies a radio frequency signal received through an antenna and a coherent carrier frequency signal and converts the baseband signal into a baseband signal. Walsh code generator 221 generates a Walsh code used in the transmitter. The despreader 211 multiplies the signal from the multiplier 201 with the Walsh code from the Walsh code generator 221 and despreads the output signal. The switch 231 switches and outputs the despread signal from the despreader 211 according to a predetermined sampling period.

3 illustrates a channel transmitter of the asynchronous system.

Referring to FIG. 3, the OVSF code generators 311 to 31N generate a predetermined OVSF code. Then, each of the spreaders 301 to 30N multiplies and outputs the OVSF code generated by the OVSF code generator corresponding to the input user data. Thereafter, the adder 321 adds and outputs spread signals from the spreaders 301-30N. The multiplier 321 multiplies the output signal of the adder 121 by a carrier wave, converts the radio signal into a radio frequency (RF) signal, and outputs the result to an antenna.

4 illustrates a configuration of a receiver corresponding to the transmitter of FIG. 3.

Referring to FIG. 4, first, the multiplier 401 multiplies a radio frequency signal received through an antenna and a coherent carrier frequency signal to convert the baseband signal into a baseband signal. The OVSF generator 421 generates the OVSF code used by the transmitter. The despreader 411 multiplies the signal from the multiplier 401 with the OVSF code from the OVSF code generator 421 and outputs the result. The switch 431 switches and outputs the despread signal from the despreader 411 according to a predetermined sampling period.

That is, as described above, the orthogonal codes used for channel spreading are different from each other in the synchronous system and the asynchronous system. This means that different orthogonal code generators are used. Therefore, when implementing a system that processes the two methods in dual mode, each code generator (a Walsh code generator and an OVSF code generator) is required, which causes a problem in that the hardware becomes large.

Accordingly, an object of the present invention relates to an apparatus and a method for generating a Walsh code and an OVSF code through one device.

In order to achieve the above object, according to a preferred embodiment of the present invention, a device for generating a Walsh code (walsh code) and orthogonal variable spread factor (OVSF) code, input channel ID corresponding to the OVSF code In the case of bit inverse arrangement of the input channel ID to convert the channel ID for generating the OVSF code, and if the input channel ID corresponds to the Walsh code, and outputs the channel ID as it is, the OVSF code A multiplexer for selectively outputting a channel ID output from the bit inverse array, a counter for sequentially generating counter signals in a predetermined range determined according to a length of the input channel ID, and a code ID from the multiplexer And spread signals using the counter signals from the counter. Characterized by including the sex-code generator for.

According to a preferred embodiment of the present invention, a method for generating a Walsh code and an Orthogonal Variable Spread Factor (OVSF) code together is output when the channel ID corresponding to the Walsh code corresponds to the Walsh code and is output as it is. When the code corresponds to a code, the input code ID is bit-inverted, converted into a code ID for generating the OVSF code, and outputted, and the counter signals are sequentially arranged in a predetermined range determined according to the length of the input code ID. And generating a spreading code using the output code ID and the counter signals sequentially generated.

1 shows a channel transmitter of a conventional synchronous mobile communication system.

2 is a diagram illustrating a configuration of a receiver corresponding to the transmitter of FIG. 1.

3 shows a channel transmitter of a typical asynchronous mobile communication system.

4 is a diagram illustrating a configuration of a receiver corresponding to the transmitter of FIG. 3.

5 is a view showing a channel transmitter according to an embodiment of the present invention.

6 is a diagram illustrating a configuration of a receiver corresponding to the transmitter of FIG. 5.

7 is a view showing a detailed configuration of a spreading code generator for generating a Walsh code and an OVSF code according to an embodiment of the present invention.

8 is a diagram showing the detailed configuration of the code generator 704 in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First, the characteristics of the channel spreading codes used in the synchronous system (CDMA2000) and the asynchronous system (UMTS), respectively, are as follows.

First, Table 1 shows the Walsh code generation method, and Table 2 below shows the OVSF code generation method.

For example, when the spread factor is "4", when the channel code "2" is assigned in the physical layer, as shown in Table 1 and Table 2, the synchronization timing system is (1, -1, 1, -1) is used, and the asynchronous system uses (1,1, -1, -1) as the channel spreading code.

Looking at the Walsh code and the OVSF code, a code (or codeword) corresponding to a predetermined code ID is found in the OVSF code, which is the same as the Walsh code of the ID in which the code IDs are arranged in reverse. For example, if the length is 4, the third Walsh code in Table 1 is (1,1, -1, -1), which is the second OVSF code in Table 2 (1,1, -1, -1). Same as). That is, if the first ID of the Walsh code starts from 0, the ID of the third Walsh code corresponds to 2 (binary bit: 10). Inverting it bitwise makes it 1 (binary bit: 01). This means that the orthogonal code and the OVSF code corresponding to each of the two indices that are inversely aligned with each other are identical. This regularity applies equally even if the length of the codeword is extended. The present invention is to generate a Walsh code and an OVSF code together with one code generator based on this property.

5 illustrates a channel transmitter having a Walsh / OVSF code generator according to an embodiment of the present invention.

Referring to FIG. 5, Walsh / OVSF code generators 511 to 51N generate a predetermined spreading code according to a current communication mode. For example, Walsh codes are generated when the current communication mode is synchronous, and OVSF codes are generated when asynchronous. Then, each of the spreaders 501 to 50N multiplies and outputs the input user data by multiplying a spreading code generated by the Walsh / OVSF generator. Thereafter, the adder 521 adds and outputs spread signals from the spreaders 501-50N. The multiplier 521 multiplies the output signal of the adder 521 by the carrier wave, converts the radio signal into a radio frequency (RF) signal, and outputs the result to an antenna.

FIG. 6 illustrates a configuration of a receiver corresponding to the transmitter of FIG. 5.

Referring to FIG. 6, first, the multiplier 601 multiplies a radio frequency signal received through an antenna and a coherent carrier frequency signal to convert the baseband signal into a baseband signal. Walsh / OVSF code generator 621 generates Walsh or OVSF codes used by the transmitter. The despreader 611 multiplies the signal from the multiplier 601 by the Walsh / OVSF code or the OVSF code from the Walsh / OVSF code generator 621 and outputs the result. The switch 631 switches and outputs the despread signal from the despreader 611 according to a predetermined sampling period.

7 illustrates a detailed configuration of the Walsh code / OVSF code generator according to an embodiment of the present invention. The Walsh code / OVSF code generator is used, for example, in dual module systems capable of operating synchronously and asynchronously. Accordingly, the Walsh code / OVSF generator generates a corresponding channel spread code according to the present communication mode. For example, if it is determined synchronously, it generates a Walsh code. If it is determined asynchronously, it generates an OVSF code.

Referring to FIG. 7, the controller 701 outputs an indication bit indicating a current communication mode and a value indicating a channel ID (or code ID) to the channel ID converter 702, and replaces the most significant bit in the channel ID. (M) is output to the counter 703. Here, the M value is a value obtained by subtracting "1" from the number of bits constituting the channel ID. For example, if the current communication mode is a synchronous system, the controller 701 designates and outputs the indication bit as "0", and if it is an asynchronous system, designates as "1". A binary bit string ([M: 0]) consisting of bits, meaning that the channel ID consists of M + 1 bits, meaning that the length of the channel spreading code is 2 ^{M + 1} . The / OVSF code generator is for generating codes of length 2 ^{M + 1} .

The ID converter 702 includes a bit inverse array 712 and a multiplexer 722 therein. The bit inverse aligner 712 bit-inverts the channel ID [M: 0] provided from the controller 701 to generate a channel ID [[0: M]) for generating another spreading code. For example, if the code generator 704 described below is configured to generate a Walsh code, the other spreading code is an OVSF code, and the inversely arranged channel is a ID of the Walsh code for generating the OVSF code. . The multiplexer 722 inputs the channel ID [[M: 0]) from the controller 701 and the channel ID [[0: M]) from the bit inverse array 712, and the controller 701. One of the two inputs is selected and output by the indication bit from "

The counter 703 outputs a counter signal by performing M + 1 bit module counting in response to the M value from the controller 701. For example, when the M value is "2", the counter 703 performs counting from 0 (000) to 7 (111) to sequentially output counter signals.

The code generator 704 generates a spreading code (a Walsh code or an OVSF code) using the channel ID from the multiplexer 712 and the counter signal from the counter 703. The code generator 704 has a structure of, for example, a Walsh code generator 704. A detailed configuration of the code generator 704 is as shown in FIG.

The configuration of the code generator illustrated in FIG. 8 includes a plurality of logical product gates 810 and exclusive logical sum gates 820. In this case, the number of logical product gates 810 is determined based on the longest Walsh code. That is, when the length of the orthogonal code is 4, 8, 16, 32, 64, 128 chips, the number of logical product gates 310 is determined based on the longest 128 chip. In this case, the number of the logical product gates 810 determined will be seven corresponding to 7 bits, which is the number of bits of the orthogonal code index and the count value. Accordingly, when generating an orthogonal code for an orthogonal code length shorter than the above defined pseudo long orthogonal code length, bits other than the actual valid value are regarded as "0". In other words, a bit other than the actual valid value is masked with "0".

Each of the logical product gates 810 logically multiplies the orthogonal code index CODE_ID provided by the multiplexer 722 and the corresponding bit of the count value COUNT provided by the counter 703. The exclusive logical sum gate 820 outputs one bit (or chip) constituting a spreading code by performing an exclusive logical sum operation on values output from each of the logical product gates 810.

An example of the operation will be described with reference to the configuration of FIGS. 7 and 8 as described above.

For example, it is assumed that the code generator 704 is a configuration for generating a Walsh code, assumes that the current communication mode is asynchronous, and generates a third OVSF code.

Then, the controller 701 provides an indication bit (for example, 0) indicating the asynchronous mode of the current communication mode to the multiplexer 722, and provides a channel ID " 3 ([0 1 1]) " 712 and multiplexer 722. Then, the bit inverse aligner 712 inversely arranges the channel ID "3 ([0 1 1])" to create an ID [[1 1 0]) for generating the third OVSF code to the multiplexer 722. Output The multiplexer 722 receives the output ([1 1 0]) and the code ID ([0 1 1]) of the bit inverse array 712 as inputs, and inputs the indication bits from the controller 701. Selects and outputs the output of the bit inverse array 712 to the code generator 704. At this time, the counter 703 performs (M + 1) bit module counting by the M value (the most significant bit digit value of the code ID) from the controller 701 to the code generator 704 to obtain the counter value. It is provided to the code generator 704 sequentially. In this case, the M value becomes 2, and the counter 703 performs a 3-bit module counting to provide a counter value from (000) to (111) to the code generator 704. That is, the channel ID provided to the code generator 704 is 6 ([1 1 0]), and the counter range t is 8 (0-7). Looking at the bits (chips) output corresponding to each counter as follows. The following operation is performed by the AND gates 810 and the exclusive AND gate 820 of the code generator 704 shown in FIG.

CODE_ID = (1 1 0), counter range is (0≤ t ≤ 7)

Therefore, t = 0 (0 0 0)-> (1 x 0) xor (1 x 0) xor (0 x 0) = 0

t = 1 (0 0 1)-> (1 × 0) xor (1 × 0) xor (0 × 1) = 0

t = 2 (0 1 0)-> (1 × 0) xor (1 × 1) xor (0 × 0) = 1

t = 3 (0 1 1)-> (1 × 0) xor (1 × 1) xor (0 × 1) = 1

t = 4 (1 0 0)-> (1 × 1) xor (1 × 0) xor (0 × 0) = 1

t = 5 (1 0 1)-> (1 × 1) xor (1 × 0) xor (0 × 1) = 1

t = 6 (1 1 0)-> (1 × 1) xor (1 × 1) xor (0 × 0) = 0

t = 7 (1 1 1)-> (1 × 1) xor (1 × 1) xor (0 × 1) = 0

Therefore, the final generated diffusion code is (0, 0, 1, 1, 1, 1, 0, 0). That is, the generated spreading code corresponds to No. 6 of the Walsh code of length 8 and 3 of the OVSF code of length 8. That is, the present invention constitutes an apparatus for generating a Walsh code and an OVSF code simultaneously by using a property in which the Walsh code index corresponding to the specific spreading code and the index of the OVSF code have a bit inverse array relationship.

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 those equivalent to the scope of the claims.

As described above, the present invention has the advantage of reducing the hardware size by implementing the channel spreader of the physical layer as one channel spreader code generator in a transceiver of a mobile communication system using both asynchronous and synchronous code spreading schemes.

Claims (4)

A device for generating a Walsh code and an orthogonal variable spread factor (OVSF) code together, A bit inverse array for converting the input channel ID into bit inverse when the input channel ID corresponds to the OVSF code and converting the input channel ID into a channel ID for generating the OVSF code; A multiplexer for outputting the channel ID as it is if the input channel ID corresponds to the Walsh code; and selecting and outputting a channel ID output from the bit inverse array when the channel ID corresponds to the OVSF code; A counter for generating counter signals sequentially in a predetermined range determined according to the length of the input channel ID; And a code generator for generating a spreading code using the code ID from the multiplexer and the counter signals from the counter. The method of claim 1, The counter is a K-bit module counter, wherein K is the number of bits constituting the input code ID. The method of claim 1, wherein the code generator, Logical product gates for performing a logical multiplication on each of bits of a code ID from the multiplexer and bits of the sequentially generated counter signal; And an exclusive logical sum gate which sequentially generates the bits constituting the spreading code by performing an exclusive logical sum operation on the output bits of the logical product gates. In the method for generating a Walsh code and orthogonal variable spread factor (OVSF) code together, Outputting the input channel ID as it is corresponding to the Walsh code, and converting the input code ID into a code ID for generating the OVSF code by bit inversely arranging the input code ID; Generating counter signals sequentially in a predetermined range determined according to the length of the input code ID; And generating a spreading code using the output code ID and the counter signals sequentially generated.