KR20030068013A - Apparatus for creating hs-scch using user specific id in cdma system - Google Patents

Abstract

PURPOSE: An apparatus for generating control data using an user ID in a mobile communication system is provided to minimize a size of a CRC bit and optimize the performance of an encoder by using an user peculiar CRC and an user peculiar tail bit. CONSTITUTION: An apparatus for generating control data using an user ID in a mobile communication system includes an user peculiar CRC(Cyclic Redundancy Check) bit generator(400), an user peculiar tail bit generator(410), and an encoder(420). The user peculiar CRC bit generator is used for receiving signals of a control information bit and an user information 1 and generating a bit stream including user peculiar CRC bits. The user peculiar tail bit generator is used for outputting the bit stream including the bit stream of the user peculiar CRC bit generator and the user information 2. The encoder is used for encoding the bit stream of the user peculiar tail bit generator.

Description

Device for generating control data using user's unique number in mobile communication system {APPARATUS FOR CREATING HS-SCCH USING USER SPECIFIC ID IN CDMA SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a code division multiple access mobile communication system, and more particularly, to an apparatus for generating control data for recognition according to a user identification number.

In general, a mobile communication system that performs code division multiple access (CDMA) (hereinafter referred to as an IMT2000 system), in particular, in a high speed data packet access (HSDPA) for high speed transmission, all users transmit high speed data. For this purpose, HS-DSCH channels are used by sharing each other in time. Therefore, when several users share and use the HS-DSCH as described above, a method for recognizing when data about itself is transmitted is required. To this end, a user unique number is given to the user by the base station to the user belonging to each base station. In addition, by applying a CRC (Cyclic Redundancy Check) for the HS-SCCH which is the control channel of the HS-DSCH using the user's unique number, when the user other than the user receives the data, It is possible to determine that the data is not.

1 shows the structure of control information bits transmitted on the HS-SCCH.

Referring to FIG. 1, one frame is transmitted for three slots (2ms: one slot is 0.667ms), and among the first slot, 8 bits of control information 1 and 12 bits according to the control information 1 and the user identification number. CRC is added and transmitted. In addition, during the subsequent two slots, the control information 2 and the CRC according to the control information 2 are added and transmitted together.

2 is a diagram illustrating a transmission structure for transmitting the control information 1 and a CRC corresponding thereto.

Referring to FIG. 2, when the 8-bit control information bit is input to the user-specific CRC generator 200, at the same time, the 10-bit user unique number is input to the CRC generator 200. In this case, the CRC generator 200 ) Generates a 12-bit CRC according to the control information bit and the user's unique number, outputs the 8-bit control information string, and then outputs the generated 12-bit CRC bits to a total of 20-bit bit strings. Outputs Then, the output 20-bit bit strings are 8 bit tail bits having a value of 0 for a convolutional code having a constraint length of 9 used in the encoder 220 after the 20-bit bit string. In addition to this, a total of 28 bits are outputted and input to the encoder 220. Then, the encoder 220 encodes the input 28-bit input bit string and outputs an encoded symbol string composed of 40 encoded symbols.

3 shows the structure of the CRC generator.

First, referring to FIG. 3, when an 8-bit input signal is input to the switch 320 and the CRC generator 300, the switch 320 connects the circuit of the input signal and the output circuit to input the 8-bit input. The CRC generator 300 outputs a 12-bit CRC bit according to the input signal during the above operation. Then, the output 12-bit CRC bits are applied to the exclusive adder 310, and at the same time, a user's unique number is input to the exclusive adder 310, and the 12-bit CRC bits are exclusively added to the 12-bit CRC bits to switch 320. Is entered. Then, the switch 320 connects the output unit of the adder and the final output unit, and outputs all 12 bits of output bits of the exclusive adder 310. Thus, the user-specific CRC generator outputs 20 bits.

In this case, referring to the prior art transmission structure of FIG. 2, eight information bits and twelve CRC bits are encoded and 40 symbols are output, so that the code rate is 20/40 = 1/2 (40,20). Become an encoder. The reason why the CRC generator for generating the 12 CRC bits is described below. The HSDPA system currently has a CRC generator that generates 10, 12, 16, and 24 CRC bits of the user unique number of bits. Referring to the CRC generator of FIG. 3, in order to identify all user unique numbers, CRC bits of 10 or more bits must be generated so that CRC bits between different users are different. Accordingly, the above-described prior art has no choice but to use a CRC generator that generates the CRC bits closest to the ten of the CRC generators that generate ten or more CRC bits. Thus, we use a CRC generator that generates 12 bits of CRC bits. However, in the code theory, because the length of the CRC bits is large, the actual coding rate is high, which causes the performance of the encoder to be degraded. Therefore, the smaller the number of bits of the CRC bit is, the lower the code rate can be. Thus, the transmission performance is excellent. If the CRC bit is 8 bits, the code rate is 16/40 = 2/5 because the code rate is 16/40 = 2/5 because 8 information bits and 8 CRC bits, that is, 16 bits are encoded to encode 40 bits. Is remarkable. Therefore, in order to optimize the performance of the encoder as described above, the number of CRC bits should be minimized. However, as described above, when the number of CRC bits is smaller than the unique user number, the same CRC between different users may occur. Therefore, there is a need for a method of minimizing the number of CRC bits used to optimize encoder performance and thereby preventing a signal not transmitted to itself.

Accordingly, an object of the present invention is to use a minimum CRC bit in a code division multiple access mobile communication system and to prevent a signal not transmitted to itself from being transmitted to each other by using a user unique number between two different users. In providing.

Another object of the present invention is to provide an apparatus for optimizing the performance of an encoder by using the above method in a code division multiple access mobile communication system.

In order to achieve the above objects, the present invention provides a user-specific CRC generator that generates a user-specific CRC bit using a part of the user ID and a user-specific tail bit using another part of the user ID as a tail bit for the convolutional encoder. A control data generation apparatus using a user's unique number is used in a mobile communication system characterized by being configured as a generator.

1 illustrates a channel structure according to the prior art.

2 illustrates a transmitter structure according to the prior art;

3 is a diagram showing the structure of a user-specific CRC generator according to the prior art;

4 illustrates a transmitter structure according to the present invention.

5 illustrates the structure of a user specific tail bit generator in accordance with the present invention.

6 illustrates the structure of a CRC generator for generating a CRC bit in accordance with the present invention;

7 illustrates a structure of an encoder according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention. In addition, although an embodiment of the present invention represents a specific value for a numerical value, such as the number of bits, it should be noted that this is to help understanding of the present invention and may vary with respect to the specific value.

First of all, the present invention provides a method of preventing a signal that is not transmitted to each other by using a minimum CRC bit and using a user unique number between two different users in a mobile communication system. For example, a part of the 10-bit user's unique number is applied to the CRC generator to generate a user's own CRC, and another part is used as a tail bit for the convolutional code to operate when any user receives a signal that is not transmitted to the receiver. One way to avoid this is to apply it to a mobile communication system.

In the prior art, a 10-bit user identification number is applied to a CRC generator having an output bit of 12 bits, whereas in the present invention, a CRC having an output value of 8 bits having the smallest output bit among the CRC generators currently available in the HSDPA system is used. A method of applying a part of the 10-bit user's unique number to a generator and using the other part as a tail bit for a convolutional encoder. The user's unique number is distributed to a CRC generator and a tail bit generator, not to the CRC generator. It provides a way to apply. In many existing systems, tail bits for convolutional encoders only have a value of 0, which improves the performance of the encoder by adjusting the memory value to a fixed value at the end of encoding all input information bits in the convolutional encoder. . However, in actual code theory, the above performance improvement can be obtained as long as the tail bits are promised on the transmitter and the receiver. Therefore, as described above, when the user's unique number is used as the tail bit, the received data matches the user's unique number in the case of a legitimate user of the data, and there is no deterioration in the performance of the encoder. On the other hand, if the user is not a legitimate user of the data, if the received signal is decoded with a convolutional code decoder, decoding is not performed properly, and the output value of the decoder outputs arbitrary signals other than the original information signal. In addition, the transmitter determines that the output value of the decoder is not valid data in the CRC searcher of the receiver corresponding to the CRC generator, and does not operate on the input signal. A method of the system having the user specific tail bit generator as described above will be described with reference to the accompanying drawings.

4 shows a transmitter structure according to the present invention.

In the transmitter structure shown in FIG. 4, a part of user identification number is defined as user information 1, and another part is defined as user information 2, and the user information 1 is used for generating a user-specific CRC bit, and the user Information 2 is used for generating user specific tail bits. In FIG. 4, which will be described below, an example of using an 8-bit long CRC bit and using a convolutional code having a constraint length of 9 is illustrated. At this time, the user information 1 has 8 bits of information, which is the length of the CRC bit, and the user information 2 also has a length of confinement code (length of binding length)-1 = 9-1 = 8 bits. Accordingly, the user information 1 of the 10-bit user unique number is selected by using 8 bits or less, and when selected by 8 bits or less, the remaining bits are filled with specific bits to make 8 bits and used as the user information 1. In addition, the user information 2 is also made of 8 bits in the same manner as the user information 1. In addition, in the system using the user's unique number bits, all the bits of the user's unique number are preferably used in one of the user information 1 or the user information 2 to distinguish the users. For example, if a user's unique number of 10 bits in total (u0, u1, u2, u3, u4, u5, u6, u7, u8, u9) is used, (u0, u1, u2) 8 bits such as, u3, u4, u5, u6, u7) are selected as user information 1, and 2 bits are selected as (u8, u9, 0,0,0,0,0,0) and the rest are filled with 0 8 bits can be used for user information 2. The transmitter structure of FIG. 4 shown below will be used in the user specific CRC generator 400 and the user specific tail bit generator 410 using the user information 1 and the user information 2 generated from the user ID as described above.

Referring to FIG. 4, when the transmitter operation of the present invention is described, when the 8-bit control information bit is inputted to the user-specific CRC generator 400, at the same time, user information that is part of 8-bit or less of the 10-bit user-specific number is simultaneously. 1 is input to the user-specific CRC generator 400, where the user-specific CRC generator 400 generates an 8-bit CRC according to the user information 1, and outputs the 8-bit control information string. Subsequently, the 8-bit generated user-specific CRC bits are output, followed by a total of 16 bits. The structure of the user-specific CRC generator 400 has a difference that the number of bits of the CRC is 8 bits instead of 12 bits as compared to FIG. 3.

Referring to FIG. 3, when the user-specific CRC generator 400 is described, when an 8-bit input signal is input to the switch 320 and the CRC generator 300, the switch 320 may include a circuit and an output circuit of the input signal. The 8-bit input signal is output as it is, and the CRC generator 300 outputs 8-bit CRC bits according to the input signal. Then, the output 8-bit CRC bits are applied to the exclusive adder 310, and at the same time, user information 1 is input to the exclusive adder 310, and is exclusively added to the 8-bit CRC bits to switch 320. Is entered. Then, the switch 320 connects the output unit of the adder and the final output unit, and outputs all 8-bit output bits of the exclusive adder 310. Thus, the user-specific CRC generator 400 outputs 16 bits.

An operation of the CRC generator 300 outputting CRC bits having a length of 8 bits according to an embodiment of the present invention is shown in FIG. 6. Referring to Fig. 6, the operation of the CRC bit generator of 8 bits in length is shown first, and the stored values of all the memories m0-m7 are filled with zeros. When the input bits are sequentially input, when the input bits are input one by one and at the same time the stored value is input to the exclusive adder 610 in the memory m7, the input bits are added exclusively and then exclusive adders 620 to 623. Is entered. Then, at the same time, the stored value and the output value of the exclusive adder 610 are inputted to the exclusive adder 623 to be added exclusively, and then input to the memory m7 and stored, and at the same time, the stored value to the memory m5. Is stored in the memory m4, and at the same time, the stored value is stored in the memory m5, and the stored value and the output value of the exclusive adder 610 are exclusively added to the memory m3. ) Is added to the memory m4 and stored in the memory m4, and at the same time, the stored value and the output value of the exclusive adder 610 are input to the exclusive adder 621 and exclusively added to the memory m2. is input to m3 and stored, and at the same time the value stored in the memory m1 is input to and stored in memory m2. At the same time, the stored value and the output value of the exclusive adder 610 are inputted to the exclusive adder 620 and are exclusively added to the memory m0, and then the input values are stored and stored in the memory m1, and the output value of the exclusive adder 610 is It is input to m0 and stored. Then, the second input bit is input to the exclusive adder 610 again, and the above operation is repeated. If the above operation is repeated until all of the input bits are input, that is, eight times, the switch 600 is disconnected during the operation, and then connected to output eight times the output values from m7. The output values then become CRC bits for the input bits.

Then, the output signals of the 16-bit user specific CRC generator output the user-specific tail bit generator for generating 8-bit tail bits for a convolutional encoder having a constraint of 9 used in the encoder 420. 410 is input. At the same time, user information 2, which is another part of 8 bits or less of the user ID, is input to the user specific tail bit generator 410. Then, after the 16-bit bit string as the input bit, the user information 2 is added to output a bit string of 24 bits and input to the encoder 220. User Fig. 5 shows the structure of the user specific CRC generator. Referring to FIG. 5, the input signal is input to the switch 500, and the user information 2 is input to the delay unit 510. Then, the switch 500 connects the input signal terminal and the output signal terminal, and outputs first input signals. When the output of the input signal is finished, the delay unit 510 delays the output of the user information 2. At the same time, the switch 500 connects the output terminal of the delay unit and the output signal terminal, and outputs all user information 2 which are output signals of the delay unit 510. In this manner, the user-specific tail bit generator 410 of FIG. 4 outputs a total of 24 bits of bit stream to the encoder 420. Then, the encoder 420 encodes the input 24-bit input bit string and outputs an encoded symbol string composed of 40 encoded symbols.

7 illustrates a convolutional encoder having a code rate of 1/2 used in the encoder 420. Referring to FIG. 7, referring to the operation of the encoder, first, a portion indicated by a dotted line is a convolutional code having a restriction length of 9 and a code rate of 1/2, and when an input bit of 24 bits is input and encoded in the convolutional code, The parity portion and the second parity portion are output at every bit input. Each time the input bit is input by one bit, one symbol is output to the first parity part and the second parity part, and the first parity bit and the second parity bit are input to the multiplexer 710, respectively. 710 sequentially outputs the first parity bit and the second parity bit. Then, a total of 48 code symbols are output in the above operation, the output code symbols are input to the puncturer 720, and the puncturer 720 receives the 48 symbols to output only 40 symbols. For this purpose, the 0th, 7th, 12th, 19th, 24th, 31st, 36th, and 43rd symbols are punctured and output. The puncturing position of the symbol is only an example for better understanding in the present invention and may be changed to optimize the performance of the convolutional code.

As described above, the present invention relates to a method of transmitting data by using a user's unique number in a mobile communication system, wherein when a user receives data for another user, the user cannot analyze the signal. By using the user-specific tail bits as well as the unique CRC, the size of the CRC bits can be minimized, thereby optimizing the performance of the encoder.

Claims (1)

An apparatus for generating control data using a user's unique number in a mobile communication system, A user that receives two signals of control information bits and user information 1 configured as part of the user identification number, and generates and outputs a bit string consisting of the control information bits and the user unique cyclic redundancy check bits generated from the user identification number. A unique circular redundancy check bit generator, A user-tailed tail bit generator for outputting a bit string obtained by adding the user information 2 consisting of the remainder not used in the configuration of the user information 1 among the user-specific numbers to the bit string received from the user-specific cyclic redundancy check bit generator; And a coder for encoding and outputting a bit string received from the user specific tail bit generator.