KR20010016793A - Pseudorandom sequence produce method in wireless communication system - Google Patents

Abstract

PURPOSE: A method for generating a pseudo random sequence in a wireless communication system, is provided to generate the pseudo random sequence using binary data generated by repeatedly multiplying an optional input integer by binary parallel data of a tuple, so as to easily implement a scrambler and a de-scrambler with a simple digital logical circuit and a register. CONSTITUTION: Initial data of a tuple is previously generated, and an optional random integer is inputted for deciding a pseudo random sequence finally generated. Whether the inputted integer is capable of generating a sequence satisfying entire period is confirmed. The first tuple multiplication is repeatedly performed by using the initial data of the tuple and a normal basis of a time origin, according to whether the greatest common measure between an entire period value and the inputted integer is a predetermined value, to calculate a conjugate group for an inputted time origin. Coefficient values are calculated in the first tuple type of a minimum polynomial in a Galois field for the inputted time origin. Mapping data in a predetermined second tuple type corresponding to each coefficient value are decided. An input value for the multiplication with the second tuple of data is calculated. A calculation value fed back according to predetermined clocks and the second tuple of data are multiplied. The second tuple of data are inputted, to generate a predetermined bit of pseudo random sequence.

Description

PseudoOROMOM SEQUENCE PRODUCE METHOD IN WIRELESS COMMUNICATION SYSTEM}

The present invention relates to a method for generating a pseudorandom sequence in a wireless communication system.

In general, in a digital wireless communication system, it is necessary to protect exposure of important data to a wireless channel that is very insecure in nature when transmitting broadband service signals such as voice signals, data signals, and video signals through a wireless channel.

In addition, it belongs to the field of cryptography or scrambling for the protection of all data transmitted / received in digital form as well as the transmission of data through a wireless channel. Pseudorandom sequence is applied for the purpose of scrambling to protect.

However, the related art has a problem that it is difficult to implement hardware of a pseudorandom sequence generator having a high cryptographic ratio.

Accordingly, the present invention has been made to solve the above problems, in implementing a pseudo-random sequence generator composed of a galloche form, by multiplying an arbitrary input integer by the binary parallel data of the repetitive tuple It is an object of the present invention to provide a method of generating a pseudorandom sequence capable of greatly increasing the encryption ratio of transmitted data by generating a pseudorandom sequence using the generated data and a computer-readable recording medium recording a program for realizing the pseudorandom sequence. .

1 is a schematic configuration diagram of a wireless communication system to which the present invention is applied.

2 is a flowchart illustrating a method for generating a pseudorandom sequence in a wireless communication system according to the present invention.

3 is an exemplary configuration diagram of a pseudorandom sequence generator implemented by applying the present invention.

Figure 4 is an exemplary configuration of the multiplier of Figure 3 implemented by applying the present invention.

5 is an exemplary configuration of the pseudorandom sequence generator of FIG. 3 to which the present invention is applied.

Explanation of symbols on the main parts of the drawings

1, 2: Pseudorandom Sequence Generator 5: Scrambler

6: descrambler

In order to achieve the above object, the present invention relates to a method for generating a pseudorandom sequence in a wireless communication system, wherein an initial data of a tuple is generated in advance, and then an arbitrary pseudorandom sequence to be finally generated is determined. A first step of receiving a random integer; After checking whether the input integer value is an integer value capable of generating a sequence satisfying the entire full period, the initial data and the original data of the tuple are determined according to whether the maximum common factor of the total period value and the input integer value is a predetermined value. A second step of performing a predetermined first tuple multiplication by using a regular basis of a coolant to calculate a conjugate group for the input source circle; Compute coefficient values in the form of the first tuple of the minimum polynomial in Galoache with respect to the input source, and map the mapping data in the form of a corresponding predetermined second tuple for each coefficient value. Determining a third step; And calculating an input value for multiplying the data of the second predetermined tuple, multiplying the calculated value fed back according to a predetermined clock and the data of the second predetermined tuple, and then the second predetermined tuple. And a fourth step of receiving the data of < RTI ID = 0.0 > and < / RTI > generating a pseudorandom sequence of predetermined bits.

The present invention also provides a first function of receiving an arbitrary random integer that determines a pseudorandom sequence to be generated after generating initial data of a tuple in advance in a wireless communication system having a processor. ; After checking whether the input integer value is an integer value capable of generating a sequence satisfying the entire full period, the initial data and the original data of the tuple are determined according to whether the maximum common factor of the total period value and the input integer value is a predetermined value. A second function of performing a predetermined predetermined tuple multiplication by using a regular basis of the coolant to calculate a conjugate group for the input source circle; Compute coefficient values in the form of the first tuple of the minimum polynomial in Galoache with respect to the input source, and map the mapping data in the form of a corresponding predetermined second tuple for each coefficient value. Determining a third function; And calculating an input value for multiplying the data of the second predetermined tuple, multiplying the calculated value fed back according to a predetermined clock and the data of the second predetermined tuple, and then the second predetermined tuple. The present invention provides a computer-readable recording medium having recorded thereon a program for realizing a fourth function of receiving data of a predetermined bit and generating a pseudo-bit sequence of a predetermined bit.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a schematic configuration diagram of a wireless communication system to which the present invention is applied, and includes pseudorandom sequence generators 1 and 2, a scrambler 5, and a descrambler 6.

The pseudorandom sequence generator 1 generates a random sequence and outputs the random sequence to the scrambler 5 to output the scrambled data through an exclusive logical sum operation between the original source 1 and the input data.

The pseudorandom sequence generator 2 generates the same random sequence as the transmitting end and delivers it to the descrambler 6 in order to extract the original data from the digital data received through the radio channel scrambled.

Primitive source 1 and primitive source 2 enter the initial input key value into the pseudorandom generators 1 and 2 of the transceiver to generate a pseudorandom sequence as the same value.

The scrambler 5 transmits the digital input data to be transmitted to the descrambler 6 at the receiving end.

The descrambler 6 extracts original data from the received data.

On the other hand, when the scrambler 5 and the descrambler 6 are actually implemented, the pseudorandom sequence generators 1 and 2, and the source 1 and the source 2 may be composed of one hardware.

2 is a flowchart illustrating a method of generating a pseudorandom sequence in a wireless communication system according to the present invention.

Referring to FIG. 2, initially, 201 initial data of 64 tuples used to perform repetitive 64 tuple binary vector multiplication is generated in advance (201).

An input value that determines a pseudorandom sequence to be generated finally, accepts a random random integer (202), and inputs a value that can generate a sequence that satisfies the complete full period of "2 ⁶⁴ -1". In operation 202, if it is not an input value capable of generating a sequence satisfying the entire period, a new input integer value is randomly generated and a random random integer is input until it is satisfied. Rerun

If it is an input value capable of generating a sequence satisfying the entire period in the step 203 of determining whether it is an input value capable of generating a sequence, it is determined whether the maximum common divisor of the entire period value and the input value is '1'. In step 204, if the greatest common divisor is not '1', the whole sequence does not have a complete period, and thus the process proceeds to step 202 of receiving a random random integer.

On the other hand, if the greatest common divisor is '1' in the process of determining whether the greatest common divisor is '1', the repetitive 64 tuples using the initial data pre-calculated in the initial data generation process 201 and the normal basis of the original source. The multiplication is performed to calculate a conjugate group for the input source circle (205).

The coefficient values are then calculated (206) in the form of 64 tuples of least polynomials in galloche GF 16 for the input source.

Thus, the calculated 64-tuple type result corresponds one-to-one correspondence with the 4-tuple type representation of the minimum polynomial of Galoache GF 16, and determines the mapping data of the corresponding 4-tuple type for each coefficient value. In operation 207, the input value of the circuit which multiplies the data of 4 tuples fed back from the linear feedback shift register can be calculated (208), and the data of 4 tuples fed back when one clock is applied is multiplied by the multiplication circuit. The whole flow is terminated by performing multiplication (209), accepting four tuples of data as an input, and outputting a pseudorandom sequence of one bit (210).

3 is an exemplary configuration diagram of a pseudorandom sequence generator using a linear feedback shift register implemented by applying the present invention, and includes registers R311 through R326, adders A311 through A325, and multipliers M311 through M325. And pseudorandom sequence generators 310.

An arbitrary initial value is set in the four-level parallel registers R311 to R326, and this value must match the scrambler of the transmitter and the descrambler of the receiver.

When a clock is applied, the operation is performed by the 4-tuple binary data β ^t fed back, the coefficients β ₁ to β ₁₆ calculated by the input source, and the 4-tuple multipliers M311 to M325. An exclusive logical sum operation is performed on the result and the 4-tuple binary data of each previous register.

The four-tuple exclusive logical sum operation result 22 is shifted to the next stage of each register and fed back to generate the next binary sequence, and at the same time, a pseudorandom sequence generator consisting of a simple logic circuit to generate one bit output sequence. Input 310.

The binary sequence of one bit is finally outputted through the configuration circuit of the pseudorandom sequence generator 310.

4 is an exemplary configuration diagram of the multiplier of FIG. 3 implemented by applying the present invention, in which the 4-tuple data generated by the previous clock is stored in the register 410, and the 4-tuple data βt fed back and the raw polynomial are previously described. It consists of logical multiplication gates A411 through A426 and exclusive logical sum gates X411 through X426 configured to multiply the calculated four four-tuple data a00 through a33.

In this case, when a clock is applied, an exclusive logical sum operation is performed on the multiplication result of the tuple data stored in the register 410 of the previous stage and stored in the register 420 of the next stage.

5 is an exemplary configuration diagram of the pseudorandom sequence generator of FIG. 3 to which the present invention is applied, and includes logical AND gates M511 to M516 and exclusive logical gates A511 to A516.

When the clock is applied, four tuple data (a ₀ to a ₃ ) equal to the value to be fed back are given to the input of the pseudorandom sequence generator, and the calculation process and the exclusive logical sum gate (OR) by the AND gates M511 to M516 are performed. Finally, a pseudorandom sequence of one bit is generated through an operation process by A511 to A516.

Although the technical idea of the present invention has been described in detail according to the above preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

As described above, the present invention generates a pseudorandom sequence using binary data generated by multiplying an arbitrary input integer with binary parallel data of an iterative tuple, thereby using a scrambler using a simple digital logic circuit and a register. The descrambler can be easily implemented in hardware.

Claims (7)

A method for generating a pseudorandom sequence in a wireless communication system, A first step of generating an initial data of a tuple in advance and receiving an arbitrary random integer which determines a pseudorandom sequence that is finally generated; After checking whether the input integer value is an integer value capable of generating a sequence satisfying the entire full period, the initial data and the original data of the tuple are determined according to whether the maximum common factor of the total period value and the input integer value is a predetermined value. A second step of performing a predetermined first tuple multiplication by using a regular basis of a coolant to calculate a conjugate group for the input source circle; Compute coefficient values in the form of the first tuple of the minimum polynomial in Galoache with respect to the input source, and map the mapping data in the form of a corresponding predetermined second tuple for each coefficient value. Determining a third step; And After calculating an input value for performing multiplication with the data of the second predetermined tuple, multiplying the calculated value fed back according to a predetermined clock and the data of the second predetermined tuple, and then Fourth step of receiving data and generating pseudo random sequence of predetermined bits Method of generating a pseudorandom sequence in a wireless communication system comprising a. The method of claim 1, The first step is, A fifth step of generating in advance initial data of the tuple; And A sixth step of receiving a random random integer which determines a pseudorandom sequence to be generated finally Method of generating a pseudorandom sequence in a wireless communication system comprising a. The method of claim 1, The second step, A fifth step of determining whether the integer value input in the first step is an integer value capable of generating a sequence satisfying a complete full period; A sixth step if the determination result in the fifth step is not an integer value capable of generating a sequence satisfying the entire period, the process proceeds to the first step; And If the determination result of the fifth step is an integer value capable of generating a sequence satisfying the entire period, the initial data and the source of the tuple are determined according to whether the maximum common divisor of the total period value and the input integer value is a predetermined value. A seventh step of calculating a conjugate group for the input source by performing an iterative predetermined first tuple multiplication using a regular basis of Method of generating a pseudorandom sequence in a wireless communication system comprising a. The method of claim 3, wherein The seventh step, An eighth step of determining whether the greatest common divisor of the total period value and the input integer value is substantially '1'; As a result of the determination in the eighth step, if the maximum common divisor is substantially '1', iteratively multiplies a predetermined first tuple multiplication by using the initial data of the tuple and the normal basis of the primitive source, and inputs the input source with respect to the input source. A ninth step of calculating the conjugate group; And If the maximum common divisor is substantially '1' as a result of the determination in the eighth step, the tenth step is passed to the first step Method of generating a pseudorandom sequence in a wireless communication system comprising a. The method of claim 1, The third step, A fifth step of calculating coefficient values in the form of 64 tuples of a minimum polynomial in Galoache for the input source; And A sixth step of determining mapping data in the form of corresponding 4-tuples for each coefficient value calculated in the fifth step; Method of generating a pseudorandom sequence in a wireless communication system comprising a. The method according to any one of claims 1 to 5, The fourth step, An eleventh step of calculating an input value for performing multiplication with four tuples of data; A twelfth step of multiplying the calculated value fed back according to the predetermined clock by four tuples of data; And The thirteenth step of receiving a 4-tuple of data and generating a pseudorandom sequence of one bit Method of generating a pseudorandom sequence in a wireless communication system comprising a. In a wireless communication system having a processor, A first function of generating an initial data of a tuple in advance and receiving an arbitrary random integer which determines a pseudorandom sequence that is finally generated; After checking whether the input integer value is an integer value capable of generating a sequence satisfying the entire full period, the initial data and the original data of the tuple are determined according to whether the maximum common factor of the total period value and the input integer value is a predetermined value. A second function of performing a predetermined predetermined tuple multiplication by using a regular basis of the coolant to calculate a conjugate group for the input source circle; Compute coefficient values in the form of the first tuple of the minimum polynomial in Galoache with respect to the input source, and map the mapping data in the form of a corresponding predetermined second tuple for each coefficient value. Determining a third function; And After calculating an input value for performing multiplication with the data of the second predetermined tuple, multiplying the calculated value fed back according to a predetermined clock and the data of the second predetermined tuple, and then A fourth function of receiving data and generating a pseudorandom sequence of predetermined bits A computer-readable recording medium having recorded thereon a program for realizing this.