KR100752925B1 - Method of Generating Pseudo Noise Sequence - Google Patents

Abstract

The present invention relates to a method of generating a pseudo noise (PN) sequence delayed by a specific value in a CDMA wireless modem. The method of generating a pseudo noise (PN) sequence according to the present invention includes a register seed of pseudo noises which are delayed at regular intervals. Storing the values in advance in memory, and selecting a seed value in the memory having a sequence less than the delay value given a desired delay value; And inserting the selected seed value into a register of the pseudonoise sequence generator, and sequentially driving the pseudonoise sequence generator as much as the delay difference between the delay value and the sequence of the selected seed value in the memory.

The present invention can generate a PN sequence having a desired delay with a relatively small amount of operation by storing the seed value of the PN sequence register in advance in a small memory and using the required value without any hardware logic.

PN Sequence Generator, Seed Value, Mask, Delay

Description

Method of Generating Pseudo Noise Sequence

1 is a structural diagram showing a conventional general PN sequence generator.

2 is an IMT-2000 forward PN sequence generator.

3 is a block diagram showing a form in which seed values are stored in a memory according to the present invention;

The present invention relates to a method for generating a pseudo noise (PN) sequence delayed by a specific value in a CDMA wireless modem.

In general, the period of a PN sequence in a CDMA system is very long, reaching tens of thousands of chips.

1 is a structural diagram showing a conventional general PN sequence generator.

의 다항식을 갖는 경우이고, PN 시퀀스의 레지스터는 쉬프트(shift) 레지스터이다.The PN sequence generator shown in FIG.

In the case of having a polynomial of, the register of the PN sequence is a shift register.

The initial value of the PN sequence register is given by Equation 1, and then the PN sequence x (n) is generated while the register values are shifted by Equation 2.

If the period of the PN sequence register is 38400 chips, the sequence value exists from x (0) to x (38399).

In the case of the PN sequence generator shown in FIG. 1, a method of generating a sequence will be described below.

First, the shift registers of the PN sequence generator are 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 in the left-to-right direction by Equation (1) above. , 0,0,1 bits are stored.

Since '1' at address 0 of the register is shifted to the right, the first sequence value is x (0) = 1, and at address 0, '0' of address 1 is shifted to the right and output of x (1) = 0. This comes out.

The PN sequences x (0) to x (17) are output as they are set to the initial value of Equation 1, and x (18) to x (38399) can be represented by the operation of Equation 2 above. .

After the bit information of register 0 is output during the initial shift, the bits from address 17 to address 1 of the register are shifted to the right by one space.

That is, '0' in the original address 1 is shifted to 0, and '0' in the original 2 address is shifted to the empty 1, and '0' at 17 in the MSB is 16. Is shifted to                         

Then, register 17 is emptied. Here, '0' of register 0 and '0' of register 7 perform Exclusive OR operation (hereinafter referred to as 'XOR'). Inserted at address 17.

The value inserted into the 17th address is the x (18) value, which is the 19th value of the PN sequence.

In the same way, the PN sequence generator can be driven to find all values up to x (38399).

The 3GPP standard, which is an asynchronous IMT-2000 standard, uses PN sequences having different delay values for each base station. Therefore, in order to access the base station, the terminal should be able to generate a PN sequence having a specific delay value used by the base station.

In order to generate such a PN sequence with a desired delay, there is a conventional method of covering a mask.

In FIG. 1, if the normal PN sequence without delay is x (n), the PN sequence which is delayed by 131072 (for example) by x (n) using a mask specific to registers is x (n + 131072). .

In the case of the delay, the mask used (the XOR operation is performed using the mask written in registers 4, 6, and 15) is a mask corresponding to the delay 131072. To generate another delay, a mask of another type is used. .

However, obtaining a mask requires a separate hardware logic for mask generation or a large amount of clock is required to process it in a microprocessor.

In addition, when the mask is stored in memory beforehand, a large size memory is required.

Accordingly, an object of the present invention is to provide a pseudo-noise sequence generation method capable of generating a PN sequence in a delayed state as desired without requiring additional hardware logic or large memory. .

Pseudo-noise sequence generation method according to the present invention for achieving the above object,

Storing register seed values of pseudonoises which are delayed at regular intervals in advance, and selecting seed values of the sequence having a delay value less than the delay value given a desired delay value;

And inserting the selected seed value into a register of the pseudonoise sequence generator, and sequentially driving the pseudonoise sequence generator as much as a delay difference between the delay value and the sequence of the selected seed value in the memory. .

Also, in the present invention, the seed value means a bit string that enters the PN sequence generator register for outputting a specific sequence.

The seed value selected from the memory may be a seed value corresponding to an integer obtained by dividing a delay value of the base station by a delay interval value of sequence seed values stored in memory.

The present invention uses a method of putting a specific seed value in a PN sequence generator register in order to be able to generate a PN sequence with a specific delay.

Here, the seed value refers to a bit string that enters a PN sequence generator register for outputting a specific sequence, which is 18 bits in the 18th order generator.

In other words, with several seed values stored in memory in advance, the seed value that is closest to the desired delay is retrieved, taken out of memory and put into the register of the PN sequence generator, and then the PN code generator is directly turned on for the remaining residues. Use the method to get the corresponding seed value.

Hereinafter, a method of generating a pseudo noise sequence according to the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a 3GPP forward PN sequence generator, which is an asynchronous IMT-2000 standard, and FIG. 3 is a block diagram showing a seed value stored in a memory according to the present invention.

Referring to FIG. 2, the period of the 3rd Generation Partnership Project (3GPP) forward PN sequence, which is an asynchronous IMT-2000 standard, is 38400 chips, in which p (0) to p (38399) exist, and one frame is divided into 15 slots. One slot consists of 2560 chips. The forward PN sequence generator consists of a modulo sum of two PN sequence generators, the x and y generators.

As shown in FIG. 2, the register of the 3GPP forward PN sequence generator is 18th order, and the initial values of the two x and y generators are as follows.

Looking at the operation of the PN sequence generator, in the case of the x generator, the result of the XOR operation (10) of x (0) and x (7) enters x (17) and the values from x (0) to x (17) It is shifted right by bit.

And in the case of the y generator, the result of XOR operation (20) of y (0) and y (5) and y (7) and y (10) goes into y (17) and y (0) to y (17). Are shifted right by one bit.

Then bit 1 in x (0) and bit 1 in y (0) perform XOR operation 30, resulting in p (0), which is the LSB of the PN sequence.

If the above-described forward PN sequence generation process is expressed by an equation, it may be expressed as Equation 4.

의 결과가 바로 p(0), p(1), p(2), ..., p(38399)의 값들이 된다. In Equation 4 i is i = 0, 1, ..., 38399, since the period of the PN sequence is 38400,

Results in p (0), p (1), p (2), ..., p (38399).

에서 'n' 값이 시퀀스의 지연 값으로 주어진다. As shown in Equation 4, the output of the forward PN sequence

Is given as the delay value of the sequence.

의 'n'값에 따라서 x 시퀀스를 'n'만큼 지연된 상태에서 생성시킬 수 있어야 한다.Therefore, the PN sequence used by the base station to which the terminal wants to access

According to the value of 'n', x sequence should be able to be created with 'n' delayed.

In the current 3GPP (3rd Generation Partnership Project) standard, the range of n values that can be used by each base station is 0 to 24575, which is 24576 in total.

Therefore, it is impossible to use the method of storing all the seed values of the x sequence register corresponding to the delay 'n' in memory in advance because it requires too much memory.

In addition, since the period of the PN sequence is 38400, it is virtually impossible to store them all in memory in advance.

In other words, when a terminal accesses a base station, it should generate a forward PN sequence used by the base station. At this time, the terminal should generate a sequence having a 'n' delay with a minimum amount of storage memory and computation.

The existing masking method is to create a mask of a register corresponding to the delay 'n' and simply write it to the register so that the output sequence has a delay 'n'.

Meanwhile, the present invention proposes a method of storing and using a seed value corresponding to a delay 'n' in a memory of a terminal.                     

3 is a block diagram illustrating a form in which seed values are stored in a memory according to the present invention.

As mentioned earlier, the 'n' case is 24576, so it is virtually impossible to store it in memory for all 'n' cases.

However, for example, as shown in FIG. 3, when storing the seed value corresponding to 'n' at 2560 intervals, only ceil (24576/2560) = 10 seed values need to be stored.

That is, the seed values of the PN generator registers corresponding to p (0), p (2560), p (5120), p (7680), ..., p (23040) are stored in the memory.

Therefore, if the desired delay is given, the seed value nearest to it can be retrieved from memory, put into the register of the PN sequence generator, and the desired seed value can be obtained by running the PN sequence generator by the difference corresponding to the difference.

For example, to generate a PN sequence delayed 6000 times, the seed value to be selected is floor (6000/2560) = 2, that is, the second seed value, and the additional number of clocks that the PN sequence generator needs to run is 6000-. 2560 * 2 = 880 clocks.

Therefore, by storing only 10 seed values in memory, in the worst case, a clock of 2560 can be generated to generate a PN sequence with the desired delay.

Since the 3GPP forward PN sequence generator uses 18th-order registers, 10 * 18 bits = 180 bits of memory are required to store 10 seed values, which can require significant gate counts in hardware.

In general, however, a wireless modem is composed of hardware logic driven by a chip rate clock and a microprocessor such as a DSP that controls the chip. Therefore, when a wireless modem is stored in the memory of the DSP, only about 23 bytes are required.

Therefore, by using only a small amount of DSP memory (23 bytes) without any hardware logic, it is possible to generate a PN sequence having a desired delay with a relatively small amount of computation (2560 clocks).

As described above, the present invention relates to a method for generating a PN sequence delayed by a specific value, and the seed close to the delay required after storing the seed value of the PN sequence generator register in memory so that the PN sequence can be generated from an arbitrary delay. By reading the value and driving it into the register of the PN sequence generator, a PN sequence can be generated with a relatively simple operation amount without any hardware logic.

As described above, according to the method of generating a pseudo-noise sequence according to the present invention, since the seed value of the PN sequence generator register is stored in a small memory in advance without using any hardware logic, and the necessary value is called and used, a desired delay with a relatively small calculation amount is used. It is possible to generate a PN sequence with.

Claims (3)

After storing the register seed values, which are each delayed into a plurality of delay values having a predetermined delay interval, in advance in the memory, and if a desired delay value is given, one of the register seed values delayed below the given delay value is recalled. Selecting in the memory; and inserting the selected register seed value into a register of a pseudo noise sequence generator, and sequentially driving the pseudo noise sequence generator by a delay difference between the given delay value and the delay value of the selected register seed value in the memory. Pseudo noise sequence generation method comprising the step of. The method of claim 1, And the register seed value represents a bit string that enters a register of the pseudo noise sequence generator for outputting a specific sequence. The method of claim 1, And a register seed value selected from the memory is a register seed value delayed by a delay value corresponding to an integer obtained by dividing the given delay value by the delay interval value.

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