KR20010046767A - PN code generating method - Google Patents

Abstract

PURPOSE: A pseudo noise code generating method is provided to selectively perform a 1 PN chip advance or retard during 1 system clock while operating a pseudo noise code generator with a system clock higher than a PN chip rate, and extend the accommodation capacity of a finger of a receiving terminal of a parallel processing and radio communication system through sharing a resource by performing a PN code tracking by using a system clock in case that a pseudo noise code generator is adopted to the receiving terminal of the radio communication system of CDMA. CONSTITUTION: A circuit for obtaining the next state of a linear sequence shift register in a normal state, a circuit for obtaining the next state of the linear sequence shift register for performing a 1 PN chip advance and a circuit for obtaining the next state of the linear sequence shift register for performing a 1 PN chip retard are all coupled. Shift registers(11-14) receives a load enable signal and a sequence enable signal and coupled to each other. Multiplexers(21-24) are connected to an input terminal of each of the shift registers(11-14) and output a single input signal among a multiple input signals according to each control signal. An encoder(31) generates a control signal to set the state of a pseudo noise code generator. One input of the multiplexer(21) connected to the input terminal of the first shift register(11) is determined with the nth value of a generation polynomial expression for the pseudo noise code generator, and another input of the multiplexer(21) is determined by a value obtained by ANDing an output signal value of the nth shift register(14) and an output signal value of the n-1th shift register(13) through an adder(15). Still another input of the multiplexer(21) is determined by an output signal of the shift register(11).

Description

PN code generating method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PN code generator, and in particular, advances one PN chip generated by a pseudo noise code generator within one clock in a wireless communication network based on a code division multiple access (CDMA) scheme (advanced). Or a method of generating a pseudo noise code suitable for delay (retard).

In a wireless communication network based on a code division multiple access (CDMA) scheme, a pseudo-noise or pseudorandom noise generator is generally provided at a receiving end or a transmitting end of a communication device. The pseudo noise code generator provided in the receiver generates a PN sequence and performs operations such as user classification, time and phase synchronization, and demodulation on the signal received from the transmitter.

The PN code generated in this pseudo noise code generator is usually generated by a linear sequence shift register (LSSR) consisting of n flip flops or shift registers. In particular, a pseudo noise code generator is used to quickly acquire a pilot signal included in a received signal by a searcher provided in a base station receiver or a terminal receiver, and furthermore, a finger included in the receiver is included in the received signal. Used to track PN code. At this time, the PN code is intentionally created by the base station or the receiver of the terminal to generate the PN code through the pseudo noise code generator to detect the PN code included in the received signal, and to perform the operation for capturing the pilot signal or finding the PN code. Retard or advance the offset of the code.

1 is a block diagram of a conventional pseudo noise code generator equipped with a linear sequence shift register. Referring to FIG. 1, the linear sequence shift register 10 shows a four-stage linear sequence shift register capable of generating a PN code of length 2 ^N-1 (in FIG. 1, N is assumed to be 2). The linear sequence shift register shown in FIG. 1 is composed of three shift registers (or storage elements) 1-3 connected in series, one shift register 4, and between the shift register 3 and the shift register 4. It consists of an adder 5 located.

In the linear sequence shift register of FIG. 1, the system clock is provided with N times the clock (CHIP x N) of the PN chip rate, and the clock enable adjusts the number of clocks applied to the linear sequence shift register of the pseudo noise code generator. Perform normal operation of the pseudo-noise code generator or PN chip retard or PN chip advance.

For example, when the pseudo noise code generator operates in a normal state, the clock enable operation is enabled by one system clock for every N system clocks. That is, N system clocks are applied to the linear sequence shift register for one PN chip time. Thus, the pseudo noise code generator shown in FIG. 1 operates N times faster than its PN chip rate when using a system clock that is N times faster than its PN chip rate.

One PN chip retard performs an operation in which the state of the linear sequence shift register is repeated for one PN chip time. That is, the clock enable is adjusted to apply 0 system clocks to the linear sequence shift register for 1 PN chip time (N system clocks).

On the other hand, the 1 PN chip advance performs an operation in which the state of the linear sequence shift register skips the state of normal operation and transitions to the next state. In other words, by adjusting the clock enable applied to the pseudo noise code generator, two system clocks are applied to the linear sequence shift register for one PN chip time (N system clocks). Therefore, in order to implement 1 PN chip advance using this scheme, a system clock twice that of 1 PN chip rate must be used.

However, in the future communication environment, the requirements for the function of the modem provided in each communication equipment such as a base station or a terminal are increasingly varied. Therefore, the configuration of the modem becomes more complicated and the number of subscribers of the wireless communication network is also increasing. Under these communication environments, there is a need for a pseudo noise code generator capable of performing 1 PN chip retard or advance within the minimum system clock possible.

SUMMARY OF THE INVENTION An object of the present invention has been made in view of the above-mentioned problems of the prior art, and in a code division multiple access wireless communication system, one PN generated by a pseudo noise code generator during one clock while using the same clock as the chip rate It is to provide a method of generating a pseudo noise code that can advance or retard the chip.

According to an aspect of the present invention for achieving the above object, the present invention provides an n-order pseudo noise code generator having a linear sequence shift register including n mux and shift registers connected in series with each other. Operation to obtain the next state of the linear sequence shift register, operation to obtain the next state of the linear sequence shift register for PN chip advance, and next to the linear sequence shift register for the PN chip retard. Inputting a signal to each mux to execute an operation for obtaining a state; Generating a control signal for changing a next state for the linear sequence shift register; Multiplexing the signals input to the respective muxes according to the control signal; and executing an operation corresponding to the multiplexed signal for one clock.

1 is a block diagram of a pseudo noise code generator given a conventional quadratic generated polynomial;

FIG. 2 is a partial block diagram of a pseudo noise code generator for obtaining the next state of a linear sequence shift register (LSSR) in normal operation with respect to the pseudo noise code generator shown in FIG.

3 is a partial block diagram of a pseudo noise code generator for obtaining the next state of a linear sequence shift register (LSSR) to perform 1 PN chip advance for a pseudo noise code generator in an embodiment of the invention.

4 is a partial block diagram of a pseudo noise code generator for obtaining the next state of a linear sequence shift register (LSSR) to perform a 1 PN chip retard for a pseudo noise code generator in an embodiment of the invention. .

Figure 5 is a block diagram of a pseudo noise code generator given a fourth-order generation polynomial according to a preferred embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

11-14: Shift register 15-17: Logic element

21-24: MUX 31: Encoder

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

In general, a pseudo noise code generator is composed of a linear OR (SOR) of a linear sequence shift register consisting of an exclusive OR gate (XOR gate) by a generation polynomial and a plurality of shift registers, as shown in FIGS.

For the purpose of explanation of the present invention, first, it is assumed that the n th generation polynomial g (X) such as Equation 1 is represented by a vector such as Equation 2 below.

In the present invention, the current state of the linear sequence shift register Suppose that the current state can be expressed in a vector form as shown in Equation 3 below.

At this time, when the pseudo noise code generator operates normally, the next state of the linear sequence shift register ( ) Is the current state of the linear sequence shift register ( ), The most significant bit of the linear sequence shift register (MSB) (r _{n, m} ), and the generation polynomial shown in Can be obtained by

Equation (4) shows an output signal of the n th shift register and the pseudo noise code generator at an input terminal of an i th shift register except the least significant shift register among the n shift registers. This means that the result value obtained by performing an AND operation on the i-1 th value of the generated polynomial given by AND and the output signal of the i-1 th shift register is input.

Also, the next state of the linear sequence shift register for executing 1 PN chip advance is the state of the linear sequence shift register that operates normally. , Which is the current state of the linear sequence shift register as shown in Equation 5 below. And n-th generation polynomials )

Equation (5) is the output signal of the nth shift register at the input of the least significant bit (Least Significant Bit: LSB) of the n shift registers in the nth order pseudo-noise code generator including the n shift registers. And a result obtained by performing an AND on the n-1 th value of the generated polynomial given to the pseudo-noise code generator and ORing the OR signal with the output signal of the n-1 th shift register. This means that it is input. In addition, when 1 <i≤n is satisfied, the result obtained by performing a logical multiplication with the output signal of the n th shift register and the n-1 th value of the generated polynomial at the input terminal of any i th shift register except the LSB shift register A first value obtained by performing an OR operation on the value of the n-1 th shift register with the output signal of the n-1 th shift register; a second value obtained by performing an AND operation on the output signal of the n th shift register and the i-2 th value of the generation polynomial; This means that a result value obtained by simultaneously ORing the third value, which is the output signal of the i-2th shift register, is input.

Further, the next state of the linear sequence shift register for one PN chip retard is as described in FIG. 4 to be described later, and the current state of the linear sequence shift register. Is displayed. That is, according to r _{i, m + 1} = r _{i, m} , an output signal of the i th shift register is fed back to the input terminal of the i th shift register, or one pseudo noise chip is used as an external enable signal applied to each shift register. PN chip) retard is performed using a method of disabling for a time.

FIG. 2 shows a partial block of a pseudo noise code generator for obtaining the next state of a linear sequence shift register (LSSR) when the pseudo noise code generator given a generation polynomial g (X) = X ⁴ + X ³ + 1 is operating normally. Show the schematic. Each component of the next state of the linear sequence shift register may be represented by Equation 6 below using Equation 4 above.

Figure 3 shows a pseudo noise code for a pseudo noise code generator with generation polynomial g (X) = X ⁴ + X ³ + 1 to obtain the next state of a linear sequence shift register (LSSR) for executing 1 PN chip advancement. Partial block diagram of the generator. The operation for obtaining the next state of the linear sequence shift register shown in FIG. 3 is the same as that described in Equation 5 and its meaning.

Each component of the next state of the linear sequence shift register may be represented by Equation 7 below using Equation 5 above.

Figure 4 shows a pseudo noise for the pseudo noise code generator with generation polynomial g (X) = X ⁴ + X ³ + 1 to obtain the next state of the linear sequence shift register (LSSR) for executing a 1 PN chip retard. Partial block diagram of the code generator. 4 shows that an output signal of each shift register 11-14 is fed back to an input terminal of each shift register 11-14. In addition, each shift register (as shown in FIG. 5 is provided externally as a pseudo noise code generator with generating polynomial g (X) = X ⁴ + X ³ + 1 to execute a 1 PN chip retard. The same effect may be obtained by disabling the enable signal applied to 11-14) for one PN chip time.

5 is a block diagram of a pseudo noise code generator given a generated polynomial g (X) = X ⁴ + X ³ + 1, which is a combination of FIGS. 2 to 4.

That is, in Fig. 5, a circuit for obtaining the next state of the linear sequence shift register in the steady state, a circuit for obtaining the next state of the linear sequence shift register for executing 1 PN chip advance, and one PN chip retard are executed. The circuits for finding the next state of the linear sequence shift register are combined. The pseudo noise code generator of the present invention is provided with a load enable signal and a sequence enable signal, respectively, and each of n shift registers 11-14 connected in series with each other and an input terminal of each shift register 11-14, respectively. N muxes 21-24 for outputting one input signal among multiple input signals according to respective control signals, and control signals for setting the state of the pseudo noise code generator in n muxes 21-24. It consists of the encoder 31 which generate | occur | produces.

Here, one input of the mux 21 connected to the input of the first shift register 11 of the n shift registers is defined as the nth value of the generation polynomial of the pseudo noise code generator, and the other input of the mux 21 is nth. The output signal of the shift register 14 and the output signal value of the n-1 th shift register 13 are determined to be logical sums through the adder 15, and another input of the mux 21 is connected to the shift register 11. Determine the output signal.

In addition, the mux 23 connected to an input terminal of an i th (2 ≦ i ≦ n, i is an integer) shift register (for example, 13) except the first shift register 11 of the n shift registers 11-14. One input of) multiplies the value of the n th shift register 14 by the output value of the i-1 th shift register 12 of the pseudo-noise code generator generated polynomial, and then returns the result of the i th shift register ( 12) is determined as a value obtained by performing a logical sum, and the other input of the mux 23 connected to the input terminal of the i th shift register 13 is an output signal of the n th shift register 14 and the n-1 th value of the generated polynomial. And a third value obtained by performing an OR operation on the first value obtained by AND and the output signal of the n th shift register 14 and the i-2 th value of the generation polynomial, and the output signal of the i-2 th shift register. The first, second, and third values are discussed as values. Jeonghamyeo sum as a result processing, i Another input of MUX 23 is connected to an input of the second shift register 13 is determined by the output signal of the i th shift register.

5 combines the sequence output by FIG. 2 to FIG. 4 into each mux 21-24, and controls the output of each mux 21-24 by the control signal applied from the encoder 31. FIG. Showing that it can.

Accordingly, the receiving end of the transmitter can selectively process a desired operation among the steady state operation of the pseudo noise code generator, the 1 PN chip advance operation, and the 1 PN chip retard operation within one clock.

According to the present invention as described above, while operating the pseudo noise code generator at a system clock higher than the PN chip rate, there is an effect that can selectively perform one PN chip advance or retard during one system clock. Therefore, when the pseudo noise code generator is applied to the receiving end of the code division multiplex wireless communication system, since the PN code tracking can be performed as the system clock, parallel processing through resource sharing and the receiving end of the wireless communication system can be performed. There is an effect of expanding the receiving capacity of the provided finger.

Claims (3)

In an nth order pseudo noise code generator with a linear sequence shift register comprising n mux and shift registers in series with each other, An operation for obtaining the next state of the linear sequence shift register in the steady state, an operation for obtaining the next state of the linear sequence shift register for PN chip advance, and the linear sequence for PN chip retard Inputting a signal to each mux to execute an operation for obtaining a next state of a shift register; Generating a control signal for changing a next state for the linear sequence shift register; Multiplexing a signal input to each mux according to the control signal; And executing an operation corresponding to the multiplexed signal during one clock. The method of claim 1, wherein the operation for obtaining the next state of the linear sequence shift register for the PN chip advance is as follows. The n-1 th shift is a result obtained by logically multiplying the output signal of the n th shift register and the n-1 th value of the generated polynomial given to the pseudo-noise code generator at an input of the first shift register among the n shift registers. A result value obtained by ORing the output signal of the register is input; When i is greater than 1 and less than or equal to n, a result obtained by performing a logical multiplication with the output signal of the nth shift register and the n-1th value of the generated polynomial at the input terminal of any i-th shift register except for the first shift register. A first value obtained by performing an OR operation on a value of the n-1 th shift register with the output signal of the n-1 th shift register; A second value obtained by performing an AND operation on the output signal of the n th shift register and the i-2 th value of the generation polynomial; and a result value obtained by simultaneously ORing the third value, which is the output signal of the i-second delay element, is input. The method of claim 1, wherein the operation for obtaining a next state of the linear sequence shift register for the PN chip retard comprises: feeding back an output signal of the i th shift register to an input terminal of the i th shift register; And disabling a pseudo noise chip (PN chip) time with an external enable signal applied to each shift register.