KR100250435B1 - Pn code generator - Google Patents

Abstract

PURPOSE: A PN(Pseudo Noise) code outputter is provided to include necessary functions to one PN code generator. Therefore, a controller structure and a PN code generator structure can be simplified. CONSTITUTION: A PN(Pseudo Noise) code late block(25) receives PN codes outputted from one PN code generator(23), and outputs each different late code. A walsh block(24) makes a controller(29) select channels through a multiplex(26) in order that walsh codes can be changed according to channel kinds while performing a cross-arm adding. A PN code multiplex(26) receives the each different late code generated from the PN code late block(25), and outputs many PN codes(28) for being inputted to many correlators(21) according to an offset assigned by the controller(29).

Description

Pseudo Noise Code Output

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pseudo-noise (pn) code output, and in particular to n connected to n correlators when using a parallel search scheme to reduce code synchronization acquisition time in a Code Division Multiple Access (CDMA) system. It relates to a pn code output that can be configured as one pseudo noise code generator.

In general, in the conventional code division multiple access (CDMA) system, in the case of the parallel search method, an individual pseudo noise code generator is connected to each of the n correlators.

A parallel search method in a conventional code division multiple access system will be described with reference to FIG. 1.

FIG. 1 is a block diagram of a correlator and pseudonoise code generator block in a parallel search method, and a block for calculating a correlation value by multiplying a received data 11 with a PN code 12 and a Walsh code 13 is shown in FIG. It is also. Correlators 14 for calculating correlation values of I data and Q data have n I and Q, respectively, and Walsh code 13 for cross-arm adding 15 considering QPSK demodulation. A Walsh block 16 for multiplying and a pn code generator 17 for generating a pseudo noise code are composed of n, and a control unit 18 for controlling them. The detailed structure 19 of the pseudo-noise code generator has a 32-stage register structure that receives a seed value from the control unit 18 and generates the pn code 12. As shown in FIG. 1, each pn code generator 17 receives a seed value from the controller 18, generates a pn code 12 for a given integration section, and then generates a pn code generator ( 17), the logic to assign the seed (seed) is required, so the logic of the same function is overlapped.

In addition, the clock input from the controller 18 to the pn code generator 17 in order to operate the correlator 14 by dividing the correlator 14 into on-time and late-time in order to increase the accuracy of synchronization acquisition. To be input to each pn code generator 17 by controlling in units of 1/2 chip, the structure of the controller is complicated.

As described above, since the integral section to be calculated by each correlator 14 is different in the parallel search method, a pseudo noise code generator capable of assigning an arbitrary integral section to each correlator 14 is required. Is controlled by the seed value of the pn code generator 17. In particular, in the case of the parallel search method that requires operating in several modes to reduce the error probability in the code acquisition, the operation of the pn code generator 17 is different for each mode. The structure is very complicated.

Accordingly, an object of the present invention is to provide a pseudo-noise code outputter that can accommodate the operation of each mode to solve the above-mentioned disadvantages, and can simplify the structure by sharing the shareable part.

In order to achieve the above object, the present invention provides a pseudo noise code (pn) code generator, a pseudo noise code delay block for receiving a pseudo noise code output from the pseudo noise code generator and outputting different delay codes; Receive a Walsh block for the controller to select through the multiplex so that the Walsh code can be changed according to the channel type when cross-arming, and different delay codes generated from the pseudo-noise code delay block, and are allocated by the controller. And a pseudo-noise code multiplex for outputting a plurality of pseudo-noise codes to be input to a plurality of correlators according to the offset.

1 is a block diagram of a correlator and a pn code generator of a conventional code division multiple access system.

2 is a block diagram of a correlator and pn code generator of a code division multiple access system in accordance with the present invention.

<Description of the symbols for the main parts of the drawings>

11: data 12: pn code

13: Walsh Code 14 and 21: Correlator

17: pn code generator 18 and 29: control unit

23: pn code generation block 16 and 24: Walsh block

25: pn code delay block 26: multiplex

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

2 is a block diagram of a correlator and a pseudo noise code generator according to the present invention, in which a pn code generation block 23 and a Walsh block 24 are included in a pseudo noise code generator. The Walsh block 24 controls the control unit 29 through the multiplex so that the Walsh code is changed according to the type of channel at the time of cross-arm adding. To choose. When the pseudo noise code output from the 32-stage register is input to the pn code delay block 25, the pn code generator 23 generates the code 27 from the original pseudo noise code up to 63 chips later in phase. The delay code generated is input to the pseudo noise code multiplex block 26. The pseudo noise code multiplex block 26 outputs n pseudo noise codes 28 to be input to each correlator 21 according to an offset allocated by the control unit 29.

In this case, the reason for generating the code that is 63 chips behind is based on the round trip delay (RTD) obtained in the initial synchronous acquisition mode. Therefore, in the verification mode, in the worst case, since the pseudo noise offset between the correlator 21 and the correlator 21 is 63 chips, the code that is out of 63 chip phase is generated. In addition, the 64 pseudo noise codes 27 output from the pn delay block 25 are converted into on-time codes or late-time codes according to the pseudo noise clock control of the controller 29. Since the structure is free to select, it is possible to control in which mode the correlator 21 is operated.

As described above, since the present invention includes all the necessary functions in one pseudo noise code generator, the structure of the controller can be easily configured, and since the structure can be used by sharing the overlapping functions, the entire pseudo noise code generator The structure also has the effect of being simplified.

Claims (1)

One pseudo-noise (pn) code generator, A pseudo noise code delay block for receiving a pseudo noise code output from the pseudo noise code generator and outputting different delay codes; A Walsh block that can be selected by the control unit through the multiplex so that the Walsh code can be changed according to the channel type when cross-arming, And a pseudo noise code multiplex for receiving different delay codes generated in the pseudo noise code delay block and outputting a plurality of pseudo noise codes to be input to a plurality of correlators according to offsets allocated by the controller. Pseudo-noise code writer.

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