KR20010054453A - apparatus for despreading gold code sequence, using double delay mask - Google Patents

Abstract

PURPOSE: A gold code sequence despreading device using a dual delay mask is provided to miniaturize the gold code sequence despreading device, in a communication system using a gold code sequence having a non-linear cycle in scrambling or spreading. CONSTITUTION: Delay mask tables(32,33) are arranged. A code sequence generator generates a delayed code sequence having a non-linear cycle, using a dual structure of delay masks by the delay mask tables(32,33). A mixer(37) correlates the code sequence generated in the code sequence generator with a received signal. A detector(39) compares a result accumulating correlation values by the mixer(37) for a predetermined time with a preset threshold, to decide a code phase. And an index calculator(40) calculates an index of a mask value for shifting the code phase and outputs a corresponding delay mask to the delay mask tables(32,33), if a correct code phase is not decided in the detector(39).

Description

Device for despreading gold code sequence, using double delay mask

The present invention relates to mobile communications, and more particularly, to a despreading apparatus of a gold code sequence having a nonlinear period in a CDMA communication system.

Conventional CDMA communication systems use PN codes with linear periods. For this reason, the PN code generator used for the PN despreader implements the PN descrambling code for synchronization by using a delay mask / delay mask of a simple structure.

FIG. 1 is a block diagram illustrating a structure of a despreading device in a receiver according to the prior art, in which FIG. 1A illustrates a delay mask and FIG. 1B illustrates a delay state.

When a delay mask is used as shown in FIG. 1A, a code sequence generator for generating a PN descrambling code using only one MLSG 1 and a mask 3 is configured. Furthermore, a PN descrambling code is generated using one MLSG 1, a delay mask table 2 and a mask 3 implementing PN delay.

After that, the mixer 4, the accumulator 5, and the detector 6 which detects the final synchronization by comparing the output of the accumulator 5 with a given threshold value are implemented.

In the case of using the delay state as shown in FIG. 1B, the gold code is used as the PN descrambling code. The basic structure is similar to that of FIG. 1A, but many codes are used compared to the configuration of FIG. 1A.

In addition, when the gold code sequence has a nonlinear period, synchronization is performed using the delay state table 10 rather than the delay mask table.

In FIG. 1B, a conventional apparatus uses two or more MLSGs 11 and 12 to generate a code sequence for descrambling. If a gold code sequence has a linear period, the configuration shown in FIG. 1A may be used as a despreading device as it is regardless of the type of gold code.

Next, FIG. 2 illustrates timings of a Tx code sequence and an Rx code sequence used in a conventional despreading apparatus, and illustrates timings of a transmission Tx code sequence and a reception Rx code sequence.

As shown in FIG. 2A, since the Tx code sequence has N periods (where N periods may be either chip units, slot units, or frame units), code generation is repeatedly performed after a predetermined period. .

Therefore, the despreading apparatus of FIG. 1A selects one random delay mask, correlates the received signal and the PN code sequence generated through the mask 3, and increases the correlation unit if the correlation value is smaller than a predetermined threshold. increment) (7) to use the next delay mask. This operation is repeated to obtain initial synchronization.

In the case where the gold code sequence is a nonlinear period K as shown in FIG. 2B, the transmitting PN code sequence does not repeat the linear period N, but generates a code sequence for K hours and then forcibly initializes the initial code sequence. Create Therefore, one delay mask cannot generate the required code sequence. This basically means that the delay mask always maintains a constant delay from the current value regardless of the state values of the code sequence generators 11, 12, 13 (in FIG. 1B, the code sequence generator consists of MLSG1 and MLSG2 and an exclusive OR gate). This is because it generates a code sequence that has.

Forcing initialization, like non-linear gold code sequences, requires changing the delay mask at initialization. In this case, without using a delay mask as shown in FIG. 1B, a necessary code sequence is generated by directly allocating a necessary delay state to the code sequence generators 11, 12, and 13 during each despreading period, and then despread the received signal.

As described above, when implementing a gold code sequence despreading apparatus having a nonlinear period, a delay state table is used. However, this is a problem that if the number of gold code sequences used in the system and the delay period is large, the memory used to store the state for generating the code sequence is excessively required.

SUMMARY OF THE INVENTION An object of the present invention has been devised in view of the above, and provides a smaller gold code sequence despreading apparatus using a double delay mask in a communication system using a gold code sequence having a nonlinear period for scrambling or spreading.

A feature of the gold code sequence despreading apparatus using a double delay mask according to the present invention for achieving the above object is a non-linear using a plurality of delay mask tables and a delay structure of a dual structure by the plurality of delay mask tables. A code sequence generator for generating a delayed code sequence having a period; a mixer for correlating the code sequence generated by the code sequence generator with a received signal; A detector for comparing the values to determine the code phase, and if the correct code phase is not determined by the detector, calculating a index of a mask value for shifting the code phase and outputting a corresponding delay mask to the delay mask table. It is composed of an index calculation unit.

Preferably, the index calculator comprises: a modulo counter for counting a period of a code sequence generated by the code sequence generator into a module; a first timing value for adding an output of the modulo counter and a reference timing value of a known reception signal; An adder, a modular operating module by a predetermined index from the output of the first adder, a subtractor which subtracts the output of the modular counter from the output of the modular, and an output of the subtracter by a predetermined modulo index value And a second adder for outputting a table index value of the delay mask table.

1 is a block diagram showing the configuration of a despreading device in a receiver according to the prior art.

2 is a diagram showing timing of a Tx code sequence and an Rx code sequence used in a conventional despreading apparatus.

3 is a block diagram showing the configuration of a gold code sequence despreading apparatus in a receiver according to the present invention;

Figure 4 is a block diagram showing the internal structure of the index calculation unit in the gold code sequence despreading apparatus of the present invention.

FIG. 5 is a diagram showing timing settings of a Tx code sequence and an Rx code sequence used in the gold code sequence despreading apparatus of the present invention. FIG.

6 is a view for explaining the order of storage of the mask value in the gold code sequence despreading apparatus of the present invention.

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

30: MLSG1 31: MLSG2

32: first delay mask table 33: second delay mask table

34: first mask 35: second mask

36: Exclusive-OR gate (XOR) 37: Mixer

38: accumulator 39: detector

40: index calculator

Hereinafter, a preferred embodiment of a gold code sequence despreading apparatus using a double delay mask according to the present invention will be described with reference to the accompanying drawings.

The device configuration of the present invention is shown in FIGS. 3 and 4.

3 is a block diagram showing the configuration of a gold code sequence despreading apparatus in a receiver according to the present invention.

Referring to FIG. 3, in the present invention, a code sequence generator for generating a gold code sequence is exclusively ORed with two MLSGs 30 and 31 and two masks 34 and 35 connected to each MLSG 30 and 31. A gate (XOR) 36 is formed.

The gold code sequence generated at this time is used to correlate the received signal in the mixer 37 and the accumulator 38, and the detector 39 determines the correct code phase by using the output of the accumulator 38.

However, if the correct code phase is not found, an index calculator 40 for shifting the code phase and two delay mask tables 32 and 33 for outputting a delay mask according to the code phase shifting are provided. Used.

Referring to the operation according to the configuration of FIG. 3, first, the output of the gold code sequence generator, that is, the output of the exclusive OR gate 36 and the received signal are multiplied in the mixer 37, and the result is accumulated in the accumulator 38. To accumulate in.

The accumulator 38 outputs an accumulated value according to an accumulation interval T _S , and then the detector 39 samples a value obtained by sampling the output value of the accumulator 38 and a given threshold value. Compare and determine motivation.

At this time, if the synchronization fails, one of the outputs of the detection unit 39 is input to the index calculation unit 40 to calculate the index of the next mask value, the index calculation unit 40 is the two delay mask table 32, 33, the appropriate mask value is output. An internal configuration of the index calculator 40 for this purpose is shown in FIG. 4.

4 is a block diagram showing the internal structure of the index calculator in the gold code sequence despreading apparatus of the present invention.

Referring to FIG. 4, a modulo counter 41 counts the period of the gold code sequence to the module, and the counting start of the modulo counter 41 follows the reference timing of the receiver. The first adder 42 adds the output of the modulo counter and the reference timing of the receiver, provides it to the modular 45, and then takes the modulo operation with the index K. In this case, the reference timing may be determined by a timing value or an arbitrary value of a reception signal that the receiver already knows.

For example, in the case of a multi-stage searcher, since the gold code sequence despreader knows the slot boundary or the frame boundary at the last stage, the reference timing value is used to find the correct slot boundary or frame boundary. Determine the delay mask value for the branch.

However, when the timing information of the received signal is unknown, the reference timing value is set to an arbitrary value and increases by a predetermined value according to the signal of the detector 39.

The output of the modular 45 is again calculated by the output signal of the modulo counter 41 and the subtractor 43, and the result of the calculation is again added by the modulo index value and the second adder 44 to finally obtain the necessary delay mask table. The table index value of (32, 33) is calculated.

Next, a more detailed operation example will be described with reference to FIG. 5.

5 is a diagram illustrating timing settings of a Tx code sequence and an Rx code sequence used in the gold code sequence despreading apparatus of the present invention.

In the case of FIG. 5A, the timing of the transmitting end is delayed by one unit (wherein one unit can be either chip, slot, or frame) compared to the timing of the receiving end.

As shown in FIG. 5A, the transmission signal appears to be delayed by "K-1" units compared to the received signal in the first interval, but is delayed by "-1" units in the second interval. Therefore, in order to generate accurate code sequence, it is necessary to use "K-1" unit delay mask in the first time interval and "-1" unit delay mask in the second time interval to Kth time interval.

In this case, the reference timing value is "K-1", and the table index value is "2K-1" at the first time interval, and the table index value from the second time interval to the Kth time interval is "K-2". "Becomes.

In the case of FIG. 5B, the relative delay is 2 units, and the table index value at the first and second time intervals is "2K-2", and the remaining time intervals are "K-2".

Table index values are determined according to relative delay values, and delay mask tables 32 and 33 for this purpose are configured as shown in FIG.

FIG. 6 is a diagram illustrating a storage order of mask values in the gold code sequence despreading apparatus of the present invention.

So far, the description of the present invention is a case where the searcher searching for the synchronization timing at the receiving side already knows the timing boundary of the received signal, and inputs it to the increasing unit 46 configured inside the index calculation unit 40. The enable signal becomes low so that the same reference timing value is always used.

On the other hand, when the searcher does not know the timing boundary of the received signal, the input reference signal value is fixed to an arbitrary value, and the reference timing value actually used according to the signal of the detector 39 is set by a predetermined value whenever the K period is changed. Is increased.

Separately, for systems using multiple gold code sequences with nonlinear periods, a delay state table is used for initial timing settings.

For example, if the number of code sequences used is 64, the gold code sequence generator has a state length of 18, and the required delay state is 15, then the total number of memory required is "64 x 18 x 15 x 2 (= number of code sequences). × state length × delay state × number of MLSGs). However, when using the double delay mask structure as in the present invention, only " 18 × [2 × (15-1)] × 2 (= state length × [2 × (delay state-1)] × MLSG count) " need.

As a result, the size of the code sequence generator used in the despreading apparatus can be reduced to about " 2 / (total number of PN codes used) ".

According to the gold code sequence despreading apparatus using the double delay mask of the present invention described above, when the number and the delay period of the gold code sequence used in the system is large, the memory used to store the state for generating the code sequence is Much less is needed than before.

As a result, the despreading apparatus of the present invention in which a double delay mask is used can be made smaller in a communication system using a gold code sequence having a nonlinear period for scrambling or spreading.

Claims (2)

A plurality of delay mask tables, A code sequence generator for generating a delayed code sequence having a nonlinear period by using a delay mask having a dual structure by the plurality of delay mask tables; A mixer for correlating a code sequence generated at the code sequence generator with a received signal; A detector configured to determine a code phase by comparing a result of accumulating a correlation value by the mixer for a predetermined period with a predetermined threshold value; And a double delay mask configured to calculate an index of a mask value for shifting a code phase and output a corresponding delay mask to the delay mask table when the correct code phase is not determined by the detector. Gold code sequence despreading device using. The method of claim 1, wherein the index calculator, A modulo counter for counting the period of the code sequence generated by the code sequence generator into a module; A first adder for adding the output of the modulo counter and a reference timing value of a known reception signal; A modular operating module with a predetermined index from an output of the first adder, A subtractor for subtracting the output of the modular counter from the output of the modular; And a second adder configured to output a table index value of the delay mask table by adding an output of the subtractor to a predetermined modulo index value.