KR20020041528A - traffic channel control apparatus encoding multi data in WLL - Google Patents

Abstract

PURPOSE: A traffic channel control apparatus for encoding multiplexed data in a WLL system is provided to increase both transfer speed and channel capacity by controlling traffic channels. CONSTITUTION: A traffic channel control apparatus consists of a data multiplexer(100), a data comparator(110), a data encoder(120), a processor(130), a convolution encoder(140), a block interleaver(150), a symbol repetition unit(160), a PN code generator(170), a digital gain unit(180), and a combiner(190). The data multiplexer(100) multiplexes data. The data comparator(110) outputs the multiplexed data to the data encoder(120). The data encoder(120) encodes the multiplexed data so that the data can use a PN code and a Walsh code in common. The processor(130) receives the data from the data comparator(110) and controls the data encoder(120). The convolution encoder(140) receives the data from the data encoder(120) and sets its code rate and convolution code to 1/2 and 9 respectively. The block interleaver(150) receives the output of the convolution encoder(140) and prevents a burst error. The symbol repetition unit(160) adjusts the output of the block interleaver(150) to a modulated symbol rate. The PN code generator(170) spreads the band of a signal. The digital gain unit(180) gives a digital gain to the band-spread signal. The combiner(190) combines traffic channels.

Description

Traffic channel control apparatus encoding multi data in WLL}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a traffic channel control apparatus for encoding multiple data in a wireless local loop (WLL), and more particularly, to a traffic channel control apparatus capable of increasing a transmission capacity and a channel capacity.

A block interleaver for preventing a burst error by receiving a convolutional encoder 10 having a code rate of 1/2 and a constraint length of 9 for data error correction, and an output of the encoder 10. a block interleaver 20, a symbol repeater 30 for matching the output of the block interleaver 20 to a modulation symbol rate, a channel PN (Perceived Noise) code generator 40 for spreading the spectrum, and The digital gain unit 50 provides a digital gain of the spread signal and a combiner 60 for combining the respective traffic channels. The operation thereof will be described as follows.

If there is data to be sent to the traffic channel, the data is sent to the convolutional encoder 10. At this time, the data input to the convolutional encoder 10 is converted into a convolutional encoder 10 having a code rate r = 1/2 and a constraint length k = 9. Is encoded and sent to the block interceptor 20.

In order to prevent the burst error by receiving the output of the convolutional encoder 10, the block interleaver 20 sends the interleaver again to the symbol repeater 30, and in the symbol repeater 30, 64kbps or In order to convert at a rate of 128 kbps, the input data is repeatedly set at the symbol rate.

To spread the symbol data from the symbol repeater 30 to the signal from the PN code generator 40 and multiply it to the digital gain unit 50, the digital gain unit 50 obtains a digital gain to the spread signal To be sent to the combiner (60).

On the other hand, when sending data in the forward channel to increase the transmission rate to increase the digital gain value, increasing the digital gain value has a problem that the number of communication subscribers is reduced because the capacity of the wireless channel is reduced to reduce the number of transmission channels.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object thereof is to increase the transmission capacity and the channel capacity by controlling the traffic channel.

1 is a block diagram of a conventional traffic channel control apparatus.

2 is a block diagram of a traffic channel control apparatus of the present invention.

3 is a flowchart of data applied to the present invention.

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

10, 140: convolutional encoder 20, 150: block interleaver

30, 160: symbol repeater 40, 170: PN code generator

50, 180: digital gain unit 60, 190: combiner

100: data multiplexer 110: data comparator

120: data encoder 130: processor

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

An embodiment of the traffic channel control apparatus of the present invention,

A data multiplexer 100 for multiplexing data;

A data comparator 110 for comparing the multiplexed data and outputting a low signal at the same time and a high signal at the same time to the processor, and outputting the multiplexed data to a data encoder;

A data encoder 120 for encoding the multiplexed data under the control of a processor such that the multiplexed data shares the Walsh code with the PN code;

A processor 130 that receives data from the data comparator 110 and controls the data encoder 120;

A convolutional encoder 140 receiving the data from the data encoder 120 and having a code rate of 1/2 and a constraint length of 9 for error correction of the data;

A block interleaver 150 for receiving an output of the convolutional encoder 140 and preventing a burst error;

A symbol repeater 160 that matches the output of the block interleaver 150 at a modulation symbol rate,

PN code generator 170 for spreading the band,

A digital gain unit 180 for giving a digital gain of the spread signal;

It is preferable to configure the combiner 190 for combining the respective traffic pack channels.

The output of the data multiplexer 100 preferably has a double rate.

The data encoder 120 preferably inverts the other data when the data are different from each other so as to be identical to the one data.

FIG. 2 is a configuration diagram of a traffic channel control apparatus of the present invention, and FIG. 3 is a flow chart of data applied to the present invention.

Data A and B of each traffic channel are input to the data multiplexer 100 to perform data multiplexing, and the output data of the multiplexing has a data rate of twice the input data and receives the output data of the multiplexer 100. The data comparator 110 compares the multiplexed data and outputs a low signal when it is the same and a high signal when it is different to the processor 130 and simultaneously outputs the multiplexed data to the data encoder 120. do.

The data encoder 120 under the control of the processor 130 inverts the B data such that different bits among the data input from the comparator 110 are the same as the A data.

Then, as shown in FIG. 3, when the inversion information bits of the B data are pasted, the double rate output from the multiplexer 100 becomes the original data rate, and the data output from the data encoder 120 corresponds to the code rate r. Coded by the convolutional encoder 140 = 1/2 and constraint length k = 9, it is sent to the block interval unit 150.

In order to prevent the burst error by receiving the output of the convolutional encoder 140, the block interleaver 150 performs over 20 ms, and then sends the interleaver 150 to the symbol repeater 160 again. In order to convert the 64kbps or 128kbps rate according to the modulation symbol rate, the input data is repeatedly set to the symbol rate.

To spread the symbol data from the symbol repeater 160, the signal is multiplied by the signal from the PN code generator 170 and sent to the digital gain unit 180, where the quadrature spreading of the forward channel is performed in two different forward directions. I-channel sequence and forward Q-channel sequence are used, and both sequences are shortened sequences using only 20ms of 2 ²³ -1 length PN sequences.

Generation of Forward I-Channel Sequence Polynomial PI (X) and Generation of Forward Q-Channel Sequence Polynomial PQ (X) is as follows.

PI (X) = X ³² + X ²² + X ² + 1

PQ (X) = X ³² + X ³¹ + X ³⁰ + X ¹⁰ + 1

The digital gain unit 180 gives a digital gain to the spread spectrum signal and sends it to the combiner 190.

Therefore, the data transmission speed can be increased and the channel capacity can be increased through the above process.

As described above, according to the present invention, since the transmission speed can be increased without increasing the digital gain value, the number of subscribers can be relatively increased without reducing the radio channel capacity.

Claims (3)

A data multiplexer for multiplexing data; A data comparator for comparing the multiplexed data to output a low signal at the same time and a high signal at the same time to the processor, and output the multiplexed data to a data encoder; A data encoder for encoding the multiplexed data under the control of a processor so that the multiplexed data shares the Walsh code with the PN code; A processor unit which receives data from the data comparison unit and controls the data encoder; A convolutional encoder unit which receives data from the data encoder and sets a code rate of 1/2 and a constraint length of 9 for error correction of data; A block interleaver for receiving an output of the convolutional encoder and preventing a burst error; A symbol repeater for matching an output of the block interleaver to a modulation symbol rate; PN code generator for spreading the band, A digital gain unit for giving a digital gain of the spread spectrum signal, Traffic channel control device comprising a combiner unit for combining the respective traffic pack channel. The apparatus of claim 1, wherein the output of the data multiplexer has a double data rate. The data encoder of claim 1, Traffic data control device, characterized in that if the data is different from the other data to invert the same as the data on one side.