KR101008612B1 - Data decoding method - Google Patents

Abstract

The present invention relates to a decoding method of a communication system, and the decoding method of the present invention includes receiving a first channel having a variable data rate and a second channel transmitting a frame smaller than the first channel. The channel relates to a data decoding method that enables efficient decoding by dividing and decoding the data rate of each candidate set of the first channel.

Decoding, variable data rate channels

Description

Data decoding method

1 is a view for explaining a data decoding method when receiving a variable data rate auxiliary channel according to a conventional example

2 is a diagram for describing a data decoding method when receiving a variable data rate auxiliary channel according to another conventional example.

3 is a diagram illustrating a data decoding method when receiving a variable data rate auxiliary channel according to the present invention.

The present invention relates to a decoding method of a communication system, and also to a data decoding method that enables efficient decoding when a first channel having a variable data rate and a second channel transmitting a frame smaller than the first channel are received. It is about.

In the case of the supplemental channel of the conventional synchronous CDMA mobile communication system (IS95-0), data is transmitted in units of 20, 40 and 80 ms frames, and a data rate of one frame is used. Uses only fixed data rates (19.2k, 38.4k bps, etc.).

In the next generation CDMA system (IS95-A or higher), the development of a modem capable of transmitting and receiving data using an arbitrary data rate (flexible data rate) as well as a fixed data rate is required. have.

In addition, Variable Data Rates, which were used only in the Fundamental Channel, have also been extended in the Supplemental Channel (Variable-rate Supplemental Channel).

This Variable-rate Supplemental Channel transmits high-speed data and has four candidate sets up to 307.2kbps, so that all the given blind detection methods are provided at the receiving end. Decoding should be performed on the candidate set. For example, if a 10ms frame channel and a variable-rate supplemental channel are simultaneously being serviced, the receive decoder has a priority of 10ms frame channel to restore it. Decoding is performed. That is, even if the 20 ms frame signal is received before the 10 ms frame signal, the 10 ms frame signal is decoded preferentially. In addition, when a variable-rate supplemental channel is 20ms in order to decode a 10ms frame channel, a candidate set of all channels must complete decoding for 10ms. The 10ms frame channel is, for example, a reverse access channel.                         

Hereinafter, a decoding method in the case of receiving a variable data rate auxiliary channel according to the prior art will be described with reference to the accompanying drawings.

1 is a diagram illustrating a data decoding method when receiving a variable data rate auxiliary channel according to a conventional example.

In FIG. 1, when CH0 and CH1 are 20ms frames in which the variable data rate auxiliary channel is 20ms, and CH2 is in 10ms frame channel, the received signals received by the decoder are C1, C2, B1, A1, and C3 in time as shown in FIG. , C4, B2, A2, and C5, but the decoding order is to decode C1, C2, B1, C3, A1, C4, B2, C5, and A2 in order to prevent excessive storage of 10ms frame data.

2 is a diagram for describing a data decoding method when receiving a variable data rate auxiliary channel according to another conventional example.

In FIG. 2, CH1 is a 20 ms frame and a variable data rate auxiliary channel having a candidate set of 3 is used to describe a case where the CH2 is a 10 ms frame as an example. As described above, the 10 ms frame is decoded with priority. At the time when C5 data is received, the data of C3 and C4 should also be stored.

In other words, when the data rate of a candidate set is high in a variable-rate supplemental channel, it is impossible to decode all candidate sets for 10 ms. Therefore, in order to decode the 10ms frame signal, more than a predetermined number of 10ms frames, and 3 or more frames here, must be stored.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems of the prior art, and the present invention provides an efficient method for decoding data, and also transmits a first channel having a variable data rate and a frame smaller than the first channel. The present invention provides a data decoding method that enables efficient decoding when a second channel is received.

Further objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

According to one aspect of the data decoding method of the present invention, receiving a first channel having a variable data rate and a second channel transmitting a frame having a length shorter than a frame transmitted in the variable data rate channel; In the case of decoding the first channel and the second channel, the first channel includes assigning and decoding different channel resources for each data rate corresponding to the candidate set.

According to another aspect of the data decoding method of the present invention as described above, at least one first channel data frame over a first channel having a high variable data rate, and at least one first shorter than the first channel data frame Receiving a two-channel data frame on a second channel; and when the first channel data frame is received before the second channel data frame, the first channel data frame includes a data rate candidate set of the first channel. decoding at least one data rate of the candidate set).

Preferably, when the second channel data frame is received during decoding of the first channel data frame, the at least one data rate-specific decoding of the first channel data frame is performed continuously after decoding the second channel data frame. do.

Hereinafter, a data decoding method according to the present invention will be described with reference to the accompanying drawings.

The present invention provides a channel index called a sub-channel for assigning candidate data sets to other channel resources in a variable-rate supplemental channel. index). The channel index used here may be used logically for channel resource allocation.

In other words, the received data is not assigned to one channel, but is allocated to different channel resources for each candidate channel.

This means that when a channel resource is 32 channels in a base station modem and each channel decodes each candidate set, another channel resource is used when all 32 channel resources are not in use.

FIG. 3 is a diagram for describing a data decoding method according to the present invention, and is a view for explaining a decoding method when receiving a variable data rate auxiliary channel.

One embodiment of the data decoding method according to the present invention is that when a variable data rate auxiliary channel and a 10 ms frame channel (e.g., reverse access) are being serviced simultaneously, a 10 ms frame is assigned a fixed number of frames, here only. It only stores 2 frames and decodes the variable data rate auxiliary channel.

First, in FIG. 3, when CH1 is a variable data rate auxiliary channel having a 20 ms frame and a candidate set is 3, and CH2 is a 10 ms frame channel, each candidate set of signals B1 and B2 of CH1 may be, for example, B1_sub1. , B1_sub2, B1_sub3, and B2_sub1, B2_sub2, and B2_sub3 are divided into types having channel indexes, and assigned to different channel resources, respectively, to perform decoding separately.

That is, as shown in FIG. 3, decoding is performed in the order of C1, C2, B1_sub1, B1_sub2, C3, B1_sub3, C4, B2_sub1, B2_sub2...

That is, when receiving C3 while decoding B1 in FIG. 3, when receiving B1, each candidate set of B1 is divided into B1_sub1 and B1_sub2, and decoding is performed. After decoding C3, B1_sub3 is decoded. By decoding, the number of 10 ms frames of CH2 should be stored, and the decoding can be performed in two 10 ms frames.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

As described above, the present invention can efficiently perform data decoding, and in particular, it is possible to efficiently decode the channel having a variable data rate and a channel transmitting a shorter frame than the variable data rate channel. The effect is that the data can be decoded without adding the number of frames that need to be stored.

Claims (4)

Receiving a first channel having a variable data rate and a second channel transmitting a frame having a length shorter than a frame transmitting at the variable data rate channel; Decoding the first channel and the second channel, wherein the first channel consists of a plurality of candidate sets, each of the plurality of candidate sets corresponding to a different data rate, and each of the candidate sets And said decoding step assigned to different channel resources and decoded separately from each other. The method of claim 1, In the decoding step, And when the frame of the first channel is received before the frame of the second channel, decoding the frame of the first channel according to a data rate corresponding to each of the candidate sets of the first channel. Decoding method. Receiving at least one first channel data frame and at least one second channel data frame having a length shorter than the first channel data frame via a first channel at a high variable data rate; Decoding the first channel data frame, When the first channel data frame is received before the second channel data frame, decoding the first channel data frame for at least one data rate of a plurality of candidate sets belonging to the first channel, When the second channel data frame is received during decoding of the first channel data frame, performing decoding of the at least one data rate of the first channel data frame continuously after decoding of the second channel data frame. Data decoding method. The method of claim 3, wherein Wherein each of the plurality of candidate sets corresponds to a different data rate, and each of the candidate sets is allocated to different channel resources.

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