KR0180299B1 - Method for getting the number of bit allocation of audio data - Google Patents

Abstract

The present invention discloses a method for obtaining the number of bit allocations of audio data. The method includes a first judging step of determining whether a subband has a limit of 26 or less, a second judging step of judging whether a subband coefficient of 11 or less if the subband limit is 26 or less, and if the subband coefficient is 11 A first value setting step of setting the number of bit allocations to 4 if less, a third judging step of judging whether or not the subband coefficient is 23 or less, and if the third judging step is satisfied, the bit allocation A second value setting step of setting the number of times to 3, a third value setting step of setting the number of bit allocations to 2 if the third judgment step is not satisfied, and if the result of the first judgment step is not satisfied And a fourth determination step of determining whether the subband coefficient is 2 or less, and if satisfied, proceeds to the first value setting step, and if not, proceeds to the second value setting step. Therefore, in the method of obtaining the number of bit allocations of the present invention, the number of bit allocations can be obtained by using the similarity between the tables.

Description

How to get the number of bit allocations for audio data

1 is a flowchart for explaining a method for obtaining the number of bit allocations of audio data of the present invention.

2 is a block diagram of a circuit for obtaining the number of bit allocations of audio data of the present invention.

The present invention relates to a moving picture extraction group, and more particularly to a method for obtaining the number of bit allocations of audio data of a bit stream in a moving picture extraction group.

The audio bit stream of the video extraction group MPEG1 includes a header (synchronization and status information), an error check (information for error detection), audio data (information about audio samples), and ancillary data. Consists of

The audio data is composed of bit allocation, scale factor selection information, scale factor, and samples.

Therefore, in order to decode the audio bitstream of the picture extraction group, information about how many bits are allocated to each subband (hereinafter, expressed as nbal) is required.

In case of layer 1, nbal is fixed to 4 bits. In case of layer 2, how many subband limits are allocated from the header to obtain nbal (hereinafter, referred to as sblimit). Obtain According to this sblimit, four tables are given, and nbal can be obtained from this table.

It is an object of the present invention to provide a method of obtaining the number of bit allocations of audio data that can be easily obtained using the similarity of the tables, rather than the number of bit allocations from a given table.

The method for obtaining the number of bit allocations of the audio data of the present invention for achieving the above object comprises a first determination step of determining whether the subband limit is 26 or less, and if the subband limit is 26 or less, the subband coefficient is 11; A second determination step of determining whether or not the subband coefficient is 11 or less, and a first value setting step of setting the number of bit allocations to 4 if the subband coefficient is 11 or less, and determining whether it is 23 or less, if the subband coefficient is not 11 or less. A third value setting step, if the third decision step is satisfied, a second value setting step of setting the number of bit allocations to three, and a second value setting step of setting the number of bit allocations to two if the third judgment step is not satisfied. If the result of the three-value setting step and the first determination step is not satisfied, it is determined whether the subband coefficient is 2 or less, and if it is satisfied, the process proceeds to the first value setting step. Proceed to setting values It is characterized in that it includes a fourth determining step.

Referring to the accompanying drawings, a method of obtaining the number of bit allocations of the audio data of the present invention will be described.

In the case of the layer 1 bit allocation table, the number of bit allocations (nbal) for the subband limits (sblimit) is the same as 4, so each subband limit need not be considered in the circuit configuration.

However, in the case of the layer 2 bit allocation table, the number of bit allocations (nbal) for each subband limit is different, so each subband limit must be considered when configuring the circuit.

The table below shows the Layer 2 bit allocation table.

1) Table for sblimit-27 (tale0)

2) Table when sblimit = 30 (table1)

3) Table when sblimit = 8 (table2)

4) Table when sblimit = 12 (table3)

In the table above, except for the unallocated bits, nbal is 4 from subband coefficient 0 to subband coefficient 10 and nbal from subband coefficient 11 to subband coefficient 22 when sblimit = 27, 30. Is 3, and the subband coefficient 23 to the subband coefficient 31 are two.

When sblimit = 8 and 12, nbal is 4 from subband coefficient 0 to subband coefficient 1, and when sblimit = 8, nbal is 3 from subband coefficient 2 to subband coefficient 7 and subband coefficient 2 Nbal equals 3 to the negative subband coefficient 11, and nbal equals 0 to the subband coefficients 12 to 31 when sblimit = 8 and 12.

Using this similarity, we can find nbal by two tables instead of each nbal according to the sblimit value.

1 is a flowchart for explaining a method for obtaining the number of bit allocations of audio data of the present invention.

First, it is determined whether the sblimit is 26 or less (step 100). In other words, the tables for sblimit 27 and 30 and for sblimit 8 and 12 have similarities. If the sblimit is 26 or less, it is determined whether the subband coefficient is 11 or less (step 110). If it is determined in step 110 that it is 11 or less, nbal is set to 4 (step 120). Then, if it is determined in step 110 that it is not 11 or less, it is determined whether it is 23 or less (step 130). If it is determined in step 130 that it is determined that the value is 23 or less, nbal is set to 3 (step 140). Otherwise, nbal is 2 (step 150). If the determination result of step 100 is not satisfied, it is determined whether the subband coefficient is smaller than 2 (step 160). If the determination result of step 160 is satisfied, the process proceeds to step 120, and if not satisfied, the process proceeds to step 140.

In the flowchart of the present invention, no consideration is given to the case where nbal becomes zero. This is because if nbal becomes 0, it has no effect on the next stage of signal processing.

2 is a block diagram of a circuit for calculating the number of bit allocations of audio data of the present invention, which is a logic circuit for generating 3-bit nbal corresponding to a 5-bit subband coefficient input in response to a 5-bit sblimit signal. Consists of.

In other words, as shown in FIG. 2, the method shown in FIG. 1 can be implemented using a logic circuit.

Therefore, in the method of obtaining the number of bit allocations of the present invention, the number of bit allocations can be obtained by using the similarity between the tables.

Claims (1)

The first judgment step of determining whether the subband limit is 26 or less. A second determination step of determining whether the subband coefficient is 11 or less if the subband limit is 26 or less; A first value setting step of setting the number of bit allocations to four if the subband coefficient is 11 or less; A third determination step of determining whether the subband coefficient is 23 or less, if it is not 11 or less; A second value setting step of setting the number of bit allocations to three if the third judging step is satisfied; A third value setting step of setting the number of bit allocations to two if the third determination step is not satisfied; And if the result of the first judging step is not satisfied, determines whether the subband coefficient is 2 or less, and if so, proceeds to the first value setting step, and if not, proceeds to the second value setting step. And a fourth judging step to determine the number of bit allocations of the audio data.