KR19990024476A - Stereoscopic Image Diffusion Device Using Lookup Table - Google Patents

Abstract

The present invention discloses an acoustic image diffusion device using a lookup table. The apparatus inputs an output signal of a log scaling means and a log scaling means for generating a first row and a second column address by log scaling a plurality of left and right input signals classified into a plurality of frequency bands, If the address is larger than the first column address, the first row and the first column address are output as the first signal and the second signal, respectively. If the address is smaller, the first row and the first column address are the second signal and the first signal. Comparing and classifying means for generating a third signal, and if the second signal is smaller than n, outputting the first signal and the second signal to the second row and second column addresses; If the two signals are greater than or equal to n and the first signal and the second signal are different, the two's complement value of the first signal and the second signal is output to the second row and the second column address, and the second signal is greater than n. Greater than or equal to 1st signal and 2nd scene Is the same, the address mapping circuit for outputting m to the second row address and the two's complement value of the second signal to the second column address, and (m + 1) × n, It consists of a plurality of ROMs that output the stored parameter values corresponding to the column addresses. Therefore, the product cost can be reduced by reducing the ROM size.

Description

Stereoscopic Image Diffusion Device Using Lookup Table

The present invention relates to a stereoscopic apparatus, and more particularly to a stereoscopic image diffusion apparatus that can reduce the size of the parameter ROM for storing the parameter.

A conventional stereoscopic image diffusing device is disclosed in Korean Patent Application No. 96-11244.

In general, the stereo sound signals include a left channel input signal and a right channel input signal. The sum signal is obtained by adding the input signals of both channels, while the difference signal is obtained by subtracting the input signal of one channel from the input signal of one channel.

The conventional stereoscopic image spreading method disclosed in Korean Patent Application No. 96-11244 is extended stereo by multiplying the stereo signals of both input channels L and R by the parameters α and β stored in the lookup table, respectively. To get an image. That is, it can be represented by the following formula.

L _out = αL + βR

R _out = βL + αR

In the above formula, the address of the ROM including the parameters α and β becomes the level of both channels L and R. In the case where the representation of both channels (L, R) is 16 bits, if all representable channels (L, R) are obtained, the number of filter banks implemented in the lookup table is 2 ¹⁶ × 2 ^16. In terms of the granulation of L, R as N, in the conventional apparatus, the parameters (α, β) for all (L, R) pairs are stored in ROM so that a total of 2 2 B ⅹ N ⅹ N word size ROM was required. However, the parameters (α, β) that should actually be stored in the ROM are B ｘ N ｘ (N + 1) word due to the symmetry of the parameters used for the output signals L _out and R _out of both channels. do.

An object of the present invention is to provide a stereoscopic sound image diffusion device using a lookup table that can reduce the size of the ROM by reducing the parameters repeatedly stored in the parameter ROM.

The stereoscopic image spreading apparatus using the look-up table of the present invention for achieving the above object includes log scaling means for generating a first row and a second column address by log scaling a plurality of left and right input signals, and the log scaling. Inputting an output signal of the means and outputting the first row and first column addresses as first and second signals, respectively, when the first row address is greater than the first column address; Comparison and sorting means for outputting row and first column addresses as the second signal and the first signal, respectively, and in the same case, for generating a third signal; and if the second signal is smaller than n, Outputs a second signal to a second row and a second column address; and if the second signal is greater than or equal to n and the first signal and the second signal are different, the first signal and the second signal Outputs a complement of 2 of the call to the second row and the second column address, and if the second signal is greater than or equal to n and the first signal and the second signal are the same, then m is the second row address. An address mapping circuit for outputting and outputting the two's complement value of the second signal to the second column address, and a parameter value having a size of (m + 1) ｘ n and stored in correspondence with the second row and column address. And a plurality of ROMs for outputting them.

1 is a block diagram of a stereoscopic image diffusing device using a conventional lookup table.

2A and 2B show the conventional parameter ROM and the modified parameter ROM of the present invention, respectively.

3 is a block diagram of an addressing circuit of a parameter ROM of the present invention.

4 is a detailed block diagram of the comparison and classification circuit shown in FIG.

5A and 5B are detailed block diagrams of the address mapping circuit shown in FIG.

FIG. 6 is a detailed logic circuit diagram of the logic circuit blocks shown in FIG.

Hereinafter, with reference to the accompanying drawings, a stereoscopic image diffusing apparatus using a conventional lookup table will be described before describing the stereoscopic image diffusing apparatus using the lockup table of the present invention.

Fig. 1 is a block diagram of a stereoscopic sound image spreading apparatus using a conventional lookup table, and is composed of logarithmic scalers 10 and 12 and a parameter ROM 100.

The log scaler 10 generates a row (or column) address signal by log scaling the left channel input signals. The log scaler 12 generates a column (or row) address signal by converting right channel input signals to a log scale. The parameter ROM 100 outputs the parameters α and β stored in the cell selected by the log scalers 10 and 12.

The parameter values output in this way are multiplied by the stereo signals L and R of both channels, respectively, and added as represented in the above equation, thereby generating output signals L _out and R _out of both channels. In Fig. 1, the multiplier and the adder behind the parameter ROM are not shown.

However, looking at the parameter values stored in the conventional parameter ROM, the parameter values are the same with respect to the diagonal. Thus, the present invention reduces the ROM size by newly storing the values stored in the two addresses once using this same identity, and newly configures the addressing circuit for the changed ROM.

2A and 2B show the conventional parameter ROMs and the modified parameter ROMs of the present invention, respectively, showing that the 8 × 8 size parameter ROM is changed to the 9ｘ4 size parameter ROM.

2A and 2B show the addresses of the cells of the parameter ROM, and the parameter values stored in the addresses of the parts symmetrical with the parameter values stored in the addresses of the parts indicated by the dotted lines. For example, the parameter value stored in 10 and the parameter value stored in 01 are the same, and the parameter value stored in 70 and the parameter value stored in 07 are the same. That is, when the row address is represented by i and the column address is represented by j, the parameter value stored in the address ij and the parameter value stored in the address ji are the same. In addition, parameter values stored at diagonal addresses 00, 11, 22, 33, 44, 55, 66, and 77 exist only once and must be stored.

FIG. 2B shows the configuration of the parameter ROM of the present invention. The parameter values stored in the address located diagonally in FIG. 2A are stored in the address 01 in the address 76 and the address 75 in the address 02. ) The value of address (03) at the position of address (03) the value of address (65) at the position of address (12) the value of address (64) at the position of address (13) The value of the address 54 at the position of is constructed by storing the parameter value corresponding to the address 44, 55, 66, 77 at the position of the address 80, 81, 82, 83, respectively. The parameter ROMs shown in FIG. 2B should be provided in order to store three low, medium, and high frequency band-specific parameters, respectively. If the frequency band is further subdivided, the parameter ROM should be provided as many as the divided frequency band.

As described above, since the parameter ROM is changed, the addressing of the address indicated by a dotted line in FIG. 2B should be different from that of the related art.

Fig. 3 is a block diagram of the addressing circuit of the parameter ROM of the present invention, which is composed of log scalers 10 and 12, a comparison and classification circuit 20, an address mapping circuit 30, and a parameter ROM 200.

The log scaler 10 generates a row (or column) address signal by log scaling the left channel input signals. The log scaler 12 generates a column (or row) address signal by log scaling the right channel input signals. The comparison and classification circuit 20 compares the row address with the column address and connects the one with the greatest intensity to the row and the other with the column. That is, when the address i is compared and the address i is larger than the address j, the address i is used as the row address and the address j is used as the column address. When the address j is larger than the address i, the address j is a row address, and the address i is a column address. Thus, signal B is a row address and signal S is a column address. In the same case, a signal EQ indicating the same is generated. The address mapping circuit 30 outputs the signals B and S as row and column addresses if the signal S is smaller than four, that is, if the column address is smaller than four. If the signal S is greater than or equal to 4, that is, corresponding to the conventional addresses 76, 75, 74, 65, 64, and 54, the two's complement value of the signals B and S is performed. Output to the column address. Finally, if signal S is greater than or equal to 4 and signals B and S are the same, i.e. conventional addresses 44, 55, 66, 77, then the row address is 8 and the column address is signal 2's complement value of (S) is output.

4 is a detailed block diagram of the comparison and classification circuit shown in FIG. 3, which is composed of a comparator 22 and multiplexers 24 and 26. FIG.

The row and column addresses (i, j) corresponding to the left and right channels passing through the log scaler are compared. When the row address (i) is larger than the column address (j), the multiplexer 24 signals the row address (i). B) and the multiplexer 22 outputs the column address j as a signal S. When the row address i is smaller than the column address j, the multiplexer 24 outputs the column address j as a signal B and the multiplexer 22 compares the row and column addresses i and j. The row address i is output as the signal S. If the row and column addresses are the same, the signal EQ is output.

5A and 5B are detailed block diagrams of the address mapping circuit shown in FIG. 3, and are composed of an AND gate 31 and logic circuit blocks 32, 33, 34, 35, and 36. As shown in FIG.

The address mapping method of the address mapping circuit 30 shown in Figs. 5A and 5 can be divided into the following three cases.

In the case of S 4, the row and column addresses use the signals B and S as they are.

In the case of S? 4 and B? S, the row and column addresses are used by taking two's complement of the signals B and S.

In the case of S? 4 and B = S, the row address is 8 and the column address is used by taking two's complement of the signal S.

The above-described case can be represented by the following logical expression.

r [3] = EQ × S [2]

r [2] = B [2] × S [2] '+ B [2]' × EQ '× S [2]

r [1] = B [1] × S [2] '+ B [1]' × EQ '× S [2]

r [0] = B [0] × S [2] '+ B [0]' × EQ '× S [2]

C [1] = S [1] × S [2] '+ S [1]' × EQ '× S [2]

C [0] = S [0] × S [2] '+ S [0]' × EQ '× S [2]

FIG. 6 is a detailed logic circuit diagram of the logic circuit blocks shown in FIG. 5, which is composed of AND gates 40 and 41 and an OR gate 42. The circuit shown in Fig. 6 is constructed in accordance with the above logical formula.

AND gate 40 transmits signals B [2], B [1], or B [0] in response to the inverted signal of signal S [2] and inverted signal of signal EQ. In response, the signal S [1], or S [0] is transmitted. The AND gate 41 transmits the signals B [2], B [2], or B [0] in response to the signal S [2] and the inverted signal EQ, and the signal EQ and The signal S [1], or S [0] is transmitted in response to the inverted signal S [0]. The OR gate 42 combines the output signals of the AND gates 40 and 41 so that row and column addresses r [0], r [1], r [0], c [1], or c [0] Outputs

4, 5a, b, and 6 show an embodiment of newly constructing a parameter ROM as shown in FIGS. 2a, b and mapping an address according to this changed ROM configuration, without departing from the spirit and spirit of the invention. You can change as much as you like.

A stereoscopic image diffusing device using a conventional lookup table requires a 2 × 3 × 8 × 8 = 384 word ROM, but an acoustic image diffusing device using a lookup table of the present invention has a size of 2 × 3 × 9 × 4 = 216. Ad Rom is enough.

The acoustic image diffusion device using the lookup table of the present invention can reduce the size of the ROM, thereby reducing the cost of the product.

Claims (6)

Log scaling means for log scaling left and right channel input signals to generate first row and second column addresses; When the output signal of the log scaling means is input and the first row address is larger than the first column address, the first row and first column addresses are output as first and second signals, respectively. Comparison and sorting means for outputting the first row and first column addresses as the second signal and the first signal, respectively, and generating a third signal if they are identical; When the second signal is smaller than n, the first signal and the second signal are output to the second row and the second column address, and the second signal is greater than or equal to the n and the first signal and the second signal. Is different, the two's complement value of the first signal and the second signal is output to the second row and the second column address, and the second signal is greater than or equal to the n and the first signal and the second signal. Is the same, an address mapping circuit for outputting m to the second row address and outputting two's complement value of the second signal to the second column address; And and a plurality of ROMs having a size of (m + 1) × n and outputting parameter values stored corresponding to the second row and column addresses. The ROM of claim 1, wherein the (m + 1) × n ROM stores parameter values symmetrically stored in an m × m size ROM accessed by the first row and column address and not repeating the second values. An acoustic image diffusion device using a look-up table, configured to be accessed by row and column addresses. The method of claim 1, wherein the first comparison and sorting means Comparison means for generating a signal indicating whether the first row address and the first column address are larger, smaller or equal to each other; Outputting the first row address as the first signal when the first row address is larger than the first column address, and outputting the first column address as the first signal when the comparison means First means for selecting; And Outputting the first column address as the second signal when the first row address is larger than the first column address and comparing the first row address as the second signal when the comparison means A sound image diffusion device using a look-up table, characterized in that it comprises a second selection means for. 4. An acoustic image spreading apparatus using a look-up table according to claim 1 or 3, wherein said first selecting means is a multiplexer. 4. An acoustic image spreading apparatus using a look-up table according to claim 1 or 3, wherein said third selecting means is a multiplexer. The method of claim 1 or 3, wherein the address mapping circuit When m is 8 and n is 4, a first signal for outputting the fourth bit signal of the second row address by logically multiplying the same signal output from the comparing means with the third bit signal of the second signal Logical multiplication means; Three second logical products for outputting third, second, and first bit signals of said first signal as third, second, and first bit signals of said second row address in response to an inverted third bit signal of said second signal; field; Outputting the third, second, and first bit signals of the first signal as the third, second, and first bit signals of the second row address in response to the inverted signal of the signal representing the same and the third bit signal of the second signal; Three third logical means for; Two fourth logical multiplication means for outputting second and first bit signals of the second signal as second and first bit signals of the second column address in response to the inverted signal of the signal indicating the same; And Two signals for outputting the second and first bit signals of the second signal as the second and first bit signals of the second column address in response to the signal indicating the same and the inverted signal of the first bit signal of the second signal. A sound image diffusion device using a look-up table, comprising a fifth logical product.