KR970003148Y1 - An apparatus for regenerating super stereo sound - Google Patents

Abstract

None.

Description

Super Stereo Sound Player

1 is a circuit diagram of a super stereo sound reproduction apparatus according to the present invention.

* Explanation of symbols for main parts of the drawings

12: first phase inverting amplifier 14: second phase inverting amplifier

16: first channel sound reproduction unit 18: second channel sound reproduction unit

20: vocal sound output circuit

The present invention relates to a device for reproducing stereo sound, and more particularly, to a super stereo sound reproducing apparatus in which stereo sound is reproduced by removing crosstalk caused by a mixed component of a right channel sound and a channel sound.

Typically, a stereo sound reproduction system reproduces sound recorded on a recording medium such as a music soft, that is, an audio tape or a compact disc, an LP record, and outputs stereo sound. However, the general stereo sound reproducing system could not emphasize the stereo sound field by simply reproducing and outputting the sound recorded in stereo to the music software as described above. This is because the recording channel of a typical music software has some left channel sounds (hereinafter referred to as "SL") and some right channel sounds (hereinafter referred to as SR), and on the contrary, some SLs are added to SR.

In general, the stereo system reproduces the SL and the SR recorded in the music software as it is, and outputs the SL speaker to reproduce the SL as an audible sound. Similarly, even an SR speaker that reproduces SR as an audible sound reproduces and outputs a slight SL sound to generate cross talk.

The crosstalk component as described above causes the stereo listening feeling to be narrowed, and the listener is unable to hear more accurate stereo sound.

Accordingly, an object of the present invention is to provide a super stereo sound reproducing apparatus that reproduces stereo sound more accurately by eliminating cross talk caused by the reproduction of SL and SR.

Another object of the present invention is to provide a speech processing circuit that emphasizes stereo listening by removing sound of adjacent channels mixed in channels having mutually exclusive sounds.

The construction of the present invention for achieving the above object, phase-inverted the SL (SL = L + △ R) signal and the SR (R + △ L) signal mixed with the sound of neighboring channels, respectively -SL {-SL =- Phase inverting amplifying means for outputting an SL =-(L + ΔR)} signal and an SR {-SR = -R + ΔL)} signal, and-(R + outputted from the phase inverting means to the input L + ΔR signal; A first channel sound reproducing means for adding only the L signal from which the crosstalk signal component is canceled by adding the? L) signal, and a-(L + ΔR) signal outputted from the phase inverting means to the input R + ΔL signal. Second channel sound reproducing means for adding only the R signal from which the crosstalk signal component is canceled, and a vocal sound output means for reproducing and outputting mono vocal sound by differentially amplifying the L + ΔR signal and the R + ΔL signal. It is characterized by the configuration.

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

1 is a circuit diagram of a super stereo sound reproducing apparatus according to the present invention, in which a phase inverted SL (SL = L + ΔR) signal in which neighboring channels are mixed is -SL (-SL =-(L + ΔR)). Phase inverting the first phase inverting amplifier 12 for outputting the signal and the SL (R + ΔL) signal in which the sound of the neighboring channels is mixed, and outputting the -SL {-SL = (R + ΔL)} signal. Outputs only the L signal from which the crosstalk signal component is canceled by adding the two-phase inverting amplifier 14 and the-(R + ΔL) signal output from the first phase inverting amplifier 12 to the input L + ΔR signal. R of which the crosstalk signal component is canceled by adding the first channel sound reproducing unit 16 and the-(L + ΔR) signal output from the second phase inverting amplifier 14 to the input R + ΔL signal. A second channel sound reproducing unit 18 for outputting only a signal, and a vocal yarn for reproducing and outputting mono vocal sound by differentially amplifying the L + ΔR and R + ΔL signals. It consists of a de-output circuit 20.

In the above configuration, the first phase inverting amplifier 12 is composed of the resistors R1 and R2 and the inverting amplifier LA1 and inverts the SL signal inputted to a predetermined amplification gain value X, and outputs the second. The phase inverting amplifier 14 is composed of resistors R3 and R4 and inverting amplifier RA1 and inverts the input SR signal to a predetermined amplification gain value X and outputs it.

The first channel sound reproducing unit 16 inputs a resistance (LR1) for inputting the SL signal and a-(R + ΔL) signal output from the inverting amplifier LA1 of the first phase inverting amplifier 12. It consists of a resistor LR2 and a non-inverting amplifier LA2 that adds and amplifies a signal input through the two resistors and outputs an L signal from which the ΔL signal is removed.

The second channel sound reproducing unit 18 inputs a resistor RR1 for inputting the SR signal and a-(R + ΔL) signal output from the inverting amplifier RA1 of the second phase inverting amplifier 14. And a non-inverting amplifier RA2 that adds and amplifies the signal input through the two resistors and outputs an R signal from which the ΔL signal is removed.

In addition, the vocal sound output circuit 20 amplifies the difference between the inverting amplifier CA1 for inputting the SR signal and inverting and outputting the amplified difference between the output of the inverting amplifier CA1 and the input SL signal and outputting mono sound. It consists of a differential amplifier (CA2).

Hereinafter, with reference to the accompanying drawings, an example of the operation of the present invention will be described in detail.

Now, when signals in which neighboring channels are mixed are reproduced from the above-described recording medium and input to the circuit of FIG. 1, the circuit of FIG. 1 removes the mixed sound of neighboring channels to eliminate cross talk. Same as

SR (signal source of left channel of stereo) mixed with signal component △ R of stereo sound R (right channel) and SR (right of stereo) mixed with signal component △ L of L (left channel) of stereo sound When the signal source of the channel) is supplied to the circuit of FIG. 1, the SL signal is input to the inverting amplifier LA1 in the first phase inverting amplifier 12 through the resistors R1 and LR1 and at the same time the non-inverting amplifier. It is input to the non-inverting terminal (+) of LA2. The SR signal is input to the inverting amplifier RA1 in the second phase inverting amplifier 14 through the resistors R3 and RR1 and to the noninverting terminal (+) of the noninverting amplifier RA2.

By the above operation, the inverting amplifier LA1 in the first phase inverting amplifier 12 inverts the input SL signal and outputs the -SL signal whose phase is inverted through the resistor RR2. At this time, the amplification constant of the inverting amplifier LA1 is determined by the resistors R1 and R2.

The inverted amplifier RA1 in the second phase inverting amplifier 14 inverts the input signal to the amplification gain value X by the resistors R3 and R4 and inverts the input signal to the -SR signal whose phase is inverted. Is output through the resistor LR2.

In this case, the SR and SL signals are L + ΔR and R + ΔL as described above, and each of the -SL and -SR signals inverted and amplified as described above is-(L + ΔR) and-(R + ΔL), respectively. It can be seen that the signal of.

Therefore, when the signal of the connection node of the resistors (LR1, LR2) is PL1, it can be seen that the following equation 1.

X1 in the above formula 1 is a coefficient set by the following formula 2.

In Equation 2, GR is the gain of the inverting amplifier RA1 in the second phase inverting amplifier 14.

Therefore, it can be seen from Equation 1 that when the X1 value is adjusted such that ΔR = Δ1R, the R components mixed in the SL cancel each other out. The above X1 value can be easily adjusted by adjusting the resistance LR2. Therefore, if the resistor LR2 is properly adjusted, only the sound of the pure left channel is input to the non-inverting terminal (+) of the non-inverting amplifier LA2 and amplified and output.

Similarly, if the signal of the connection node of the resistors (RR1, RR2) is PL2, it can be seen that the following equation (3).

In Equation 3, X2 is a coefficient set in the same manner as in Equation 2, which becomes as in Equation 4 below.

In Equation 4, GL is the gain of the inverting amplifier LA1 in the first phase inverting amplifier 12.

Therefore, it can be seen from Equation 3 that the L component mixed in the SR cancels each other when the X2 value is adjusted such that ΔL = Δ2L. The value of X2 can be easily adjusted by adjusting the resistance RR2. Therefore, it can be easily adjusted by adjusting the resistance RR2. Therefore, when the resistor RR2 is adjusted, the non-inverting terminal (+) of the non-inverting amplifier RA2 receives and amplifies and outputs a pure right channel recording.

The signals LO and RO output from the first and second channel amplifying units 16 and 18 by the above operation are respectively the sound of the pure left channel and the sound of the right channel from which the sound of the neighboring channel is removed. As a result, the crosstalk shape generated by the mixed sound of neighboring channels is eliminated.

On the other hand, the vocal sound output circuit 20 for inputting the SL signal and the SR signal separates only the mono audio signal combined with the left channel and the right channel, and outputs them to the center speaker (not shown). Looking at its operation process is as follows.

The SL signal is inverted and amplified by the inverting amplifier CA1 having the resistors R7 and R8 and input to the inverting terminal (-) of the differential amplifier CA2. At this time, the SL signals of the resistors R5 and R6 are input to the non-inverting terminal (+) of the differential amplifier CA2. Therefore, the differential amplifier CA2 amplifies the difference between the signals input to the non-inverting terminal (+) and the inverting terminal (-), respectively, and outputs a mono audio signal such as a vocal.

As described above, the present invention processes the channel sound of the stereo mixed with the sound of the neighboring channel, respectively, and cancels the sound of the neighboring channel, thereby outputting only the pure magnetic channel sound, thereby accurately separating the signals. We can extend stereo listening feeling and can widen sound field

Claims (3)

In a super stereo sound reproduction apparatus for reproducing stereo sound, a phase inversion of an SL = (L + ΔR) signal and an SR (R + ΔL) signal in which neighboring channel sounds are mixed, respectively, is applied to -SL {SL =-(L + DELTA R)} signal, phase inverting amplifying means for outputting the -SR {-SR =-(R + ΔL)} signal, and-(R + ΔL outputted from the phase inverting means to the input L + ΔR signal The first channel sound reproducing means for outputting only the R signal from which the crosstalk signal component is canceled by adding the? Signal, and the-(L + ΔR) signal output from the phase shifting means to the input R + ΔL signal. And a second channel sound reproducing means for outputting only an R signal from which the crosstalk signal component is canceled. 2. The apparatus of claim 1, wherein the phase inversion amplifying means inverts the SL (SL = L + ΔR) signal in which the sound of neighboring channels is mixed to output a -SL (-SL =-(L + ΔR)) signal. Phase inversion of the first phase inversion amplifier 12 and the SR (R + ΔL) signal in which the sound of the neighboring channels is mixed, and a second phase inversion of the output of a -SR (-SR =-(R + ΔL)) signal. Super stereo sound reproduction apparatus, characterized in that consisting of an amplifier (14). The super stereo sound reproducing apparatus according to claim 1, further comprising vocal sound output means for differentially amplifying the L + ΔR signal and the R + ΔL signal to reproduce and output mono vocal sound.