KR930011742B1 - Frequency characteristics compensation system for sound signal - Google Patents

Abstract

The sound compensation method discriminates obstacles in the room and compensates the frequency operation of the sound signal according to the listening conditions. A test signal is generated after switching audio lines to silence during a test mode. A difference in level between a standard test signal and the test signal which has passed through the room is evaluated. A play back signal is generated whose frequency operation is compensated in accordance with the evaluated level difference by switching over to the sound signal play back mode and releasing the silenced sound lines.

Description

Frequency Characteristic Correction Device for Reproducing Audio Signal According to Listening Space Condition

1 is an exemplary view of a listening space.

2 is a frequency characteristic diagram according to the state of listening space.

3 is a circuit diagram according to the present invention.

4 is a detailed circuit diagram of the variable filter 13 in FIG.

5 is a flow chart according to the present invention.

6 is a correction frequency characteristic diagram of the variable filter 13 according to the present invention.

* Explanation of symbols for the main parts of the drawings

11, 12: first-second preamplifier 13: variable filter

14: mute section 15: switching section

16, 17: first to second main amplifier 18: test signal generator

19: delay 20, 21: left. Woo microphone

22, 23: first to second microphone amplifier 24, 25: first to second rectifier

26, 27: 1st-second analogue / digital converter.

The present invention relates to an audio device, and more particularly, to an apparatus and method for correcting frequency characteristics of a reproduced speech signal by detecting an obstacle in a listening space and correcting a frequency characteristic of the reproduced speech signal according to the characteristic of the listening space.

In general, the sound is greatly changed by the space or time at which the sound is reproduced. Therefore, the volume of the sound felt by the listener may be different each time the size of the reproduced place and the environment (temperature, humidity, etc.) are changed.

In addition, even in the same space, the volume or clarity of the sound that is heard when the number of listeners or the resulting noise is large decreases.

FIG. 1 is an exemplary view of a listening space, and FIG. 1a is an exemplary view when there are few obstacles, and FIG. 1b is an exemplary view when there are many obstacles.

When there are few listeners (or obstacles) 20a or 20b as shown in FIG. 1a, the sound diffused or absorbed in the listening space is reduced. Therefore, the listener 40A or 40B located at the rear can normally hear the sound generated by the speaker 30A or 30B. However, when there are many listeners (or obstacles) 20a-20i as shown in FIG. 1B, the sound scattered in the listening space increases in the middle. Therefore, the listener 40A or 40B located at the rear cannot normally hear the sound generated by the speaker 30A or 30B.

In order to solve this problem, the present patent application No. 91-1531 generates a test beep and checks to what level the test beep is dropped after passing through the listening space. However, as shown in Fig. 2, when there are no obstacles in the listening space, the frequency characteristics of the playback sound is flat for all bands as shown in (a). However, when there are obstacles in the listening space, (b) or (c) and Likewise, the reproduction sound has a problem in that the frequency characteristic (high frequency portion) is distorted.

Accordingly, an object of the present invention is to generate a predetermined test signal before reproducing the original sound, and to check the obstacles in the listening space, and then to reproduce the audio signal according to the listening room state to automatically correct the frequency distortion of the playback sound according to the obstacle state of the listening room. The present invention provides an apparatus and method for compensating for frequency characteristics.

Another object of the present invention is to correct the frequency characteristics of the reproduced speech signal according to the listening space state to automatically correct the frequency distortion of the reproduced sound by boosting the high frequency portion of the speech signal for the reproduced sound according to the obstacle state in the listening space. An apparatus and method are provided.

In order to achieve the above object, the present invention generates a predetermined test signal before reproducing the original sound, checks an obstacle in the listening space, and then boosts the high frequency portion of the sound reproduced according to the state of the obstacle. It is characterized by the correction.

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

FIG. 3 is a circuit diagram of a listening space adaptive frequency characteristic correction device according to the present invention, wherein the first and second preamplifiers 11 amplify the signals input through the left and right input terminals L-IN and R-IN. 12, a variable filter 13 for correcting the frequency characteristics of the reproduction sounds of the first and second preamplifiers 11 and 12 by a predetermined frequency characteristic control signal, and the variable filter under predetermined mute control. A muting unit 14 for muting the reproducing audio signal outputted from 13), a switching unit 15 for selectively switching the reproducing audio signal and the test signal under a predetermined switching control, and the switching unit 15 of the First and second main amplifiers 16 and 17 for second amplifying the output signal to the speakers 23 and 24, a test signal generator 18 for outputting a predetermined test signal, and generating the test signal. It is generated between the test signal outputted from the unit 18 and the test signal passed through the listening space. Amplifying a test signal received and reproduced from the delay unit 19, the left and right microphones 20 and 21, and the left and right microphones 20 and 21, which delay the test signal for a predetermined time to correct the time difference. First and second digital conversions of the first and second microphone amplifiers 22 and 23 and the analog output signals from the delay unit 19 and the first and second microphone amplifiers 22 and 23. 2 the variable filter by comparing the test signal output from the analog / digital converters 26 and 27 and the first and second analog / digital converters 26 and 27 with the reproduction test signal that has passed through the listening space. A frequency characteristic correction control signal of 13 and a mute control signal and a switching control signal of the muting unit 14 and the switching unit 15 are generated, and the frequency characteristic correction control signal, the muting unit 14 and the switching unit. A lookup for generating a mute control signal and a switching control signal of (15) and determining a frequency correction value The microcomputer 28 stores a table, and a mode switch 29 for inputting the mode control of the microcomputer 28.

The portions of the first to second preamplifiers 11 and 12 and the variable filter 13 in the above configuration correct the frequency of the signal input to the frequency characteristic correction means. The muting unit 14 becomes a muting means, the test signal generating unit 18 becomes a test signal generating means, and the switching unit 15 becomes a switching means. The portion consisting of the first-second main amplifiers 16, 17 and the speakers SP1-SP2 is an output means, and the portion of the ADC 26, the first rectifier 24, and the delay portion 19 is a test signal. A portion consisting of the ADC 27, the second rectifier 25, the first-second microphone amplifiers 22, 23, and the microphones 20, 21 is a listening space passing test signal processing means. The microcomputer 28 becomes a control means.

FIG. 4 is a specific circuit diagram of the variable filter 13 in FIG. 1, and a frequency correction value setting unit 13a for selecting a frequency correction amount for correcting the frequency characteristic by the frequency characteristic control signal of the microcomputer 10, and the frequency correction. A frequency characteristic correction unit 13b that corrects the high frequency characteristics of the reproduction sound by the correction value of the value setting unit 13a.

In the above configuration, the frequency correction value setting unit 13a includes transistors Q1 and Q2, capacitors C1-C2, and resistors R2-R3, and the frequency characteristic correction unit 13b includes an operational amplifier OP1 and a resistor. It consists of (R1).

5 is a flowchart according to the present invention.

The test signal reproducing process of generating a predetermined test signal in a voice signal mute state and then spreading and reproducing the listening space, and detecting the test signal reproduced in the listening space during the test signal reproducing process and before spreading to the listening space. And a frequency characteristic correction control signal generation process for generating a frequency characteristic correction control signal in comparison with the test signal, and a frequency characteristic correction process for correcting high frequency characteristics of the reproduced voice signal by the frequency characteristic correction control signal.

FIG. 6 is a frequency characteristic diagram of correcting frequency distortion according to a listening space of the variable filter 13 in FIG.

Based on the above configuration, the present invention will be described in detail with reference to FIGS. 3-6.

Immediately after the set is powered on, the microcomputer 28 controls the muting unit 14 in step 5a of FIG. 5 to mute the voice line. After muting the voice line in step (5a), it is checked whether the test mode is selected by checking the state of the mode switch 29 in step (5b). When the test mode is selected as a result of the checking, the process proceeds to step 5c to control the switch of the switching unit 27 to be connected to the test signal selection signal selection terminal Auto, and then proceeds to step 5d to generate the test signal. The unit 18 is controlled to output a test signal for a predetermined time.

In this case, the test signal uses white noise or pink noise. The test signal generated from the test signal generator 18 is amplified by the first and second main amplifiers 16 and 17 through the switching unit 15 and then output through the sputter SP1 and SP2, respectively. At the same time, it is delayed by the delay unit 19 and then rectified via the first rectifier 24 and converted into a digital form via the first analog / digital converter 26.

The test signal output through the speakers SP1 to SP2 is passed through the listening space and received and reproduced through the microphones 20 and 21 and amplified by the first to second microphone amplifiers 22 and 23. The amplification reproduction test signal transmitted through the listening space by the first to second microphone amplifiers 22 and 23 is rectified by the second rectifier 25 and the digital reproduction test signal of the second analog / digital conversion unit 26 and the first reproduction signal. The digital test signal input is passed through the listening space of the analog-to-digital converter 27.

After inputting the test signal and the listening space passing test signal, the microcomputer 28 proceeds to step 5f to calculate a level difference between the original test signal and the reproduction test signal passing through the listening space.

After calculating the level difference, the microcomputer 28 reads the control data corresponding to the level difference from the look-up table of the ROM to determine an appropriate frequency correction value in step 5g. In step 5h), control data is output to the control input terminals CONO and CON1 of the variable filter 13.

At this time, the microcomputer 28 outputs ＂00＂ if there is no level difference between the test signal and the reproduction test signal passing through the listening space, that is, because there is no obstacle in the space, and the level difference between the test signal and the reproduction test signal passing through the listening space is small. In case that there are some obstacles in the space, it outputs ＂01＂ and if there is a large level difference between the test signal and the reproduction test signal passing through the listening space, 즉 10 ＂is output. When the frequency correction control data is received from the microcomputer 28, the variable filter 13 determines the frequency correction value and then corrects the frequency characteristic.

The operation of correcting the frequency characteristic in the variable filter 13 will be described with reference to FIG. 4. When the state '00' is input to the two control input terminals CON0 and CON1, the test Q1-Q2 is turned off so that the operational amplifier OP1 operates as a buffer and buffers the reproduced sound output from the first and second preamplifiers 11 and 12 as shown in FIG.

In addition, when the state? 1Φ is input to the two control input terminals CON0 and CON1, the transistor Q1 is turned off and the transistor Q2 is turned on so that the resistor R1, the resistor R3, and the capacitor C2 are turned on. The reproducing sound of the first and second preamplifiers 11 and 12 is compensated for as shown in FIG. 6C, and the gain Av of the operational amplifier OP1 is expressed by Equation 1 below.

In addition, when the state '0 1' is input to the two control input terminals CON0 and CON1, the transistor Q1 is turned on and the transistor Q2 is turned off to the resistor R1, the resistor R2, and the capacitor C1. As a result, the reproduction characteristics of the first and second preamplifiers 11 and 12 are compensated for as shown in FIG. 6B, and the operational amplifier OP1 and the gain Av are represented by Equation (1).

After performing the step (5h) (5i) and proceeds to step (5i) to switch the switching of the switching unit 15 to the reproduction signal selection terminal (NOR) position, and in step (3j) to control the muting unit 14 in the voice line Cancel the mute state and exit.

On the other hand, if the test mode is not selected in step (5b) described above, proceed to step (5k) to transmit the initial control data in the set or the frequency characteristic control data previously used by the user to the variable filter (13) ( By controlling the muting unit 14 in step 5L), the muting of the voice line is canceled and finished.

As described above, the tester generates a test signal and passes the listening space, and then compares the test signal with the test signal before passing through the listening space to correct the frequency characteristics of the reproduced audio signal according to the level difference between the two signals. There is an advantage to improve the condition.

Claims (6)

An apparatus for correcting frequency characteristics of a reproduced audio signal according to a listening space state in an acoustic device, comprising: frequency characteristic correction means for correcting frequency characteristics of a reproduced audio signal by a predetermined frequency characteristic correction control signal, and for measuring a state of the listening space; A test signal generating means for generating a test signal, switching means for switching the test signal and the reproduced audio signal by a predetermined switching control signal, and outputting a test signal or a reproducing audio signal selected and output from the switching means to a listening space; A test signal reproducing processing means for receiving a test signal which has passed through a listening space after the test signal is output from the voice output means, and reproducing and processing the digital signal into a digital signal; and a test signal generated by the test signal generating means. Test signal processing means for processing a digital signal, and And a control means for comparing the digitally processed test signal and the digitally processed reproduction test signal to output a frequency specific correction control signal according to the comparison difference, and generating a switching control signal for outputting a test signal and a reproduced audio signal. Device characterized in that. 2. A reproduction apparatus according to claim 1, wherein the frequency characteristic correction means sets a frequency correction amount for setting a frequency correction amount for correcting the frequency characteristic according to the frequency characteristic correction control signal, and a correction value of the frequency correction value setting unit. Apparatus comprising a frequency characteristic correction unit for correcting the high frequency characteristics of the signal. An apparatus for correcting frequency characteristics of a reproduced voice signal according to a listening space state in an audio device, comprising: a test signal reproducing process of generating a predetermined test signal in a voice signal mute state and then spreading and reproducing the listening signal in the listening space; The process of generating a frequency characteristic correction control signal that detects a test signal spread and reproduced in the listening space and generates a frequency characteristic correction control signal compared to the test signal before spreading to the listening space, and reproduces the voice by the frequency characteristic correction control signal. And a frequency characteristic correction process for correcting the frequency characteristic of the signal. 4. The method of claim 3, wherein the frequency characteristic correction control signal generation process receives an original test signal and a reproduction test signal that has passed through the listening space, and calculates a level difference, and data corresponding to the calculated level difference. And a level data reading step of reading from a lookup table, and a correction control signal outputting step of outputting frequency correction control data corresponding to the read level data. The apparatus of claim 1, wherein the test signal processing means comprises: a delay unit 19 for delaying a predetermined time to compensate for a time difference generated between a test signal output from the test signal generating means or a test signal passing through the listening space; The first rectifier 24 rectifies the test signal delayed by the delay unit 19, and the first analog / digital converter 26 converts the test signal rectified by the first rectifier 24 into a digital signal. Device characterized in that. The test signal reproducing processing means according to claim 1, wherein the test signal reproducing processing means receives the microphones 20 and 21 for reproducing the test signal passing through the listening space, and the received reproduction test signal passing through the listening space in the microphones 20 and 21. And a second analog / digital converter (27) for converting the test signal rectified by the second rectifier (25) into a digital signal.