KR100965878B1 - Apparatus and method for compensating the characteristic of speaker automatically - Google Patents

Abstract

A speaker characteristic correction method and apparatus for automatically setting a target frequency characteristic are disclosed. The present invention is a process for measuring the impulse response characteristics of the speaker by inputting a predetermined signal, and converting the impulse response characteristics to frequency response characteristics, the low- and high-frequency roll-off region in the frequency response characteristics and Detecting a dip area of a predetermined level or more, calculating a mean level in a region excluding the detected roll-off area and a dip area of a predetermined level or more, determining a target frequency response characteristic, a target frequency response characteristic and the speaker Calculating a corrected impulse response characteristic by comparing the frequency response characteristic of?.

Description

Apparatus and method for compensating the characteristic of speaker automatically}

1A to 1C are conceptual views illustrating a conventional speaker characteristic correction method.

2 is an overall block diagram of a speaker characteristic correction apparatus according to the present invention.

3 is an overall flowchart of a speaker characteristic correction method according to the present invention.

4 is an embodiment showing a speaker frequency response characteristic.

The present invention relates to a sound field correction system, and more particularly, to a speaker characteristic correction method and apparatus for automatically setting target frequency characteristics.

Typically, when listening to audio, listeners will actually hear deteriorated sound quality due to low quality speaker characteristics or limited listening space. To this end, conventionally, an audio amplifier is equipped with a filter for correcting bad characteristics of a speaker.

1A is a schematic diagram of a conventional speaker impulse response measurement.

Referring to FIG. 1A, random noise is output through the speaker 110. Subsequently, the intrinsic impulse response h _sp of the speaker 110 is measured using the microphone 120.

Referring to FIG. 1B, the impulse response h _{eq is} corrected by comparing the target impulse response h _T (n) preset with the impulse response h _sp (n) measured by the microphone 120 as shown in Equation 1 below. (n))

[Equation 1]

h _sp (n) * h _eq (n) = h _T (n)

As a result, the audio input signal is output as a speaker signal through an equalizer 130 that yields a corrected impulse response h _eq (n).

Referring to FIG. 1C, the target impulse response h _T (n) output through the speaker 140 may be set and stored as a frequency characteristic of an ideal impulse response as shown in (a) or may be stored by the user as shown in (b). Set the size directly in the frequency band.

However, if the frequency characteristics of the target impulse response are ideally set as shown in (a) of FIG. Can be. In addition, when a dip occurs in which the level changes rapidly due to physical characteristics, a circuit may be overloaded to correct a portion that is difficult to correct. Although the frequency characteristics of the target impulse response may be set by the user in consideration of the speaker characteristics as shown in FIG. 1C (b), an appropriate target frequency characteristics of the target impulse response may also be cumbersome.

An object of the present invention is to provide a speaker characteristic correction method and apparatus for automatically setting to have an optimal impulse characteristic in accordance with the physical performance of a speaker to use the target impulse response characteristics that are the criteria for speaker characteristic correction.

In order to solve the above technical problem, the present invention provides a speaker characteristic correction method comprising: measuring an impulse response characteristic of the speaker by inputting a predetermined signal, and converting the impulse response characteristic into a frequency response characteristic;

Detecting low and high roll-off areas and dip areas of a predetermined level or more in the frequency response characteristic;

Calculating an average level in a region excluding a roll-off region detected in the process and a dip region of a predetermined level or more and determining the target frequency response characteristic;

And calculating the corrected impulse response characteristic by comparing the target frequency response characteristic with the frequency response characteristic of the speaker.

In order to solve the above other technical problem, the present invention provides a speaker characteristic correction device,

An impulse characteristic measurement unit configured to input predetermined random noise to measure an intrinsic impulse of the speaker;                         

A frequency characteristic analyzer for analyzing the frequency characteristics through the impulse response measured by the impulse characteristic measurer;

The low- and high-frequency roll-off areas and dip areas of a predetermined level or more are detected from the frequency characteristics analyzed by the frequency characteristic analyzer, and the roll-off areas and dip areas of a predetermined level or more are excluded. A target frequency response determiner which determines an average level as a target frequency response characteristic in the region;

A target impulse response calculator for converting the frequency response determined by the target frequency response determiner into an impulse response;

And an impulse equalization calculator configured to correct an impulse response of an input signal with a target impulse response calculated by the target impulse response calculator.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is an overall block diagram of a speaker characteristic correction apparatus according to the present invention.

The impulse characteristic measuring unit 210 measures the intrinsic impulse of the speaker using random noise according to the conventional method.

The frequency characteristic analyzer 220 changes the impulse response h _sp (n) measured by the impulse characteristic measurer 210 into a frequency response through FFT (Fast Fourier Transformation) and analyzes the frequency characteristic.

The target frequency response determiner 230 detects low- and high-frequency roll-off regions and dip regions of a predetermined level or more from the frequency characteristics analyzed by the frequency characteristic analyzer 220, and the rolls. The average level is determined as a target frequency response characteristic in a region except an off region and a deep region of a predetermined level or more.

The target impulse response calculator 240 converts the frequency response determined by the target frequency response determiner 230 into an impulse response using Inverse Fast Fourier Transformation (IFFT).

The impulse equalization calculator 250 calculates an impulse equalization value h _eq (n) for correcting the impulse response of the input signal with the target impulse response h _T (n) calculated by the target impulse response calculator 240. do.

As a result, the impulse equalization value h _eq (n) is calculated to satisfy h _sp (n) * h _eq (n) = h _T (n).

3 is an overall flowchart of a speaker characteristic correction method according to the present invention.

First, intrinsic impulse of the speaker is measured using random noise according to the conventional method (step 310).

Subsequently, the measured impulse response is changed into a frequency response through fast fourier transformation (FFT), and then the frequency characteristic is analyzed (step 320). For example, it is assumed that the analysis is performed using the frequency characteristics as shown in FIG. 4.

Subsequently, low and high roll-off regions are detected from the analyzed frequency characteristics (step 330). For example, in FIG. 4, the low- and high-frequency roll-off regions have a -3 dB frequency where the amplitude gradually decreases as the frequency changes from the flat to the flat portion toward the higher frequency (or lower frequency). Regions 410 and 420.

At this time, the low- and high-frequency roll-off regions detected in the frequency characteristics are determined as the target roll-off (step 330).

Subsequently, a dip region of 15 dB or more is detected from the analyzed frequency characteristic (step 350). For example, in FIG. 4, the deep region is a point 430 where the level suddenly changes. At this time, the target level is set to a predetermined level, preferably a +5 dB dip, in the frequency region where the dip occurs (step 360).

Subsequently, the average level is calculated from the low- and high-pass roll-off regions and regions except the deep region of a predetermined level or more, and is determined as the target frequency response characteristic h _T (n) (step 370).

As a result, the target frequency response characteristic h _T (n) is converted into a target impulse response characteristic through an IFFT, and the target impulse response characteristic is corrected by comparing the impulse response characteristic h _sp (n) of the speaker. Calculate the impulse response characteristic (h _eq (n)).

The present invention is not limited to the above-described embodiment, and of course, modifications may be made by those skilled in the art within the spirit of the present invention.

 As described above, according to the present invention, the target frequency characteristic is automatically calculated when only the impulse response characteristic of the speaker is measured. Therefore, the user can set the target frequency characteristics manually without the hassle of manually setting the target frequency characteristics, thereby preventing the speaker from being damaged or deteriorating the sound quality with the reference frequency setting which cannot be reached due to the speaker's performance limit, and having the optimum frequency response characteristics. have.

Claims (3)

In the speaker characteristic correction method, Measuring an impulse response characteristic of the speaker by inputting a random noise signal, and converting the impulse response characteristic into a frequency response characteristic; Detecting low and high roll-off regions and dip regions of a predetermined level in the frequency response characteristic; Calculating an average level of the roll-off region and the non-deep region in the frequency response characteristic to determine a target frequency response characteristic; And comparing the target frequency response characteristic with the impulse response characteristic of the speaker to correct the frequency response characteristic. The method of claim 1, further comprising converting the target frequency response characteristic into a target impulse response through an IFFT. In the speaker characteristic correction device, An impulse characteristic measurement unit configured to input random noise to measure an intrinsic impulse of the speaker; A frequency characteristic analyzer for analyzing the frequency characteristics through the impulse response measured by the impulse characteristic measurer; A low- and high-frequency roll-off region and a dip region having a predetermined level are detected from the frequency characteristics analyzed by the frequency characteristic analyzer, and the roll-off region and the dip region in the frequency characteristic are detected. A target frequency response determiner that determines an average level of the other region as a target frequency response; A target impulse response calculator for converting the target frequency response determined by the target frequency response determiner into a target impulse response; And an impulse equalization calculator configured to correct an impulse response of an input signal with a target impulse response calculated by the target impulse response calculator.

Images