KR20110080640A - Active noise control system and method - Google Patents

Abstract

PURPOSE: An active noise control system and method are provided to enable desired arrangement of a speaker for active noise control. CONSTITUTION: An active noise control system(100) comprises a speaker(110), a duct(120) which receives the sounds of the speaker and outputs active noise control sounds, and an active noise control module which controls the sounds of the speaker.

Description

Active noise control system and method

The present disclosure generally relates to an active noise control system, and more particularly, to an active noise control system and method.

In active noise control technology for noise reduction, there have been many studies on the control method for improving the performance and the method of finding the optimum position of the sensor and the speaker. As a control method, many feedfoward and feedback control methods have been developed that use information about the noise source and information at the location to be controlled. Also, the method of positioning the sensor and the driver to derive the optimum noise control performance in a given space Much research has been conducted through simulations using modeling. In this simulation, the sensor and speaker are modeled in the actual shape, but in general, the ideal model is applied for easy analysis. However, in the actual implementation, the speaker installation is not considered about the design problem or the possibility of installation. For example, in order to apply active noise control to a building environment, when installing speakers around windows to reduce noise from outside, it is difficult not only to install a large number of loud speakers, but also because of the design of the building. It can also work badly.

In one embodiment, an active noise control system is disclosed. The active noise control system includes a speaker and a duct receiving the sound of the speaker and outputting an active noise control sound.

In another embodiment, an active noise control method is disclosed. The active noise control method includes controlling a sound of a speaker and receiving a sound of the speaker using a duct and outputting an active noise control sound.

In another embodiment, an active noise control method is disclosed. The active noise control method includes controlling a sound of a speaker and receiving a sound of the speaker using a duct and outputting an active noise control sound. The process of controlling the sound of the speaker is performed by an active noise control module.

The foregoing provides only optional concepts in a simplified form for the details that follow. This disclosure is not intended to limit the main or essential features of the claims or to limit the scope of the claims.

1 is a diagram illustrating an active noise control system according to an exemplary embodiment.
2 is a flowchart illustrating an active noise control method according to an exemplary embodiment.
3 and 4 are diagrams for describing a method of calculating or estimating a transfer function of a speaker and a duct and a transfer function of an inverse transform filter, according to an exemplary embodiment.

Hereinafter, exemplary embodiments disclosed herein will be described in detail with reference to the accompanying drawings. Unless otherwise indicated in the text, like reference numerals in the drawings indicate like elements. The illustrative embodiments described above in the detailed description, drawings, and claims are not meant to be limiting, other embodiments may be utilized, and other changes may be made without departing from the spirit or scope of the technology disclosed herein. Those skilled in the art can arrange, configure, combine, and designate the components of the present disclosure, that is, the components generally described herein and described in the figures, in a variety of different configurations, all of which are expressly devised and It will be readily understood that they form part of. In order to clearly express various layers (or layers), regions, and shapes in the drawings, the width, length, thickness, or shape of the components may be exaggerated.

1 is a diagram illustrating an active noise control system according to an exemplary embodiment. Referring to FIG. 1, the active noise control system 100 includes a speaker 110 and a duct 120. In some other embodiments, the active noise control system 100 may optionally further include an active noise control module 130.

Various speakers may be used as the speaker 110. The type of the speaker 110 is not limited as long as it can generate sound.

The duct 120 receives sound from the speaker 110 and outputs an active noise control sound. Duct 120 may have a variety of forms. The shape of the duct 120 is not limited as long as it receives the sound of the speaker 110 at one end and reproduces the sound of the speaker 110 at the other end. The shape of the duct 120 may be, for example, round, square, polygonal, or the like. As shown in the figure, one end of the duct 120 may be connected to the speaker 110. In this case, the other end of the duct 120 not connected to the speaker 110 serves as a speaker for outputting the active noise control sound. One of the factors that determine the control performance in the active noise control is the position of the sensor (not shown) and the speaker 110. Among these, in the position of the speaker 110, it may be difficult to install in a desired position due to the size of the speaker 110 or the actual installation problem. The present disclosure proposes a method for installing the speaker 110 at a desired position using the speaker 110 and the duct 120. When using the duct 120, the speaker 110 can be installed in any place, the speaker 110 is easy to install, it can be installed where there is no problem in appearance. That is, the speaker 110 is installed at an arbitrary place, and the duct 120 is connected to a position where the actual speaker 110 is installed to output the active noise control sound. In this case, one end of the duct 120 not connected to the speaker serves as a speaker for outputting the active noise control sound.

The active noise control module 130 controls the sound of the speaker 110. In one embodiment, the active noise control module 130 may include an inverse filter 140 for inverting the control input. The inverse transform filter 140 converts the control input to the speaker 110 so that the sound of the speaker 110 distorted by the duct 120 becomes the active noise control sound. That is, as shown in the figure, in the case of the active noise control system 100 in which the duct 120 is additionally installed in the speaker 110, the sound of the speaker 110 controlled by the control input is a duct Distorted by 120. In other words, the sound generated by the speaker 110 by the control input input to the speaker 110 is distorted by the duct 120 so that the active noise control system 100 cannot generate the active noise control sound. do. Despite the distortion, the active noise control system 100 must compensate for the distortion of the sound of the speaker 110 by the duct 120 in order to generate the active noise control sound according to the control input. Various methods may be used as a method for compensating for the distortion of the sound of the speaker 110 by the duct 120. As a method for compensating for the distortion of the sound of the speaker 110 by the duct 120, for example, a transfer function corresponding to the distortion phenomenon by the duct 120 is measured through a system identification process. And an inverse transform filter 140 corresponding thereto. In this case, when the control input is passed through the inverse transform filter 140 and is given as the input of the speaker 110, the desired active noise control sound can be reproduced at the end of the duct 120 which will act as the actual speaker. have. The transfer function of the inverse transform filter 140 may be calculated by inversely transforming the transfer functions of the speaker 110 and the duct 120. The transfer function of the inverse transform filter 140 may be calculated by an inverse transform filter estimator (not shown). A method of calculating or estimating the transfer function of the speaker 110 and the duct 120 and the transfer function of the inverse transform filter 140 will be described in detail with reference to FIGS. 3 and 4.

2 is a flowchart illustrating an active noise control method according to an exemplary embodiment. 2, in block 210, the sound of the speaker is controlled. In an embodiment, the controlling of the sound of the speaker may include: measuring a transfer function of the speaker and the duct, inversely converting a transfer function of the speaker and the duct, and generating an inverse transform filter; And providing a control input for controlling the speaker to the speaker via the inverse transform filter. The transfer function of the speaker and the duct can be measured by various methods. According to an embodiment, the measuring of the transfer function of the speaker and the duct may include generating a white noise signal of a predetermined frequency band using a signal regenerator, reproducing the white noise signal through the speaker, The method may include measuring a reproduction sound of the speaker passing through the duct and measuring the transfer function from the white noise signal and the measured reproduction sound of the speaker by using a transmission function measuring unit. The process of generating the inverse transform filter may be performed by various methods. In an embodiment, the generating of the inverse transform filter may include generating the inverse transform filter from the transfer function measured using an inverse transform filter estimator. In some other embodiments, the process of controlling the sound of the speaker may be optionally performed by an active noise control module. The active noise control module may include the inverse transform filter for inverting the control input. The inverse transform filter may convert the control input to the speaker so that the sound of the speaker distorted by the duct becomes the active noise control sound. The transfer function of the inverse transform filter may be calculated by inversely transforming the transfer functions of the speaker and the duct. A method of measuring, estimating or calculating the transfer function of the speaker and the duct and the transfer function of the inverse transform filter will be described in detail with reference to FIGS. 3 and 4.

In block 220, a duct is used to receive the sound of the speaker and output an active noise control sound.

Referring back to Figure 2, using the active noise control method of the present disclosure, it is possible to install the speaker in an easy-to-install location or where there is no apparent obstacle, and output the active noise control sound through the ducts of the speaker installation Convenience can be obtained.

3 and 4 are diagrams for describing a method of measuring, estimating or calculating a transfer function of a speaker and a duct and a transfer function of an inverse transform filter, according to an exemplary embodiment.

3 shows a system 300 for measuring the transfer function of the speaker 320 and the duct 330. System 300 includes signal player 310, speaker 320, duct 330, microphone 340, and measurement system 350.

The signal regenerator 310 may generate a white noise signal of a predetermined frequency band. The predetermined frequency band may be an audible frequency band, for example. The audible frequency band may be about 20 Hz to about 20,000 Hz. The speaker 320 may reproduce the sound by receiving the white noise signal of the signal reproducer 310. The sound reproduced by the speaker 320 may be transmitted to the acoustic measurement unit through the duct 330. The acoustic measurement unit may include a microphone 340 and a measurement system 350. The microphone 340 measures the sound of the speaker 320, and the sound measured by the microphone 340 can be transmitted to the measurement system 350. The sound transmitted to the measurement system 350 may be signal processed in the measurement system 350. Measurement system 350 may store or output the sound as a digital or analog electrical signal. The measurement system 350 may include a signal processor (not shown), a storage device (not shown), or the like. In other words, the white noise signal of the player 310 may be distorted by the speaker 320 and the duct 330. Through the above-described process, the measurement system 350 may obtain a white noise signal of the signal reproducer 310 distorted by the speaker 320 and the duct 330.

4 shows a system 400 for generating an inverse transform filter 140. System 400 includes a transfer function measurer 410 and an inverse transform filter estimator 420.

The transfer function measuring unit 410 receives a white noise signal (hereinafter referred to as an input signal) of the signal regenerator 310 and an output signal (hereinafter referred to as an output signal) of the measurement system 350. The transfer function measuring unit 410 may measure, estimate, or calculate a transfer function of the speaker 320 and the duct 330 from the input signal and the output signal. The transfer function of the speaker 320 and the duct 330 measured, estimated or calculated is transferred to the inverse transform filter estimator 420.

The inverse transform filter estimator 420 generates an inverse transform filter from the transfer function of the speaker 320 and the duct 330. The inverse transform filter compensates for the white noise signal of the signal regenerator 310 distorted by the speaker 320 and the duct 330. That is, when the signal passing through the inverse transform filter passes through the speaker 320 and the duct 330, the active noise control sound is reproduced at the outlet of the duct 330.

Since the structure, function, and the like of the speaker 320 and the duct 330 are substantially the same as the structure, function, and the like of the speaker 110 and the duct 120 described above with reference to FIG. 1, the detailed description thereof is provided for convenience of description. Omit.

Referring back to FIGS. 1 to 4, the present disclosure provides an active noise control system that enables a speaker to be placed at a desired position by using a system consisting of a speaker and a duct in order to overcome the problem of speaker placement in active noise control. It is about a method. In general, in the implementation of an active noise control system and method, the speaker is located on a noise transmission path or where the optimum performance can be achieved. However, the speaker may not be installed at a desired position due to speaker size or design problem. In this case, the speaker is placed in the space where it can be installed and connected to the position where the actual speaker should be installed by using a duct system. In such a system, the active noise control sound to be reproduced in the speaker is distorted by the duct system, which can be reproduced by using the inverse transform filter of the transfer function between the speaker and the duct inlet through the system identification. have. In other words, the active noise control system and method proposed in the present disclosure is expected to propose a way to overcome the restrictions on the speaker installation in the actual active noise control.

From the above, various embodiments of the present disclosure have been described for purposes of illustration, and it will be understood that various modifications are possible without departing from the scope and spirit of the present disclosure. And the various embodiments disclosed are not intended to limit the present disclosure, the true spirit and scope will be presented from the following claims.

Claims (12)

In an active noise control system,
speaker; And
A duct receiving the sound of the speaker and outputting an active noise control sound
Active noise control system comprising a. The method of claim 1,
Active noise control system further comprising an active noise control module for controlling the sound of the speaker. The method of claim 2,
The active noise control module includes an inverse transform filter for inverting a control input,
And the inverse transform filter converts the control input to the speaker so that the sound of the speaker distorted by the duct becomes the active noise control sound. The method of claim 3,
The transfer function of the inverse transform filter is calculated by inverting the transfer function of the speaker and the duct active noise control system. The method of claim 4, wherein
And a transfer function of the inverse transform filter is calculated by an inverse transform filter estimator. In the active noise control method,
Controlling the sound of the speaker; And
The process of receiving the sound of the speaker using a duct, and outputs an active noise control sound
Active noise control method comprising a. The method of claim 6,
The process of controlling the sound of the speaker
Measuring a transfer function of the speaker and the duct;
Generating an inverse transform filter by inversely transforming a transfer function of the speaker and the duct; And
Providing a control input for controlling the sound of the speaker to the speaker via the inverse transform filter;
Active noise control method comprising a. The method of claim 7, wherein
The process of measuring the transfer function
Generating a white noise signal of a predetermined frequency band using a signal regenerator;
Reproducing the white noise signal through the speaker;
Measuring reproduction sound of the speaker passing through the duct; And
Measuring the transfer function from the white noise signal and the reproduced sound of the measured speaker using a transfer function measurer;
Active noise control method comprising a. The method of claim 7, wherein
The generating of the inverse transform filter comprises generating the inverse transform filter from the transfer function measured using an inverse transform filter estimator. In the active noise control method,
Controlling the sound of the speaker; And
Receiving a sound of the speaker using a duct, and outputting an active noise control sound,
The active noise control method of controlling the sound of the speaker is performed by an active noise control module. The method of claim 10,
The active noise control module includes an inverse transform filter for inverting a control input,
And the inverse transform filter converts the control input to the speaker so that the sound of the speaker distorted by the duct becomes the active noise control sound. The method of claim 11,
The transfer function of the inverse transform filter is calculated by inverting the transfer function of the speaker and the duct active noise control method.

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