KR20110102989A - Noise monitoring system, noise monitoring method and computer readble medium on which noise monitoring program is recorded - Google Patents

Abstract

The present invention relates to a computer readable medium recording a noise monitoring system, a noise monitoring method and a noise monitoring program.
The noise monitoring system according to the present invention includes at least one installed in a space where noise is generated, and a first signal generating noise signal by detecting a noise signal detected by the noise detector and a noise detector. Noise data generation unit, frequency band measuring unit for measuring the frequency band of noise from a specific noise source in the space, frequency band noise excluding the frequency band measured frequency band of the first noise data and an integer multiple of the measured frequency band A second noise data generation unit configured to remove the data to generate second noise data, and to receive the first noise data and the second noise data, and to process the signal into the first corrected noise data and the second corrected noise data in an audible frequency band. Receiving the first corrected noise data and the second corrected noise data from the noise data processor and the noise data processor, A first noise correction data and second correction data includes noise, the noise data display unit to display, respectively.

Description

Computer-readable media that records noise monitoring systems, noise monitoring methods, and noise monitoring programs

The present invention relates to a computer readable medium recording a noise monitoring system, a noise monitoring method and a noise monitoring program.

In general, noise is a kind of sound, and a person feels noise in such a way that a wave transmitted through the vibration of air stimulates the eardrum in a person's ear. A wave pulsates a human eardrum as the air pressure changes. At this time, the smallest sound pressure that a person can feel is 0.00002N / m2. The sound pressure is expressed as a logarithmic function because the sense of sound that a person feels is raised logarithmically based on this figure. The unit of sound pressure is dB (decibels).

However, a person feels the loudest sound having a frequency of about 1000 Hz due to the nature of the auditory structure. And a person feels the sound of 100Hz as the smallest sound. Therefore, the sound pressure using the dB unit to measure the noise that a person is uncomfortable cannot accurately measure the magnitude of the noise. Therefore, when noise is measured, dB (A), which is a unit that complements the frequency characteristic audible to humans, is used. If the loudness is louder than 50dB (A), the sound is judged as noise.

Recently, various environmental pollutions have occurred as a side effect of the rapid development of the industry. In particular, the noise pollution is a pollution that stimulates the human sense of hearing, and the direct damage of the human body due to the noise pollution does not appear well, but the indirect damage is considerable. Therefore, in recent years, the problem of noise pollution has emerged as a social issue, and the noise complaints among environmental complaints are gradually increasing.

More specifically, the number of noise complaints in 2005 was 28,940 (19.2% of all environmental complaints), more than 10 times higher than the 2000 noise complaints in 2000. Among noise complaints, civil noise (e.g., workplaces such as substations) account for over 90% of all noise complaints (see Ministry of Environment press release in June 2006).

Therefore, in an effort to reduce and prevent noise pollution, the government and local organizations have enacted laws and regulations related to noise pollution. For example, some local organizations require workplaces to install a continuous noise measurement device, to allow noise to be measured at all times, and from time to time at which damage is expected for prevention and administrative guidance, such as noise reduction. We establish the regulations to prescribe that we can measure noise. As such, mandatory installation of a noise measuring device in a workplace such as a substation and monitoring the measured noise limit the use of equipment that generates noise at a location where the noise is higher than a predetermined standard or at a time. Can prevent or reduce noise pollution.

However, since the conventional noise measuring apparatus merely functions as a sound level meter, it only displays the sound pressure level of the measured noise in real time. In addition, the conventional noise measuring apparatus displays the sound pressure level of the noise to be measured, and the case of the substation, for example, both the noise generated in the substation itself and the noise generated around the substation. Therefore, when a complaint was raised due to noise generated in the substation, there was a problem in that it was not possible to determine the cause of whether the noise was generated from the substation itself or the noise generated around the substation.

Therefore, in order to identify the cause of complaints due to noise generated at the workplace, such as a substation, it has been required to develop a device that can display only the noise generated at the workplace itself.

The present invention is to solve the above problems, the problem to be solved by the present invention, noise monitoring system, noise monitoring to enable easy and convenient monitoring only the noise generated from a specific noise source in the space where the noise occurs To provide a computer-readable medium recording the method and noise monitoring program.

Another object of the present invention is to provide a computer-readable medium that records a noise monitoring system, a noise monitoring method, and a noise monitoring program, which allow the user to constantly disclose information on noise generated in a space where noise occurs. It is.

The noise monitoring system of the present invention according to claim 1, wherein the noise monitoring system is installed in at least one or more spaces in which the noise is generated, the noise detection unit for detecting the noise, the noise signal detected by the noise detection unit for generating a first noise data 1 noise data generating unit, frequency band measuring unit for measuring the frequency band of noise from a specific noise source in the space, the frequency band except the frequency band of the measured frequency band and integer frequency of the measured frequency band of the first noise data A second noise data generation unit for removing the noise data to generate second noise data, receiving the first noise data and the second noise data, and processing the signal with the first corrected noise data and the second corrected noise data in the audible frequency band The first correction noise data and the second correction noise data are received from the noise data processing unit, the noise data processing unit And, a first noise correction data and second correction data includes noise, the noise data display unit to display, respectively.

Therefore, according to the noise monitoring system of the present invention according to claim 1, the first noise data generation unit signals the noise data detected by the noise detection unit to generate the first noise data, the second noise data generation unit of the first noise data The second noise data is generated by removing the noise data of the frequency band except the frequency band measured by the frequency band measuring unit and an integer multiple of the frequency band, and the noise data processing unit generates the first noise data and the second noise data. Is processed by the first corrected noise data and the second corrected noise data of the audible frequency band, and the noise data display unit displays the first corrected noise data and the second corrected noise data, thereby predetermining a frequency band of noise from a specific noise source. If you set the measured frequency band instead of the frequency band, Only the noise generated from the noise sources in a particular area may be more accurately monitored. In addition, since the entire system from the detection to the display is always made by each component, and the noise data display unit may be located at a different place from the noise detector, it is always possible to disclose information about the noise.

In the noise monitoring system of the invention according to claim 2, in the invention according to claim 1, the second noise data is P _Ai of the following equation,

Here, P _Aυ is noise data of measured frequency band and frequency band of integer multiple of the measured frequency band, υ is a positive integer, υ _max is 213 for 51.2k Sample per second, and changes according to sampling frequency. do.

Therefore, according to the noise monitoring system of the invention according to claim 2, the second noise data generating unit adds the noise data of the frequency band measured in the first noise data and the frequency band of an integer multiple of the measured frequency band by the equation. Therefore, only the noise generated from the specific noise source in the space where the noise is generated can be monitored.

The noise monitoring system according to claim 3 is the noise monitoring system according to claim 1 or 2, wherein the first noise data generating unit analyzes the noise signal to generate first noise data.

Therefore, according to the noise monitoring system of the present invention according to claim 3, since the first noise data is generated through frequency analysis, various information about the noise generated in the space can be monitored.

The noise monitoring system according to claim 4 is the noise monitoring system according to claim 1 or 2, wherein the noise data display unit can remotely process and display the first corrected noise data and the second corrected noise data. The remote computer unit, the noise data processing unit is connected to the Internet network, and transmits the first correction noise data and the second correction noise data to the remote computer unit via the Internet network.

Therefore, according to the noise monitoring system of the invention according to claim 4, the remote computer unit receives the first corrected noise data and the second corrected noise data from the noise data processing unit via the Internet network, and the first corrected noise data and the second corrected noise data. Since the data is processed and displayed, the noise data can be processed and displayed remotely without being limited by the physical distance from the noise data processor. In addition, according to the noise monitoring system, the information on the noise generated in the space can be monitored more easily and conveniently and more variously, and furthermore, the noise data can be processed again, so that the noise data can be collected at various angles. Can be monitored.

The noise monitoring system according to claim 5 is the noise monitoring system according to claim 1 or 2, wherein the noise data display unit is a display electronic display board displaying the first corrected noise data and the second corrected noise data, and the noise data processing unit The first corrected noise data and the second corrected noise data are transmitted to the display display board wirelessly or by wire.

Therefore, according to the noise monitoring system of the invention according to claim 5, the noise data processing unit transmits the first corrected noise data and the second corrected noise data to the display board by wireless or wired, so that the display board is first corrected noise data and second correction. Since the noise data is displayed, it can be easily recognized by people's eyes through the display electronic board installed in the streets where many people travel, and the information on the noise generated in the space can be monitored more easily and conveniently and more variously. can do.

The noise monitoring system according to claim 6 is the noise monitoring system according to claim 1 or 2, wherein the first noise data generation unit includes a display unit for displaying the generated first noise data.

Therefore, according to the noise monitoring system of the invention according to claim 6, since the first noise data generated by the first noise data generation unit is not displayed through the noise data display unit but is directly displayed through the display unit, a position for detecting noise The first noise data can also be monitored.

The noise monitoring method of the present invention according to claim 7, the first noise data generation step of generating a first noise data by signal processing the noise signal detected in the noise detection step, the noise detection step of detecting the noise in the space where the noise occurs A frequency band measurement step of measuring a frequency band of noise from a specific noise source in a space, and removing noise data of a frequency band except for a frequency band of the measured frequency band and an integer multiple of the measured frequency band among the first noise data. A second noise data generating step of generating second noise data, and a noise data processing step of receiving the first noise data and the second noise data and signal-processing the first corrected noise data and the second corrected noise data in the audible frequency band; Receiving the first corrected noise data and the second corrected noise data, and receiving the first corrected noise data and the second corrected noise data. And a noise data display step of displaying the corrected noise data, respectively.

Therefore, according to the noise monitoring method of the present invention according to claim 7, in the first noise data generation step, the first noise data is generated by signal processing the noise data detected in the noise detection step, and the first noise in the second noise data generation step. The second noise data is generated by removing the noise data of the frequency band except the frequency band measured in the frequency band measuring step and the frequency band of an integer multiple of the frequency band, and in the noise data processing step, the first noise data and the first noise data are generated. 2 The noise data is signal-processed into the first corrected noise data and the second corrected noise data in the audible frequency band, and the first corrected noise data and the second corrected noise data are displayed in the noise data display step, so that the frequency of noise from a specific noise source The actual measured frequency of the band rather than the predetermined frequency band As a band, only noise generated from a specific noise source in a space where noise is generated can be monitored more accurately. In addition, since the entire steps from detection to display are always performed, and the noise data display step may be located at a different place from the noise detection unit, it is possible to always disclose information about the noise.

The computer-readable medium having recorded the noise monitoring program of the present invention according to claim 8, at least one installed in the space where the noise is generated, by processing the noise signal detected in the noise detection step, the noise detection step to detect the noise by A first noise data generating step of generating first noise data, a frequency band measuring step of measuring a frequency band of noise from a specific noise source in a space, an integer multiple of the measured frequency band and the measured frequency band of the first noise data A second noise data generating step of generating second noise data by removing noise data of a frequency band excluding a frequency band of the first frequency band; receiving first noise data and second noise data, and receiving first corrected noise data of an audible frequency band. Noise data processing step of signal processing with second correction noise data, first correction noise day And the second receiving the noise correction data, the sound data to execute the display step of displaying a first calibration noise data and the second calibration noise data, respectively.

Therefore, according to the computer-readable medium that records the noise monitoring program of the present invention according to claim 8, in the first noise data generation step, the first noise data is generated by signal processing the noise data detected in the noise detection step, and the second In the noise data generating step, second noise data is generated by removing noise data of a frequency band except for a frequency band measured in the frequency band measuring step and an integer multiple of the frequency band among the first noise data, and processing the noise data. In the step, the first noise data and the second noise data are signal-processed into the first corrected noise data and the second corrected noise data of the audible frequency band, so that the first corrected noise data and the second corrected noise data are displayed in the noise data display step. Frequency band of noise from specific noise source By using the actually measured frequency band instead of the frequency band, it is possible to more accurately monitor only the noise generated from a specific noise source in the space where the noise is generated. In addition, since the entire steps from detection to display are always performed, and the noise data display step may be located at a different place from the noise detection unit, it is possible to always disclose information about the noise.

As described above, the present invention makes it possible to more accurately monitor only the noise generated from a specific noise source in a space where the noise is generated by using the frequency band of the noise from the specific noise source as the actually measured frequency band instead of the predetermined frequency band. It has an effect.

In addition, the present invention has the effect of allowing the information of the noise generated in the space where the noise occurs at all times.

Specific matters other than the problem to be solved, the problem solving means, and the effects of the present invention as described above are included in the following embodiments and the drawings. Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. Like reference numerals refer to like elements throughout.

1 is a block diagram illustrating a noise monitoring system according to an embodiment of the present invention.
2 is a view showing the output of the second noise data generation unit of the noise monitoring system according to an embodiment of the present invention.
Figure 3 is a schematic diagram showing the noise monitoring system applied to a substation according to an embodiment of the present invention.
4 is a view for explaining a noise monitoring method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only described in order to more easily disclose the contents of the present invention, but the scope of the present invention is not limited to the scope of the accompanying drawings that will be readily available to those of ordinary skill in the art. You will know.

1 to 3 are views for explaining a noise monitoring system according to an embodiment of the present invention. Specifically, Figure 1 is a block diagram showing a noise monitoring system according to an embodiment of the present invention, Figure 2 is a view showing the output of the second noise data generating unit of the noise monitoring system according to an embodiment of the present invention. 3 is a schematic diagram showing a noise monitoring system applied to a substation according to an embodiment of the present invention.

As shown in Figures 1 to 3, the noise monitoring system according to an embodiment of the present invention, the noise detector 100, the first noise data generator 200, the frequency band measuring unit 300, the second The noise data generator 400, the noise data processor 500, and the noise data display unit 600 are included.

The noise detector 100 detects the noise in the space where the noise occurs. The noise detector 100 is installed in the electrical equipment to measure the noise in the space. When there are a plurality of electrical equipment to measure the noise, the noise detector is also installed for each electrical equipment. For example, when the space in which the noise occurs is a substation, since the internal space of the substation is considerably wide, it is difficult to monitor the noise generated in the entire substation by one noise detector 100. Therefore, in the substation, it is preferable that the noise detection unit 100 is installed at a predetermined interval.

In addition, although not shown, the noise detector 110 uses a microphone. The microphone converts the noise generated by the electrical equipment into a voltage signal according to the frequency.

The first noise data generator 200 is installed together with the noise detector 100 to generate first noise data by signal processing the noise signal detected by the noise detector 100. Here, the first noise data is data obtained by quantifying the noise at a sound pressure level in decibels (dB), for example, to measure the noise level. In this case, the first noise data generator 200 generates various noise data using the frequency analysis method of the noise signal. Frequency analysis is performed by 1/3 octave band frequency analysis or the like.

In addition, the first noise data generator 200 may include a display unit 210 that displays the generated first noise data. Accordingly, the first noise data generation unit 200 does not display the generated noise data through the second noise data generation unit 400, the noise data processing unit 500, and the noise data display unit 600, which will be described later. , Can be displayed immediately. For example, in a substation, site managers or technicians can check and monitor noise data at the site (noise detection location) at that time as needed.

The frequency band measuring unit 300 measures a frequency band of noise from a specific noise source (for example, an electrical installation such as a substation) in a space where noise occurs. For example, some substations are supplied with a current of 60 Hz, while others are supplied with a current of 59 Hz. These substations generate noise and vibration at harmonic frequencies of the supplied frequencies. That is, when the frequency supplied to such a substation is 59 Hz, the noise generated in the substation is distributed in 59 Hz drainage components. Therefore, the present noise monitoring system measures the frequency band of the noise actually generated from the specific noise source through the frequency band measuring unit 300, and monitors only the noise of the specific noise source more accurately than the conventional method using the predetermined frequency band. can do.

The second noise data generator 400 is installed together with the noise detector 100 to remove noise data of a frequency band except for a frequency band of an integer multiple of the measured frequency band and the measured frequency band among the first noise data. To generate second noise data. In this case, the measured frequency band means 1/10 octave, 10% of the narrow band selected frequency, or 5 Hz or 10 Hz band with respect to the frequency measured by the frequency band measuring unit 300 using a narrow band measuring method.

For example, the second noise data generator 400 generates the second noise data P _Ai by summing noise data of the measured frequency band and the measured frequency band among the first noise data by the following equation. .

Here, P _Aυ is the noise data of the measured frequency band and the frequency band of integer times (1, 2, 3, etc.) of the measured frequency band, υ is a positive integer, and υ _max is 51.2k Sample per second. 213, and varies depending on the sampling frequency. In addition, the noise data at P _Ai and P _Aυ means the sound pressure level at the corresponding frequency.

As shown in FIG. 2, the second noise data generating unit 400 may include a frequency band of an integer multiple of the measured frequency band of 59 Hz when the frequency of the noise from the specific noise source is 59 Hz and υ _max is 10, 118 Hz, 236 Hz... Noise data of 118 (υ-1) and 118υ, that is, second noise data obtained by summing the respective sound pressure levels are generated.

In the present invention, a method of removing noise data of a frequency band except a frequency band of a measured frequency band and an integer multiple of the measured frequency band among the first noise data has been described using a narrowband measurement method as an example, but is not limited thereto. It is also possible to apply time-synchronous measurements. Here, the above-mentioned narrowband and time-synchronous measurements are in accordance with the technical standard (KS C IEC 60076-10: 2003).

The noise data processor 500 is installed together with the noise detector 100, receives the first noise data and the second noise data, and processes the signal into first corrected noise data and second corrected noise data in an audible frequency band. . The noise data processing unit 500 receives the first noise data from the first noise data generation unit 200, compensates for the frequency characteristic that a human can hear the received first noise data to a dB (A) value. To generate the first corrected noise data. Then, the noise data processor 500 transmits the first corrected noise data to the noise data display unit 600. In addition, the noise data processing unit 500 receives the second noise data from the second noise data generation unit 400, and supplements the frequency characteristic of hearing the received second noise data to a dB (A) value. To generate second correction noise data. Then, the noise data processor 500 transmits the second corrected noise data to the noise data display unit 600.

The noise data display unit 600 receives the first correction noise data and the second correction noise data from the noise data processing unit 500 by wireless or wired, and displays the first correction noise data and the second correction noise data, respectively. Here, the noise data displayed by the noise data display unit 600 is data that has only sound pressure level information of noise measured as in the prior art, and that is noise data processed, that is, data that complements a frequency characteristic that a human can hear.

For example, the noise data display unit 600 may be a remote computer unit 140 (see FIG. 3) capable of remotely processing and displaying the first correction noise data and the second correction noise data. In this case, if the noise data processing unit 500 is a kind of sub computer 151, the remote computer unit 140 receives the first corrected noise data and the second corrected noise data from the noise data processing unit 500 as a kind of client computer. In addition, noise data can be monitored from multiple angles since it can be reworked and displayed. In addition, since the remote computer unit 140 receives noise data through the Internet network, the remote computer unit 140 is not limited to the physical distance from the noise data processing unit 500 so that the remote computer unit 140 may process / display the noise data even from a remote location.

As another example, the noise data display unit 600 may be a display display board 152 (see FIG. 3) displaying noise data. In this case, the noise data processor 500 transmits the noise data to the display display board 152 by wireless or wired 150. In general, the display display board 152 is a large display device, and is installed in a street or the like for a lot of people. That is, the noise data displayed on the display display board 152 may be well recognized by the eyes of people. Therefore, the information on the noise generated in the space can be monitored more easily and conveniently and more variously.

As described above, in the noise monitoring system according to the exemplary embodiment of the present invention, the first noise data generator 200 processes the noise data detected by the noise detector 100 to generate first noise data. 2 The noise data generating unit 400 removes the noise data of the frequency band except for the frequency band measured by the frequency band measuring unit 300 and the frequency band of an integer multiple of the frequency band among the first noise data to generate the second noise data. The noise data processor 500 processes the first noise data and the second noise data into the first corrected noise data and the second corrected noise data of the audible frequency band, and the noise data display unit 600 corrects the first. By displaying the noise data and the second corrected noise data, the frequency band of the noise from a specific noise source is not measured in the predetermined frequency band but is actually measured frequency band. And, it is possible to more accurately monitor only the noise generated from a particular source of noise in the spatial noisy. In addition, since the entire system from the detection to the display is always made by each component, and the noise data display unit may be located at a different place from the noise detector, it is always possible to disclose information about the noise.

4 is a view for explaining a noise monitoring method according to an embodiment of the present invention.

As shown in Figure 4, the noise monitoring method according to an embodiment of the present invention, first, to detect the noise in the space where the noise occurs using the noise detector (S100). The noise detector is installed in the electrical equipment to measure the noise in the space. When there are a plurality of electrical equipment to measure the noise, the noise detector is also installed for each electrical equipment. At this time, it is preferable that the noise detector uses a microphone.

Next, signal processing the noise signal detected in the noise detection step (S100) to generate the first noise data (S200). Here, the first noise data is data for measuring the noise level, for example, quantifying the noise at a sound pressure level in decibels (dB). At this time, signal processing is performed using a frequency analysis method. Also, the noise data generating step S200 may include a display step (not shown) for displaying the generated first noise data. In addition, the frequency band measurement step (S300) measures the frequency band of the noise from the specific noise source in the small space.

Next, the noise data of the frequency band excluding the frequency band measured in the frequency band measurement step (S300) and the frequency band of an integer multiple of the measured frequency band among the first noise data generated in the first noise data generation step (S200). To generate a second noise data by removing (S400). In the second noise data generating step (S400), by using a kind of server computer, the noise data of the frequency band excluding the frequency band measured among the first noise data and the frequency band of an integer multiple of the measured frequency band is expressed by the above equation. Remove That is, in the second noise data generation step S400, the second noise data is generated by summing noise data of the measured frequency band and the measured frequency band among the first noise data by the equation.

Next, the first noise data generated in the first noise data generation step S200 and the second noise data generated in the second noise data generation step S400 are received, and the first corrected noise data of the audible frequency band is received. Signal processing is performed with the second corrected noise data (S500). That is, in the noise data processing step S500, the first noise data generated in the first noise data generation step S200 is received, and the frequency characteristic of the human hearing of the received first noise data is compensated for in dB ( A) to generate the first corrected noise data. In addition, in the noise data processing step S500, the second noise data is received from the second noise data generation step S400, and the frequency characteristic of the human hearing of the received second noise data is compensated for by dB (A). Convert to a value to generate second corrected noise data.

Next, the first corrected noise data and the second corrected noise data signal-processed in the noise data processing step S500 are received wirelessly or by wire, and the first corrected noise data and the second corrected noise data are respectively displayed (S600). ). Here, the noise data displayed in the noise data display step S600 is data obtained by signal processing in the noise data processing step S600, in addition to data having only sound pressure level information of the noise measured in the conventional manner.

At this time, the noise data display step (S600) may display the noise data using at least one of the remote computer or the display sign.

Accordingly, in the noise monitoring method according to an embodiment of the present invention, in the first noise data generation step S200, the first noise data is generated by signal processing the noise data detected in the noise detection step S100. In the second noise data generating step (S400), the second noise data is removed by removing the noise data of the frequency band except for the frequency band measured in the frequency band measuring step (S300) of the first noise data and an integer multiple of the frequency band. In the noise data processing step (S500), the first noise data and the second noise data are signal-processed into the first corrected noise data and the second corrected noise data of the audible frequency band, and the noise data display step (S600) is performed. By displaying the first corrected noise data and the second corrected noise data, the labor of the operator is reduced, and the noise can be easily and conveniently monitored. In addition, since the entire steps from detection to display are always performed, and the noise data display step S600 may be located at a different place from the noise detection unit, it is always possible to disclose information on noise.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Therefore, the exemplary embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from equivalent concepts should be construed as being included in the scope of the present invention.

Claims (8)

At least one noise detector installed in a space where noise is generated and detecting the noise;
A first noise data generator configured to signal-process the noise signal detected by the noise detector to generate first noise data;
A frequency band measuring unit measuring a frequency band of noise from a specific noise source in the space;
A second noise data generation unit configured to generate second noise data by removing noise data of a frequency band except for a frequency band of the measured frequency band and an integer multiple of the measured frequency band among the first noise data;
A noise data processor configured to receive the first noise data and the second noise data and to signal-process the first corrected noise data and the second corrected noise data in an audible frequency band; And
And a noise data display unit configured to receive the first corrected noise data and the second corrected noise data from the noise data processor and to display the first corrected noise data and the second corrected noise data, respectively.
Noise monitoring system. The method of claim 1,
The second noise data is P _Ai of the following equation,

here,
P _Aυ is noise data of a frequency band of an integer multiple of the measured frequency band and the measured frequency band,
υ is a positive integer
υ _max is 213 for 51.2k Sample per second, and varies with sampling frequency,
Noise monitoring system. The method according to claim 1 or 2,
The first noise data generating unit generates the first noise data by performing frequency analysis on the noise signal.
Noise monitoring system. The method according to claim 1 or 2,
The noise data display unit is a remote computer unit that can remotely process and display the first correction noise data and the second correction noise data,
The noise data processor is connected to an internet network, and transmits the first corrected noise data and the second corrected noise data to the remote computer unit through the internet network.
Noise monitoring system. The method according to claim 1 or 2,
The noise data display unit is a display display board displaying the first corrected noise data and the second corrected noise data,
The noise data processor transmits the first correction noise data and the second correction noise data to the display display board wirelessly or by wire.
Noise monitoring system. The method according to claim 1 or 2,
The first noise data generation unit includes a display unit that displays the generated first noise data.
Noise monitoring system. At least one or more installed in the space where the noise occurs, the noise detection step of detecting the noise;
A first noise data generation step of generating first noise data by signal processing the noise signal detected in the noise detection step;
A frequency band measuring step of measuring a frequency band of noise from a specific noise source in the space;
A second noise data generation step of generating second noise data by removing noise data of a frequency band excluding a frequency band of the measured frequency band and an integer multiple of the measured frequency band among the first noise data;
A noise data processing step of receiving the first noise data and the second noise data and signal processing the first corrected noise data and the second corrected noise data in an audible frequency band; And
A noise data display step of receiving the first corrected noise data and the second corrected noise data and displaying the first corrected noise data and the second corrected noise data, respectively;
Including, the noise monitoring method. At least one or more installed in the space where the noise occurs, the noise detection step of detecting the noise;
A first noise data generation step of generating first noise data by signal processing the noise signal detected in the noise detection step;
A frequency band measuring step of measuring a frequency band of noise from a specific noise source in the space;
A second noise data generation step of generating second noise data by removing noise data of a frequency band excluding a frequency band of the measured frequency band and an integer multiple of the measured frequency band among the first noise data;
A noise data processing step of receiving the first noise data and the second noise data and signal processing the first corrected noise data and the second corrected noise data in an audible frequency band; And
A noise data display step of receiving the first corrected noise data and the second corrected noise data and displaying the first corrected noise data and the second corrected noise data, respectively;
A computer-readable medium that records a noise monitoring program for executing the program.

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