KR20050100909A - Noise measurement system using internet - Google Patents

Abstract

The present invention relates to a noise measurement system via the Internet. The system of the present invention includes a signal converter for amplifying a noise signal from a microphone and converting the digital signal into digital data, and a wireless LAN I / F for interfacing the digital data input from the signal converter to be transmitted through the wireless Internet; A noise data transmission device including an authentication unit for adding identification information to the digital data, a control unit for controlling each component to convert the identification information and digital data of the authentication unit into wireless data, and to receive the noise data transmission device. And a noise data receiver for converting wireless data into an analyzable data after performing authentication through identification information, and an image display device connected to the noise data receiver for outputting an image of the noise data analysis. Therefore, the present invention can measure the noise in real time using the Internet, it can be analyzed in various forms by analyzing it provides an effect that can more effectively perform the noise management.

Description

Noise measurement system using internet

The present invention relates to a noise measurement system, and relates to a noise measurement system via the Internet for measuring noise from a noise source and analyzing the noise to calculate accurate analysis data about the noise.

In general, noise refers to a sound that is unpleasant, and its physical properties are the same as sound. Noise can interfere with daily life and alter the physiological functions of humans and interfere with hearing. In addition, noise causes a decrease in work efficiency and sleep disorders, and severely affects people by causing physical diseases such as heart disease, respiratory disorders, and hearing loss. In modern cities, along with industrial development, various environmental noises such as noise of construction sites at construction sites, road traffic noise due to increase of passenger cars, factory noise due to increase of factories, and aircraft noise due to takeoff and landing of aircraft are being generated. Such environmental noise has become a major complaint of modern people seeking comfortable living spaces. Therefore, the government has tightened regulations on environmental noise, and induces low noise of noise sources in regulated areas. The government also periodically measures the noise level of aircraft noise, which has recently been filed as a major noise source, and publishes it on the Internet.

However, in other noise-controlled areas, a limited number of officials directly measure or manage quarterly at the measuring point. It is not easy. Therefore, it is difficult to resolve such complaints about environmental noise and to present accurate evidence of the time in the relevant area in case of noise dispute.

An object of the present invention is to measure the noise in the environmental noise regulatory areas or noise dispute areas in real time via the Internet to solve the above problems in real time noise measurement system via the Internet to provide accurate environmental noise data In providing.

The noise measuring system via the Internet according to the present invention for achieving the above object is a signal conversion unit for amplifying the noise signal from the microphone to convert the digital data and output the digital data input from the signal conversion unit through the wireless Internet A wireless LAN I / F for interface to enable transmission, an authentication unit for adding identification information to digital data, and a control unit for controlling each component to convert the identification information and digital data of the authentication unit into wireless data and transmit the same. Noise data receiver connected with noise data receiver, noise data receiver which converts wireless data into data that can be analyzed and then analyzes it through identification information received from noise data transmitter, and noise data receiver It includes an image display device for outputting an image.

Hereinafter, with reference to the accompanying Figures 1 to 14 will be described in detail a preferred embodiment of the present invention.

1 is a schematic diagram of a noise measurement system via the Internet according to an embodiment of the present invention.

Referring to FIG. 1, a microphone 10 for receiving noise measured from a noise source and a noise measured for analyzing the noise measured from the microphone 10 and outputting a result, or transmitting noise data through a WLAN An access point 40 for receiving wireless data from the transmitting device 20, the noise data transmitting device 20 and transmitting it through the Internet 50, and an AP for receiving wireless data via the Internet 50; 60), and outputs the analysis results of the noise data analyzed by the noise data receiving device 80 and the noise data receiving device 80 to receive the wireless data transmitted from the AP 60 to convert the noise data to analyze; It includes an image display unit 90 for. Here, the image display unit 90 refers to a monitor of a general PC. That is, the noise data receiving apparatus 80 may be connected to a PC and transmit the analysis result of the noise data.

In FIG. 1, the microphone 10 is a sensor that measures noise from a noise source and converts the noise into an electrical signal, and is connected to the noise data transmission device 20. Usually, the microphone 10 should be a commercially available microphone that has been proven to be durable and accurate since it should not be affected by the surrounding environment while being precise for outdoor use. Commonly used commercially available microphones are the B & K 4189 microphone and the UA1404 outdoor microphone kit, but the present invention is not particularly limited to the type of microphone or the noise measuring device. That is, the sensor may have its own amplifier or use a microphone of various types.

The noise data transmitter 20 receives the noise signal, converts the noise signal into wireless data to meet the wireless LAN standard, and transmits the noise signal to the AP 40. This radio data includes identification information of the noise data transmitting device 20. Since the identification information is pre-stored in the noise data receiving apparatus 80, the identification information is used for mutual authentication.

The AP 40 transmits wireless data to the AP 60 through the Internet 50. The AP 60 receives the wireless data and transmits the wireless data to the noise data receiving apparatus 80 through the wireless LAN 70. The noise data receiving apparatus 80 performs authentication using identification information in the input wireless data, and when the authentication is completed, converts the wireless data into data that can be analyzed to analyze the noise data. This analysis process will be described with reference to the screen state diagrams with reference to FIGS. 4 to 14.

The noise data receiving apparatus 80 outputs the analyzed noise data to the image display unit 90 of the connected PC to provide an accurate analysis result.

The operation of this noise measurement system will be described in more detail with reference to FIGS. 2 and 3.

FIG. 2 is a detailed block diagram of the noise data transmitting apparatus of FIG. 1.

Referring to FIG. 2, the noise data transmitter 20 receives a signal from the microphone 10 and amplifies the signal amplifier 21 to amplify the signal, and converts the signal amplified by the signal amplifier 21 into digital data. The A / D conversion unit 22, the authentication unit 25 for storing identification information for authentication, and the control unit 23 for generating and outputting wireless data by adding identification information previously stored in the authentication unit 25 to digital data. And a wireless LAN I / F 24 that performs an interface for transmitting wireless data through the wireless LAN. In addition, it includes a signal analyzer 26 for receiving the noise signal from the microphone 10 to analyze the noise signal, and a screen output unit 27 for outputting the analysis results of the signal analyzer 26.

In FIG. 2, the signal amplifier 21 receives a noise signal from the microphone 10 and amplifies and outputs the noise signal. Then, the A / D converter 22 converts the analog amplified noise signal into digital data and outputs the digital data. The control unit 23 receives the digital data, adds the pre-stored identification information to the authentication unit 25 and outputs it to the WLAN I / F 24. Then, the WLAN I / F 24 converts the input digital data into wireless data so as to conform to the communication standard of the wireless LAN and transmits it to the AP 40.

On the other hand, the signal analyzer 26 has a function of analyzing by using the input noise signal. That is, noise analysis such as FFT (fast fourier transform) and noise level check is possible. The analysis result may be output to the screen output unit 27 provided in the noise data transmission device 20. Therefore, the analysis result of the measured noise signal can be confirmed in real time in the field.

3 is a detailed block diagram of the noise data receiving apparatus of FIG. 1.

The noise data receiving apparatus 80 receives wireless data input from the AP 60 and converts the noise data into identification data and identification information so as to be analyzed, and performs authentication from the identification information. The data analysis unit 84 receives the authentication unit 83 and the noise data and analyzes them in the time domain, the frequency domain, and the time-frequency domain, and calculates the results. And a control unit 82 for outputting a result.

In FIG. 3, the wireless LAN I / F 81 receives wireless data input from the AP 60 and converts the noise data and identification information so as to be analyzed. The control unit 82 outputs the identification information to the authentication unit 83. The authentication unit 83 confirms whether the identification information of the pre-stored noise data transmission device 20 and transmits the result to the control unit 83. The control unit 83 receives the authentication result from the authentication unit 83, and when the authentication is completed, outputs the input noise data to the data analysis unit 84. Then, the data analyzer 84 analyzes the noise data in the time domain, the frequency domain, and the time-frequency domain, and outputs the result to the image display unit 90.

An analysis process of the data analysis unit 84 will be described with reference to the screen state diagrams referring to FIGS. 4 to 14.

4 calculates and outputs an equivalent noise level for showing the received result by measuring the noise data of the data analyzer 84 in real time. Noise values are expressed numerically in decibels (dB) or A-weighted decibels (dB (A)). And it receives the noise data of the measuring point and calculates the equivalent noise to show the characteristics of each band in real time.

The data analyzer 84 may analyze the noise data into a time domain characteristic and a frequency domain characteristic. This will be described with reference to FIGS. 5 to 15.

5 shows a time domain analysis panel of noise data.

The root mean square (RMS), maximum, average, variance, and standard deviation of the measured sound pressure data can be checked. In addition, the graph shows how the sound pressure values of the measured noise data are distributed based on the average value.

FIG. 6 shows a panel showing the noise data in the time domain and frequency analysis simultaneously.

The panel can perform a fast fourier transform (FFT) on the measured environmental noise to see what frequency characteristics the noise has.

7 shows a panel that can perform 1/3 octave band frequency analysis.

The linear scale of noise data shows the sound pressure level, the A-weighted sound pressure level and the overall level. And, it includes a waterfall analysis function that can analyze the time-frequency characteristics of the measured noise data in three dimensions for the time and frequency domain.

8 shows such a waterfall analysis panel.

When the sound pressure increase is confirmed at a specific frequency at a specific time in the waterfall analysis, the time-frequency characteristics of the noise data through three types of time-frequency analysis as disclosed in FIGS. 9 to 11 below. You can do a more detailed analysis of.

9 shows a short time fourier transform (STFT) panel during this time-frequency analysis.

STFT is a time-frequency analysis technique that divides a noise signal into a window of a certain size and performs a Fourier transform, so that the frequency resolution and the time resolution cannot be increased at the same time.

10 shows a wavelet transform panel during time-frequency analysis.

Wavelet transform is a method used to express the characteristics of a typical shock wave signal. Fourier transform by changing the size of the window to a logarithmic scale increases the time resolution at high frequencies and the frequency resolution at low frequencies. On the contrary, it has a drawback that the frequency resolution becomes worse at high frequencies and the time resolution is poor at low frequencies.

11 shows the Wigner distribution panel during time-frequency analysis.

The Wigner distribution is a Fourier transform for the autocorrelation function. The Wigner distribution can increase both the time resolution and the frequency resolution at the same time, so that the non-steady signal can be represented more accurately. However, the Fourier transform is applied to the autocorrelation function expressed as the square of the signal to generate the interference term. To remove these interference terms, we need kernels to remove the interference terms. In this case, an exponential kernel is used.

As described above, the data analysis unit 84 may analyze the noise data and calculate the noise level, and may process the analysis result into information for providing the public with the analysis result. Thus, it provides an evaluation panel and a management panel for noise data.

12 shows an evaluation panel of noise data.

The evaluation panel calculates the equivalent noise level of the measured noise and the estimated noise level applying various correction values to the equivalent noise level and stores the calculated value.

13 shows a management panel of noise data.

The management panel shows the information of the measured measurement points and the noise level so that the local noise level can be checked in real time. The data of these management panels are automatically stored in the storage unit (not shown) so that you can check the historical noise history at any time. In addition, when storing data in the storage unit may include a function of imposing data that can be separately informed about the noise exceeding the environmental noise standard. That is, the noise measurement and analysis process may further include a device that can send an alarm signal when the noise level of the region exceeds the environmental regulatory standards, and the data can be imposed a function that is stored separately. Through this function, the noise manager or the government can easily find out whether the complaint is true.

On the other hand, the noise measurement system via the Internet may include a function of displaying a noise map by applying a geographic information system (GIS) to the noise management panel. Recently, geographic information system can receive spatial information about geography by simply attaching a module. The geographic information applied in the present invention may use the GIS module or may be used to show the noise information by inputting or showing the geographic information of an area where complaints frequently occur.

14 shows a noise map applied to a geographic information system.

In order to prepare the noise map, it is necessary to measure the noise measuring system of the present invention in several places, which can be used to create a noise map by moving multiple channels simultaneously or by moving several channels.

As described above, after acquiring the noise information of the corresponding region, as shown in FIG. 14, the region having the same noise may be displayed as geographic information of different colors for each region, and thus the noise state of the region may be compared with other regions.

Therefore, the system of the present invention can measure the noise in real time using the Internet, it can be analyzed in a variety of forms by analyzing it provides an effect that can more effectively perform the noise management.

In addition, the system of the present invention can calculate the accurate noise data for the regulation of environmental noise, it is possible to create a noise map by applying a geographic information system (GIS) to provide information on the noise to the general public more easily It provides an effect that can be done.

In addition, the system of the present invention can be configured at a lower price than conventional measuring equipment has a cost-effective effect

1 is a schematic diagram of a noise measurement system via the Internet according to an embodiment of the present invention,

2 is a detailed block diagram of the noise data transmitting apparatus of FIG. 1;

3 is a detailed block diagram of the noise data receiving apparatus of FIG. 1;

4 to 14 is a screen state in accordance with the present invention.

* Explanation of symbols for main parts of the drawings

10: microphone 20: noise data transmission device

30, 70: WLAN 40, 60: AP

50: Internet 80: noise data receiving device

90: image display unit 21: signal amplifier

22: A / D conversion unit 23, 82: control unit

24, 81: Wireless LAN I / F 25, 85: Authentication part

26: signal analysis unit 27: screen output unit

84: data analysis unit

Claims (5)

In a noise measuring system having a microphone, A signal converter for amplifying a noise signal from the microphone and converting the signal into digital data; and a wireless LAN I / F for interfacing the digital data input from the signal converter to be transmitted through a wireless Internet; A noise data transmitting device including an authentication unit for adding identification information to the identification unit, and a control unit which controls the respective components to convert the identification information and the digital data into wireless data and transmit the identification information; A noise data receiver which performs authentication through identification information received from the noise data transmitter and then converts the wireless data into data that can be analyzed; And And a video display device connected to the noise data receiver for outputting an image analysis result of the noise data. The method of claim 1, The noise data transmission device A signal analysis unit configured to receive and analyze the noise signal; And Noise measurement system via the Internet further comprises a screen output unit for outputting the analysis result of the signal analysis unit. The method according to claim 1 or 2, The noise data receiving device A wireless LAN I / F which receives the wireless data and converts it into noise data and identification information for analysis; An authentication unit for performing authentication from the identification information; A data analyzer which receives the noise data and analyzes the result in a time domain, a frequency domain, and a time-frequency domain and calculates a result; A controller configured to output an analysis result of the data analyzer to the image display unit when authentication of the authentication unit is completed; And Noise storage system via the Internet comprising a; storage unit for storing the noise data. The method of claim 3, wherein The data analysis unit includes an environmental noise management panel for evaluating the noise level and comparing the environmental standard with the environmental noise management panel to check the environmental noise level in the region. The method of claim 4, wherein The noise management system through the Internet characterized in that the noise map is displayed on the environmental noise management panel by applying a geographic information system.