KR101751696B1 - Device and method for noise test by distance information - Google Patents

Abstract

A noise measuring method and apparatus using distance information are disclosed. The method and apparatus for measuring noise using distance information includes the steps of receiving noise measurement values measured from a noise measurement sensor and storing the noise measurement values in a database, checking whether there is a noise information calculation request from an external terminal, The method comprising: collecting position information of a beacon receiver closest to the external terminal; calculating a distance between the beacon receiver and the noise measurement sensor based on the collected position information and the position value of the previously stored noise measurement sensor Calculating a noise sensed by the beacon receiver based on the noise measurement value and the distance, storing the bass noise and the connection record of the external terminal in a database, and storing the noise measurement value and the bass noise on a display unit And displaying the information.

Description

TECHNICAL FIELD [0001] The present invention relates to a method and an apparatus for measuring noise using distance information,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise measurement method and apparatus using distance information, and more particularly, to a noise measurement method and apparatus using distance information indicating bodily noises corresponding to distance information.

In order to inform the noise of a construction site, a conventional electric signboard capable of measuring noise and a noise measurement method thereof (Korean Patent Laid-Open No. 10-2009-0023884) have been disclosed. However, since the prior art simply measures noise in a noise source, Noise can not be measured and displayed at a distance from the source.

Therefore, there is a need for research on an apparatus and a method for measuring and displaying a noise sensed at a long distance as well as a noise measurement at a noise source.

The present invention provides a method and an apparatus for measuring noise using distance information for calculating a distance from a noise source by acquiring position information using a GPS function of a beacon receiver and a smartphone to display a noise experienced by the user.

The present invention provides a method and an apparatus for measuring noise using distance information for measuring a bodily noises using distance information at any position by using a noise attenuation formula according to distance

The method for measuring noise using distance information according to an embodiment of the present invention includes receiving noise measurement values measured from a noise measurement sensor and storing the measured noise values in a database, checking whether there is a noise information calculation request from an external terminal, Acquiring location information of a beacon receiver closest to the external terminal when there is a request for noise information calculation, acquiring location information of a beacon receiver closest to the external terminal, Calculating a noise of the beacon receiver based on the noise measurement value and the distance, storing the bass noise and the connection record of the external terminal in a database, and calculating the noise measurement value and the noise measurement value, And displaying the bodily noises on the display unit.

According to an aspect of the present invention, the step of calculating the bass noise may include calculating a bass noise of a single layer using a distance damping effect equation when the position of the external terminal is located inside a single-story building, Deriving the maximum bass noise floor according to a maximum bass noise floor deriving equation for calculating a layer having the highest bass noise when the position of the maximum bass noise floor is located inside the multi-storey building, Calculating a noise, and determining a bodily sensation noise of the maximum bodily-sound-absorbing layer as a bodily-sensible noise by substituting the bodily-sensible noise that is increased by 20% with the bodily-sensible noise.

According to an aspect of the present invention, the distance attenuation effect equation can be expressed by the following equation (1).

[Equation 1]

here,

는 외부단말에서의 단층 체감소음,

A single-layer bodily sensation noise at an external terminal,

는 소음측정센서에서 측정된 소음측정값,

Is a noise measurement value measured by a noise measurement sensor,

은 소음측정센서 및 외부단말 사이의 거리를 각각 의미함.

Means the distance between the noise measurement sensor and the external terminal, respectively.

According to an aspect of the present invention, the maximum bodily-sound-absorbing layer derivation equation can be expressed by the following equation (2).

&Quot; (2) "

here,

는 외부단말에서의 복층 체감소음,

Layered bodily noises at an external terminal,

은 소음측정센서 및 외부단말 사이의 거리를 각각 의미함.

Means the distance between the noise measurement sensor and the external terminal, respectively.

The apparatus for measuring noise using distance information according to an embodiment of the present invention includes a beacon receiver installed at a preset location, connected to an external terminal through Bluetooth, and having unique ID information, a hardness value and a latitude value, A noise storage unit for receiving the noise measurement value measured by the noise measurement sensor and storing the noise measurement value in a database, a noise inquiry confirmation unit for checking whether there is a noise information calculation request from an external terminal, A distance calculator for calculating a distance between the external terminal and the noise measurement sensor based on the collected position information and the previously stored position value of the noise measurement sensor; A bodily sensation noise calculator for calculating bodily sensation noise of the beacon receiver based on the distance; It may include a display control unit for displaying the part.

According to an embodiment of the present invention, a method for measuring noise using distance information for calculating a distance from a noise source by acquiring position information using a GPS function of a beacon receiver and a smartphone to display a noise experienced by a user, Device is provided.

According to an embodiment of the present invention, there is provided a method and an apparatus for measuring noise using distance information that measures bodily noises using distance information at any position by using a noise attenuation formula according to the distance

FIG. 1 is a flowchart illustrating a noise measurement method using distance information according to an embodiment of the present invention. Referring to FIG.
2 is a diagram illustrating a step of calculating a bounce noise in a noise measurement method using distance information according to an embodiment of the present invention.
FIG. 3 is a graph showing the measured values of the noise perceived by the floor.
4 is a diagram illustrating a configuration of a noise measurement apparatus using distance information according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

FIG. 1 is a flowchart illustrating a noise measurement method using distance information according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 1, a noise measurement method using distance information includes a step (10) of receiving a noise measurement value measured from a noise measurement sensor and storing the noise measurement value in a database, a step of checking whether there is a noise information calculation request from an external terminal A step (30) of collecting position information of a beacon receiver closest to the external terminal if there is a request for noise information calculation, a step (30) of acquiring position information of a beacon receiver closest to the external terminal, (50) calculating a noise of the beacon receiver based on the noise measurement value and the distance, storing the connection noise of the external terminal in the database (60), and calculating a noise And displaying the measurement value and the bodily noises on the display unit (70).

First, in step 10, a noise measurement value measured from a noise measurement sensor is received and stored in a database, a noise measurement value is collected from a noise measurement sensor installed in a noise source, and the collected noise measurement value is input to the noise storage unit in real time Can be stored.

In step 20 of checking whether there is a noise information calculation request from an external terminal, an external terminal such as a smart phone can check whether there is an inquiry about noise information.

For example, the smartphone application checks in real time whether the smartphone application requested a noise information inquiry to a noise reduction calculator (module for calculating noise reduction). If there is an inquiry request (Yes in 20 of FIG. 2) The ID list is compared with the ID entered in the currently-viewed smart phone, and if it matches, it is judged that the ID authentication is performed.

Thereafter, when the ID authentication is completed, the smartphone application can receive the real-time noise measurement value, bodily noises at the current position, and the like from the bodily noise calculation unit. When the smartphone does not request the inquiry (No in (20) of FIG. 1), the noise measurement value measured from the noise measurement sensor is input again and the process returns to step (10).

In the step 30 of collecting the location information of the beacon receiver closest to the external terminal, if there is an authenticated noise information calculation request (Yes in 20 of FIG. 2), the beacon receiver Can be collected.

That is, when the ID verification of the smartphone application is completed in step 20, the beacon receiver closest to the smartphone receives the beacon receiver location information (e.g., GPS information-longitude value and latitude value) To the bodily noise calculation unit.

In the step 40 of calculating the distance between the beacon receiver and the noise measurement sensor based on the collected position information and the position value of the pre-stored noise measurement sensor, the hardness value and the latitude value of the collected beacon receiver are compared with the hardness value of the noise measurement sensor, The linear distance between the beacon receiver and the noise measurement sensor can be calculated by comparing it to the latitude value.

In the step 50 of calculating the beating noise of the beacon receiver based on the noise measurement value and the distance, a bodily noise at a distance from the noise generating place can be calculated. That is, when the distance from the noise source is increased, the sensible noise is different from the noise of the noise source. Therefore, the sensory noise at the present position is calculated by calculating the difference. Hereinafter, the step of calculating the bass noises will be described in more detail with reference to FIG.

2 is a diagram illustrating a step 50 of calculating a bounce noise in a noise measurement method using distance information according to an embodiment of the present invention.

Referring to FIG. 2, in step 50, the calculated distance may be calculated by substituting the distance calculated in step 40 into the distance attenuation effect formula in which the noise measurement value is decreased according to the distance.

If the location of the external terminal is located inside a single-story building, apply the single-distance distance attenuation equation (step 51) to calculate the noise of the beacon (the beacon receiver and the noise measurement The distance between the sensors can be substituted).

On the other hand, when the location of the external terminal is located inside the multi-storey building, the maximum bass noise floor can be derived according to the maximum bass noise floor deriving equation for calculating the highest bass noises in step 52, (Step 53) of calculating a perceptible noise of the first floor using the distance attenuation effect formula and multiplying the perceptible noise of the first floor by 20% to determine the perceptible noise of the maximum perceptible noise floor 54), it is possible to calculate the perceived noise of the maximum bass noise floor.

Here, the bodily sensation noise of the first floor is multiplied by 20% to derive the bodily sensation noise of the maximum bodily sensation noise layer, because the change of the bodily noise according to the height occurs, which will be described in more detail with reference to FIG.

 FIG. 3 is a graph showing measured values of the noise perceived by the floor.

Referring to FIG. 3, a number of experiments have been conducted to investigate the correlation between the first floor and the maximum noise reduction layer. According to the experimental results, the maximum bodily noise floor is derived as a 20% increase of the first floor bodily noise.

Therefore, by multiplying 20% of the perceived noise of the first floor, the perceived noise of the maximum perceived noise floor can be derived.

 The above-described single-layer distance attenuation effect equation can be expressed by the following equation (1).

[Equation 1]

here,

는 외부단말에서의 단층 체감소음,

A single-layer bodily sensation noise at an external terminal,

는 소음측정센서에서 측정된 소음측정값,

Is a noise measurement value measured by a noise measurement sensor,

은 소음측정센서 및 외부단말 사이의 거리를 의미할 수 있다.

May refer to the distance between the noise measurement sensor and the external terminal.

The maximum bodily-sound-absorbing layer derivation equation described above can be expressed by the following equation (2).

&Quot; (2) "

here,

는 최대 체감소음층,

The maximum bodily noise floor,

은 소음측정센서 및 비콘 수신기 사이의 거리를 의미할 수 있다.

May refer to the distance between the noise measurement sensor and the beacon receiver.

In step 60, in which the sensible noise and the connection record of the external terminal are stored in the database

It can be used as evidence when data of noise management analysis and noise perception are problematic by storing connection record of external terminal and noise perceived.

For example, by analyzing noise measurement values and sensory noises stored in real time, it is possible to check the noise level at which time, when a certain construction is carried out, and at what time, to avoid noise construction such as making noise at dawn or at night And when a protest comes in, it is possible to use the noise measurement value and the bust noise at the time of the protest as objective judgment data.

In step 70 of displaying the noise measurement value and the bust noise on the display unit, the noise measurement value and the bust noise can be displayed in real time through a display unit such as a smart phone or a display board.

For example, the bass noise calculated in the step 50 of calculating the bass noise of the beacon receiver based on the noise measurement value and the distance may be transmitted to the smartphone application so as to be confirmed in real time, and displayed on the electric sign board, Can be checked.

Hereinafter, the configuration of the noise measurement apparatus utilizing the distance information will be described in more detail.

4 is a diagram illustrating a configuration of a noise measurement apparatus using distance information according to an embodiment of the present invention.

4, the apparatus for measuring noise using distance information includes a beacon receiver 100, a noise storage unit 200, a noise inquiry confirmation unit 300, an external terminal position collecting unit 400, a distance calculating unit 500 ), A bodily sensation noise calculation unit 600, and a display control unit 700.

The beacon receiver 100 is installed at a preset location, is connected to an external terminal through Bluetooth, and may include unique ID information, a longitude value, and a latitude value.

For example, before the construction starts, the beacon receiver 100 derives the maximum bass noise level using Equation 2 for each building before the noise measurement sensor measures the noise, Respectively.

When the beacon receiver 100 approaches a smartphone within a certain distance, the beacon receiver 100 performs ID authentication unique to the smartphone using the Bluetooth function of the smartphone. After that, if the previously registered IDs match in the storage server, the ID authentication is completed and the latitude and longitude of the beacon receiver can be collected.

The noise storage unit 200 may receive the noise measurement value measured from the noise measurement sensor and store the noise measurement value in a database.

The noise storage unit 200 is connected to the noise measurement sensor, receives noise measurement values measured by the noise measurement sensor, stores the noise measurement values in the database, and transmits the noise measurement values to the distance calculation unit 500 have.

The noise inquiry confirmation unit 300 can confirm whether there is a noise information calculation request from an external terminal.

The noise inquiry confirmation unit 300 is connected to the beacon reception unit 100 in real time. When the smartphone connected to the beacon reception unit 100 inquires about the noise information, the ID list stored in the storage server and the ID of the currently viewed smart phone The ID authentication is performed. After the ID authentication is completed, the real-time noise measurement value, the bass noise at the current position, and the like can be retrieved, and the external terminal position collecting unit 400 connected to the noise inquiry confirmation unit 300 can collect the position.

The external terminal location collecting unit 400 may collect location information of the beacon receiving unit 100 when there is a noise information calculation request.

More specifically, when the noise inquiry confirmation unit 300 receives an instruction to collect the position, it can collect the longitude value and the latitude value of the beacon receiver 100 after locating the beacon receiver 100 closest to the smartphone .

The distance calculating unit 500 may calculate the distance between the beacon receiver 100 and the noise measurement sensor based on the collected position information and the position value of the previously stored noise measurement sensor.

It is possible to calculate the distance between the beacon receiver 100 and the noise measurement sensor by comparing the hardness value and the latitude value of the smartphone with the hardness value and the latitude value of the noise measurement sensor and calculate the distance value to the bodily noise calculation unit 600 .

The bodily noise calculation unit 600 may calculate the bodily noise of the beacon receiver 100 based on the noise measurement value and the distance.

The beacon receiver 100 closest to the smartphone using the distance value and the noise measurement value received from the distance calculator 400 in the step 50 of calculating the beep noise of the beacon receiver based on the noise measurement value and the distance, ) Can be calculated.

Hereinafter, an operation procedure of the noise measurement method and apparatus using distance information will be described in more detail.

Before installing the initial noise measurement device, the beacon receiver 100 attaches a single layer directly to a single apartment in a neighboring apartment or a house, and in case of a multi-layer, a maximum bass noise layer using Equation 2 is obtained and attached to the maximum bass noise floor.

The noise measurement value measured by the noise measurement sensor is received and stored in a database (10). The noise measurement value is measured in a noise source using a noise measurement sensor and transmitted to the noise storage unit (200) The distance measuring unit 200 receives the transmitted noise measurement values and stores the received noise measurement values in a database, and transmits the hardness value and the latitude value of the noise measurement sensor to the distance calculation unit 500.

In the step 20 of checking whether there is a noise information calculation request from an external terminal, the noise inquiry confirmation unit 300 checks in real time whether the smart phone connected to the beacon receiver 100 inquires about noise information, And confirms the ID authentication by comparing the ID list stored in the smart phone with the ID of the smart phone that is currently being viewed. After the ID authentication, the external terminal position collecting unit 400 can collect the position by inquiring the real-time noise measurement value and the bust noise at the current position in the smartphone.

In a case where there is a request for calculating the noise information, in the step (30) of collecting the location information of the beacon receiver closest to the external terminal when there is the request for calculating the noise information, the external terminal location collecting unit (400) The beacon collecting unit 100 to receive the latitude and longitude values of the beacon collecting unit 100 and transmit the location information to the distance calculating unit 500. [

In the step 40 of calculating the distance between the beacon receiver and the noise measurement sensor based on the collected position information and the position value of the pre-stored noise measurement sensor, the distance calculation unit 500 calculates the distance from the noise measurement unit 200, The latitude value and the hardness value of the beacon collector 100 are received and the distance between the latitude value and the latitude value of the beacon collector 100 is received by the external terminal position collector 400 and transmitted to the bodily noise calculation unit 600 do.

In the step 50 of calculating the bass noise of the beacon receiver based on the noise measurement value and the distance, the bass noise calculator 600 substitutes the distance received from the distance calculator 500 into Equation 1, Value.

In the case of a single layer, a bodily noisiness value is calculated in a step 51 of calculating the bodily noises of a single layer using [Expression 1].

In the case of a multi-layered structure, the step of deriving the maximum bodily-sound-absorbing layer includes calculating a maximum bodily-sound-absorbing layer derived from the equation 2 in step 52 and calculating a bodily- ), A sensed-noise value is calculated by multiplying the sensed-noise value by 20% in step 54, which is a multi-layered sensation-based noise.

The reason for calculating the 20% increase is that the bass noise of the maximum bass noise layer is 20% higher than that of the first layer.

After calculating the calculated values for the single layer and the multiple layer, the calculation result is transmitted to the display control unit 700 and the noise storage unit 200, and the connection record of the smartphone is also transmitted to the noise storage unit 200.

In the step 60 of storing the bust noise and the connection record of the external terminal in the database, the noise storage unit 200 stores the sensory noise value received from the bust noise calculation unit 600 and the connection record of the smartphone in the database .

The reason for storing the sensory noise value and the connection history of the smartphone is based on the sensory noise value and the location and access time of the beacon receiver 100 in the connection record of the smartphone at that time due to reasons such as litigation or inspection It is for submission.

In step 70 of displaying the noise measurement value and the bust noise on the display unit, the bass noise value and the noise measurement value received from the bass noise calculator 600 in the display control unit 700 are transmitted to a display medium such as a smart phone or a display board Output noise and noise measurement values.

In addition, the maximum bodily noisiness layer of the building in which the external terminal is currently located can be further displayed.

As described above, according to the embodiment of the present invention, the beacon receiver and the smartphone work together to acquire the positional information, thereby calculating the distance from the noise source, A measuring method and an apparatus can be provided.

Also, in one embodiment of the present invention, by using the noise attenuation calculation formula according to distance, it is possible to provide a noise measurement method and apparatus using distance information for calculating actual noise to be sensed by utilizing distance information at any position.

In addition, the noise measurement method using distance information according to an embodiment of the present invention may be recorded in a computer readable medium including program instructions for performing various computer-implemented operations. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The media may be program instructions that are specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. Various modifications and variations are possible in light of the above teachings. Accordingly, it is to be understood that one embodiment of the present invention should be understood only by the appended claims, and all equivalent or equivalent variations thereof are included in the scope of the present invention.

100: Beacon receiver
200: Noise storage unit
300: Noise inquiry confirmation unit
400: External terminal position collecting unit
500: Distance calculation unit
600: bodily noise calculation unit
700:

Claims (5)

Receiving a measured noise measurement value from the noise measurement sensor and storing the measured noise measurement value in a database;
Checking whether there is a noise information calculation request from an external terminal;
Collecting location information of a beacon receiver closest to the external terminal when the noise information calculation request is received;
Calculating a distance between the beacon receiver and the noise measurement sensor based on the collected position information and a previously stored position value of the noise measurement sensor;
Calculating a bounce noise of the beacon receiver based on the noise measurement value and the distance;
Storing the bounce noise and the connection record of the external terminal in a database; And
Displaying the noise measurement value and the bodily noises on a display unit;
Wherein the noise information is obtained by using the distance information. The method according to claim 1,
The step of calculating the bodily noises comprises:
Calculating a bodily sensation noise of a single layer by using a distance attenuation effect equation when the position of the external terminal is located inside a single-story building;
Deriving the maximum bass noise floor according to a maximum bass noise floor derivation equation for calculating the highest bass noise level when the location of the external terminal is located inside a multi-story building;
Calculating a bodily sensation noise of the first layer using the distance attenuation effect equation; And
Determining a bodily sensation noise of the maximum bodily-sound-absorbing layer as a bodily-sensible noise by substituting a bodily-sensible noise that is 20% greater than the bodily-sensible noise;
Wherein the noise information is obtained by using the distance information. 3. The method of claim 2,
Wherein the distance attenuation effect expression is expressed by the following equation (1). ≪ EMI ID = 1.0 >
[Equation 1]

here,

A single-layer bodily sensation noise at an external terminal,

Is a noise measurement value measured by a noise measurement sensor,

Distance between the noise measurement sensor and the external terminal
Respectively. 3. The method of claim 2,
Wherein the maximum bodily-sound-absorbing layer derivation expression is expressed by the following equation (2).
&Quot; (2) "

here,

Layered bodily noises at an external terminal,

Distance between the noise measurement sensor and the external terminal
Respectively. A beacon receiver installed at a preset location and connected to an external terminal through Bluetooth, the beacon receiver including unique ID information, a longitude value and a latitude value;
A noise storage unit for receiving measured noise measurement values from the noise measurement sensor and storing the measured noise values in a database;
A noise inquiry confirmation unit for checking whether there is a noise information calculation request from an external terminal;
An external terminal location collector for collecting location information of the external terminal when the noise information calculation request is received;
A distance calculating unit for calculating a distance between the external terminal and the noise measurement sensor based on the collected position information and the previously stored position value of the noise measurement sensor;
A bodily noise calculation unit for calculating a bodily sensation noise of the beacon receiver based on the noise measurement value and the distance; And
A display control unit for displaying the noise measurement value and the bodily noises on a display unit;
Wherein the distance measuring unit measures a distance between the sound source and the sound source.

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