KR20230130296A - Method for creating noise map based on selective use of non-directional microphone or directional microphone and apparatus using the same - Google Patents

Abstract

Disclosed are a method for generating a noise map using an non-directional microphone or a directional microphone and a device using the same. The method for generating a noise map according to the present invention comprises the steps of: collecting audio through at least one non-directional microphone or directional microphone installed in the target area; obtaining additional information by considering the type of microphone corresponding to the audio; calculating a noise level corresponding to the audio; and generating a noise map showing the noise area of the target area using the noise level and the additional information. Accordingly, the present invention may visually confirm regional noise information corresponding to the level of various units.

Description

Noise map generation method based on selective use of omni-directional microphone or directional microphone and device using the same {METHOD FOR CREATING NOISE MAP BASED ON SELECTIVE USE OF NON-DIRECTIONAL MICROPHONE OR DIRECTIONAL MICROPHONE AND APPARATUS USING THE SAME}

The present invention relates to a method of generating a noise map based on the selective use of an omni-directional microphone or a directional microphone, and to a device using the same. In particular, in the case of a directional microphone, the direction of the microphone is controlled according to the user input to collect audio from a more accurate direction. The present invention relates to a method of generating a noise map based on the selective use of an omni-directional microphone or a directional microphone capable of generating a noise map with improved accuracy, and to a device using the same.

A noise map (=noise map) is a map that visually presents the level and distribution of noise collected in each region. Recently, there has been an increasing number of cases of creating noise maps to check noise damage in each region and prepare noise measures accordingly.

In general, a noise map can be created based on audio information collected through microphones installed in the target area to measure noise damage.

Korean Patent Publication No. 10-2019-0030275, published on March 22, 2019 (Name: Big data-based real-time noise map providing system using an earphone-type sound collection device)

The purpose of the present invention is to provide a noise map that can visually confirm regional noise information corresponding to the levels of various units.

In addition, the purpose of the present invention is to effectively reduce noise by using a directional microphone that can intensively record sounds coming from a specific direction and an omnidirectional microphone (omni-directional microphone) that can uniformly record sounds coming from all directions. Creating a map.

In addition, the purpose of the present invention is to provide an interface that allows the user to move, enlarge, or reduce the position displayed on the noise map, or adjust the direction of the directional microphone located in the noise map, thereby providing a noise map corresponding to regional characteristics or user purposes. It is done.

A method of generating a noise map using an omni-directional microphone or a directional microphone according to the present invention for achieving the above object includes the steps of collecting audio through at least one omni-directional microphone or directional microphone installed in a target area; Obtaining additional information by considering the type of microphone corresponding to the audio; calculating a noise level corresponding to the audio; and generating a noise map showing the noise area of the target area using the noise level and the additional information.

At this time, the additional information may include the microphone installation location, microphone installation direction, and audio collection time.

At this time, providing the noise map to the user based on the user interface; and updating the noise map corresponding to a user command input through the user interface.

At this time, if the type of microphone corresponds to a directional microphone, the step of controlling the direction of the directional microphone based on the user command may be further included.

At this time, if the type of microphone corresponds to a directional microphone, the noise direction corresponding to the noise area may be displayed on the noise map.

At this time, the noise level may be displayed in at least one measurement unit selected by the user command among a plurality of measurement units.

At this time, the noise area may be visually displayed differently depending on the noise level.

In addition, a noise map generating device using an omnidirectional microphone or a directional microphone according to the present invention to achieve the above object collects audio through at least one omnidirectional microphone or directional microphone installed in the target area, and transmits the audio to the audio. A processor that acquires additional information in consideration of the type of corresponding microphone, calculates a noise level corresponding to the audio, and generates a noise map showing the noise area of the target area using the noise level and the additional information; and a memory that stores the audio, the additional information, and the noise map.

At this time, the additional information may include the microphone installation location, microphone installation direction, and audio collection time.

At this time, the processor may provide the noise map to the user based on the user interface and update the noise map corresponding to a user command input through the user interface.

At this time, if the type of microphone corresponds to a directional microphone, the processor may control the direction of the directional microphone based on the user command.

At this time, if the type of microphone corresponds to a directional microphone, the noise direction corresponding to the noise area may be displayed on the noise map.

At this time, the noise level may be displayed in at least one measurement unit selected by the user command among a plurality of measurement units.

At this time, the noise area may be visually displayed differently depending on the noise level.

In addition, the noise map generation system using an omnidirectional microphone or a directional microphone according to the present invention to achieve the above object collects audio through at least one omnidirectional microphone or directional microphone installed in the target area, and transmits the audio to the audio. A noise map that acquires additional information by considering the type of corresponding microphone, calculates a noise level corresponding to the audio, and generates a noise map showing the noise area of the target area using the noise level and the additional information. generating device; and a user terminal that displays the noise map to the user.

At this time, the additional information may include the microphone installation location, microphone installation direction, and audio collection time.

At this time, the noise map generating device may provide the noise map to the user based on the user interface and update the noise map corresponding to a user command input through the user interface.

At this time, if the type of microphone corresponds to a directional microphone, the noise map generating device may control the direction of the directional microphone based on the user command.

At this time, if the type of microphone corresponds to a directional microphone, the noise direction corresponding to the noise area may be displayed on the noise map.

At this time, the noise level may be displayed in at least one measurement unit selected by the user command among a plurality of measurement units.

At this time, the noise area may be visually displayed differently depending on the noise level.

According to the present invention, it is possible to provide a noise map (noise map) that allows regional noise information to be visually confirmed corresponding to the levels of various units.

In addition, the present invention efficiently creates a noise map by using a directional microphone that can intensively record sounds coming from a specific direction and an omnidirectional microphone (omni-directional microphone) that can uniformly record sounds coming from all directions. can be created.

In addition, the present invention can provide a noise map corresponding to regional characteristics or user purposes by providing an interface that allows the user to move, enlarge, or reduce the position displayed on the noise map, or adjust the direction of the directional microphone located in the noise map. there is.

Figure 1 is an operational flowchart showing a method for generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention.
Figure 2 is a block diagram showing an example of a noise map generation system using an omni-directional microphone or a directional microphone according to the present invention.
Figures 3 and 4 are diagrams showing an example of noise level measurement results according to the present invention.
Figures 5 and 6 are diagrams showing an example of a noise map showing noise levels measured using a non-directional microphone and a non-directional microphone according to the present invention.
7 to 8 are diagrams showing an example of a noise map showing a directional microphone and a noise level measured using a directional microphone according to the present invention.
Figure 9 is an operation flowchart showing the process of controlling the noise map screen according to a user command among the noise map generation method according to the present invention.
Figure 10 is an operation flowchart showing in detail the process of controlling the noise map screen according to a user command among the noise map generation method according to the present invention.
Figure 11 is an operation flowchart showing in detail the process of calculating the noise level in the noise map generation method according to the present invention.
Figure 12 is a diagram showing a noise map generating device using an omni-directional microphone or a directional microphone according to an embodiment of the present invention.

The present invention will be described in detail with reference to the attached drawings as follows. Here, repeated descriptions, known functions that may unnecessarily obscure the gist of the present invention, and detailed descriptions of configurations are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings.

Figure 1 is an operational flowchart showing a method for generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention.

Referring to FIG. 1, the method of generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention collects audio through at least one omni-directional microphone or directional microphone installed in the target area (S110). .

For example, one or multiple omnidirectional microphones can be pre-installed in the target area and collect audio corresponding to noise occurring in the target area.

As another example, one or multiple directional microphones can be pre-installed in a specific direction of the target area and collect audio corresponding to noise occurring in a specific direction of the target area. At this time, the direction of the directional microphone can be set to correspond to the value input by the operator at the time of manually installing the microphone.

At this time, omnidirectional microphones or directional microphones can be installed in areas where noise management is required.

For example, it can be installed in various areas where noise is likely to occur and noise management is required, such as around roads, within apartment complexes, parks, and construction sites.

In addition, the method of generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention acquires additional information by considering the type of microphone corresponding to the audio (S120).

At this time, the additional information may include the microphone installation location, microphone installation direction, and audio collection time.

For example, if the microphone is an omni-directional microphone, additional information including the microphone installation location or audio collection time can be obtained, and if the microphone is a directional microphone, additional information including the microphone installation direction can be obtained. can do.

At this time, the audio collection time can be obtained by setting a time interval for collecting audio from an omni-directional microphone or a directional microphone and recording the time when the audio is collected.

At this time, the microphone installation location may be acquired at the time the omni-directional microphone or directional microphone is installed, or may be obtained through a GPS sensor attached to the omni-directional microphone or directional microphone.

At this time, the microphone installation direction can be obtained through a geomagnetic sensor attached to the directional microphone.

For example, referring to the noise map generation system 200 shown in FIG. 2, the information collection unit 210 can acquire additional information including audio and microphone installation direction through a directional microphone equipped with a geomagnetic sensor. there is.

The audio and additional information obtained in this way can be stored by matching related information.

For example, the audio collected from omni-directional microphone 1, microphone installation location, and audio collection time can be matched and stored, and the audio collected from omni-directional microphone 2, microphone installation location, and audio collection time can be matched and stored. .

For another example, the audio collected from directional microphone 1, microphone installation location, microphone installation direction, and audio collection time are matched and stored, and the audio collected from directional microphone 2, microphone installation location, microphone installation direction, and audio collection are stored. You can match and save the time.

Additionally, the method of generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention calculates a noise level corresponding to audio (S130).

For example, when audio is collected as shown in FIG. 3, the noise level of the audio can be calculated corresponding to three measurement units (eq, 10, max) as shown in FIG. 4.

At this time, the measurement units of the noise level shown in FIG. 4 are examples for explanation, and various measurement units available to represent audio as a noise level can be used.

For example, referring to the noise map generation system 200 shown in FIG. 2, the noise level is calculated in the processing unit included in the information collection unit 210, and the information related to the noise level is sent to the central server 230. It can be delivered.

At this time, the noise level can be stored along with additional information matched with the audio.

For example, the noise level calculated for the audio collected from the first omni-directional microphone may be matched and stored with the audio collected from the first omni-directional microphone and additional information. Additionally, the noise level calculated for the audio collected from the second non-directional microphone may be matched and stored with the audio collected from the second non-directional microphone and additional information.

For another example, the noise level calculated for the audio collected from the first directional microphone may be matched and stored with the audio collected from the first directional microphone and additional information. Additionally, the noise level calculated for the audio collected from the second directional microphone may be matched and stored with the audio collected from the second directional microphone and additional information.

In addition, the method of generating a noise map using an omni-directional microphone or a directional microphone according to an embodiment of the present invention generates a noise map showing the noise area of the target area using the noise level and additional information (S140).

For example, when the central server 230 shown in FIG. 2 provides information collected to the map forming unit 240, the information collected by the map forming unit 240 is displayed according to the location to generate a noise map. You can.

In other words, omni-directional microphones are displayed on the map based on the microphone installation location collected from omni-directional microphone No. 1, and the noise level calculated corresponding to the audio collected from omni-directional microphone No. 1 corresponds to omni-directional microphone No. 1. It can be displayed in the noise area.

Additionally, when generating a noise map based on information collected from a directional microphone, the microphone installation direction collected from the directional microphone can also be displayed on the map.

For example, referring to Figures 5 and 6, Figure 5 shows an omni-directional microphone 510 and a noise area 511 corresponding to the omni-directional microphone 510, and Figure 6 shows the same as that shown in Figure 5. It shows a noise map generated based on information collected through the same omni-directional microphone.

First, since the omnidirectional microphone 510 shown in FIG. 5 is a microphone for measuring noise in all directions, the noise area 511 also does not have a specific direction, and the range of the noise area 511 is the omnidirectional microphone 510. It may vary depending on the performance.

At this time, the noise area may be visually displayed differently depending on the noise level.

That is, in the present invention, the noise level of the corresponding area can be indicated on the noise map through the noise area 511 shown in FIG. 5. For example, as shown in FIG. 6, the noise area is visually displayed according to the noise level on the noise map. It can be expressed to be distinguished. Therefore, when a user views a noise map, he or she can determine at a glance which areas have high noise levels.

At this time, if the type of microphone corresponds to a directional microphone, the noise direction corresponding to the noise area may be displayed on the noise map.

For example, referring to Figures 7 and 8, Figure 7 shows a directional microphone 710 and a noise area 711 corresponding to the directional microphone 710, and Figure 8 shows a directional microphone 710 as shown in Figure 7. It shows a noise map created based on information collected through the microphone.

First, since the directional microphone 710 shown in FIG. 7 is a microphone for measuring noise in a set direction, unlike the non-directional microphone 510 shown in FIG. 5, the noise area 711 of the directional microphone 710 has a specific direction. It can be seen that it has . At this time, the only difference is that the noise area 711 of the directional microphone 710 is also directional, and the range may vary depending on the performance of the directional microphone 710.

At this time, the noise area 711 caused by the directional microphone 710 may also be visually displayed according to the noise level. For example, referring to Figure 8, on the noise map, noise areas are displayed to be visually distinguished according to noise level. However, unlike Figure 6, the noise areas are displayed so that the direction in which each microphone measured noise can be known. You can see that

At this time, a noise map can be provided to the user based on the user interface.

For example, when the generation of the noise map is completed through the map forming unit 240 shown in FIG. 2, the central server 230 provides the noise map to the user terminal through the map display unit included in the control unit 220. You can. At this time, the map display unit may provide the user with access to the noise map using a separate user interface.

At this time, the noise map can be updated corresponding to the user command input through the user interface.

For example, when a user command is input through the user interface in the user terminal shown in FIG. 2, the user command can be transmitted to the central server 230 through the command input unit of the control unit 220, and the central server 230 may provide the received user command to the map forming unit 240 to update the noise map to correspond to the user command.

At this time, a user command may be input for various contents displayed on the noise map.

For example, a user command may be input to move the location of the map displayed on the noise map or to enlarge or reduce it. That is, the noise map may be provided by changing the displayed position or enlarging or reducing the display screen by a user command.

For another example, by entering a user command to select a noise area or microphone displayed on the noise map as shown in FIGS. 6 and 8, information such as coordinates, audio reception distance, noise level, and direction for the selected noise area or microphone is obtained. You can also check .

At this time, if the type of microphone corresponds to a directional microphone, the direction of the directional microphone can be controlled based on a user command.

For example, the user selects a specific directional microphone as shown in Figure 8 through the user interface and then controls the direction of the directional microphone by entering a user command to change the direction of the microphone from 'southeast' to 'east'. You may. At this time, the direction of the microphone can be controlled by adjusting the directional microphone using a servomotor or another device that performs a similar function.

At this time, the noise level may be displayed in at least one measurement unit selected by a user command among a plurality of measurement units.

For example, the noise level can be measured in three units corresponding to 'eq', '10', and 'max', as shown in Figure 4, and can be measured in only one measurement unit on the noise map through a user command. The noise level may be displayed or the noise level may be displayed in three units of measurement.

At this time, the noise level can be calculated corresponding to [Equation 1].

[Equation 1]

In [Equation 1], p ₀ may correspond to the reference pressure level (typically 20 μPa), p _a may correspond to the acquired sound pressure, t ₁ may correspond to the audio start time, and t ₂ may correspond to the audio end time (t ₁ + t).

At this time, when the noise level is displayed in a plurality of measurement units, measurement units other than the standard measurement unit among the plurality of measurement units may be selectively displayed and switched by a user command.

For example, when displaying 'eq' as the standard measurement unit among 'eq', '10', and 'max', the '10' unit and 'max' unit are selectively displayed or displayed on the noise map by user command. It can be switched to not work.

In the present invention, the user terminal used by the user to use the noise map is a device that is connected to a communication network and can execute a user interface, and is not limited to mobile communication terminals, but all information and communication devices, multimedia terminals, wired terminals, and fixed terminals. It may be a variety of terminals such as IP (Internet Protocol) terminals. In addition, the user terminals are respectively a mobile phone, PMP (Portable Multimedia Played), MID (Mobile Internet Device), smart phone, desktop, tablet PC, laptop (note book), and netbook (net). It may be a mobile terminal with various mobile communication specifications, such as a book, a personal digital assistant (PDA), a smart TV, and an information and communication device.

In addition, the user terminal can receive various information such as number and character information, and transmit signals related to setting various functions and controlling functions of the user terminal to the control unit through the input unit. Additionally, the input unit of the user terminal may be configured to include at least one of a keypad and a touchpad that generate an input signal according to the user's touch or manipulation. At this time, the input unit of the user terminal is configured in the form of a touch panel (or touch screen) together with the display unit of the user terminal and can perform input and display functions simultaneously. Additionally, the input unit of the user terminal may use any type of input means that may be developed in the future, in addition to input devices such as a keyboard, keypad, mouse, joystick, etc.

Additionally, the display unit of the user terminal may display information about a series of operation states and operation results that occur while performing functions of the user terminal. Additionally, the display unit of the user terminal may display menus of the user terminal and user data entered by the user. Here, the display unit of the user terminal is a liquid crystal display (LCD), an ultra-thin liquid crystal display (TFT-LCD, Thin Film Transistor LCD), a light emitting diode (LED), and an organic light emitting diode (OLED). LED), active organic light emitting diode (AMOLED, Active Matrix OLED), Retina Display, flexible display, and 3-dimensional display. At this time, when the display unit of the user terminal is configured in the form of a touch screen, the display unit of the user terminal may perform some or all of the functions of the input unit of the user terminal. In particular, the display unit of the user terminal according to the present invention can display information related to the execution of the noise map on the screen.

Additionally, the storage unit of the user terminal is a device for storing data, includes a main memory device and an auxiliary memory device, and can store application programs necessary for functional operation of the user terminal. The storage unit of such a user terminal may largely include a program area and a data area. Here, when the user terminal activates each function in response to the user's request, the user terminal executes the corresponding application programs under the control of the control unit to provide each function. Additionally, the storage unit of the user terminal may store information on the user terminal and a content DB that stores multiple contents. At this time, the content DB includes execution data for executing the content and attribute information about the content, and may store content usage information according to content execution. Additionally, information on the user terminal may include terminal specification information.

Additionally, the communication unit of the user terminal can perform a function for transmitting and receiving data through a network with the noise map generating device according to the present invention. Here, the communication unit of the user terminal may include an RF transmitting means for up-converting and amplifying the frequency of the transmitted signal and an RF receiving means for low-noise amplifying the received signal and down-converting the frequency. The communication unit of such a user terminal may include at least one of a wireless communication module and a wired communication module. In addition, the wireless communication module is configured to transmit and receive data according to a wireless communication method, and when the user terminal uses wireless communication, data is transmitted using any one of the wireless network communication module, wireless LAN communication module, and wireless fan communication module. Can send and receive. Additionally, the wired communication module is for transmitting and receiving data by wire. The wired communication module can connect to the network through a wire and transmit and receive data. That is, the user terminal connects to the network using a wireless communication module or a wired communication module and can transmit and receive data through the network.

Additionally, the control unit of the user terminal may be an operating system (OS) and a process device that drives each component. For example, the control unit may control the entire process of accessing the noise map generating device. When accessing the noise map generation device through a separate service application, the entire process of executing the service application can be controlled according to the user's request, and the service use request can be controlled to be transmitted to the noise map generation device at the same time as execution. At this time, it can be controlled so that the user terminal information required for user authentication is transmitted together.

In addition, a network provides a path for transmitting data between a noise map generating device and a user terminal, and is a concept that encompasses both existing networks and networks that can be developed in the future. For example, the network is a wired and wireless local area network that provides communication of various information devices within a limited area, a mobile communication network that provides communication between moving objects and between moving objects and the outside of the moving object, and a network that provides communication between earth stations using satellites. It may be a satellite communication network, a wired or wireless communication network, or a combination of two or more. Meanwhile, the network transmission method standard is not limited to existing transmission method standards and may include all transmission method standards to be developed in the future.

Through this noise map generation method, it is possible to provide a noise map that visually confirms regional noise information corresponding to the levels of various units.

In addition, a noise map can be efficiently created using a directional microphone that can intensively record sounds coming from a specific direction and an omnidirectional microphone that can evenly record sounds coming from all directions. there is.

In addition, by providing an interface that allows the user to move, enlarge, or reduce the position displayed on the noise map, or adjust the direction of the directional microphone located in the noise map, a noise map corresponding to regional characteristics or the user's purpose can be provided.

Figure 9 is an operation flowchart showing the process of controlling the noise map screen according to a user command among the noise map generation method according to the present invention.

Referring to Figure 9, among the noise map generation methods according to the present invention, the process of controlling the noise map screen according to a user command first waits until the user accesses the system through the user terminal (S910).

At this time, the user can access the system using a separate user interface.

For example, the map display unit shown in FIG. 2 may provide a separate user interface to the user terminal and allow the user to access the noise map by accessing the system through the user interface.

Afterwards, it is determined whether the user is connected (S915), and if the user is connected, a noise map screen is displayed on the user terminal through the user interface (S920).

At this time, the initial location of the noise map provided to the user may correspond to the location of the user, that is, the user terminal. For example, when a user accesses the system through a user terminal, the location of the user terminal is confirmed through a GPS sensor provided in the user terminal, and the location of the user terminal is set as the initial location to provide a noise map. .

Additionally, as a result of the determination in step S915, if the user has not connected, the user can wait until the user connects (S910).

Afterwards, it is determined whether a user command is input through the user interface (S925), and if the user command is input, the state of the noise map is changed according to the user command (S930).

At this time, a user command may be input for various contents displayed on the noise map.

For example, a user command may be input to move the location of the map displayed on the noise map or to enlarge or reduce it. That is, the noise map may be provided by changing the displayed position or enlarging or reducing the display screen by a user command.

For another example, by entering a user command to select a noise area or microphone displayed on the noise map as shown in FIGS. 6 and 8, information such as coordinates, audio reception distance, noise level, and direction for the selected noise area or microphone is obtained. You can also check .

At this time, if the type of microphone corresponds to a directional microphone, the direction of the directional microphone can be controlled based on a user command.

For example, the user selects a specific directional microphone as shown in Figure 8 through the user interface and then controls the direction of the directional microphone by entering a user command to change the direction of the microphone from 'southeast' to 'east'. You may. At this time, the direction of the microphone can be controlled by adjusting the directional microphone using a servomotor or another device that performs a similar function.

Afterwards, the noise map screen displayed on the user terminal is updated to correspond to the noise map whose state has been changed according to the user command (S940).

For example, if the location of the map is changed through a user command, the screen can be updated to show the noise map at the changed location.

For another example, when the noise map screen is enlarged or reduced through a user command, it can be updated to show the enlarged or reduced noise map screen.

For another example, if the direction of the directional microphone is changed through a user command, the noise map screen may be updated to display the noise level based on the audio collected in the changed direction.

Afterwards, it is determined whether the user has disconnected (S945), and if the user has disconnected, the system is terminated.

For example, when the user disconnects from the system by closing the user interface, it may be determined that the user disconnected.

Additionally, if the user command is not input as a result of the determination in step S925, it is determined whether the user has released the connection (S945).

If, as a result of the determination in step S945, the user has released the connection, the system is terminated.

In addition, if the user has not released the connection as a result of the determination in step S945, it is possible to continuously determine whether a user command is input through step S925.

Figure 10 is an operation flowchart showing in detail the process of controlling the noise map screen according to a user command among the noise map generation method according to the present invention.

Referring to FIG. 10, the detailed process of controlling the noise map screen according to a user command among the noise map generation methods according to the present invention first activates the function related to the microphone displayed on the noise map when the user command is received (S1010). (S1020).

At this time, a user command may be input for various contents displayed on the noise map.

For example, a user command may be input to move the location of the map displayed on the noise map or to enlarge or reduce it. That is, the noise map may be provided by changing the displayed position or enlarging or reducing the display screen by a user command.

For another example, by entering a user command to select a noise area or microphone displayed on the noise map as shown in FIGS. 6 and 8, information such as coordinates, audio reception distance, noise level, and direction for the selected noise area or microphone is obtained. You can also check .

At this time, if the type of microphone corresponds to a directional microphone, the direction of the directional microphone can be controlled based on a user command.

For example, the user selects a specific directional microphone as shown in Figure 8 through the user interface and then controls the direction of the directional microphone by entering a user command to change the direction of the microphone from 'southeast' to 'east'. You may. At this time, the direction of the microphone can be controlled by adjusting the directional microphone using a servomotor or another device that performs a similar function.

Accordingly, in step S1020, related functions are activated to allow selection of the measurement unit of the noise level displayed on the noise map, to input the location of the map displayed in the noise map, or to change the direction of the directional microphone. You can do it.

Afterwards, it is determined whether the measurement unit of the noise level has been selected through a user command (S1025).

If the measurement unit of the noise level is selected as a result of the determination in step (S1025), the measurement unit of the noise level is changed to the selected measurement unit (S1030).

Afterwards, the status change information is accumulated and stored (S1060), and it is determined whether all input user commands have been applied (S1055).

As a result of the determination in step S1055, if all the input user commands have been applied, the directional microphone is controlled or the noise map screen is updated and displayed corresponding to the status change information (S1070).

In addition, if the measurement unit of the noise level is not selected as a result of the determination in step S1025, it is determined whether the map location displayed on the noise map has been input (S1035).

If the location of the map displayed in the noise map is input as a result of the determination in step S1035, the location of the noise map is moved corresponding to the location of the input map (S1040).

Afterwards, the status change information is accumulated and stored (S1060), and it is determined whether all input user commands have been applied (S1055).

As a result of the determination in step S1055, if all the input user commands have been applied, the directional microphone is controlled or the noise map screen is updated and displayed corresponding to the status change information (S1070).

Additionally, as a result of the determination in step S1035, if the map location displayed on the noise map has not been input, it is determined whether a value for changing the direction of the directional microphone displayed on the noise map has been input (S1045).

If, as a result of the determination in step S1045, a value for changing the direction of the directional microphone displayed on the noise map has been input, the direction of the directional microphone is changed corresponding to the input value (S1050).

Afterwards, the status change information is accumulated and stored (S1060), and it is determined whether all input user commands have been applied (S1055).

As a result of the determination in step S1055, if all the input user commands have been applied, the directional microphone is controlled or the noise map screen is updated and displayed corresponding to the status change information (S1070).

In addition, if a value for changing the direction of the directional microphone displayed on the noise map is not input as a result of the determination in step S1045, it is determined whether all input user commands have been applied (S1055).

As a result of the determination in step S1055, if all the input user commands have been applied, the directional microphone is controlled or the noise map screen is updated and displayed corresponding to the status change information (S1070).

For example, when a user command is input through the user interface in the user terminal shown in FIG. 2, the user command can be transmitted to the central server 230 through the command input unit of the control unit 220, and the central server 230 may provide the received user command to the map forming unit 240 to update the noise map to correspond to the user command.

Figure 11 is an operation flowchart showing in detail the process of calculating the noise level in the noise map generation method according to the present invention.

Referring to FIG. 11, in the process of calculating the noise level among the noise map generation methods according to the present invention, first, when audio stored in the audio storage 1100 is input (S1110), the audio is divided into preset time units (S1120). .

Afterwards, it is determined whether the audio has ended (S1125), and if the audio has not ended, the divided audio is converted into Amplitude-to-dB to convert the amplitude of the audio into decibels (S1130).

Afterwards, the noise level is calculated in 'eq' and 'max' units based on the decibel value of the audio (S1140), and then the noise level is calculated in '10' units (S1150).

At this time, the noise level can be calculated corresponding to [Equation 1].

[Equation 1]

In [Equation 1], p ₀ may correspond to the reference pressure level (typically 20 μPa), p _a may correspond to the acquired sound pressure, t ₁ may correspond to the audio start time, and t ₂ may correspond to the audio end time (t ₁ + t).

Afterwards, the noise level for each of the plurality of measurement units calculated through the segmented audio is stored in each queue 1101, 1102, and 1103 (S1160), and audio segmentation for the next time period is performed (S1120).

At this time, the cues 1101, 1102, and 1103 corresponding to each measurement unit can be used to display the noise level on the noise map later.

At this time, the noise levels stored in each cue (1101, 1102, and 1103) may be stored in time order or may be stored separately for each microphone.

In addition, if the audio has ended as a result of the determination in step S1125, the next audio stored in the audio storage 1100 can be input and steps from step S1110 to step S1160 can be repeatedly performed.

Figure 12 is a diagram showing a noise map generating device using an omni-directional microphone or a directional microphone according to an embodiment of the present invention.

Referring to FIG. 12, the noise map generating device according to an embodiment of the present invention may be implemented in a computer system such as a computer-readable recording medium. As shown in Figure 12, computer system 1200 includes one or more processors 1210, memory 1230, user input device 1240, user output device 1250, and storage that communicate with each other via bus 1220. It may include (1260). Additionally, the computer system 1200 may further include a network interface 1270 connected to the network 1280. The processor 1210 may be a central processing unit or a semiconductor device that executes processing instructions stored in the memory 1230 or storage 1260. Memory 1230 and storage 1260 may be various types of volatile or non-volatile storage media. For example, memory may include ROM 1231 or RAM 1232.

Accordingly, embodiments of the present invention may be implemented as a computer-implemented method or as a non-transitory computer-readable medium on which computer-executable instructions are recorded. When computer-readable instructions are executed by a processor, the computer-readable instructions may perform a method according to at least one aspect of the present invention.

The processor 1210 collects audio through at least one omni-directional microphone or directional microphone installed in the target area.

For example, one or multiple omnidirectional microphones can be pre-installed in the target area and collect audio corresponding to noise occurring in the target area.

As another example, one or multiple directional microphones can be pre-installed in a specific direction of the target area and collect audio corresponding to noise occurring in a specific direction of the target area. At this time, the direction of the directional microphone can be set to correspond to the value input by the operator at the time of manually installing the microphone.

At this time, omnidirectional microphones or directional microphones can be installed in areas where noise management is required.

For example, it can be installed in various areas where noise is likely to occur and noise management is required, such as around roads, within apartment complexes, parks, and construction sites.

Additionally, the processor 1210 obtains additional information by considering the type of microphone corresponding to the audio.

At this time, the additional information may include the microphone installation location, microphone installation direction, and audio collection time.

For example, if the microphone is an omni-directional microphone, additional information including the microphone installation location or audio collection time can be obtained, and if the microphone is a directional microphone, additional information including the microphone installation direction can be obtained. can do.

At this time, the audio collection time can be obtained by setting a time interval for collecting audio from an omni-directional microphone or a directional microphone and recording the time when the audio is collected.

At this time, the microphone installation location may be acquired at the time the omni-directional microphone or directional microphone is installed, or may be obtained through a GPS sensor attached to the omni-directional microphone or directional microphone.

At this time, the microphone installation direction can be obtained through a geomagnetic sensor attached to the directional microphone.

For example, referring to the noise map generation system 200 shown in FIG. 2, the information collection unit 210 can acquire additional information including audio and microphone installation direction through a directional microphone equipped with a geomagnetic sensor. there is.

The audio and additional information obtained in this way can be stored by matching related information.

For example, the audio collected from omni-directional microphone 1, microphone installation location, and audio collection time can be matched and stored, and the audio collected from omni-directional microphone 2, microphone installation location, and audio collection time can be matched and stored. .

For another example, the audio collected from directional microphone 1, microphone installation location, microphone installation direction, and audio collection time are matched and stored, and the audio collected from directional microphone 2, microphone installation location, microphone installation direction, and audio collection are stored. You can match and save the time.

Additionally, processor 1210 calculates a noise level corresponding to the audio.

For example, when audio is collected as shown in FIG. 3, the noise level of the audio can be calculated corresponding to three measurement units (eq, 10, max) as shown in FIG. 4.

At this time, the measurement units of the noise level shown in FIG. 4 are examples for explanation, and various measurement units available to represent audio as a noise level can be used.

For example, referring to the noise map generation system 200 shown in FIG. 2, the noise level is calculated in the processing unit included in the information collection unit 210, and the information related to the noise level is sent to the central server 230. It can be delivered.

At this time, the noise level can be stored along with additional information matched with the audio.

For example, the noise level calculated for the audio collected from the first omni-directional microphone may be matched and stored with the audio collected from the first omni-directional microphone and additional information. Additionally, the noise level calculated for the audio collected from the second non-directional microphone may be matched and stored with the audio collected from the second non-directional microphone and additional information.

For another example, the noise level calculated for the audio collected from the first directional microphone may be matched and stored with the audio collected from the first directional microphone and additional information. Additionally, the noise level calculated for the audio collected from the second directional microphone may be matched and stored with the audio collected from the second directional microphone and additional information.

Additionally, the processor 1210 uses the noise level and additional information to generate a noise map showing the noise area of the target area.

For example, when the central server 230 shown in FIG. 2 provides information collected to the map forming unit 240, the information collected by the map forming unit 240 is displayed according to the location to generate a noise map. You can.

In other words, omni-directional microphones are displayed on the map based on the microphone installation location collected from omni-directional microphone No. 1, and the noise level calculated corresponding to the audio collected from omni-directional microphone No. 1 corresponds to omni-directional microphone No. 1. It can be displayed in the noise area.

Additionally, when generating a noise map based on information collected from a directional microphone, the microphone installation direction collected from the directional microphone can also be displayed on the map.

For example, referring to Figures 5 and 6, Figure 5 shows an omni-directional microphone 510 and a noise area 511 corresponding to the omni-directional microphone 510, and Figure 6 shows the same as that shown in Figure 5. It shows a noise map generated based on information collected through the same omni-directional microphone.

First, since the omnidirectional microphone 510 shown in FIG. 5 is a microphone for measuring noise in all directions, the noise area 511 also does not have a specific direction, and the range of the noise area 511 is the omnidirectional microphone 510. It may vary depending on the performance.

At this time, the noise area may be visually displayed differently depending on the noise level.

That is, in the present invention, the noise level of the corresponding area can be indicated on the noise map through the noise area 511 shown in FIG. 5. For example, as shown in FIG. 6, the noise area is visually displayed according to the noise level on the noise map. It can be expressed to be distinguished. Therefore, when a user views a noise map, he or she can determine at a glance which areas have high noise levels.

At this time, if the type of microphone corresponds to a directional microphone, the noise direction corresponding to the noise area may be displayed on the noise map.

For example, referring to Figures 7 and 8, Figure 7 shows a directional microphone 710 and a noise area 711 corresponding to the directional microphone 710, and Figure 8 shows a directional microphone 710 as shown in Figure 7. It shows a noise map created based on information collected through the microphone.

First, since the directional microphone 710 shown in FIG. 7 is a microphone for measuring noise in a set direction, unlike the non-directional microphone 510 shown in FIG. 5, the noise area 711 of the directional microphone 710 has a specific direction. It can be seen that it has . At this time, the only difference is that the noise area 711 of the directional microphone 710 is also directional, and the range may vary depending on the performance of the directional microphone 710.

At this time, the noise area 711 caused by the directional microphone 710 may also be visually displayed according to the noise level. For example, referring to Figure 8, on the noise map, noise areas are displayed to be visually distinguished according to noise level. However, unlike Figure 6, the noise areas are displayed so that the direction in which each microphone measured noise can be known. You can see that

At this time, a noise map can be provided to the user based on the user interface.

For example, when the generation of the noise map is completed through the map forming unit 240 shown in FIG. 2, the central server 230 provides the noise map to the user terminal through the map display unit included in the control unit 220. You can. At this time, the map display unit may provide the user with access to the noise map using a separate user interface.

At this time, the noise map can be updated corresponding to the user command input through the user interface.

For example, when a user command is input through the user interface in the user terminal shown in FIG. 2, the user command can be transmitted to the central server 230 through the command input unit of the control unit 220, and the central server 230 may provide the received user command to the map forming unit 240 to update the noise map to correspond to the user command.

At this time, a user command may be input for various contents displayed on the noise map.

For example, a user command may be input to move the location of the map displayed on the noise map or to enlarge or reduce it. That is, the noise map may be provided by changing the displayed position or enlarging or reducing the display screen by a user command.

For another example, by entering a user command to select a noise area or microphone displayed on the noise map as shown in FIGS. 6 and 8, information such as coordinates, audio reception distance, noise level, and direction for the selected noise area or microphone is obtained. You can also check .

At this time, if the type of microphone corresponds to a directional microphone, the direction of the directional microphone can be controlled based on a user command.

For example, the user selects a specific directional microphone as shown in Figure 8 through the user interface and then controls the direction of the directional microphone by entering a user command to change the direction of the microphone from 'southeast' to 'east'. You may. At this time, the direction of the microphone can be controlled by adjusting the directional microphone using a servomotor or another device that performs a similar function.

At this time, the noise level may be displayed in at least one measurement unit selected by a user command among a plurality of measurement units.

For example, the noise level can be measured in three units corresponding to 'eq', '10', and 'max', as shown in Figure 4, and can be measured in only one measurement unit on the noise map through a user command. The noise level may be displayed or the noise level may be displayed in three units of measurement.

At this time, the noise level can be calculated corresponding to [Equation 1].

[Equation 1]

In [Equation 1], p ₀ may correspond to the reference pressure level (typically 20 μPa), p _a may correspond to the acquired sound pressure, t ₁ may correspond to the audio start time, and t ₂ may correspond to the audio end time (t ₁ + t).

At this time, when the noise level is displayed in a plurality of measurement units, measurement units other than the standard measurement unit among the plurality of measurement units may be selectively displayed and switched by a user command.

For example, when displaying 'eq' as the standard measurement unit among 'eq', '10', and 'max', the '10' unit and 'max' unit are selectively displayed or displayed on the noise map by user command. It can be switched to not work.

The memory 1230 stores audio, additional information, and noise maps collected through an omni-directional microphone or a directional microphone.

Additionally, as described above, the memory 1230 stores various information generated by the noise map generating device according to an embodiment of the present invention.

Depending on the embodiment, the memory 1230 may be configured independently from the noise map generating device to support a function for generating a noise map. At this time, the memory 1230 may operate as a separate large-capacity storage and may include a control function for performing operations.

Meanwhile, the noise map generating device is equipped with a memory and can store information within the device. In one implementation, the memory is a computer-readable medium. In one implementation, the memory may be a volatile memory unit, and in another implementation, the memory may be a non-volatile memory unit. In one implementation, the storage device is a computer-readable medium. In various different implementations, the storage device may include, for example, a hard disk device, an optical disk device, or some other mass storage device.

In the present invention, the user terminal used by the user to use the noise map is a device that is connected to a communication network and can execute a user interface, and is not limited to mobile communication terminals, but all information and communication devices, multimedia terminals, wired terminals, and fixed terminals. It may be a variety of terminals such as IP (Internet Protocol) terminals. In addition, the user terminals are respectively a mobile phone, PMP (Portable Multimedia Played), MID (Mobile Internet Device), smart phone, desktop, tablet PC, laptop (note book), and netbook (net). It may be a mobile terminal with various mobile communication specifications, such as a book, a personal digital assistant (PDA), a smart TV, and an information and communication device.

In addition, the user terminal can receive various information such as number and character information, and transmit signals related to setting various functions and controlling functions of the user terminal to the control unit through the input unit. Additionally, the input unit of the user terminal may be configured to include at least one of a keypad and a touchpad that generate an input signal according to the user's touch or manipulation. At this time, the input unit of the user terminal is configured in the form of a touch panel (or touch screen) together with the display unit of the user terminal and can perform input and display functions simultaneously. Additionally, the input unit of the user terminal may use any type of input means that may be developed in the future, in addition to input devices such as a keyboard, keypad, mouse, joystick, etc.

Additionally, the display unit of the user terminal may display information about a series of operation states and operation results that occur while performing functions of the user terminal. Additionally, the display unit of the user terminal may display menus of the user terminal and user data entered by the user. Here, the display unit of the user terminal is a liquid crystal display (LCD), an ultra-thin liquid crystal display (TFT-LCD, Thin Film Transistor LCD), a light emitting diode (LED), and an organic light emitting diode (OLED). LED), active organic light emitting diode (AMOLED, Active Matrix OLED), Retina Display, flexible display, and 3-dimensional display. At this time, when the display unit of the user terminal is configured in the form of a touch screen, the display unit of the user terminal may perform some or all of the functions of the input unit of the user terminal. In particular, the display unit of the user terminal according to the present invention can display information related to the execution of the noise map on the screen.

Additionally, the storage unit of the user terminal is a device for storing data, includes a main memory device and an auxiliary memory device, and can store application programs necessary for functional operation of the user terminal. The storage unit of such a user terminal may largely include a program area and a data area. Here, when the user terminal activates each function in response to the user's request, the user terminal executes the corresponding application programs under the control of the control unit to provide each function. Additionally, the storage unit of the user terminal may store information on the user terminal and a content DB that stores multiple contents. At this time, the content DB includes execution data for executing the content and attribute information about the content, and may store content usage information according to content execution. Additionally, information on the user terminal may include terminal specification information.

Additionally, the communication unit of the user terminal can perform a function for transmitting and receiving data through a network with the noise map generating device according to the present invention. Here, the communication unit of the user terminal may include an RF transmitting means for up-converting and amplifying the frequency of the transmitted signal and an RF receiving means for low-noise amplifying the received signal and down-converting the frequency. The communication unit of such a user terminal may include at least one of a wireless communication module and a wired communication module. In addition, the wireless communication module is configured to transmit and receive data according to a wireless communication method, and when the user terminal uses wireless communication, data is transmitted using any one of the wireless network communication module, wireless LAN communication module, and wireless fan communication module. Can send and receive. Additionally, the wired communication module is for transmitting and receiving data by wire. The wired communication module can connect to the network through a wire and transmit and receive data. That is, the user terminal connects to the network using a wireless communication module or a wired communication module and can transmit and receive data through the network.

Additionally, the control unit of the user terminal may be an operating system (OS) and a process device that drives each component. For example, the control unit may control the entire process of accessing the noise map generating device. When accessing the noise map generation device through a separate service application, the entire process of executing the service application can be controlled according to the user's request, and the service use request can be controlled to be transmitted to the noise map generation device at the same time as execution. At this time, it can be controlled so that information on the user terminal required for user authentication is transmitted together.

In addition, a network provides a path for transmitting data between a noise map generating device and a user terminal, and is a concept that encompasses both existing networks and networks that can be developed in the future. For example, the network is a wired and wireless local area network that provides communication of various information devices within a limited area, a mobile communication network that provides communication between moving objects and between moving objects and the outside of the moving object, and a network that provides communication between earth stations using satellites. It may be a satellite communication network, a wired or wireless communication network, or a combination of two or more. Meanwhile, the network transmission method standard is not limited to existing transmission method standards and may include all transmission method standards to be developed in the future.

By using such a noise map generating device, it is possible to provide a noise map that visually confirms regional noise information corresponding to the level of various units.

In addition, a noise map can be efficiently created using a directional microphone that can intensively record sounds coming from a specific direction and an omnidirectional microphone that can evenly record sounds coming from all directions. there is.

In addition, by providing an interface that allows the user to move, enlarge, or reduce the position displayed on the noise map, or adjust the direction of the directional microphone located in the noise map, a noise map corresponding to regional characteristics or the user's purpose can be provided.

Implementations of the functional operations and subject matter described in this specification may be implemented as digital electronic circuits, computer software, firmware or hardware including the structures disclosed herein and their structural equivalents, or a combination of one or more of these. It is possible to implement. Implementations of the subject matter described herein may comprise one or more computer program products, that is, one or more modules of computer program instructions encoded on a tangible program storage medium for execution by or for controlling the operation of a processing system. It can be implemented.

The computer-readable medium may be a machine-readable storage device, a machine-readable storage substrate, a memory device, a composition of matter that affects a machine-readable radio wave signal, or a combination of one or more of these.

In this specification, 'system' or 'device' includes all instruments, devices, and machines for processing data, including, for example, programmable processors, computers, or multiple processors or computers. In addition to the hardware, the processing system may include code that forms an execution environment for computer programs on demand, such as code making up processor firmware, a protocol stack, a database management system, an operating system, or a combination of one or more of these. .

A computer program (also known as a program, software, software application, script, or code) may be written in any form of a programming language, including compiled, interpreted, a priori, or procedural languages, as a stand-alone program, or as a module. It can be deployed in any form, including components, subroutines, or other units suitable for use in a computer environment. Computer programs do not necessarily correspond to files in a file system. A program may be stored within a single file that serves the requested program, or within multiple interacting files (e.g., files storing one or more modules, subprograms, or portions of code), or as part of a file that holds other programs or data. (e.g., one or more scripts stored within a markup language document). The computer program may be deployed to run on a single computer or multiple computers located at one site or distributed across multiple sites and interconnected by a communications network.

Meanwhile, computer-readable media suitable for storing computer program instructions and data include semiconductor memory devices such as EPROM, EEPROM, and flash memory devices, magnetic disks such as internal hard disks and external disks, magneto-optical disks, and CDs. -Can include all forms of non-volatile memory, media, and memory devices, including ROM and DVD-ROM disks. The processor and memory may be supplemented by, or integrated into, special-purpose logic circuitry.

Implementations of the subject matter described herein may include backend components, such as a data server, middleware components, such as an application server, or, for example, a web browser or graphical user through which a user may interact with an implementation of the subject matter described herein. It may be implemented in a front-end component, such as a client computer with an interface, or in a computing system that includes any combination of one or more of such back-end, middleware, or front-end components. The components of the system may be interconnected by any form or medium of digital data communication, such as a telecommunications network.

Although this specification contains details of numerous specific implementations, these should not be construed as limitations on the scope of any invention or what may be claimed, but rather as descriptions of features that may be unique to particular embodiments of particular inventions. It must be understood. Likewise, certain features described herein in the context of individual embodiments may also be implemented in combination in a single embodiment. Conversely, various features described in the context of a single embodiment can also be implemented in multiple embodiments individually or in any suitable sub-combination. Furthermore, although features may be described as operating in a particular combination and initially claimed as such, one or more features from a claimed combination may in some cases be excluded from that combination, and the claimed combination may be a sub-combination. It can be changed to a variant of a sub-combination.

Additionally, although operations are depicted in the drawings in a specific order herein, this should not be understood to mean that such operations must be performed in the specific order or sequential order shown or that all illustrated operations must be performed to obtain desirable results. Can not be done. In certain cases, multitasking and parallel processing may be advantageous. Additionally, the separation of various system components in the above-described embodiments should not be construed as requiring such separation in all embodiments, and the described program components and systems may generally be integrated together into a single software product or packaged into multiple software products. You must understand that you can

As such, this specification is not intended to limit the invention to the specific terms presented. Accordingly, although the present invention has been described in detail with reference to the above-described examples, those skilled in the art may make modifications, changes, and variations to the examples without departing from the scope of the present invention. The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

According to the present invention, audio is collected through at least one omnidirectional microphone or directional microphone installed in the target area, additional information is obtained by considering the type of microphone corresponding to the audio, and a noise level corresponding to the audio is calculated, Using the noise level and additional information, you can create a noise map showing the noise area of the target area. Furthermore, the degree of noise damage can be measured more efficiently and accurately by generating a noise map by targeting the target area to check for noise damage through direction control of the directional microphone.

200: Noise map generation system
210: Information Collection Department
220: control unit
230: Central server
240: Map forming unit
510: omnidirectional microphone
511, 711: Audio collection area
710: Directional microphone
1100: Audio storage
1101~1103: Noise level database
1200: computer system
1210: processor
1220: Bus
1230: memory
1231: Rom
1232: RAM
1240: User input device
1250: User output device
1260: Storage
1270: Network interface
1280: network

Claims (10)

collecting audio through at least one omni-directional microphone or directional microphone installed in the target area;
Obtaining additional information by considering the type of microphone corresponding to the audio;
calculating a noise level corresponding to the audio; and
Creating a noise map showing the noise area of the target area using the noise level and the additional information.
A noise map generation method comprising: In claim 1,
The above additional information is
A method for generating a noise map, comprising: microphone installation location, microphone installation direction, and audio collection time. In claim 1,
providing the noise map to a user based on a user interface; and
Updating the noise map corresponding to a user command input through the user interface.
A noise map generation method further comprising: In claim 3,
If the type of microphone corresponds to a directional microphone, the method further includes controlling the direction of the directional microphone based on the user command. In claim 1,
If the type of microphone corresponds to a directional microphone, a noise direction corresponding to the noise area is displayed on the noise map. In claim 3,
The noise level is
A method of generating a noise map, characterized in that it is displayed as at least one measurement unit selected by the user command among a plurality of measurement units. In claim 1,
The noise area is
A method of generating a noise map, characterized in that the noise map is visually displayed differently depending on the noise level. Collect audio through at least one omni-directional microphone or directional microphone installed in the target area, obtain additional information considering the type of microphone corresponding to the audio, calculate a noise level corresponding to the audio, and calculate the noise level. a processor that generates a noise map showing the noise area of the target area using the level and the additional information; and
Memory for storing the audio, the additional information, and the noise map
A noise map generating device comprising: In claim 8,
The above additional information is
A noise map generating device comprising a microphone installation location, microphone installation direction, and audio collection time. In claim 8,
The processor is
The noise map is provided to the user based on the user interface, and the noise map is updated in accordance with a user command input through the user interface. If the type of microphone corresponds to a directional microphone, the noise map is updated based on the user command. A noise map generating device, characterized in that controlling the direction of the directional microphone.

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