JP2018040603A - Noise management device, electric apparatus, noise management system, noise management method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To present information that indicates a section in which a noise generation source exists and a propagation state of the noise to surroundings.SOLUTION: A noise management device 2 comprises: a noise information acquisition unit 11 for acquiring noise information that includes the feature of noise detected in each section of a building constituted from two or more sections and a noise level that indicates the magnitude of noise; a noise section determination unit 12 for determining, when a noise whose feature matches is detected in two or more sections on the basis of the noise information acquired by the noise information acquisition unit 11, that a section where a noise of maximum noise level among noises whose features match is detected, is a noise source section, and that sections other than the noise source section among sections where noises whose features match are detected, are noise destination sections that are destinations of noise propagation; a noise propagation information generation unit 15 for generating noise propagation information that includes the noise source section determined by the noise section determination unit 12 and noise levels in noise destination sections; and an output unit 32 for outputting the noise propagation information generated by the noise propagation information generation unit 15.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a noise management device, an electric device, a noise management system, a noise management method, and a program.

  In recent years, home network systems in which various electrical devices in a house are connected to a network have become widespread in ordinary homes. Accordingly, for example, a home network system that displays a floor plan of a house on a tablet terminal or a television and displays an operation state of an electric device on the floor plan of the house has been put into practical use. Development of a system in which a home network system alerts a user based on detection values of various sensors is also in progress.

  For example, Patent Document 1 discloses a system in which a home network system alerts a user based on a detection value of a sound sensor. The system disclosed in Patent Document 1 appropriately sets a specified value for determining noise in accordance with a user's life situation and time zone, and when the magnitude of noise measured in each section exceeds this specified value, The user is notified that noise is occurring.

JP 2011-163037 A

  The system disclosed in Patent Document 1 measures the magnitude of noise in each section, and notifies the user of the occurrence of noise when noise exceeding a specified value is measured. However, this system reports the occurrence of noise based only on the magnitude of noise in each section without grasping the state of noise propagation between the sections. Therefore, this system has a problem that even in a section where no noise source is present, if a large noise generated in an adjacent room propagates to the section, the generation of noise is notified to the user. Further, if noise is not propagated to the surrounding sections, there is no need to notify the surrounding sections because no trouble is caused by noise. Nevertheless, this system also has a problem that even if no noise is propagated to the surrounding area, if noise exceeding the specified value is measured in that area, the user is notified of the occurrence of the noise. .

  The present invention has been made in view of the circumstances as described above, and is a noise management device, an electrical device, and the like that can present information indicating a section where a noise generation source exists and a propagation state of the noise to the surroundings. It aims at providing a noise management system, a noise management method, and a program.

  In order to achieve the above object, a noise management device according to the present invention includes a noise information acquisition unit, a noise section determination unit, a noise propagation information generation unit, and an output unit. The noise information acquisition unit acquires noise information including the characteristics of noise detected in each section of the building composed of two or more sections and a noise level indicating the magnitude of the noise. Based on the noise information acquired by the noise information acquisition unit, the noise division determination unit has the highest noise level of the noises having the same characteristics when noises with the same noise characteristics are detected in two or more sections. The section where the noise is detected is determined as the noise source section where the noise generation source exists, and the section other than the noise source section among the sections where the noise having the same noise characteristics is detected is the noise propagation destination. It is determined as the noise destination section. The noise propagation information generation unit generates noise propagation information including the noise source zone determined by the noise zone determination unit and the noise level in the noise destination zone determined by the noise zone determination unit. The output unit outputs the noise propagation information generated by the noise propagation information generation unit.

  According to the present invention, by knowing the propagation state of noise, it is possible to present information indicating the section where the noise generation source exists and the propagation state of the noise to the surroundings.

The figure which shows the system structural example of the noise management system which concerns on Embodiment 1 of this invention. Functional block diagram of the noise management apparatus according to the first embodiment (A) The figure which shows the example of data memorize | stored in the image information storage part which concerns on Embodiment 1 (b) The figure which shows the example of an image of the noise mesh A memorize | stored in the image information storage part which concerns on Embodiment 1 (C) The figure which shows the example of the image of the noise mesh B memorize | stored in the image information storage part which concerns on Embodiment 1 (d) The image of the noise mesh C memorize | stored in the image information storage part which concerns on Embodiment 1 The figure which shows an example (e) The figure which shows the example of an image of the noise mesh D memorize | stored in the image information storage part which concerns on Embodiment 1 (f) The musical note memorize | stored in the image information storage part which concerns on Embodiment 1 (G) The figure which shows the example of an image of the note mark B memorize | stored in the image information storage part which concerns on Embodiment 1 (h) The image which memorize | stores in the image information storage part which concerns on Embodiment 1 The figure which shows the image example of the arrow A which is done (i) execution The figure which shows the example of an image of the floor plan A memorize | stored in the image information storage part which concerns on Embodiment 1 (A) The figure which shows the example of data memorize | stored in the building information storage part which concerns on Embodiment 1 (b) The figure which shows an example of the noise notification screen which concerns on Embodiment 1 (A) The figure which shows another example of the data memorize | stored in the building information storage part which concerns on Embodiment 1 (b) The figure which shows another example of the noise notification screen which concerns on Embodiment 1. The figure which shows the hardware structural example of the information terminal device which concerns on Embodiment 1. FIG. The figure which shows the hardware structural example of the television which concerns on Embodiment 1. FIG. The figure which shows the hardware structural example of the HEMS (Home Energy Management System) remote control which concerns on Embodiment 1. FIG. Functional block diagram of a display device according to Embodiment 1 Main flowchart of the entire noise management process according to the first embodiment The flowchart of the noise division determination process which concerns on Embodiment 1. The figure which shows an example of the noise source noise destination information which concerns on Embodiment 1. Flow chart of noise source grasping process according to Embodiment 1 Flowchart of noise propagation information generation processing according to Embodiment 1 The figure which shows the example with two noise sources by the noise source noise destination information which concerns on Embodiment 1. (A) A diagram showing an example in which there are two noise sources on the noise notification screen according to the first embodiment and the type of noise is represented by shading (b) there are two noise sources on the noise notification screen according to the first embodiment The figure which shows the example which shows the kind of noise with mark (A) The figure which shows the example in the case where there is a noise source in the external section in the noise source noise destination information according to the first embodiment (b) In the case where there is a noise source in the external section on the noise notification screen according to the first embodiment The figure which shows an example (c) The figure which shows another example in case a noise source exists in an external division with the noise notification screen which concerns on Embodiment 1. The figure which shows the system configuration example of the noise management system which concerns on the modification of Embodiment 1 of this invention. The figure which shows the system configuration example of the noise management system which concerns on the 2nd modification of Embodiment 1 of this invention. The figure which shows the system configuration example of the noise management system which concerns on Embodiment 2 of this invention. Functional block diagram of an electric device according to Embodiment 2 Functional block diagram of a noise management apparatus according to Embodiment 2 The figure which shows the example of data memorize | stored in the building information storage part which concerns on Embodiment 2. The figure which shows the example of data memorize | stored in the electric equipment information storage part which concerns on Embodiment 2. Main flowchart of the entire noise management process according to the second embodiment Flowchart of control information generation processing according to Embodiment 2 Flowchart of control information reception processing according to Embodiment 2 The figure which shows the system structural example of the noise management system which concerns on Embodiment 3 of this invention. Functional block diagram of an electric device according to Embodiment 3 The figure which shows the example of data memorize | stored in the alerting | reporting part control information storage part which concerns on Embodiment 3. FIG. Main flowchart of the entire noise management process according to the third embodiment Flowchart of second noise propagation information generation processing according to Embodiment 3 Flowchart of noise propagation information reception processing according to Embodiment 3 The figure which shows the hardware structural example of the noise management apparatus which concerns on this invention The figure which shows the hardware structural example of the electric equipment which concerns on this invention

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In this case, the same or corresponding parts are denoted by the same reference numerals in the drawings.

(Embodiment 1)
As shown in FIG. 1, the noise management system 1 according to Embodiment 1 includes a noise management device 2 provided in a building 100 such as a house, an apartment house, or a commercial facility, a network 4 in the building 100, and a display device 5. And sound sensors 9A, 9B, 9C, 9D, and 9E (hereinafter collectively referred to as sound sensor 9). In the noise management system 1, the sound sensor 9 detects noise in each section, the noise management device 2 grasps the noise propagation status based on the magnitude and characteristics of the noise, and the display device 5 displays the noise source and noise. This system displays a screen showing the propagation status.

  The sound sensor 9 includes a device that detects sound and a communication interface, and transmits the waveform data of the detected sound to the noise management device 2. The device for detecting sound is composed of, for example, a microphone. The communication interface is arbitrary as long as it is an interface that can communicate with the noise management device 2 via the network 4. The sound sensor 9 is disposed in each of the two or more sections constituting the building 100, detects sound in each section, and transmits the detected sound waveform data to the noise management apparatus 2 via the communication interface and the network 4. Send. In the example shown in FIG. 1, the building 100 includes sections 1 to 4, sound sensors 9 </ b> A to 9 </ b> D are disposed in each section, and a sound sensor 9 </ b> E is disposed in the external section 1 outside the building 100. However, the number of partitions is not limited to this. In addition, the outside of the building 100 is not divided into sections, but for convenience, a place where the sound sensor 9 is disposed is treated as an external section. In the example shown in FIG. 1, in order to consider the possibility of noise generated outside the building 100 being propagated to the compartments in the building 100, the sound sensor 9 </ b> E is also arranged in the external compartment 1 outside the building 100. ing. However, when the possibility that the sound generated outside propagates into the building 100 can be ignored, it is not necessary to arrange the sound sensor 9 outside.

  The noise management device 2, the sound sensor 9, and the display device 5 are connected to the network 4 in the building 100. The noise management device 2 can communicate with the sound sensor 9 and the display device 5 via the network 4. A communication standard used in the network 4 can be any communication standard. For example, a wired communication standard such as Ethernet (registered trademark), HDMI (registered trademark) (High-Definition Multimedia Interface), USB (Universal Serial Bus), or RS-232C may be used, or wireless LAN (Local Area Network). ), Bluetooth (registered trademark), and ZigBee (registered trademark). Moreover, it is not necessary to limit to the general-purpose communication standard as described above, and an original standard may be used. Since the sound sensor 9 and the display device 5 do not need to communicate directly, the network 4 between the noise management device 2 and the sound sensor 9 and the network 4 between the noise management device 2 and the display device 5 May not be connected.

  The display device 5 includes a display device such as a liquid crystal display and an organic EL (Electro-Luminescence) display, and a communication interface, and displays noise propagation information received from the noise management device 2 on a screen. As the form of the display device 5, three types of information terminal device 6 such as a tablet / smartphone, a television 7, and a HEMS remote controller 8 can be considered. The installation location of the display device 5 is arbitrary, but when the building 100 is an apartment house, it is desirable to install it in a section other than the residential section, such as a manager's room.

  The noise management device 2 acquires the waveform data of the sound detected by the sound sensor 9 via the network 4. Then, by comparing the noise levels in a plurality of sections having the same noise characteristics, noise propagation information indicating the section where the noise generation source exists and the propagation state of the noise to the surroundings is generated. Then, the generated noise propagation information is output to the display device 5 via the network 4.

  As shown in FIG. 2, the noise management device 2 includes a control unit 10, a storage unit 20, a communication unit 31, and an output unit 32 as functional configurations.

  The control unit 10 includes a CPU (Central Processing Unit), and executes each program (noise information acquisition unit 11, noise section determination unit 12, position acquisition unit 13, image acquisition unit) by executing a program stored in the storage unit 20. 14, the function of the noise propagation information generation unit 15) is realized.

  The noise information acquisition unit 11 receives the waveform data of the sound detected by the sound sensor 9 arranged in each section via the network 4, and based on the received waveform data, the noise characteristics and the noise level in each section Get noise information including The noise level is an index indicating the level of noise and is, for example, the sound pressure level of noise expressed in dB as a unit. The sound pressure level can be obtained from the waveform data of the noise, but it is desirable to obtain it by correcting each frequency component obtained from the frequency spectrum of the noise with the A characteristic. The A characteristic is a frequency weighting characteristic in consideration of human hearing, and is defined in JIS C 1502-1990 (ordinary sound level meter). Also, the value of the noise level may not be the value of the sound pressure level itself, but may be a value obtained by adding the duration of noise and the frequency of occurrence to the sound pressure level. The noise characteristics are data used as an index for determining whether or not the noise sources are the same. A method for determining whether or not the sources of noise are the same will be described later. For example, the frequency spectrum of noise can also be a feature of noise. Further, the noise information acquisition unit 11 stores noise information including the acquired noise characteristics and noise levels in each section in the noise information storage unit 23.

  The noise zone determination unit 12 determines a zone where noise is generated based on the noise characteristics and the noise level included in the noise information acquired by the noise information acquisition unit 11.

  The position acquisition unit 13 determines a display position on the screen displayed on the section where each sound sensor 9 is arranged and the display device 5 which is necessary when the noise propagation information generation unit 15 generates the noise propagation information. It acquires from the building information storage part 22 mentioned later.

  The image acquisition unit 14 acquires, from the image information storage unit 21 (to be described later), an image of a building and an image indicating noise that are required when the noise propagation information generation unit 15 (to be described later) generates noise propagation information.

  The noise propagation information generation unit 15 includes a noise generation source based on the noise generation block determined by the noise block determination unit 12, the display position acquired by the position acquisition unit 13, and the image acquired by the image acquisition unit 14. Noise propagation information that is information indicating the propagation status of the section and its noise to the surroundings is generated.

  The storage unit 20 includes a ROM (Read Only Memory) and a RAM (Random Access Memory) as hardware. The ROM stores a program executed by the CPU of the control unit 10 and data necessary for executing the program in advance. The RAM stores data created or changed during program execution. Functionally, the storage unit 20 includes an image information storage unit 21, a building information storage unit 22, a noise information storage unit 23, and a noise propagation information storage unit 24.

  As shown in FIG. 3A, the image information storage unit 21 stores a shaded image and a note mark image indicating noise, an arrow mark image indicating a noise propagation direction, and a floor plan image of the building. Each of these images is assigned an image ID (Identifier) for uniquely identifying the image. FIG. 3A shows a shaded image indicating noise. For example, the image ID is # 0001, the image type is shaded, the image name is noise mesh A, the image size is 60 × 60, and the image data is FIG. This indicates that the image information storage unit 21 stores the image information that is the image data indicated by (). The image data of the shaded image may not be data of the image itself, but may be information indicating the type of shading such as “horizontal line”, “vertical line”, “oblique line”, “dot”. Further, the noise may be indicated by color instead of shading. In this case, the image information storage unit 21 stores color information instead of the shading image information.

  FIG. 3A shows a note mark image indicating noise. For example, the image ID is # 0011, the image type is a mark, the image name is a note mark A, the image size is 50 × 80, and the image data is shown in FIG. This shows that the image information storage unit 21 stores the image information that is the image data shown in f).

  Further, FIG. 3A shows a floor plan image of a building, for example, image ID # 1001, image type is base, image name is floor plan A, image size is 300 × 210, and image data is FIG. This shows that the image information storage unit 21 stores the image information that is the image data shown in the image data shown in i). The floor plan image of the building is used as a base image representing the positional relationship of a plurality of sections constituting the building 100 when the noise management device 2 generates noise propagation information. As will be described later, the noise propagation information is screen data of a noise notification screen displayed on the display device 5, and the noise notification screen is a screen in which an image indicating noise is superimposed on a base image.

  As shown in FIG. 4A, the building information storage unit 22 stores base image information, the number of sound sensors 9, and sound sensor arrangement information corresponding to the number. The base image information is three pieces of information including “base ID”, “base position”, and “base size”. “Base ID” indicates an image ID of the base image. “Base position” indicates the display position of the base image on the noise notification screen. “Base size” indicates the display size of the base image on the noise notification screen. For example, in the example shown in FIG. 4A, since the “base ID” is # 1001, when the noise management device 2 generates the noise propagation information, the image information storage shown in FIG. With reference to part 21, “floor plan A” is selected as the base image. Then, the noise for displaying the noise notification screen arranged at the coordinates (0,600) at the “base position” by expanding and contracting the image size of the “floor plan A” to 900 × 600 at the “base size”. The noise management device 2 generates the propagation information.

  Next, in the example shown in FIG. 4A, since the “number of sound sensors” indicating the number of sound sensors 9 is 7, the building information storage unit 22 also stores 7 pieces of sound sensor arrangement information. doing. The sound sensor arrangement information is four pieces of information including “sound sensor ID”, “section No.”, “section center coordinates”, and “image ID”.

  “Sound sensor ID” indicates an ID for uniquely identifying the sound sensor 9. For example, when the network 4 to which the sound sensor 9 is connected is an Ethernet (registered trademark) or a wireless LAN and TCP / IP (Transmission Control Protocol / Internet Protocol) is used as a communication protocol, a MAC ( Media Access Control) address can be used. In the example shown in FIG. 4A, numbers 1 to 7 are assigned as sound sensor IDs.

  “Section No.” indicates in which section of the building 100 the sound sensor 9 is arranged. In the data example shown in FIG. 4A, the sound sensors 9 with the sound sensor ID = 1 to 4 are arranged in the sections 1 to 4 in the building 100, and the sound sensor 9 with the sound sensor ID = 5 to 7 is the building 100. It shows that it is arrange | positioned at the external external divisions 1-3.

  “Division center coordinates” indicate the display position of the division on the noise notification screen. The image of the mark indicating the noise and the image of the arrow are arranged on the screen on the basis of the coordinates, and need not be the exact center of the area indicating the section on the screen.

  “Image ID” is an ID of an image indicating noise to be displayed on the noise notification screen when the section where the sound sensor 9 is arranged is a section where a noise generation source exists. This corresponds to the image ID of the image stored in the image information storage unit 21 shown in FIG.

  FIG. 4A shows an example in which the sound sensors 9 with the sound sensor IDs 5, 6, and 7 are arranged in a partition outside the building 100. Normally, the noise management device 2 notifies the section where the noise source is present and the noise propagation status of the noise generated inside the building 100. Therefore, the noise generated outside the building 100 Does not notify that the noise is occurring. In this case, the building information storage unit 22 does not store the “image ID” corresponding to the external section as shown in FIG. If the noise management device 2 generates noise outside the building 100, as well as the noise generated inside the building 100, it notifies the section where the noise generating source exists and the propagation status of the noise. In this case, the building information storage unit 22 stores an “image ID” corresponding to the external section.

  Since the building 100 in which each user resides is different, the floor plan image data stored in the image information storage unit 21, the base image information stored in the building information storage unit 22, the number of sound sensors 9, and the sound The sensor arrangement information is different for each user. Therefore, when the noise management device 2 is shipped from the factory or sold at a store, the image information storage unit 21 and the building information storage unit 22 are based on the information of the building 100 in which the user of the noise management device 2 lives. It is desirable to store the necessary data for shipment or sale. Also, noise management is performed on application software that allows the image information storage unit 21 and the building information storage unit 22 to store the results of editing the floor plan image data, the number of sound sensors 9 and the sound sensor arrangement information on the screen by the user. You may make it incorporate in the apparatus 2. FIG.

  The noise information storage unit 23 illustrated in FIG. 2 stores the noise information acquired by the noise information acquisition unit 11, the section where the noise generation source is determined by the noise section determination unit 12, and the propagation destination section of the noise. The characteristics and noise level of noise in each section, and the section where the noise generation source exists and the section where the noise is transmitted can be acquired by referring to the noise information storage unit 23.

  The noise propagation information storage unit 24 stores noise propagation information generated by the noise propagation information generation unit 15. When the noise propagation information is output to the display device 5 via the output unit 32 described later, the display device 5 displays the noise propagation information on the display device included in the display device 5. The screen on which the noise propagation information is displayed on the display device included in the display device 5 is a screen that makes it easy for the user to know the section where the noise source is present and the section where the noise is transmitted, and is called a noise notification screen. Therefore, the noise propagation information stored in the noise propagation information storage unit 24 is also screen data of a noise notification screen displayed on the display device 5. It is arbitrary what kind of data structure the noise propagation information storage unit 24 stores the screen data of the noise notification screen, but for example, it can be stored in a data structure similar to a so-called video RAM. When storing in the same data structure as the video RAM, the noise propagation information storage unit 24 corresponds to the storage address and the display coordinates on the screen of the display device 5, and the value of the data to be written and the display device 5 on the screen The screen data of the noise notification screen is stored in a data structure corresponding to color and brightness.

  The communication unit 31 is a communication interface for receiving noise waveform data from the sound sensor 9. The communication unit 31 may be any communication interface as long as it can communicate with the sound sensor 9. The communication unit 31 may be a communication interface compatible with a wired communication standard such as Ethernet (registered trademark), or may be a communication interface compatible with a wireless communication standard such as a wireless LAN or Bluetooth (registered trademark).

  The output unit 32 is a communication interface for the noise management device 2 to communicate with the display device 5. For example, the output unit 32 is a communication interface for outputting the screen data of the noise notification screen stored in the noise propagation information storage unit 24 to the display device 5. The output unit 32 is also a communication interface for the noise management device 2 to receive data transmitted from the display device 5. The output unit 32 may be any communication interface as long as it can communicate with the display device 5. The output unit 32 may be a communication interface compatible with a wired communication standard such as Ethernet (registered trademark), or may be a communication interface compatible with a wireless communication standard such as a wireless LAN or Bluetooth (registered trademark). If the communication standard used when the noise management device 2 communicates with the sound sensor 9 and the communication standard used when the noise management device 2 communicates with the display device 5 are the same, the communication unit 31 can also serve as the output unit 32. The output unit 32 may not be provided. When the display device 5 is the television 7, the output unit 32 may include an HDMI (registered trademark) interface. In any case, the display device 5 includes a communication interface that can communicate with the output unit 32.

  Now that the description of each unit included in the noise management device 2 has been completed, a supplementary description of the noise notification screen displayed on the display device 5 will be given next. The display device 5 displays a noise notification screen using the noise propagation information received from the noise management device 2. With the noise notification screen, an image showing a section where a noise generation source exists and an image showing a propagation state of the noise are superimposed on a floor plan representing a positional relationship between a plurality of sections constituting the building 100. It is a screen. The first example of the noise notification screen shows the level of noise in light and dark. In this case, the display device 5 displays darkly the section where the noise source is present, displays the brightness of the section where the noise is transmitted, slightly dark according to the magnitude of the noise after propagation, A section that does not propagate to the section and does not propagate noise in other sections is displayed brightly.

  For example, the content of the image information storage unit 21 is the content shown in FIG. 3A and the content of the building information storage unit 22 is the content shown in FIG. 4A, and noise is generated in the section 1 with the sound sensor ID = 1. Suppose that the noise propagates to the section 2 of the sound sensor ID = 2 and does not propagate to other sections. In this case, the display device 5 displays a screen as shown in FIG. 4B as a noise notification screen indicating the noise generation status in the building 100. This figure shows that the building 100 is a two-story building, and the section 3 and the section 4 are arranged adjacent to each other on the first floor, and the section 1 and the section 2 are arranged adjacent to each other on the second floor. The display device 5 displays the section 1 where the noise generation source is present darkly by shading, displays the section 2 where the noise is propagating from the section 1 slightly darkly by shading with low density, and the noise is displayed in other sections. The section 3 and the section 4 in which the noise from other sections does not propagate to the area and the noise from other sections does not propagate are displayed brightly without shading.

  The display device 5 may display the noise propagation status in shades of color instead of displaying the light propagation in shades. For example, by displaying a section where noise propagating to other sections is generated in dark red, and displaying a section where the noise is propagated in red with a density corresponding to the noise level detected in that section, The section where the noise generation source exists and the state of propagation of the noise to the surroundings may be indicated. In addition, the display device 5 may display the noise propagation status with a symbol indicating noise, instead of displaying the propagation status of the noise with light and dark or shades of color. Further, the display device 5 may display an arrow mark having a starting point of an arrow in a section where a noise generation source exists and an end point of an arrow in a section where the noise is transmitted. For example, FIG. 5A is an example of the stored contents of the building information storage unit 22 when a noise notification screen is generated with a symbol indicating noise. Similarly to the above, it is assumed that noise is generated in the section 1 with the sound sensor ID = 1, the noise propagates to the section 2 with the sound sensor ID = 2, and does not propagate to other sections. In this case, the display device 5 displays, for example, a screen as shown in FIG. 5B as the noise notification screen. FIG. 5B is a display example when the noise generated in the section 1 is propagated to the section 2, and the display device 5 indicates the noise level detected in the sections 1 and 2 as the size of the note mark. The arrow mark from the section where noise is generated to the section where the noise is transmitted is displayed.

  Next, the configuration of the display device 5 will be described. As the form of the display device 5, three kinds of forms such as the information terminal device 6, the television 7, and the HEMS remote controller 8 can be considered. These display devices 5 are equipped with a noise display function for each device, and can display a noise notification screen as shown in FIG. 4B or 5B by the noise display function. it can. How to realize the noise display function is arbitrary. For example, the display device 5 can realize a noise display function by installing a noise display application which is application software for displaying the screen data of the noise notification screen transmitted from the noise management device 2 on the display device. Further, when the HDMI (registered trademark) input terminal of the display device 5 and the output unit 32 of the noise management device 2 are directly connected, the display device 5 performs noise switching by switching to HDMI (registered trademark) input. A display function can be realized.

  As shown in FIG. 6, the information terminal device 6 as the display device 5 according to the first embodiment includes a processor 640, a memory 650, an interface 661, a display panel 662, a touch panel 663, and a base station interface 664 as shown in FIG. Is provided.

  The processor 640 is a CPU that executes a program stored in the memory 650. The memory 650 includes a ROM and a RAM, and stores various programs such as basic software, communication software, and a noise display application of the information terminal device 6. The processor 640 executes the program stored in the memory 650, thereby realizing the function of the information terminal device 6.

  The interface 661 is a communication interface for communicating with other devices. The interface 661 is a wireless interface such as a wireless LAN or Bluetooth (registered trademark) for communicating with the noise management device 2 via the network 4, for example. The base station interface 664 is a communication interface for the information terminal device 6 to communicate with a base station of a mobile phone in order to perform a call and short message transmission / reception.

  The display panel 662 is a display device such as a liquid crystal display or an organic EL display. The touch panel 663 is an input device that acquires user operations on the information terminal device 6. When the user instructs activation of the noise display application via the touch panel 663, the processor 640 activates the noise display application and transmits to the noise management device 2 that the noise display is instructed via the interface 661. Then, the noise management device 2 generates noise propagation information and outputs it to the display device 5. The information terminal device 6 receives the noise propagation information output from the noise management device 2 via the interface 661 and displays it on the display panel 662. Then, a screen as shown in FIG. 4B or 5B is displayed on the display panel 662.

  Then, when the user ends the noise display application or switches to the screen of another application, the processor 640 transmits that the instruction of noise display is ended to the noise management device 2 via the interface 661, and displays the noise display. finish.

  Next, the television 7 as the display device 5 according to Embodiment 1 will be described. As an example of the hardware configuration, the television 7 includes a processor 740, a memory 750, an interface 761, a display panel 762, an operation button / remote control interface 763, and a tuner 764, as shown in FIG. The processor 740 and the display panel 762 are the same as the processor 640 and the display panel 662 included in the information terminal device 6, and thus description thereof is omitted.

  The memory 750 includes a ROM and a RAM, and stores various programs such as basic software of the television 7, television viewing software, and a noise display application. The function of the television 7 is realized by the processor 740 executing the program stored in the memory 750.

  The interface 761 is a communication interface for communicating with other devices. The interface 761 is a wireless interface such as a wireless LAN or Bluetooth (registered trademark) for communicating with the noise management apparatus 2 via the network 4, for example. The interface 761 is preferably compatible with ECHONET (Energy Conservation & Homecare Network) Lite and can receive a character display instruction in accordance with the ECHONET Lite display class specification. The interface 761 may include an interface connected to the noise management device 2 via HDMI (registered trademark). ECHONET Lite is a type of ECHONET protocol that is a communication protocol for realizing a smart house standardized by the ECHONET consortium.

  The operation button / remote control interface 763 is an input device that acquires user operations on the television 7. The tuner 764 is a tuner device that receives a television broadcast. When the user presses a noise display button among the buttons provided in the operation button / remote control interface 763, the processor 740 switches the screen displayed on the display panel 762 to a screen for noise display, and the noise management device via the interface 761. 2 indicates that the noise display is instructed. Then, the noise management device 2 generates noise propagation information and outputs it to the display device 5. The television 7 receives the noise propagation information output from the noise management device 2 via the interface 761 and displays it on the display panel 762. Then, a screen as shown in FIG. 4B or FIG. 5B is displayed on the display panel 762.

  Then, when the user presses the noise display end button among the buttons provided in the operation button / remote control interface 763, the processor 740 of the television 7 completes the noise display instruction to the noise management device 2 via the interface 761. To end the noise display and return to the original TV viewing screen display. Note that switching to the noise display screen is not limited to full-screen switching, and noise display may be performed on a sub-screen on the screen being viewed. For example, a “full-screen noise display button” and a “sub-screen noise display button” are provided on the operation button / remote control interface 763, and the processor 740 of the television 7 displays the entire screen as a noise when the “full-screen noise display button” is pressed. If the “sub-screen noise display button” is pressed, noise may be displayed on the sub-screen.

  Next, the HEMS remote controller 8 as the display device 5 according to the first embodiment will be described. The HEMS remote controller 8 displays the status of various electric devices installed in the building 100. Further, the HEMS remote controller 8 controls the electric device according to the state of various electric devices or user operation input. As shown in FIG. 8, the HEMS remote controller 8 includes a processor 840, a memory 850, an interface 861, a display panel 862, and a touch panel 863, as shown in FIG. Note that the touch panel 863 may be a touch pad. The display panel 862 is the same as the display panel 662 included in the information terminal device 6, and thus description thereof is omitted.

  The processor 840 is a CPU that executes a program stored in the memory 850. The memory 850 includes a ROM and a RAM, and stores various programs such as basic software of the HEMS remote controller 8, electrical device status display software, electrical device control software, and a noise display application. The processor 840 executes the program stored in the memory 850, thereby realizing the function of the HEMS remote controller 8. For example, the processor 840 decodes a user operation acquired by the touch panel 863, generates a control signal for the electrical device, and transmits the generated control signal to the electrical device via the interface 861.

  The interface 861 is a communication interface for communicating with other devices. The interface 861 is a wireless interface such as a wireless LAN or Bluetooth (registered trademark) for communicating with the noise management device 2 via the network 4, for example. The interface 861 is preferably compatible with ECHONET Lite and can receive a character display instruction in accordance with the ECHONET Lite display class specification.

  The touch panel 863 acquires a user operation on the HEMS remote controller 8. When the user touches the noise display button from the remote control menu displayed on the display panel 862 via the touch panel 863, the processor 840 activates the noise display application, and the noise display is displayed on the noise management device 2 via the interface 861. Send what was instructed. Then, the noise management device 2 generates noise propagation information and outputs it to the display device 5. The HEMS remote controller 8 receives the noise propagation information output from the noise management device 2 via the interface 861 and displays it on the display panel 862. Then, a screen as shown in FIG. 4B or FIG. 5B is displayed on the display panel 862.

  Then, when the user presses the noise display end button from the remote control menu, the processor 840 transmits the end of the noise display instruction to the noise management device 2 via the interface 861, ends the noise display, and returns to the original HEMS. The screen display of the remote control 8 is restored.

  The hardware configuration of the display device 5 according to the first embodiment has been described above. Since the functional block configuration of the display device 5 can be handled in common, the functional block configuration will be described. As illustrated in FIG. 9, the display device 5 includes a control unit 40, a storage unit 50, a communication unit 61, a display unit 62, and an input unit 63 as functional blocks.

  The control unit 40 includes a CPU, and realizes the function of the display device 5 by executing a program stored in the storage unit 50. The storage unit 50 includes a RAM and a ROM, and stores various necessary programs and necessary data such as basic software of the display device 5, software for executing each function, and a noise display application. The communication unit 61 includes a communication device and is a communication interface that communicates with the noise management device 2 via the network 4. The display device 5 receives the noise propagation information transmitted from the output unit 32 of the noise management device 2 via the communication unit 61. In addition, the display device 5 transmits information on a user input operation acquired by the input unit 63 described later to the noise management device 2 via the communication unit 61. The display unit 62 includes a display device and displays a noise notification screen based on the noise propagation information received via the communication unit 61. The input unit 63 includes an input device and acquires a user input operation on the display device 5.

  Next, the main flow of the entire noise management process performed by the noise management apparatus 2 will be described with reference to FIG. When the noise management device 2 is activated, this main flow starts. Further, from this main flow, the noise section determination process, the noise source grasping process, and the noise propagation information generation process are sequentially called as sub-processes. Details of the noise section determination process, the noise source grasping process, and the noise propagation information generation process will be sequentially described after the description of the main flow.

  Now, the main flow process will be described with reference to FIG. First, the control part 10 calls a noise division determination process (step S11). Next, the control unit 10 calls a noise source grasping process (step S12). Next, the control part 10 calls a noise propagation information generation process (step S13), and returns to step S11. With the above main flow, the noise management device 2 repeats a series of processes of acquiring noise information, generating noise propagation information, and outputting the noise propagation information to the display device 5.

  Next, the noise zone determination process will be described. The noise zone determination process is a process for determining the relationship between a zone where a noise generation source exists (hereinafter referred to as “noise source zone”) and a noise propagation destination zone (hereinafter referred to as “noise destination zone”). FIG. 11 is a flowchart of the noise section determination process of the noise management device 2. Here, it is assumed that there are n sound sensors 9 and the number of sections is n. It should be noted that the external compartments of the building 100 are also handled by being numbered with numbers following the internal compartments of the building 100. For example, it is assumed that there are four sections 1 to 4 in the building 100 and the sound sensor 9 is disposed in each section. The sound sensors 9 are also arranged at three locations outside the building 100. In this case, there are three external compartments 1 to 3 as the external compartments of the building 100, and the external compartments 1 to 3 are treated as the compartments 5 to 7. In this case, n = 7.

  And the noise management apparatus 2 shall set the threshold value for determining whether the noise has generate | occur | produced in each division. Note that “noise generation” in the noise zone determination processing includes both cases where noise is generated due to the presence of a noise generation source and cases where noise propagated from other zones is detected. As the threshold for determining whether noise is occurring, one value used in common for all the sections may be set, or a value suitable for the section may be set for each section. When setting a value for every division, the building information storage part 22 may memorize | store the threshold value set to each division. Here, it is assumed that the building information storage unit 22 stores Th [i] as the threshold value of the section i for each section. And if the noise level detected in a certain division is larger than a threshold value, the noise division determination part 12 will determine with the noise having generate | occur | produced in the division.

  As the threshold value, for example, a standard value notified for environmental standards related to noise based on the provisions of Article 16, Paragraph 1 of the Environmental Basic Law can be adopted. Specifically, in an area provided exclusively as a residence, the daytime reference value is 55 dB or less and the nighttime reference value is 45 dB or less. For example, the threshold value is set to 55 dB or 45 dB depending on the time. Can do. Since the control unit 10 has a clock function (not shown), the time can be determined, and the threshold value can be changed according to the time. In this way, when the noise management device 2 sets the threshold value of the noise level, it is assumed that the person in the section is inconvenienced by noise. Can be determined.

  In the present invention, it is assumed that even when a plurality of noises are generated at the same time, the noises can be detected by the sound sensor 9 without being mixed. For example, this assumption is satisfied if there is only one source of noise occurring at a certain time. In addition, even if multiple noises are generated by multiple noise sources, for example, there is a sound barrier between the areas where each noise propagates, so that the sound is blocked and no other noise propagates. This assumption is met. Even with such a premise, the present invention functions without problems when there are few sources of noise and when the building 100 is appropriately soundproofed.

  If there is a sound that is constantly generated in the section, the detection value of the sound generated by the sound sensor 9 is sampled for a predetermined time for each section and stored in the storage unit 20 in advance. You may remember it. The certain time is preferably a time corresponding to a certain cycle of a human life pattern, such as one day or one week. And the noise information acquisition part 11 handles the value which reduced the sampled value of the division from the detection value by the sound sensor 9 arrange | positioned in each division as the waveform data of the noise in the division. By this processing, the noise management device 2 can suppress the influence of the sound that is constantly generated in the section. As an example of the sound that is constantly generated in the compartment, there are operating sounds of an air conditioner and a refrigerator.

  Now, the noise section determination processing of the noise management device 2 will be described with reference to FIG. This process is a process in which the noise section determination unit 12 determines a noise source section by comparing the characteristics of noise with other sections for each section. First, the noise information acquisition unit 11 receives the waveform data of noise transmitted from each sound sensor 9 disposed in each of the sections 1 to n via the communication unit 31. Then, based on the received noise waveform data, noise information including noise characteristics and noise levels in each section is acquired (step S101) and stored in the noise information storage unit 23.

  Then, the noise zone determination unit 12 initializes a variable i for designating a zone that is a candidate noise source zone to 1 (step S102). Next, the noise section determination unit 12 determines whether or not the noise level in the section i is larger than the threshold value Th [i] (step S103). If the noise level in the section i is equal to or less than the threshold Th [i] (step S103; No), it is determined that the section i is not a noise source section, and the process proceeds to step S111. If the noise level in the section i is larger than the threshold Th [i] (step S103; Yes), the noise section determination unit 12 initializes a variable j that designates a section that is a candidate for the noise destination section to 1 ( Step S104).

  Next, the noise zone determination unit 12 determines whether i and j are different values (step S105). If i and j are the same value (step S105; No), the process proceeds to step S109. If i and j are different values (step S105; Yes), the noise section determination unit 12 determines whether or not the noise characteristics in the section [i] match the noise characteristics in the section [j]. Is determined (step S106). Details of the noise feature comparison method for determining whether or not the noise features match will be described later. If the noise characteristics in the section [i] and the noise characteristics in the section [j] do not match (step S106; No), the process proceeds to step S109. If the noise characteristics in the section [i] match the noise characteristics in the section [j] (step S106; Yes), the noise section determination unit 12 determines that the noise level in the section [i] is the section [j. ] And whether the noise level in the section [j] is larger than the threshold value Th [j] (step S107).

  If the noise level in the section [i] is less than or equal to the noise level in the section [j], or if the noise level in the section [j] is less than or equal to the threshold Th [j] (step S107; No), step The process proceeds to S109. If the noise level in the section [i] is greater than the noise level in the section [j] and the noise level in the section [j] is greater than the threshold Th [j] (step S107; Yes), the noise section determination The unit 12 determines that the section [i] is the noise source section and the section [j] is the noise destination section, and the noise source noise destination information indicating the relationship between the noise source section and the noise destination section as shown in FIG. Is stored in the noise information storage unit 23 (step S108).

  Next, the noise zone determination unit 12 sets the variable j to the next value (step S109), and determines whether j is greater than n (step S110). If j is n or less (step S110; No), the process returns to step S105. If j is larger than n (step S110; Yes), the variable i is set to the next value (step S111). And the noise division determination part 12 determines whether i became larger than n (step S112). If i is n or less (step S112; No), the process returns to step S103, and if i is larger than n (step S112; Yes), the process is terminated.

  The flow of the noise section determination processing has been described above. Here, the following three methods will be described as the noise feature comparison method in step S106.

  First, the first method will be described. This is a method of comparing the frequency spectra of noise in consideration of the attenuation characteristics. Since sound has different attenuation characteristics depending on the frequency, the frequency spectrum of noise is calculated by, for example, FFT (Fast Fourier Transform), and the frequency spectrum corrected by the attenuation characteristic for each frequency is compared in each section. Since the attenuation characteristic varies depending on the structure of the building, the building information storage unit 22 stores the attenuation characteristic between other sections for each section. For example, the frequency spectrum of the noise 1 detected in the section 1 is calculated, and the value obtained by multiplying the attenuation characteristics between the sections 1 and 2 matches the frequency spectrum of the noise 2 detected in the section 2 or a reference. If the difference is equal to or less than the threshold value, the noise section determination unit 12 determines that the noise characteristics of the section 1 and the noise characteristics of the section 2 match. As the threshold value used as a reference here, for example, 1/10 of the maximum value of the frequency spectrum can be used. Note that the attenuation characteristic also changes depending on the temperature and humidity. Therefore, the air temperature sensor and the humidity sensor are disposed in the section where the sound sensor 9 is disposed, and the noise section determination unit 12 acquires the temperature and humidity of each section, and the attenuation between the sections based on the temperature and humidity. The characteristics may be corrected.

  The second method is a method of comparing temporal fluctuation patterns of noise power in consideration of the A characteristic. Here, a value obtained by correcting all frequency components obtained from the frequency spectrum of noise with the A characteristic and integrating the frequency is defined as “noise power”. The noise zone determination unit 12 first obtains a temporal variation pattern of “noise power” calculated from the waveform data of noise detected in each zone. This temporal variation pattern can be obtained, for example, as a time interval from the maximum value of the noise power to the next maximum value. If the temporal fluctuation pattern of the noise power in a certain two sections matches or does not reach the reference threshold value or less, the noise section determination unit 12 determines that the noise characteristics in the two sections match. To do. Here, as the threshold value used as a reference, for example, a value that is twice the sampling cycle time of sound detection by the sound sensor 9 can be used.

  The third method is a method of comparing only low frequencies that are difficult to attenuate among noise components. The noise division determination unit 12 normalizes the frequency component obtained from the frequency spectrum of the noise by the above “noise power”, excludes a frequency component higher than the reference frequency, and uses a frequency component equal to or lower than the reference frequency. When each level is within the reference threshold range, it is determined that the noise characteristics match. Here, since the reference frequency depends on the attenuation characteristic, it differs depending on the structure of the building. Therefore, the building information storage unit 22 stores attenuation characteristics between other sections for each section. Then, a frequency having an attenuation rate larger than α times the attenuation rate of the lowest frequency in the frequency spectrum of the noise to be compared is set as a reference frequency. Here, α times is set to 1 dB, for example. The threshold value used as a reference can be determined to be 2α times, for example.

  As described above, three methods for comparing noise characteristics have been described. If the noise source is in the same area as the noise propagation area, the noise characteristics detected in each area are the same. Any method can be used as long as it can be determined, not limited to the above-described comparison method.

  Next, the noise source grasping process called and executed in step S12 of the main flow shown in FIG. 10 will be described with reference to FIG. The noise source noise destination information stored in the noise information storage unit 23 by the noise zone determination process described above is based on the noise source zone determined based on the noise characteristics and the noise level only between the two zones. Therefore, there is a possibility that the section determined as the noise source section here is not a true noise source section but a section in which noise in another noise source section has been propagated. In such a case, the noise source grasping process is for deleting the erroneously determined noise source section from the noise source noise destination information and leaving only the true noise source section in the noise source noise destination information. It is processing.

  First, the noise section determination unit 12 of the noise management device 2 acquires the noise source noise destination information stored in the noise information storage unit 23 (step S201). Then, a variable i for designating a section for determining whether or not it is a true noise source section is initialized to 1 (step S202), and a variable j for designating a noise destination section is also initialized to 1 (step S203). Next, the noise zone determination unit 12 determines whether i and j are different values (step S204). If i and j are the same value (step S204; No), the process proceeds to step S212. If i and j are different values (step S204; Yes), the noise section determination unit 12 determines that the section [i] is the noise source section and the section [j] is the noise source noise destination information acquired in step S201. It is determined whether or not it is a noise destination section (step S205).

  If the section [i] is not the noise source section and the section [j] is not the noise destination section (step S205; No), the process proceeds to step S212. If the section [i] is a noise source section and the section [j] is a noise destination section (step S205; Yes), the noise section determination unit 12 sets a variable k for designating a candidate for a true noise source section to 1. (Step S206). And the noise division determination part 12 determines whether k and i are different values (step S207). If k and i are the same value (step S207; No), the process proceeds to step S210. If k and i are different values (step S207; Yes), the noise section determination unit 12 determines that the section [k] is the noise source section and the section [i] is the noise source noise destination information acquired in step S201. It is determined whether or not it is a noise destination section (step S208).

  If the section [k] is not the noise source section and the section [i] is not the noise destination section (step S208; No), the process proceeds to step S210. If the section [k] is a noise source section and the section [i] is a noise destination section (step S208; Yes), the section [i] is not a true noise source section, and noise propagates from the section [k]. Therefore, the noise section determination unit 12 determines that “section [i] is the noise source section and section [j] is the noise destination section” from the noise source noise destination information. The information “section” is deleted (step S209). Then, the variable k is set to the next value (step S210), and it is determined whether or not k is larger than n (step S211).

  If k is n or less (step S211; No), the process returns to step S207, and if k is larger than n (step S211; Yes), the variable j is set to the next value (step S212). And the noise division determination part 12 determines whether j became larger than n (step S213). If j is n or less (step S213; No), the process returns to step S204. If j is larger than n (step S213; Yes), the variable i is set to the next value (step S214). And the noise division determination part 12 determines whether i became larger than n (step S215). If i is n or less (step S215; No), the process returns to step S203. If i is larger than n (step S215; Yes), the noise section determination unit 12 stores the noise source noise destination information in the noise information storage. Writing back to the unit 23 (step S216), the noise source grasping process is terminated.

  Through the noise source grasping process described above, noise source noise destination information including only the true noise source section is stored in the noise information storage unit 23. Next, the noise propagation information generation process called and executed in step S13 of the main flow shown in FIG. 10 will be described with reference to FIG. This process is a process of generating noise propagation information based on the noise source noise destination information stored in the noise information storage unit 23 and outputting the noise propagation information to the display device 5.

  First, the control unit 10 of the noise management device 2 determines whether or not a noise display is instructed from the display device 5 connected via the output unit 32 (step S301). At the time of this determination, the control unit 10 inquires of the display device 5 via the output unit 32 whether or not there is a noise display instruction if necessary.

  Here, the instruction of noise display means a user operation for causing the display device 5 to perform noise display. For example, activation of the noise display application of the display device 5 or pressing of the noise display button is an instruction for noise display. As described in the description of the hardware configuration example of the display device 5 described above, when the noise display application is activated or the noise display button is pressed, the display device 5 transmits to the noise management device 2 that the noise display is instructed. To do. Therefore, the control unit 10 can determine the presence or absence of a noise display instruction based on the presence or absence of this transmission.

  If the control unit 10 determines that the noise display is instructed (step S301; Yes), the noise propagation information generation unit 15 is the base image of the image ID indicated by the base ID acquired from the building information storage unit 22. The image data of the floor plan is acquired from the image information storage unit 21, expanded or contracted to the base size acquired from the building information storage unit 22, and written in the address of the noise propagation information storage unit 24 corresponding to the base position (step S302).

  Next, the noise propagation information generation unit 15 acquires the noise source noise destination information from the noise information storage unit 23, and assigns noise to the addresses of the noise propagation information storage unit 24 corresponding to the noise source section and the noise destination section, respectively. The image shown is written (step S303). Details of this processing will be described later. Then, the noise propagation information generation unit 15 outputs the screen data of the noise notification screen written in the noise propagation information storage unit 24 to the display device 5 via the output unit 32 (step S304), and generates the noise propagation information generation End the process.

  If the control unit 10 determines in step S301 that the noise display is not instructed (step S301; No), the control unit 10 refers to the noise source noise destination information stored in the noise information storage unit 23. Then, it is determined whether or not the noise generated in the noise source section is propagated to other sections (step S305). If the noise generated in the noise source section has not propagated to other sections (step S305; No), the noise propagation information generation process is terminated.

  If the noise generated in the noise source section is propagating to another section (step S305; Yes), the noise propagation information generation unit 15 causes the display device 5 connected via the output unit 32 to send a push notification. It is determined whether or not reception is possible (step S306). Here, the push notification is a notification that can be received and notified to the user even when the receiving side is in a sleep state, such as an e-mail, a short message, or an earthquake early warning. In this determination, the noise propagation information generation unit 15 inquires of the display device 5 via the output unit 32 whether or not the push notification can be received, if necessary. Since the push notification can be received when the display device 5 is the information terminal device 6, the determination in step S <b> 306 may be a determination as to whether or not the connected display device 5 is the information terminal device 6.

  If the display device 5 can receive the push notification (step S306; Yes), the noise propagation information generation unit 15 pushes a message to the display device 5 (step S307), and ends the noise propagation information generation processing. The content of the push notification message is, for example, “Noise is occurring” or “Noise is occurring. Please start the noise display application.” Even if the user does not manually activate the noise display application, the display device 5 automatically activates the noise display application when the control unit 40 detects that the push notification message has been read by the user. Also good.

  If the display device 5 cannot receive the push notification (step S306; No), the noise propagation information generation unit 15 determines whether the display device 5 connected via the output unit 32 complies with the ECHONET Lite display class specification. It is determined whether or not (step S308). In this determination, the noise propagation information generation unit 15 inquires of the display device 5 via the output unit 32 whether or not it complies with the ECHONET Lite display class specification. If the display device 5 does not support the ECHONET Lite display class specification (step S308; No), the noise propagation information generation process is terminated. If the display device 5 complies with the ECHONET Lite display class specification (step S308; Yes), the noise propagation information generation unit 15 outputs a character display instruction to the display device 5 in accordance with the ECHONET Lite display class specification ( Step S309), the noise propagation information generation process is terminated. The content of this character display is, for example, “Noise is generated. Press the [Noise display button] to see details”.

  The noise propagation information generation process has been described above. Next, details of the process in step S303 will be described. In this processing, the noise propagation information generation unit 15 firstly, as an image indicating noise generated in the noise source section, image data indicated by an image ID corresponding to the noise source section acquired from the building information storage unit 22. Obtained from the image information storage unit 21. If the noise source section is a section outside the building 100, the image ID corresponding to the external section may not be set. In this case, the external noise source section is described below. The image indicating the noise to be described is not displayed. By doing so, it is possible to prevent an erroneous display that the noise source section exists in the building despite the external noise.

  When the “image type” of the image data indicated by the image ID corresponding to the noise source section is “mark”, the noise propagation information generation unit 15 obtains this image data from the building information storage unit 22. The size is expanded or contracted according to the noise level in the noise source section around the “section center coordinates” of the section, and is written in the noise propagation information storage unit 24. Then, the noise propagation information generation unit 15 uses the “division center coordinates” of the noise destination section obtained from the building information storage unit 22 as image data corresponding to the noise source section as information indicating the noise level in the noise destination section. In the center, the size is reduced to a size corresponding to the noise level in the noise destination section, and is written in the noise propagation information storage unit 24.

  When the “image type” of the image data indicated by the image ID corresponding to the noise source section is “shaded” instead of “mark”, the noise propagation information generation unit 15 acquires the noise acquired from the building information storage unit 22. The inside of the source section is written in the noise propagation information storage unit 24 so as to be filled with the shaded image indicated by the image ID. Then, the noise propagation information generation unit 15 sets the shading density of the image data of the shaded image indicated by the image ID corresponding to the noise source section as information indicating the noise level in the noise destination section. The noise reduced information is written in the noise propagation information storage unit 24 so as to fill the interior of the noise target section acquired from the building information storage unit 22 with the image reduced to the density corresponding to the noise level.

  Since the noise level in the noise source section and the noise level in the noise destination section are stored in the noise information storage section 23, the noise propagation information generation section 15 refers to the noise information storage section 23. Such information can be obtained. The noise propagation information generation unit 15 may not only write an image indicating noise in the noise source section and the noise destination section, but may further write an arrow image from the noise source section to the noise destination section. When the user sets “arrow display available” in the noise management device 2, this arrow is written. In this case, the noise propagation information generation unit 15 obtains the “compartment center coordinates” of the noise source section and the “compartment center coordinates” of the noise destination section from the building information storage unit 22, and uses these coordinates as a reference for the image. The direction and length of the arrow image stored in the information storage unit 21 are adjusted and written to the noise propagation information storage unit 24.

  Through the processing by the noise propagation information generation unit 15 described above, the screen data of the noise notification screen is written in the noise propagation information storage unit 24 in step S303.

  Through the process of step S307 and step S309 of the noise propagation information generation process described above, the display device 5 is notified of a message prompting the user to display noise. When the user who sees this message tries to display noise on the display device 5, the determination in step S301 is Yes in the noise propagation information generation process called again in step S13 of the main flow shown in FIG. A screen as shown in FIG. 4B or FIG. 5B is displayed on the device 5. FIG. 4B is an example of a screen when the image type of the image indicating noise is “shaded”, and FIG. 5B is the image type of the image indicating noise being “mark” and “ It is an example of a screen when “display present” is set.

  The following describes two screens, Case A and Case B, of what screens are generated by the above-described noise section determination processing and noise propagation information generation processing. Here, the positional relationship between the sections 1 to 4 in the building 100 is a floor plan shown in FIGS. 4B and 5B. The image information storage unit 21 stores the contents shown in FIG. 3A, and the building information storage unit 22 stores the contents shown in FIG. 4A or FIG. 5A.

  First, as case A, it is assumed that the section 1 is a noise source section, the noise propagates to the section 2, and the noise is detected in the section 2. In this case, since the noise generated in the section 1 is propagated to the section 2, the noise characteristics of the section 1 and the section 2 are the same, and the noise level in the section 1 is higher than the noise level in the section 2 large. Further, it is assumed that the noise level detected in the section 1 is larger than the threshold value Th [1] of the section 1, and the noise level detected in the section 2 is larger than the threshold value Th [2] of the section 2. It is assumed that no noise is detected in the sections 3, 4 and the external section.

  Then, when i = 1 and j = 2, all the determinations in step S103, step S105, step S106, and step S107 shown in FIG. 11 are Yes. In step S108, section 1 is the noise source section and section 2 is the noise. It is determined that it is the previous section. In other combinations of i and j, it is determined No in at least one of the determination steps in FIG. 11 described above, and thus the process proceeds to step S109 or step S111 without proceeding to step S108. . Therefore, when the noise zone determination process is completed, noise source noise destination information indicating the relationship between the noise source zone and the noise destination zone as shown in FIG. 12 is generated and stored in the noise information storage unit 23. Is done.

  Next, the noise source grasping process is called in step S12 of the main flow shown in FIG. In this example, since the noise source noise destination information includes only the information of the true noise source section, the noise source noise destination information does not change. Next, the noise propagation information generation process is called in step S13 of the main flow shown in FIG. Here, it is assumed that the noise display is not instructed at first. Then, the determination in step S301 in FIG. 14 is No, and the process proceeds to step S305. Then, referring to the noise source noise destination information shown in FIG. 12, since the noise generated in the section 1 has propagated to the section 2, the determination in step S305 is Yes, and the process proceeds to step S306. Here, if the information terminal device 6 is connected to the noise management device 2 via the network 4 as the display device 5, the determination in step S306 is Yes and the process proceeds to step S307. In step S307, for example, the noise propagation information generation unit 15 performs push notification of a message “Noise is occurring. Please activate the noise display application”.

  Then, the user sees the message displayed on the information terminal device 6 and activates the noise display application. When the noise propagation information generation process is completed, the main flow shown in FIG. 10 is executed again from step S11. If there is no change in the noise generation status, the same noise source noise destination information as before is obtained in the noise section determination process. Generated. In step S13, the noise propagation information generation process shown in FIG. 14 is called again. Since the noise display application is activated this time, the determination in step S301 is Yes, and the process proceeds to step S302.

  In step S <b> 302, as the building information, the floor plan A in FIG. 3I, which is image data corresponding to the image ID = # 1001 stored in the base ID of the building information storage unit 22, is obtained from the image information storage unit 21. Obtained and written in the noise propagation information storage unit 24. In this case, since the noise source section is section 1, image data of # 0001 or # 0011, which is an image ID corresponding to section 1 of the building information storage unit 22, is acquired as an image indicating noise.

  When the image ID is # 0001, since the “image type” is “shaded”, the section 1 is filled with the shaded image shown in FIG. Then, the section 2 which is the noise destination section is filled with an image in which the shading density of the hatched image is reduced according to the noise level in the section 2, and the display data as shown in FIG. It is written in the noise propagation information storage unit 24.

  When the image ID is # 0011, since the “image type” is “mark”, the musical note mark A shown in FIG. Then, in the section 2 that is the noise destination section, an image in which the size of the image of the note mark A is reduced according to the noise level in the section 2 is written. Whether or not an arrow is displayed can be set independently of the “image type”, but the display data shown in FIG. 5B shows an example in which an arrow is displayed. Therefore, the image of the arrow A is further written in the noise propagation information storage unit 24 from the section 1 to the section 2.

  The screen data of the noise notification screen written in the noise propagation information storage unit 24 is output to the display device 5 via the output unit 32 and the network 4 in step S304, and the display device 5 receives this screen data. The screen shown in FIG. 4B or 5B is displayed.

  Next, as Case B, the section 1 is a noise source section with a large noise, the noise generated in the section 1 is propagated to the section 2 and the noise is detected in the section 2, and the section 3 is This is a noise source section where noise having characteristics different from the noise generated in section 1 is generated, and the noise generated in section 3 is propagated to section 4 and noise is detected in section 4 Take the situation as an example. In this example, the sound is completely blocked on the first floor and the second floor, the noise generated in the section 1 does not propagate to the sections 3 and 4, and the noise generated in the section 3 is not divided. It is assumed that no propagation occurs in 1 and partition 2. It is assumed that no noise is generated in the external section.

  In the case B, when the noise section determination process shown in FIG. 11 is performed, noise source noise destination information as shown in FIG. 15 is generated. When the noise propagation information generation process shown in FIG. 14 is performed, the noise notification screen displayed on the display device 5 becomes a screen as shown in FIG. 16 (a) or FIG. 16 (b). As described above, the display device 5 displays a screen indicating that the noise level is different depending on the density of the background pattern or the mark size of the section and that the noise characteristics are different depending on the type of the background pattern or the mark type. .

  In each of the above cases, no noise is generated in the external section. However, no noise is generated in the sections 1 to 4, and the noise generated in the external section 1 is propagated to the section 4 and the external section 1 Suppose that the noise propagated from section 4 to section 4 further propagates to section 3. In this case, when the noise section determination process shown in FIG. 11 and the noise source grasping process shown in FIG. 13 are performed, noise source noise destination information as shown in FIG. 17A is generated.

  Then, it is assumed that the storage content of the building information storage unit 22 is the content shown in FIG. 4A or FIG. Then, since the building information storage unit 22 does not store the image ID corresponding to the sound sensor 9 arranged in the external section, when the noise propagation information generation process shown in FIG. 14 is performed, the building information storage unit 22 is displayed on the display device 5. As shown in FIG. 17B, the noise notification screen is a screen indicating that there is no noise generation source inside the building 100.

  Assuming that the image ID of the quarter note mark image is set as the image ID corresponding to the external section 1 of the building information storage unit 22, and that an arrow is displayed from the noise source section to the noise destination section. When set, the noise notification screen displayed on the display device 5 is a screen as shown in FIG.

  As described above, according to the noise management system 1 according to the first embodiment, the display device 5 causes the noise source section where the noise source exists in the building 100 and the noise destination section where the noise propagates to the noise source section. Can be displayed on the floor plan. Therefore, it is possible to present information indicating the section where the noise generation source exists and the propagation state of the noise to the surroundings. Further, the noise management device 2 considers whether the noise level in the noise destination section is equal to or higher than the threshold Th of the noise destination section when determining the noise source section and the noise destination section. When the noise level is equal to or higher than the threshold value Th, it is assumed that the noise generated in the noise source section is disturbing the surroundings, and is determined to be the noise source section. Therefore, the noise management device 2 can notify the generation of noise only when it is assumed that the noise generated in the noise source section is disturbing the surroundings.

(Modification of Embodiment 1)
In the first embodiment, as shown in FIG. 1, the information terminal device 6 is connected to the network 4 in the building 100, but the information terminal device 6 is connected to the cloud network outside the building 100. It may be connected. As shown in FIG. 18, the configuration example of the noise management system 1 </ b> A according to the modification of the first embodiment configured as described above is such that the network 4 in the building 100 is connected to the cloud network 3 outside the building 100 by the router 301. The information terminal device 6A of the display device 5 is connected to the cloud network 3 via a base station (not shown).

  The information terminal device 6A has the same hardware configuration as the information terminal device 6 of the first embodiment, but the noise propagation information output from the noise management device 2 is transmitted to the network 4, the router 301, the cloud network 3, and the base station interface 664. To get through. Except for this point, the information terminal device 6A is the same as the information terminal device 6 of the first embodiment.

  The cloud network 3 is a network outside the building 100 such as the Internet or a mobile phone network. The router 301 is a device that relays between the network 4 inside the building 100 and the cloud network 3 outside the building 100. Except for this, the configuration of the noise management system 1A according to the modification of the first embodiment is the same as that of the noise management system 1 according to the first embodiment. In addition, the noise section determination process, the noise source grasping process, and the noise propagation information generation process according to the noise management system 1A according to the modification of the first embodiment are the same as the noise management system 1 according to the first embodiment.

  In the noise management system 1A according to the modification of the first embodiment, when the noise management device 2 transmits the noise propagation information to the information terminal device 6A, the noise propagation information does not pass through only the network 4, but the network 4 Through the router 301 and the cloud network 3. As a result, the information terminal device 6A can acquire the noise propagation information and display the noise notification screen when it is outside the building 100 and when it is outside the building 100. As described above, according to the noise management system 1A according to the modification of the first embodiment, since the information terminal device 6A is connected to the noise management device 2 via the cloud network 3, the router 301, and the network 4, the information terminal Regardless of whether the device 6A is located inside or outside the building 100, the information terminal device 6A can display the noise propagation information output by the noise management device 2.

(Second Modification of Embodiment 1)
In the first embodiment and the modification of the first embodiment, the noise management device 2 is installed in the building 100 as shown in FIGS. 1 and 18. May be installed outside the building 100. As shown in FIG. 19, the configuration example of the noise management system 1 </ b> B according to the second modification example of the first embodiment configured as described above includes a noise management device 2 </ b> A installed outside the building 100. Connected to the external cloud network 3 and connected to the network 4 in the building 100 by the router 301.

  The noise management device 2 </ b> A has the same configuration as the noise management device 2 of the first embodiment shown in FIG. 2, but the communication unit 31 is a communication interface that can communicate via the cloud network 3. The output unit 32 is a communication interface for outputting the screen information generated by the noise propagation information generation unit 15 to the display device 5 via the cloud network 3, the router 301, and the network 4. Further, since the noise management device 2 </ b> A communicates with the display device 5 and the sound sensor 9 via the cloud network 3, the addresses of the display device 5 and the sound sensor 9 to be connected are stored in the storage unit 20. Furthermore, when the noise management device 2A manages a plurality of buildings 100 at the same time, the ID of the display device 5 and the sound sensor 9 for each building 100 for identifying the display device 5 and the sound sensor 9 of each building 100 is set. The stored ID table is stored in the storage unit 20, and the noise section determination process and the noise propagation information generation process are performed for each building 100. Except for these points, the present embodiment is the same as the noise management device 2 of the first embodiment.

  The cloud network 3 and the router 301 are the same as the cloud network 3 and the router 301 according to the modification of the first embodiment. Except for the above points, the configuration of the noise management system 1B according to the second modification of the first embodiment is the same as that of the noise management system 1 according to the first embodiment. The noise section determination process, the noise source grasping process, and the noise propagation information generation process of the noise management system 1B according to the second modification of the first embodiment are also the same as the noise management system 1 according to the first embodiment. .

  In the noise management system 1B according to the second modification of the first embodiment, the noise management device 2A receives noise waveform data from the sound sensor 9 via the communication unit 31, the cloud network 3, the router 301, and the network 4. Receive. Then, the noise propagation information is output to the display device 5 via the output unit 32, the cloud network 3, the router 301, and the network 4. Therefore, the noise management device 2A can communicate with the sound sensor 9 and the display device 5 regardless of the installation location. Therefore, the user can install the noise management device 2 </ b> A outside the building 100.

  As described above, according to the noise management system 1B according to the second modification of the first embodiment, the noise management device 2A is connected to the network 4 in the building 100 via the cloud network 3, so that the user The management device 2 </ b> A can be installed outside the building 100, and there is no need to install it individually in the building 100. Further, even if the network 4 in the building 100 is disabled, the noise management device 2A can receive an upgrade and maintenance service for improving its function via the cloud network 3. Furthermore, when the noise management device 2A is connected to another information device or server (not shown) via the cloud network 3, for example, an application for presenting information for improving noise to a resident or manager of the building 100 is received. You will also be able to.

(Embodiment 2)
In the above-described embodiment, the display device 5 is not necessarily installed in the section where the noise generation source exists. For this reason, there is a possibility that a person who generates noise may continue to generate noise without noticing. However, if the display device 5 is installed in each section, in addition to being costly, if a noise source is present in another section, this is also displayed, which may cause more trouble between residents. There is also sex. Therefore, even if the display device 5 is not installed in each section, only the person in the section where the noise is generated is informed that the noise generated in the section is propagated to other sections. The form 2 will be described.

  The configuration example of the noise management system 1C according to Embodiment 2 includes a noise management device 2B, a network 4, a display device 5, a sound sensor 9, and an electric device 90, as shown in FIG. The network 4, the display device 5, and the sound sensor 9 are the same as those in the first embodiment. As the form of the electric device 90, for example, an acoustic device 91, a washing machine 92, a vacuum cleaner 93, and a lighting device 94 are conceivable. The noise management device 2B, the sound sensor 9, the display device 5, and the electric equipment 90 are each connected to the network 4. The noise management device 2 </ b> B can communicate with the sound sensor 9, the display device 5, and the electric device 90 via the network 4. In addition, since it is not necessary to communicate directly with the sound sensor 9, the display apparatus 5, and the electric equipment 90, the network 4 between the noise management apparatus 2B and the sound sensor 9, and between the noise management apparatus 2B and the display apparatus 5 are used. The network 4 and the network 4 between the noise management device 2B and the electric device 90 may not be connected to each other. When the noise management device 2B can control the electric device 90 by transmitting a remote control signal corresponding to the electric device 90, the network 4 between the noise management device 2B and the electric device 90 is a network based on the remote control signal. It may be.

  In the example illustrated in FIG. 20, the noise management device 2 </ b> B, the display device 5, the sound sensor 9, and the electric device 90 are connected only by the network 4 in the building 100. However, similarly to the modification of the first embodiment shown in FIG. 18, the cloud network 3 and the router 301 may be provided. With this configuration, the display device 5 can be connected to the noise management device 2B via the cloud network 3 and the network 4 and display noise propagation information even from outside the building 100.

  The noise management device 2B acquires noise waveform data from the sound sensor 9, generates noise propagation information, and outputs the noise propagation information to the display device 5. This point is the same as the noise management device 2 according to the first embodiment. The noise management device 2B further transmits control information in order to cause the electric device 90 installed in the noise source section to perform a notification operation according to the noise level detected in the noise destination section. The notification operation performed by the electrical device 90 is, for example, blinking or lighting of an LED indicator included in the electrical device 90, display on a display panel, output of sound from a speaker or notification sound.

  As shown in FIG. 21, the electric device 90 according to the second embodiment includes a control unit 70, a storage unit 80, a communication unit 81, and a notification unit 82 as functional configurations. The control unit 70 includes a CPU and executes the program stored in the storage unit 80, thereby realizing the functions of the electrical device 90 and the functions of the control unit 70 (the control information acquisition unit 71 and the notification control unit 72). To do. The control unit 70 has a multi-thread function, and can execute a plurality of processing flows in parallel.

  The control information acquisition unit 71 acquires the control information transmitted by the noise management device 2B via the communication unit 81. The notification control unit 72 controls the notification unit 82 based on the control information acquired by the control information acquisition unit 71, and performs a notification operation according to the noise level in the noise destination section. The storage unit 80 includes a RAM and a ROM, and stores necessary programs and data.

  The communication unit 81 is a communication interface that performs communication via the network 4 in order to obtain control information from the noise management device 2B. When transmission of control information from the noise management device 2B is transmitted as a remote control signal, the communication unit 81 is a remote control signal receiving device. The notification unit 82 is an arbitrary device included in the electric device 90 that can be used when performing a notification operation according to the noise level to the user, and is, for example, an LED indicator, a display panel, a speaker, a motor, or a vibrator. The electrical device 90 notifies the user that noise is propagating to other sections by outputting light, characters, video, and sound by the notification unit 82. Here, the sound includes not only sound but also sound that can be generated without using a speaker, such as motor sound or vibration sound.

  In the functional configuration example of the noise management device 2B according to the second embodiment, as shown in FIG. 22, a control information generation unit 16 and an electrical equipment information storage unit 25 are added to the noise management device 2 according to the first embodiment. It is a configuration. The output unit 32 is used not only when transmitting noise propagation information to the display device 5 but also when transmitting control information to the electrical device 90. However, the output unit 32 used when transmitting control information to the electric device 90 and the output unit 32 used when transmitting noise propagation information to the display device 5 may be separate output units 32. Moreover, you may provide the separate output part 32 with respect to each of the some electric equipment 90. FIG.

  As shown in FIG. 23, the building information storage unit 22 of the noise management device 2B according to the second embodiment includes a “display device presence / absence” indicating the presence / absence of the display device 5 in each section and an electric device 90 present in each section. "Electrical device destination information" indicating the address of the device is also stored. FIG. 23 shows an example in which information on the IP address of the electric device 90 is stored as “electric device destination information”, but the present invention is not limited to this. Any information may be used as long as the noise management device 2B is information necessary for transmitting control information to each electric device 90 via the network 4. For example, when the control information is transmitted as an infrared remote control signal from the noise management device 2B, the remote control signal can be transmitted without the IP address information. In this case, the “electrical device destination information” is stored in the section. This is information indicating the type of the remote control signal of the existing electric device 90.

  In this information setting method, when the IP address is stored, for example, the noise management device 2B periodically broadcasts its own IP address, and the display device 5 and the electric device 90 receive the broadcast packet. Then, a process of transmitting the IP address and the installed section to the IP address included in the IP address may be performed. Through such processing, the noise management device 2B can acquire the IP addresses and installation sections of all the display devices 5 and electrical devices 90 existing in the range where the broadcast packet can reach. The user may manually store “display device presence / absence” and “electrical device destination information” based on information on the display device 5 and the electric device 90 installed in each section of the building 100.

  Based on the information determined by the noise section determination section 12, the control information generation section 16 generates control information indicating the content that causes the electric device 90 installed in the noise source section to perform a notification operation. The generated control information is information indicating contents for controlling the notification unit 82 of the electric device 90 in order to cause the electric device 90 to perform a notification operation according to the noise level in the noise destination section. The control information is transmitted from the noise management device 2 </ b> B toward the network 4 via the output unit 32, and is received by the control information acquisition unit 71 of the electrical device 90 via the communication unit 81. When the noise propagates to a plurality of sections, the noise level in the section where the largest noise is detected among the propagation destinations is notified.

  As shown in FIG. 24, the electrical device information storage unit 25 is a notification unit that controls how the notification unit 82 is controlled when each electrical device 90 performs a notification operation according to the noise level in the noise destination section. Information of control contents is stored. In the example of FIG. 24, for example, when the electric device 90 installed in the noise source section is the vacuum cleaner 93, two types of notification unit control contents are stored depending on whether the noise level is less than 75 dB or more than 75 dB. In this example, when the noise level is less than 75 dB, the LED indicator is blinked. When the noise level is 75 dB or more, the LED indicator is blinked and the motor of the cleaner 93 is intermittently rotated. As described above, by changing the behavior of the electric device 90 according to the noise level in the noise destination section, the noise management device 2B causes the electric device 90 installed in the noise source section to transmit the noise level in the noise destination section. It is possible to perform a notification operation according to the above.

  When transmission of control information from the noise management device 2B is transmitted by a remote control signal, the notification unit control content of the electrical equipment information storage unit 25 is set to a content that can be controlled by the remote control signal. By doing in this way, the noise management device 2B controls the notification unit 82 with the remote control signal without adding a special configuration to the electric device 90, so that the electric device 90 has a noise level in the noise destination section. It is possible to perform a notification operation according to the above.

  Moreover, although the electrical equipment information storage part 25 shown in FIG. 24 has memorize | stored the alerting | reporting part control content corresponding to a noise level for every kind of electrical equipment 90, it is not restricted to this. The electrical device information storage unit 25 may store the notification unit control content corresponding to the noise level for each model number or product name of the electrical device 90 instead of storing the electrical device 90 for each type.

  As shown in FIG. 25, the main flow of the noise management device 2B is the addition of a call “control information generation process” as step S14 before step S13 of the main flow of the noise management device 2 according to the first embodiment. It is processing. The control information generation process is a process in which the noise management device 2B transmits control information corresponding to the noise level to the electrical device 90. By this processing, the electric equipment 90 installed in the noise source section receives the control information, and controls the notification unit 82 based on the notification unit control information included in the control information, so that the noise level in the noise destination section is controlled. The notification operation according to can be performed.

  Now, the control information generation process called and executed in step S14 of the main flow of the noise management device 2B will be described with reference to FIG. First, the control information generation unit 16 of the noise management device 2B acquires the noise source noise destination information stored in the noise information storage unit 23 (step S401). Then, based on the acquired noise source noise destination information, it is determined whether or not a noise source section exists (step S402). If the noise source section does not exist (step S402; No), since the notification from the electric device 90 is unnecessary, the control information generation process is terminated.

  If the noise source section exists (step S402; Yes), the control information generation unit 16 determines whether or not the display device 5 exists in the noise source section based on “display device presence / absence” in the building information storage unit 22. (Step S403). If the display device 5 is present in the noise source section (step S403; Yes), the control information generation unit 16 forcibly displays the noise notification screen on the display device 5 by the subsequent noise propagation information generation processing, A noise display instruction is transmitted to the display device 5 via the output unit 32 (step S404). The noise display instruction is an instruction to activate the noise display application on the display device 5 or an instruction to switch input for noise display. Then, the control information generation unit 16 further determines whether or not to notify the electric device 90 (step S405). Whether or not to notify the electric device 90 can be arbitrarily set for each section by storing information on whether or not to notify the electric device 90 in the building information storage unit 22, for example.

  If not notified by the electric device 90 (step S405; No), the control information generation process is terminated. If the notification is also made in the electric device 90 (step S405; Yes), the process proceeds to step S406.

  Also when it is determined in step S403 that the display device 5 does not exist in the noise source section (step S403; No), the process proceeds to step S406, and the control information generation unit 16 performs the building information storage unit 22 and the electrical equipment information storage unit 25. Based on the stored content, the electrical device destination information and the notification unit control content of the electrical device 90 existing in the noise source section are acquired (step S406). Here, the electrical device destination information of the electrical device 90 is, for example, the IP address of the electrical device 90. Then, the control information generation unit 16 acquires the noise level in the noise destination section stored in the noise information storage unit 23, uses the notification unit control content corresponding to the noise level as control information, and is acquired in step S406. Based on the electrical device destination information, the control information is transmitted to the electrical device 90 (step S407), and the control information generation process is terminated. Note that, when there are a plurality of noise destination sections, the notification unit control content corresponding to the maximum noise level among the noise levels in the plurality of noise destination sections is set as control information.

  Through the above processing, the control information is transmitted from the noise management device 2B to the electric equipment 90 installed in the noise source section. The control information reception process of the electrical device 90 that has received this control information will be described with reference to FIG. This process is a process in which the electric device 90 performs a notification operation according to the noise level in the noise destination section. This processing is started when the electrical device 90 receives the control information, and is executed in parallel with a thread different from the processing of the main function of the electrical device 90.

  First, the control information acquisition unit 71 acquires control information transmitted from the noise management device 2B via the communication unit 81 (step S501). Next, the notification control unit 72 controls the notification unit 82 based on the notification unit control content included in the control information (step S502), and the process ends.

  Through the control information reception process described above, based on the control information transmitted from the noise management device 2B, the electrical device 90 controls the notification unit 82 to perform a notification operation according to the noise level in the noise destination section. it can. By this notification operation, the user in the section can know that the noise generated in the section is propagating to another section. If the network 4 between the noise management device 2B and the electric device 90 is a network that transmits a remote control signal of the electric device 90, the control information may be a remote control signal that controls the electric device 90. In this case, the electric device 90 can control the notification unit 82 by the remote control signal received from the noise management device 2B, and perform a notification operation according to the noise level in the noise destination section.

  As in the case A described above, the noise management device is an example of a situation where the noise in the section 1 is large and the noise source section is propagated to the section 2 and the noise is detected in the section 2. 2B determines that the section 1 is a noise source section, and the control information including the notification unit control contents according to the noise level in the section 2 that is the noise propagation destination is installed in the section 1 via the network 4. It transmits to the electrical equipment 90 which is. And the electric equipment 90 installed in the division 1 receives the control information via the network 4, and performs a notification operation based on the notification unit control content included in the control information. If the content shown in FIG. 24 is stored in the electrical equipment information storage unit 25 and the noise level in the section 2 is 65 dB, in the example shown in FIG. 20, the acoustic equipment 91 installed in the section 1 is The speaker outputs “Noise is occurring” as a voice, and displays “Noise is occurring” on the screen, thereby performing a notification operation according to the noise level.

  Further, as in the case B described above, the section 1 is noisy and is a noise source section, the noise is propagated to the section 2 and noise is detected in the section 2, and the section 3 is The noise source section where noise having characteristics different from the noise generated in section 1 is generated, and the noise generated in section 3 propagates to section 4 and noise is detected in section 4 For example, the noise management device 2B determines that the sections 1 and 3 are noise source sections, and the notification unit control contents according to the noise levels in the sections 2 and 4 that are noise propagation destinations. Is transmitted to the electrical equipment 90 installed in the sections 1 and 3 via the network 4. And the electric equipment 90 installed in the division 1 and the division 3 receives the control information via the network 4, and performs a notification operation based on the notification unit control content included in the control information. If the contents shown in FIG. 24 are stored in the electrical equipment information storage unit 25, and the noise level in section 2 is 65 dB and the noise level in section 4 is 70 dB, in the example shown in FIG. The sound device 91 performs the above-described notification operation, and at the same time, the cleaner 93 existing in the section 3 causes the LED attached to the cleaner 93 to blink, so that each electric device 90 generates noise in each section. A notification operation according to the level is performed.

  However, when the display device 5 is installed in the noise source section, a noise notification screen is displayed on the display apparatus 5 installed in the section by the noise propagation information generation process (step S404 in FIG. 26), The display device 5 notifies the user that the section is a noise source section. Then, whether or not the notification operation is performed also in the electric equipment 90 installed in the section is arbitrarily determined for each section by, for example, the building information storage unit 22 storing the presence or absence of the notification operation by the electric device 90. It can be set.

  As described above, according to the noise management system 1C using the noise management device 2B of the second embodiment, the electrical device 90 installed in the noise source section is notified according to the noise level in the noise destination section. Therefore, even if the display device 5 is not in the noise source section, the user can be aware that the section is the noise source section. Moreover, since the electrical equipment information storage unit 25 provided in the noise management device 2B stores the notification unit control content indicating how to control the notification unit 82 of each electrical device 90 to notify the noise level, The electric device 90 can perform a notification operation according to the noise level in the noise destination section without storing the control content of the notification unit 82 according to the noise level.

(Embodiment 3)
The noise management device 2 </ b> B according to the second embodiment needs to store information on the notification unit control content for controlling the notification unit 82 of each electrical device 90 in the electrical device information storage unit 25. However, since the specifications of the electric devices 90 vary from one electric device 90 to another, it is complicated to deal with all the electric devices 90. Therefore, a description will be given of a third embodiment in which each electrical device 90A includes information on control part control contents.

  As shown in FIG. 28, the configuration example of the noise management system 1D according to Embodiment 3 includes a noise management device 2C, a network 4, a display device 5, a sound sensor 9, and an electric device 90A. The components other than the noise management device 2C and the electric device 90A are the same as those of the noise management system 1C according to the second embodiment. Further, the configuration including the cloud network 3 and the router 301 may be the same as the noise management system 1C according to the second embodiment.

  The noise management device 2 </ b> C acquires noise waveform data from the sound sensor 9, generates noise propagation information, and outputs the noise propagation information to the display device 5. This point is the same as the noise management device 2 according to the first embodiment and the noise management device 2B according to the second embodiment. The difference between the noise management device 2C and the noise management device 2B according to the second embodiment is that the second noise propagation information is transmitted to the electrical device 90A instead of the control information.

  As shown in FIG. 29, the electric device 90A according to the third embodiment includes a control unit 70, a storage unit 80, a communication unit 81, and a notification unit 82 as functional configurations. The communication unit 81 and the notification unit 82 are the same as the communication unit 81 and the notification unit 82 included in the electric device 90 according to the second embodiment. The control unit 70 includes a CPU and executes a program stored in the storage unit 80, thereby performing functions of the electrical device 90A and each unit of the control unit 70 (noise propagation information acquisition unit 73, control information generation unit 74, control information acquisition). The functions of the unit 71 and the notification control unit 72) are realized. The control unit 70 has a multi-thread function, and can execute a plurality of processing flows in parallel.

  The noise propagation information acquisition unit 73 acquires the second noise propagation information transmitted by the noise management device 2 </ b> C via the communication unit 81. The control information generation unit 74 generates control information indicating the control content of the notification unit 82 based on the noise level included in the second noise propagation information acquired by the noise propagation information acquisition unit 73. The control information acquisition unit 71 acquires the control information generated by the control information generation unit 74. The notification control unit 72 controls the notification unit 82 based on the control information acquired by the control information acquisition unit 71. Thereby, 90 A of electric equipment can perform alerting | reporting operation | movement according to the noise level in a noise destination division.

  The storage unit 80 includes a RAM and a ROM, and stores necessary programs and data. Further, the storage unit 80 functionally includes a notification unit control information storage unit 83. As shown in FIG. 30, the notification unit control information storage unit 83 stores notification unit control contents indicating how to control the notification unit 82 in accordance with the noise level. FIG. 30 shows a data example of the notification unit control information storage unit 83 in which the notification unit control content is stored when the electrical device 90A is the acoustic device 91A, but the notification unit control content is determined according to the electrical device 90A. The setting is arbitrary. Even if the type of the electrical device 90A is an acoustic device, in the case of an acoustic device having a function or model number different from that of the acoustic device 91A, the notification unit control content different from the notification unit control content example of the acoustic device 91A shown in FIG. It may be. Not only the type of electric equipment 90A but also the notification section control information storage section 83 can store the notification section control content dedicated to each of the individual electric equipment 90A.

  The functional configuration example of the noise management device 2C according to the third embodiment is the same as that of the noise management device 2 according to the first embodiment shown in FIG. 2, but the noise propagation information generation unit 15 includes the second noise propagation information. As shown in FIG. 23, the building information storage unit 22 includes the “display device presence / absence” indicating the presence / absence of the display device 5 in each section and the information on the electric device 90A existing in each section as shown in FIG. The difference is that “electrical device destination information” is also stored. “Display device presence / absence” and “electrical device destination information” are the same as those in the second embodiment. The output unit 32 is used not only when transmitting the noise propagation information to the display device 5 but also when transmitting the second noise propagation information to the electric device 90A. However, the output unit 32 used when transmitting to the electric device 90 </ b> A and the output unit 32 used when transmitting to the display device 5 may be separate output units 32. Moreover, you may provide the separate output part 32 with respect to several electrical equipment 90A. The building information storage unit 22 provided in the noise management device 2C according to the third embodiment is the same as the building information storage unit 22 illustrated in FIG. 23 provided in the noise management device 2B according to the second embodiment.

  As shown in FIG. 31, the main flow of the noise management device 2 </ b> C is a “second noise propagation information generation process” as step S <b> 15 before step S <b> 13 of the main flow of the noise management device 2 according to the first embodiment. It is configured with a call added. The second noise propagation information generation process is a process in which the noise management device 2C transmits the noise level in the noise destination section to the electric device 90A. By this processing, the electric device 90A installed in the noise source section can perform a notification operation according to the noise level in the noise destination section.

  Now, the second noise propagation information generation processing called and executed in step S15 of the main flow of the noise management device 2C will be described with reference to FIG. Since this process is similar to the control information generation process shown in FIG. 26 except that the main body is the noise propagation information generation unit 15 of the noise management device 2C, the description will focus on the differences. First, Steps S601 to S605 of the second noise propagation information generation process are the same as Steps S401 to S405 of FIG. 26 except that the subject is not the control information generation unit 16 but the noise propagation information generation unit 15. It is.

  In step S <b> 606, the noise propagation information generation unit 15 acquires the electric device destination information of the electric device 90 </ b> A existing in the noise source section based on the storage contents of the building information storage unit 22, and further stores it in the noise information storage unit 23. The noise level in the noise destination section is also acquired (step S606). Then, the noise propagation information generation unit 15 transmits the noise level in the acquired noise destination section as the second noise propagation information to the electric device 90A indicated by the electric device destination information acquired in step S606 (step S607). Then, the second noise propagation information generation process is terminated. If there are a plurality of noise destination sections, the maximum noise level among the noise levels in the plurality of noise destination sections is transmitted as the second noise propagation information.

  Through the above processing, the noise propagation information is transmitted from the noise management device 2C to the electric equipment 90A installed in the noise source section. The noise propagation information reception process of the electrical device 90A that has received the noise propagation information will be described with reference to FIG. This process is a process for the electric device 90A to perform a notification operation according to the noise level in the noise destination section. This processing is started when the electric device 90A receives the noise propagation information, and is executed in parallel with a thread different from the processing of the main function of the electric device 90A.

  First, the noise propagation information acquisition unit 73 acquires the second noise propagation information transmitted from the noise management device 2C via the communication unit 81 (step S701). This noise propagation information includes information on the noise level in the noise destination section. Next, the control information generation unit 74 determines the control content of the notification unit 82 based on the noise propagation information acquired by the noise propagation information acquisition unit 73 and the notification unit control content stored in the notification unit control information storage unit 83. Control information to be shown is generated (step S702). And the alerting | reporting control part 72 controls the alerting | reporting part 82 based on the control content shown by control information (step S703), and complete | finishes.

  Based on the noise propagation information transmitted from the noise management device 2C by the above-described noise propagation information reception process, the electric device 90A controls the notification unit 82 to perform a notification operation according to the noise level in the noise destination section. It can be carried out. By this notification operation, the user in the section can know that the noise generated in the section is propagating to another section.

  As described above, according to the noise management system 1D using the noise management device 2C of the third embodiment, the notification according to the noise level in the noise destination section using the electric device 90A installed in the noise source section. Since the operation is performed, even if the display device 5 is not in the section, the user in the section can notice that the section is a noise source section. Further, unlike Embodiment 2, the notification unit control content is stored not in the noise management device 2C but in each electric device 90A. For this reason, even if the noise management apparatus 2C does not store the notification unit control content corresponding to the various electric devices 90A, it is possible to perform a notification operation according to the noise level in the noise destination section. Therefore, even when a new electric device 90A is released in the future, the existing noise management device 2C can be used and the new electric device 90A can be handled.

  Note that the above-described embodiments can be arbitrarily combined. As described above, the modification of the first embodiment can be combined with the second or third embodiment, but the second modification of the first embodiment is the second or third embodiment. It is also possible to combine with. With such a configuration, the user can install the noise management device outside the building 100, and even if the network 4 in the building 100 is disabled, the noise management device can be upgraded and upgraded. The maintenance service can be received via the cloud network 3. Furthermore, when the noise management apparatus is connected to another information device or server (not shown) via the cloud network 3, for example, an application for presenting information for improving noise to a resident or manager of the building 100 is received. You will also be able to.

  Moreover, it is also possible to combine the modification of Embodiment 1 and the 2nd modification of Embodiment 1, and by setting it as such a structure, the effect of a modification and the effect of a 2nd modification Both can be enjoyed. Furthermore, the second embodiment and the third embodiment can be combined. For example, the notification unit control content of the electrical device 90 having a high diffusion rate is stored in the electrical device information storage unit 25 of the noise management device, and the notification unit control content of the other electrical device 90A is the notification unit control information of each electrical device 90A. It can be stored in the storage unit 83. Thereby, the electric equipment 90 memorize | stored in the electric equipment information storage part 25 can be manufactured at low cost with a simple structure. And since the electrical equipment information storage part 25 does not need to memorize | store the alerting | reporting part control content about the electrical equipment 90A, it can also reduce the manufacturing cost of a noise management apparatus. Further, an electric device to be released in the future can correspond to the new electric device 90A without replacing the noise management device by adopting the same configuration as that of the electric device 90A.

  The hardware of the noise management devices 2, 2A, 2B, and 2C according to the embodiment of the present invention includes a processor 210, a memory 220, and an interface 230 as shown in FIG. The functions of the noise information acquisition unit 11, the noise section determination unit 12, and the noise propagation information generation unit 15 in the noise management devices 2, 2A, 2B, and 2C are realized by the processor 210. The processor 210 is a CPU that executes a program stored in the memory 220. The processor 210 reads out and executes the program stored in the memory 220, thereby realizing the functions of the noise information acquisition unit 11, the noise section determination unit 12, and the noise propagation information generation unit 15. That is, the noise management devices 2, 2A, 2B, and 2C are steps for realizing the functions of the noise information acquisition unit 11, the noise section determination unit 12, and the noise propagation information generation unit 15 when executed by the processor 210. As a result, the noise information acquisition step, the noise section determination step, and the noise propagation information generation step are executed. The communication unit 31 and the output unit 32 in the noise management devices 2, 2A, 2B, and 2C are interfaces 230. The interface 230 is used to connect the noise management devices 2, 2A, 2B, and 2C to the constituent elements such as the display device 5, the sound sensor 9, and the electric equipment 90 via the network 4 and establish communication. Depending on the situation, the interface 230 may be composed of a plurality of types.

  Moreover, it can be said that these programs make a computer perform the procedure or method of each part of the noise management apparatus 2, 2A, 2B, 2C. Here, the memory 220 is, for example, a nonvolatile or volatile flexible semiconductor memory such as RAM, ROM, flash memory, EPROM (Erasable Programmable Read Only Memory), EEPROM (Electrically Erasable Programmable Read Only Memory), or a magnetic disk. , Optical discs, compact discs, mini discs, and DVDs (Digital Versatile Discs). Although FIG. 34 shows an example in which each of the processor 210 and the memory 220 is configured as one, a plurality of processors 210 and a plurality of memories 220 may execute the above functions in cooperation.

  Further, the hardware of the electric devices 90 and 90A according to the embodiment of the present invention includes a processor 270, a memory 280, an interface 281 and an output device 282 as shown in FIG. Each function of the electric devices 90 and 90A is realized by the processor 270 executing a program stored in the memory 280. That is, the electric devices 90 and 90A include a memory 280 for storing a program that, when executed by the processor 270, results in the step of controlling the electric devices 90 and 90A being executed. The interface 281 is for connecting the electrical devices 90 and 90A and the noise management devices 2, 2A, 2B, and 2C via the network 4 to establish communication, and a plurality of types of interfaces 281 as necessary. May be configured. The communication unit 81 in the electric devices 90 and 90 </ b> A is an interface 281. The output device 282 is a device that is included in the electric devices 90 and 90A, such as an LED, a display panel, and a motor, and can notify the user of information with light, characters, video, and sound. The notification unit 82 in the electric devices 90 and 90 </ b> A is an output device 282.

  Moreover, it can be said that these programs are what makes a computer perform the procedure or method of each part of the electric equipment 90 and 90A. Here, the memory 280 corresponds to, for example, a nonvolatile or volatile semiconductor memory such as a RAM, a ROM, a flash memory, an EPROM, and an EEPROM, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, and a DVD. FIG. 35 shows an example in which each of the processor 270 and the memory 280 is configured as one, but a plurality of processors 270 and a plurality of memories 280 may cooperate to execute the above functions.

  In addition, the hardware configuration and the flowchart described above are merely examples, and can be arbitrarily changed and modified.

  In any of the above-described embodiments, each function can be performed by a normal computer. Specifically, in the above-described embodiment, the program executed by the control units 10 and 70 has been described as being stored in advance in the ROM of the storage units 20 and 80. However, the program is stored and distributed on a computer-readable recording medium such as a flexible disk, a CD-ROM (Compact Disc Read Only Memory), a DVD, and an MO (Magneto-Optic Disc), and the program is read and installed on the computer. By doing so, you may comprise the computer which can implement | achieve each above-mentioned function. When each function is realized by sharing between an OS (Operating System) and an application, or by cooperation between the OS and the application, only a part other than the OS may be stored in the recording medium.

  In any of the above-described embodiments, each unit included in the storage unit 20 (image information storage unit 21, building information storage unit 22, noise information storage unit 23, noise propagation information storage unit 24, electrical equipment information storage unit) 25), some or all of these are not provided in the noise management devices 2, 2A, 2B, 2C, and other noise management devices 2, 2A, 2B, 2C, storage devices connected via the communication network, The structure acquired from a cloud server etc. may be sufficient.

  Furthermore, each program can be superimposed on a carrier wave and distributed via a communication network. For example, the program may be posted on a bulletin board (BBS, Bulletin Board System) on a communication network, and the program may be distributed via the network. Then, the above-described processing may be executed by starting these programs and executing them in the same manner as other application programs under the control of the OS. Then, the above-described processing may be executed by starting these programs and executing them in the same manner as other application programs under the control of the OS.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments, and the present invention includes the invention described in the claims and the equivalent scope thereof. Is included.

1, 1A, 1B, 1C, 1D Noise management system, 2, 2A, 2B, 2C Noise management device, 3 Cloud network, 4 Network, 5 Display device, 6, 6A Information terminal equipment, 7 TV, 8 HEMS remote control, 9 , 9A, 9B, 9C, 9D, 9E Sound sensor 10, 40, 70 control unit, 11 noise information acquisition unit, 12 noise section determination unit, 13 position acquisition unit, 14 image acquisition unit, 15 noise propagation information generation unit, 16, 74 Control information generation unit, 20, 50, 80 storage unit, 21 image information storage unit, 22 building information storage unit, 23 noise information storage unit, 24 noise propagation information storage unit, 25 electrical equipment information storage unit, 31, 61, 81 Communication unit, 32 output unit, 62 display unit, 63 input unit, 71 control information acquisition unit, 72 notification control unit, 73 noise propagation information acquisition unit, 82 Intelligent unit, 83 Notification unit control information storage unit, 90, 90A electric device, 91, 91A acoustic device, 92 washing machine, 93 vacuum cleaner, 94 lighting device, 100 building, 210, 270, 640, 740, 840 processor, 220 , 280, 650, 750, 850 Memory, 230, 281, 661, 761, 861 interface, 282 Output device, 301 router, 662, 762, 862 Display panel, 663, 863 Touch panel, 664 Base station interface, 763 Operation buttons / Remote control interface, 764 tuner.

Claims (9)

A noise information acquisition unit for acquiring noise information including noise characteristics detected in each section of the building composed of two or more sections, and a noise level indicating the magnitude of the noise;
Based on the noise information acquired by the noise information acquisition unit, when noise with matching noise characteristics is detected in two or more sections, noise having the maximum noise level among the noises with matching characteristics Is detected as a noise source section where a noise generation source exists, and a section other than the noise source section among the sections in which noise having the same noise characteristics is detected is transmitted as the noise. A noise zone determination unit for determining a noise destination zone as a destination;
A noise propagation information generator for generating noise propagation information including the noise source block determined by the noise block determination unit and the noise level in the noise destination block determined by the noise block determination unit;
An output unit for outputting the noise propagation information generated by the noise propagation information generation unit;
A noise management device comprising: In the section, a threshold of the noise level for determining whether noise is generated in the section is set,
The noise section determination unit
The characteristics of the noise detected in one section coincide with the characteristics of the noise detected in another section, and
When the noise level of the noise detected in the other section is not less than the threshold value set in the other section and is smaller than the noise level of the noise detected in the one section,
The one section is determined as the noise source section, and the other section is determined as the noise destination section.
The noise management device according to claim 1. The noise propagation information generation unit displays information on a screen in which an image showing the noise source section and an image showing a noise level in the noise destination section are superimposed on the floor plan of the building. Generate as
The noise management device according to claim 1 or 2. A control information generating unit that generates control information including control content for controlling the notification unit provided in the electric equipment installed in the noise source section based on the noise level in the noise destination section;
Transmitting the control information generated by the control information generation unit to the electrical device;
The noise management device according to any one of claims 1 to 3. Electric equipment installed in a noise source section where noise sources exist,
A notification unit capable of outputting light, text, video or sound;
A control information acquisition unit for acquiring control information including control content for controlling the notification unit;
A notification control unit for controlling the notification unit based on the control content included in the control information acquired by the control information acquisition unit;
With
The notification unit performs a notification operation according to a noise level in a noise destination section that is a propagation destination of the noise.
Electrical equipment. A noise propagation information acquisition unit for acquiring noise propagation information including the noise source section and a noise level in the noise destination section;
Based on the noise propagation information acquired by the noise propagation information acquisition unit, a control information generation unit that generates control information including control content for controlling the notification unit;
Further comprising
The control information acquisition unit acquires the control information generated by the control information generation unit.
The electric device according to claim 5. The noise management device according to any one of claims 1 to 4,
Two or more sound sensors that are arranged in each section of the building composed of two or more sections and detect noise;
A display device;
With
The noise information acquisition unit of the noise management device acquires noise information including a feature of noise detected by the sound sensor in two or more sections and a noise level indicating the magnitude of the noise,
The display device displays the noise propagation information output by the output unit of the noise management device;
Noise management system. A noise information acquisition step of acquiring noise information including noise characteristics detected in each section of the building composed of two or more sections and a noise level indicating the magnitude of the noise;
Based on the noise information acquired in the noise information acquisition step, a noise section determination step for determining a noise source section that is a section where a noise generation source is present and a noise destination section that is a propagation destination of the noise; ,
A noise propagation information generation step for generating noise propagation information including the noise source section determined in the noise section determination step and a noise level in the noise destination section determined in the noise section determination step;
A noise management method comprising: On the computer,
A noise information acquisition step of acquiring noise information including noise characteristics detected in each section of the building composed of two or more sections and a noise level indicating the magnitude of the noise;
Based on the noise information acquired in the noise information acquisition step, when noise with matching noise characteristics is detected in two or more sections, the maximum noise level of the noise with matching characteristics is detected. The section in which noise is detected is determined as a noise source section in which a noise generation source exists, and a section other than the noise source section among the sections in which noise having the same noise characteristics is detected is determined. A noise zone determination step for determining a noise destination zone as a propagation destination; and
A noise propagation information generation step for generating noise propagation information including the noise source section determined in the noise section determination step and a noise level in the noise destination section determined in the noise section determination step;
A program for running

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