JP2016066604A - Position information management system, position management system, position information management method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve such a problem that, conventionally, the presence or absence of human is detected by a temperature distribution sensor using a thermopile, and energy saving is achieved by turning off lighting apparatuses in an area where human is not present, but however information other than information on the presence or absence of human is not taken into account, so that energy saving corresponding to an actual situation cannot be achieved.SOLUTION: In a position information management system 8, a control content of a control target means is adjusted corresponding to not only the presence or absence of human, but also a predetermined position in a predetermined space, so that the effect of achieving energy saving corresponding to an actual condition furthermore is produced.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an invention for managing the positions of one or more control target means in a predetermined space.

  When a space such as an office is divided into areas, it is normal that areas where humans are present and areas where humans are not present are mixed. In a region where a person is present, it is necessary to turn on the lighting device so as not to hinder the human work. In a region where there is no human being, there is no need to turn on the lighting device. In order to eliminate waste of power, it is better to turn off the lighting equipment. Conventionally, the presence or absence of a human being is detected by a temperature distribution sensor using a thermopile, and energy saving is realized by turning off the luminaire in an area where no human is present (see Patent Document 1).

  However, since the apparatus described in Patent Document 1 does not consider information other than the presence or absence of human beings, there arises a problem that it is not possible to realize energy saving that matches the actual situation.

  The invention according to claim 1 is a position information management system that is capable of communicating with a detection device that detects the temperature of a predetermined space, and that manages the position of one or more control target means in the predetermined space. Heat source presence / absence information indicating the presence / absence of a heat source in the predetermined area, first control pointer management means for managing the control contents of each control target means in the predetermined space in association with each other, and a position indicating a predetermined position in the predetermined space A second control guideline management means for managing information and adjustment information for adjusting the control content in association with each other, and reception for receiving detection data indicating the temperature of each of the plurality of regions in the predetermined space from the detection device Means, first generation means for generating heat source data including heat source presence / absence information for each area based on the detection data, and the heat source presence / absence included in the heat source data By searching the second control guideline management means based on the position of the control target means for the specific control content read out by searching the first control guideline management means based on the information In consideration of the read specific adjustment information, second generation means for generating control data indicating final control content for each region, and the control data generated by the second generation means, A position information management system comprising: a transmission unit configured to transmit to each control target device including each control target unit.

  As described above, according to the present invention, the control contents of the control target means are adjusted according to a predetermined position in a predetermined space as well as the presence / absence of a human being, thereby realizing energy saving more suited to the actual situation. There is an effect that can be.

It is a schematic diagram of the whole position management system concerning an embodiment of the present invention. It is an external appearance block diagram in case a control object apparatus is a fluorescent lamp type LED lighting fixture. The hardware block diagram of a detection apparatus. It is a hardware block diagram of a positional information management system. It is each function block diagram of a position management system. (A) is a conceptual diagram of layout information of the control target device, and (B) is a conceptual diagram of layout information of the room α. It is a conceptual diagram of a control guideline management table. It is the sequence diagram which showed the process of the position management system. (A) is the conceptual diagram which showed temperature distribution, (B) is the conceptual diagram of the heat source data which shows the presence or absence of a heat source. It is a conceptual diagram of the heat source data which shows the presence or absence of all the heat sources in one living room. It is a conceptual diagram of the control guideline management table which concerns on 1st Embodiment. It is the flowchart which showed the process for calculating the light control degree of each control object apparatus. It is a conceptual diagram of the control guideline management table which concerns on 2nd Embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Outline of Embodiment]
First, the outline of the present embodiment will be described with reference to FIGS.

<< Outline of location management system >>
FIG. 1 is a schematic diagram of an entire location management system according to an embodiment of the present invention. As shown in FIG. 1, the position management system 1 of the present embodiment includes a plurality of control target devices (2a11, 2a12, 2a13, 2a21, 2a22, 2a23, 2a31, 2a32, 2a33), the control target device 2x11, the wireless router 6, and the location information management system 8.

  In addition, the control target devices (2a11, 2a12, 2a13, 2a21, 2a22, 2a23, 2a31, 2a32, 2a33) are respectively installed in the respective areas where the ceiling β is divided into nine as shown in FIG. Yes. And the detection apparatus 3 is provided in the control object apparatus 2a22 in the middle. Hereinafter, among the control target devices (2a11, 2a12, 2a13, 2a21, 2a22, 2a23, 2a31, 2a32, 2a33), any control target device is indicated as “control target device 2a”. One region is, for example, a square area of 70 cm × 70 cm.

  The control target device 2a is a fluorescent lamp type LED (Light Emitting Diode) lighting fixture. Among these, in particular, the detection device 3 of the control target device 2a22 detects a temperature distribution in which the room α is divided into a plurality of regions (here, 9 regions) by a thermopile function, and indicates a heat source indicating the presence or absence of the heat source. Send data wirelessly. The control target device 2x11 is an air conditioner.

  The wireless router 6 receives the heat source data transmitted from the detection device 3 and transmits it to the location information management system 8 via the communication network 7. The communication network 7 is constructed by a LAN (Local Area Network), and the Internet may be included in part.

  The position information management system 8 generates control data for controlling the control target devices 2a and 2x based on the heat source data and the like sent from the wireless router 6, and transmits the control data to the control target devices 2a and 2x. . The control target device 2a performs dimming control of the LED based on the control data. The control target device 2x11 controls temperature, humidity, wind force, and wind direction based on the control data. That is, the control target device 2a22 not only detects the temperature distribution of the room α, but also performs dimming control of the LED of its own device.

<< Outline of Controlled Device >>
Next, the apparatus main body for attaching the control target apparatus 2a and the control target apparatus 2a will be described with reference to FIG. FIG. 2 is an external configuration diagram when the control target device is a fluorescent lamp type LED lighting apparatus.

  As shown in FIG. 2, the control target device 2a22 as a fluorescent lamp type LED lighting fixture is a straight tube type lamp 130, around the center of the ceiling β of the room α shown in FIG. It can be attached to the installed apparatus main body 120. A socket 121a and a socket 121b are provided at both ends of the apparatus main body 120, respectively. Among these, the socket 121a has power supply terminals (124a1, 124a2) for supplying power to the LED lamp 130. The socket 121b also has power supply terminals (124b1, 124b2) for supplying power to the LED lamp 130. Thereby, the apparatus main body 120 can supply the power from the power source to the LED lamp 130.

  On the other hand, the LED lamp 130 includes a translucent cover 131, caps (132 a and 132 b) provided at both ends of the translucent cover 131, and the detection device 3 inside the translucent cover 131. Among these, the translucent cover 131 is formed, for example with resin materials, such as an acrylic resin, and is provided so that an internal light source may be covered.

  Further, the base 132a is provided with terminal pins (152a1, 152a2) connected to the power supply terminals (124a1, 124a2) of the socket 121a, respectively. The base 132b is provided with terminal pins (152b1, 152b2) connected to the power supply terminals (124b1, 124b2) of the socket 121b, respectively. Then, the LED lamp 130 is attached to the apparatus main body 120, so that each terminal pin (152a1, 152a2, 152b1, 152b2) is connected to the apparatus main body 120 via the power supply terminals (124a1, 124a2, 124b1, 124b2). Electric power can be supplied. Thereby, the LED lamp 130 irradiates light to the outside through the translucent cover 131. The detection device 3 operates with power supplied from the device main body 120.

<< Hardware configuration of location management system >>
Hereinafter, the hardware configuration of the detection apparatus 3 and the position information management system, which are the main parts constituting the position management system, will be described.

<Hardware configuration of detection device>
Next, the hardware configuration of the detection apparatus will be described with reference to FIG. FIG. 3 is a hardware configuration diagram of the detection apparatus. The detection device 3 electrically connects the wireless module 301, the antenna I / F 302, the antenna 302a, the sensor driver 304, the temperature distribution sensor 311, the illuminance sensor 312, the temperature / humidity sensor 313, the device controller 315, and each of the above components. For this purpose, a bus line 310 such as an address bus or a data bus is provided.

  Among these, the wireless module 301 is a component for performing wireless communication, and can perform communication by a communication method such as Bluetooth (registered trademark), WiFi, or ZigBee, via the antenna I / F 302 and the antenna 302a. Wireless communication with an external device is realized. The communication method may be not only wireless communication but also wired communication such as Ethernet (registered trademark) cable or PLC (Power Line Communications). The wireless module 301 operates under the control of the communication control program.

  The temperature distribution sensor 311 is a thermopile sensor that detects the temperature distribution in the living room α by detecting infrared rays.

  The illuminance sensor 312 is a sensor that detects the brightness in the room α. The temperature / humidity sensor 313 is a sensor that detects the temperature and humidity of the room α.

  The sensor driver 304 is a circuit that drives the temperature distribution sensor 311, the illuminance sensor 312, and the temperature / humidity sensor 313, and further generates heat source data indicating the presence or absence of a heat source from the temperature distribution data output from the temperature distribution sensor 311. is there. The sensor driver 304 may realize a function by software. The device controller 315 is a circuit for controlling dimming of the LED when provided in the control target device 2a. The device controller 315 is a circuit for controlling the air volume of the air conditioner and the like when provided in the control target device 2x11. These circuits are operated by a program that operates under the control of software (for example, a detection control program stored in a memory such as a RAM). The control target device 2a other than the control target device 2a22 includes a wireless module 301, an antenna I / F 302, an antenna 302a, a bus line 310, and a device controller 315 in the configuration shown in FIG. The control target device 2a other than the control target device 2a22 includes a communication device 5 having the ability to communicate with the position information management system 8.

<Hardware configuration of location information management system>
Next, the hardware configuration of the location information management system will be described. FIG. 4 is a hardware configuration diagram of the location information management system.

  The location information management system 8 is configured by a computer. The location information management system 8 is used as a work area for the CPU 801 that controls the overall operation of the location information management system 8, a ROM 802 that stores programs used to drive the CPU 801 such as an IPL (Initial Program Loader), and the CPU 801. RAM 803, HD 804 for storing various data such as a position information management program, HDD (Hard Disk Drive) 805 for controlling reading or writing of various data to the HD 804 according to the control of the CPU 801, data reading to a recording medium 806 such as a flash memory Or a media I / F 807 for controlling writing (storage), a display 808 for displaying various information such as a cursor, menu, window, character, or image, and a network for data communication using the communication network 7. Work I / F 809, a keyboard 811 having a plurality of keys for inputting characters, numerical values, various instructions, a mouse 812 for selecting and executing various instructions, selecting a processing target, moving a cursor, and the like, detachable A CD-ROM drive 814 that controls reading or writing of various data with respect to a CD-ROM (Compact Disc Read Only Memory) 813 as an example of a recording medium, and an address bus for electrically connecting each of the above components A bus line 810 such as a data bus is provided.

<< Functional configuration of location management system >>
Subsequently, the hardware configuration of the control target device 2a22 including the detection device 3, the control target device 2a11 (2x), and the position information management system 8 will be described with reference to FIG. FIG. 5 is a functional configuration diagram of the position management system.

<Functional Configuration of Control Target Device 2a22>
First, the functional configuration of the control target device 2a22 will be described. The control target device 2 a 22 includes the detection device 3 and the control target unit 20. Furthermore, the detection device 3 includes a transmission / reception unit 31, a detection unit 32, and a control unit 35 as functions or means. The control target unit 20 is, for example, an LED lamp 130 that is a target of light control.

  In the detection device 3, the transmission / reception unit 31 is a function or means realized by operating according to a command according to a program in the wireless module. For example, the transmission / reception unit 31 transmits / receives data to / from the location information management system 8 via the communication network 2.

  The detection unit 32 is a function or means realized by the operation of each sensor 311, 312, 313. For example, the detection unit 32 detects the temperature distribution of each region in the predetermined space.

  The control unit 35 is a function or means realized by the operation of the device controller 315. For example, the control unit 35 generates a control signal to be output to the control target unit 20 based on the control data sent from the position information management system 8.

<Functional Configuration of Control Target Device 2a11>
Next, the functional configuration of the control target device 2a11 will be described. The control target device 2a11 includes the communication device 5 and the control target unit 20. Further, the communication device 5 includes a transmission / reception unit 51 and a control unit 55. The control target unit 20 is, for example, a light emitting function of an LED that is a subject of light control. In the case of the control target device 2x11 as an air conditioner, the control target unit 20 is a compressor or the like of an air conditioner that controls temperature, humidity, wind power, and wind direction.

  In the communication device 5, the transmission / reception unit 51 is a function or means realized by operating according to a command according to a program in the wireless module. Note that the transmission / reception unit 51 has the same function or means as the transmission / reception unit 31 described above, and thus the description thereof is omitted.

  The control unit 55 is a function or means realized by the operation of the device controller 315. Note that the control unit 55 has the same function or means as the control unit 35 described above, and a description thereof will be omitted.

<Functional configuration of location information management system>
Next, the functional configuration of the location information management system will be described. The location information management system 8 includes a transmission / reception unit 81, a collation unit 82, a generation unit 84, and a storage / read processing unit 89. Each unit is a function or means realized by operating according to a command from the CPU 801 according to the location information management program developed from the HD 804 onto the RAM 803. Further, the location information management system 8 has a storage unit 8000 constructed by the RAM 803 and the HD 804 shown in FIG. In the storage unit 8000, a layout management DB 8001 and a control guide management DB 8002 are constructed.

(Layout management DB)
Next, the layout management DB 8001 will be described with reference to FIG. The layout management DB 8001 manages the layout information of the control target device as shown in FIG. 6A is a conceptual diagram of the layout information of the control target device, and FIG. 6B is a conceptual diagram of the layout information of the living room. Each area of the layout information shown in FIG. 6A shows an area separated by a wavy line or a solid line on the layout of the actual room α shown in FIG. 6B.

  Further, as shown in FIG. 6A, the layout information of the control target device divides one living room α into 54 regions, and identifies the control target device as an LED lighting apparatus in each region. Device IDs are managed. Among these, the upper left block whose device ID starts with “a” corresponds to the nine regions in FIG. That is, FIG. 1 shows a part of the room α, and the room ID is divided into six blocks whose device IDs start with a, b, c, d, e, and f. Further, each block is divided into 9 regions, and a total of 54 regions. This division is an example, and it may be divided into any number of blocks, and one block may be divided into a number of areas other than nine areas.

  In FIG. 6A, device IDs x11, x12, x21, and x22 are device IDs for identifying control target devices 2x11, 2x12, 2x21, and 2x22 as air conditioners, respectively. Although the control target devices 2x12, 2x21, and 2x22 are not shown in FIG. 1, they are installed on the ceiling β where x12, x21, and x22 are shown in FIG. That is, four air conditioners are attached to the ceiling β of the living room α. Hereinafter, among the control target devices (2 × 11, 2 × 12, 2 × 21, 2 × 22), when an arbitrary control target device is indicated, “control target device 2x” is indicated.

  FIG. 6B shows an actual layout in which desks and chairs are arranged. 6B, the same room as the room shown in FIG. 6A is divided into 54 areas. That is, the position of each area in FIG. 6B is the same as the position of each area in FIG. In FIG. 6B, the lower side of the paper is the corridor γ side, and the upper side of the paper is the window side.

(Control guideline management DB)
Next, the control guideline management DB 8002 will be described with reference to FIG. A control guide management table as shown in FIG. 7 is managed in the control guide management DB. In this control guideline management table, the control contents of the control target unit 20 are associated and managed for each heat source presence / absence information. For example, when the heat source presence / absence information is “1” indicating that there is a heat source, since there is a person in the area, the dimming degree is set to 100% in order to maximize the light quantity of the LED. On the other hand, when the heat source presence / absence information is “0” indicating that there is no heat source, since there is no person in the area, the light amount of the LED is slightly reduced to 60% in order to realize energy saving. Note that 100% and 60% are examples, and may be any percentage as long as the dimming degree of the heat source “1” is higher than the dimming degree of the heat source “0”, such as 90% and 50%.

(Functional configuration of location information management system)
Next, each functional configuration of the position information management system 8 will be described with reference to FIG.

  The transmission / reception unit 81 illustrated in FIG. 5 receives, for example, detection data from the detection device 3 or transmits control data to the detection device 3.

  For example, the collation unit 82 collates layout information shown in FIG. 6A described later with heat source data shown in FIG. 10 described later.

  For example, the generation unit 84 generates heat source data indicating the presence or absence of a heat source based on the temperature distribution data. Moreover, the production | generation part 84 produces | generates the control data which show the light control degree with respect to control object apparatus 2a, 2x, for example.

  For example, the storage / reading processing unit 89 reads data from the storage unit 8000 or stores data in the storage unit 8000.

<< Processing or operation of location management system >>
Hereinafter, processing or operation of the location management system will be described with reference to FIGS. FIG. 8 is a sequence diagram showing processing of the location management system. FIG. 9A is a conceptual diagram showing a temperature distribution, and FIG. 9B is a conceptual diagram of heat source data indicating the presence or absence of a heat source. FIG. 10 is a conceptual diagram of heat source data indicating the presence or absence of all the heat sources in one room.

  Here, the position information management system 8 generates control data for controlling each control target device 2a, 2x based on various data detected by the control target device 2a22, and sends it to each control target device 2a, 2x. A process is disclosed in which the control target devices 2a and 2x perform control of light control, air volume, and the like by transmitting control data. For simplification of description, processing of the control target device 2a22 including the detection device 3 and the control target device 2a11 including the communication device 5 among the control target devices 2a will be described.

  First, as illustrated in FIG. 8, the detection unit 32 of the control target device 2a22 detects the temperature distribution of each region in the living room α (step S21). The detection unit 32 of the control target device 2a22 detects the illuminance, temperature, and humidity near the control target device 2a22 (step S22). And the transmission / reception part 31 transmits detection data with respect to the positional infomation management system 8 (step S23). The detection data includes temperature distribution data indicating the result detected in step S21, and temperature / humidity data and illuminance data indicating the result detected in step S22. Thereby, the transmission / reception part 81 of the positional information management system 8 receives detection data.

  Next, the production | generation part 84 of the positional information management system 8 produces | generates heat source data based on temperature distribution data (step S24). Here, generation of heat source data will be described with reference to FIG. As a result of detecting the temperature of each region by the detection unit 32 of the detection device 3, when the temperature distribution of the nine regions is in the state shown in FIG. 9A, the generation unit 84 of the location information management system 8 Heat source data as shown in 9 (B) is generated. That is, the heat source data is indicated by heat source presence / absence information indicating the presence / absence of a heat source. A region where the temperature is 30 ° C. or higher is expressed as “1”, and a region where the temperature is lower than 30 ° C. is expressed as “0”. Moreover, in step S24, the production | generation part 84 synthesize | combines the heat source data produced | generated based on the temperature distribution data sent from each block. The synthesized data is shown in FIG. FIG. 10 is a conceptual diagram of heat source data indicating the presence or absence of all the heat sources in one room. For example, the heat source data shown in FIG. 9B constitutes the first block at the upper left in FIG.

  Next, the storage / reading processing unit 59 of the position information management system 8 reads the layout information shown in FIG. 6A from the layout management DB 8001 (step S25). And the collation part 82 collates the layout information shown by FIG. 6 (A), and the heat source data shown by FIG. 10 (step S26). By this collation, for example, the position (a11) of the control target device in the layout information is “1”, that is, “there is a heat source” based on the heat source data.

  Next, the storage / reading processing unit 59 of the position information management system 8 searches the control guideline management DB 8002 using “1” and “0” indicating the presence / absence of the heat source in the heat source data as a search key, thereby corresponding control information. The luminous intensity is read (step S27). And the production | generation part 84 produces | generates the control data which show the light control degree with respect to the control object apparatus 2a11 (step S28). In the case of the control target device 2x as an air conditioner, the generation unit 84 generates control data indicating the air volume and the like for each control target device 2x.

  Next, the transmission / reception part 51 transmits each control data with respect to the control object apparatus 2a22, 2a11 (step S29-1, S29-2). On the other hand, the transmission / reception unit 31 in the detection device 3 of the control target device 2a22 receives control data. The transmission / reception unit 51 in the communication device 5 of the control target device 2a11 receives control data.

  Next, in the control target device 2a22, the control unit 35 of the detection device 3 generates a control signal to be output to the control target unit 20 as an LED lamp based on the control data (step S30-1). It outputs to the part 20 (step S31-1). Thereby, the light quantity of the control object part 20 as an LED lamp is controlled. Similarly, in the control target device 2a11, the control unit 55 of the communication device 5 generates a control signal to be output to the control target unit 20 as an LED lamp based on the control data (step S30-2). It outputs to the part 20 (step S31-2). Thereby, the light quantity of the control object part 20 as an LED lamp is controlled. For example, in FIG. 9A, since there is no heat source immediately below the control target device 2a22, it is indicated by “0”. Therefore, the control content of the control target device 2a22 has a dimming degree of 60% according to FIG. . On the other hand, in FIG. 9 (A), it is indicated by “1” that there is a heat source directly under the control target device 2a11. Therefore, the control content of the control target device 2a11 is 100% dimming according to FIG. . As a result, when the heat source is detected because there is a person, the light quantity of the LED is maximized, and when the heat source is not detected because there is no person, the light quantity of the LED is reduced, thereby realizing energy saving. Can do.

[Specific Description of this Embodiment]
Hereinafter, this embodiment will be described in detail with reference to FIGS. 11 to 13. Here, two patterns in steps S27 and S28 in FIG. 8 will be described.

<< First Embodiment >>
<Characteristics of First Embodiment>
Hereinafter, the first embodiment will be described with reference to FIGS. 11 and 12. FIG. 11 is a conceptual diagram of the control guideline management table. 7 is a basic control guideline management table (an example of a first control guideline management table) used for calculating the basic dimming degree, and the table in FIG. 11 is a basic dimming degree. 6 is an application control guideline management table (an example of a second control guideline management table) for changing according to the area type. The control guide management DB 8002 manages the basic control guide management table of FIG. 7 and the application control guide management table of FIG.

  The application control guideline management table shown in FIG. 11 includes region position information and adjustment information for adjusting the dimming degree by multiplying the basic dimming degree (for example, for each area type indicating the type of area). , Coefficient) are managed in association with each other. For example, when the region type is “window side”, the position on the window side is “a”, which is the first symbol of the device ID of the control target device in the layout information of the control target device shown in FIG. “B” and “c” are areas where the basic dimming factor is multiplied by “0.8”. This guideline is set in consideration of the fact that the window side is brighter than the corridor side.

  Next, the processing or operation of this embodiment will be described with reference to FIG. FIG. 12 is a flowchart illustrating a process for calculating the dimming degree of each control target device. In FIG. 12, in order to explain the process of step S27 of FIG. 8 in detail, the process of step S27-1, 2 is shown, and in order to explain the process of step S28 of FIG. Process 2 is shown.

  First, the storage / reading processing unit 89 of the location information management system 8 performs basic control using “1” and “0” indicating the presence / absence of a heat source in the temperature distribution data received in step S23 for each region as search keys. By searching the pointer management table (see FIG. 7), the corresponding dimming degree is read (step S27-1). Further, the storage / reading processing unit 89 uses the application control guideline management table (see FIG. 11) for each region using the symbol “a” at the beginning of the device ID shown in FIG. 6A as a search key. By searching, the corresponding coefficient is read (step S27-2).

  Next, the generation unit 84 multiplies the basic dimming level read out in step S27-1 by the coefficient read out in step S27-2 so that the final dimming for each region is performed. The luminous intensity is calculated (step S28-1). And the production | generation part 84 produces | generates the control data in each area | region using the calculation result of step S28-1 (step S28-2).

  In the application control guideline management table, the area type considering the layout is set. However, the present invention is not limited to this, and the area type may be set considering the layout including the time zone element. For example, a coefficient may be set every 3 hours.

<Effect of the first embodiment>
As described above, according to the present embodiment, the dimming degree can be controlled in detail in consideration of not only the presence or absence of a human being but also the layout of a room such as a window side or a corridor side. Thereby, there exists an effect that the energy saving matched with the actual condition is realizable.

<< Second Embodiment >>
<Characteristics of Second Embodiment>
Hereinafter, the second embodiment will be described with reference to FIG. FIG. 13 is a conceptual diagram of the control guideline management table. The table in FIG. 13 is an applied control guide management table (an example of a second control guide management table) for changing the basic dimming degree according to the region type. The control guide management DB 8002 manages the basic control guide management table of FIG. 7 and the application control guide management table of FIG.

  The application control guideline management table shown in FIG. 13 has the same structure as the application control guideline management table shown in FIG. 11, but the managed attributes are different. That is, in the first embodiment, the dimming degree is determined in consideration of a layout including sunlight as an element, but in the second embodiment, the dimming degree is determined in consideration of work contents. In FIG. 13, a break place, an office work place, and a precision work place are managed as area types. In addition, here, the entire room α shown in FIGS. 6A and 6B is divided into three, with the left side being a resting place, the center being an office work place, and the right side being a precision work place. And the factor is "0.6" because the resting place may be dark, the factor is "0.8" because the office work place should be relatively bright, and the precision work place needs the maximum brightness Therefore, the coefficient is “1”.

  In addition, since the process or operation | movement of this embodiment is a process or operation | movement similar to 1st Embodiment, description is abbreviate | omitted. Further, the application control management tables of the first and second embodiments may be used in combination.

<Effects of Second Embodiment>
As described above, according to the present embodiment, the dimming degree can be controlled in detail in consideration of not only the presence / absence of a person but also work contents such as work precision. Thereby, there exists an effect that the energy saving matched with the actual condition is realizable.

DESCRIPTION OF SYMBOLS 1 Position management system 2a11 Control object apparatus 2a22 Control object apparatus 2x11 Control object apparatus 3 Detection apparatus 5 Communication apparatus 6 Wireless router 7 Communication network 8 Location information management system 20 Control object part (an example of control object means)
31 Transmission / Reception Unit 32 Detection Unit 33 Determination Unit 34 Generation Unit 35 Control Unit 51 Transmission / Reception Unit 55 Control Unit 81 Transmission / Reception Unit (Example of Receiving Unit, Example of Transmission Unit)
82 collation unit 84 generation unit (an example of a first generation unit, an example of a second generation unit)
89 Storage / Read Processing Unit 8000 Storage Unit 8001 Layout Management DB
8002 Control guideline management DB (an example of first control guideline management means, an example of second control guideline management means)

Patent No. 4340925

Claims (8)

A position information management system capable of communicating with a detection device for detecting a temperature of a predetermined space and managing the position of one or more control target means in the predetermined space,
Heat source presence / absence information indicating the presence / absence of a heat source in a predetermined region in the predetermined space, and first control guideline management means for managing the control contents of each control target means in the predetermined space in association with each other;
Second control guideline management means for managing in association with position information indicating a predetermined position of the predetermined space and adjustment information for adjusting the control content;
Receiving means for receiving detection data indicating the temperature of each of the plurality of regions in the predetermined space from the detection device;
First generating means for generating heat source data including heat source presence / absence information for each region based on the detection data;
For the specific control content read out by searching the first control guideline management unit based on the heat source presence / absence information included in the heat source data, the second control unit based on the position of the control target unit. In consideration of the specific adjustment information read out by searching the control guideline management means, a second generation means for generating control data indicating the final control content for each region;
Transmitting means for transmitting the control data generated by the second generating means to each control target device provided with each control target means;
A positional information management system comprising:   The positional information management according to claim 1, wherein when the control target device is a lighting fixture and the control target means is a lamp in the lighting fixture, the control content indicates a dimming degree of the lamp. system.   When the predetermined space is a living room, the position information indicates a window side or a hallway side, and the adjustment information indicates that the dimming degree of the lamp is closer to the maximum on the hallway side than the window side. The location information management system according to claim 2.   When the predetermined space is a living room, the position information indicates a precision work place, an office work place, or a rest place, and the adjustment information indicates the dimming degree of the lamp in the order of the precision work place, the office work place, and the rest place. The position information management system according to claim 2, wherein the position information management system indicates that the value is close to a maximum.   The position information management system according to any one of claims 1 to 4, wherein the lamp is an LED lamp. The location information management system according to any one of claims 1 to 5,
The detection device;
A location management system comprising: A position information management method executed by a position information management system capable of communicating with a detection device for detecting a temperature of a predetermined space and managing the position of one or more control target means in the predetermined space,
The location information management system includes:
Heat source presence / absence information indicating the presence / absence of a heat source in a predetermined region in the predetermined space, and first control guideline management means for managing the control contents of each control target means in the predetermined space in association with each other;
Second control guideline management means for managing in association with position information indicating a predetermined position of the predetermined space and adjustment information for adjusting the control content;
Have
The location information management system includes:
A reception step of receiving detection data indicating the temperature of each of the plurality of regions in the predetermined space from the detection device;
A first generation step of generating heat source data including heat source presence / absence information for each region based on the detection data;
For the specific control content read out by searching the first control guideline management unit based on the heat source presence / absence information included in the heat source data, the second control unit based on the position of the control target unit. A second generation step of generating control data indicating final control content for each of the areas in consideration of the specific adjustment information read out by searching the control guideline management means;
A transmission step of transmitting the control data generated by the second generation step to each control target device provided with each control target means;
A location information management method comprising:   The program for making a computer perform each step of Claim 7.

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