Patent Publication Number: US-2019179274-A1

Title: Control content management system, power control system, control content management method, and computer-readable recording medium

Description:
FIELD 
     The present invention relates to an invention for management of contents of control for a controlled system in a predetermined space. 
     BACKGROUND 
     When an area of a space, such as an office, is partitioned, both an area with a person (a user) and an area without a person (a user) are normally present. In an area with a user, lighting equipment needs to be turned on such that work of the user is not undermined, and in an area without a user, lighting equipment does not need to be turned on. Illumination equipment is preferably turned off for elimination of waste of power. Conventionally, energy saving has been realized by: detection of presence or absence of a user by use of a temperature distribution sensor with a thermopile; and lighting equipment being turned off in an area where a user is not present (see Patent Literature 1). 
     SUMMARY 
     Technical Problem 
     However, since the apparatus described in Patent Literature 1 controls the lighting equipment according to presence or absence of a user without exception, the apparatus has been unable to control lighting in a way matching the actual conditions. 
     Solution to Problem 
     An invention according to claim  1  is a control content management system that is able to communicate with a detection device, which detects temperature of a predetermined space, and with a mobile terminal, and that manages a control content of a controlled system in the predetermined space; the control content management system including: a control content management means for management of predetermined heat source presence or absence information indicating presence or absence of a heat source in the predetermined space, in association with a predetermined control content for the controlled system in the predetermined space; an adjustment target management means for management of predetermined adjustment target identification information for identification of one or plural controlled systems, for which control contents are adjusted altogether, in association with control target identification information for identification of each controlled system indicated by the predetermined adjustment target identification information; a receiving means that receives, from the detection device, specific control target identification information for identification of a specific controlled system that is able to communicate with the detection device, and specific heat source presence or absence information indicating presence or absence of a heat source in a specific space where the specific controlled system is present; and a transmitting means that transmits, to the specific controlled system, control data indicating a specific control content corresponding to the received specific heat source presence or absence information in the control content management means; the receiving means receiving, from the mobile terminal, the specific adjustment target identification information, and an adjustment degree for adjustment of a control content for the controlled system indicated by the specific adjustment target identification information; the transmitting means transmitting, to the specific controlled system indicated by the specific control target identification information corresponding to the received specific adjustment target identification information in the adjustment target management means, adjustment data indicating the adjustment degree. 
     Advantageous Effects of Invention 
     As described above, according to the present invention, not only determination of a control content for a controlled device according to presence or absence of a heat source is enabled, but also adjustment of the control content for the controlled device based on a past control content adjustment degree from a mobile terminal is enabled. Thereby, an effect of enabling lighting control matching the actual conditions more is able to be achieved. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  is a schematic diagram of the whole of a power control system according to an embodiment of the present invention. 
         FIG. 2  is an external appearance configuration diagram in a case where a controlled system is fluorescent lamp type LED lighting equipment. 
         FIG. 3  is a hardware configuration diagram of a detection device. 
         FIG. 4  is a hardware configuration diagram of a mobile terminal. 
         FIG. 5  is a hardware configuration diagram of a control content management system. 
         FIG. 6  is a functional configuration diagram of the power control system. 
         FIG. 7(A)  is a conceptual diagram of layout information of controlled systems, and  FIG. 7(B)  is a conceptual diagram of layout information of a room α. 
         FIG. 8  is a conceptual diagram of a control content management table. 
         FIG. 9  is a conceptual diagram of an adjustment degree management table. 
         FIG. 10  is a conceptual diagram of a consumption management table. 
         FIG. 11  is a conceptual diagram of a user management table. 
         FIG. 12  is a conceptual diagram of an adjustment target management table. 
         FIG. 13  is a conceptual diagram of an adjustment range management table. 
         FIG. 14  is a diagram illustrating an example of an adjustment range registration screen. 
         FIG. 15  is a sequence diagram illustrating processing of the power control system. 
         FIG. 16(A)  is a conceptual diagram illustrating a temperature distribution, and  FIG. 16(B)  is a conceptual diagram of heat source data indicating presence and absence of heat sources. 
         FIG. 17  is a conceptual diagram of heat source data indicating presence and absence of all of heat sources in one room. 
         FIG. 18  is a sequence diagram illustrating control content adjustment processing. 
         FIG. 19  is a screen transition diagram for a mobile terminal upon lighting adjustment. 
         FIG. 20  is a screen transition diagram for a mobile terminal upon air conditioning adjustment. 
         FIG. 21  is a sequence diagram illustrating processing for display of power consumption. 
         FIG. 22  is a screen transition diagram for a mobile terminal upon display of power consumption. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     Hereinafter, by use of the drawings, an embodiment of the present invention will be described. 
     Outline of Power Control System 
       FIG. 1  is a schematic diagram of the whole of a power control system according to an embodiment of the present invention. As illustrated in  FIG. 1 , a power control system  1  according to this embodiment is constructed of: plural controlled systems ( 2 A 11 ,  2 A 12 ,  2 A 13 ,  2 A 21 ,  2 A 22 ,  2 A 23 ,  2 A 31 ,  2 A 32 , and  2 A 33 ) installed at a ceiling β side of a room α that is an example of a predetermined space; a controlled system  2 X 11 ; a wireless router  6 ; and a control content management system  9 . 
     Further, the controlled systems ( 2 A 11 ,  2 A 12 ,  2 A 13 ,  2 A 21 ,  2 A 22 ,  2 A 23 ,  2 A 31 ,  2 A 32 , and  2 A 33 ) are respectively installed, as illustrated in  FIG. 1 , in nine areas resulting from division of the ceiling β. The controlled system  2 A 22  in the middle has a detection device  3  provided therein. Hereinafter, an arbitrary one of the controlled systems ( 2 A 11 ,  2 A 12 ,  2 A 13 ,  2 A 21 ,  2 A 22 ,  2 A 23 ,  2 A 31 ,  2 A 32 , and  2 A 33 ) will be referred to as a “controlled system  2 A”. Further, an arbitrary one of the controlled system  2 X 11  and controlled systems ( 2 X 12 ,  2 X 21 , and  2 X 22 ) that will be described later will be referred to as a “controlled system  2 X”. One area corresponds to, for example, a square range of 70 cm×70 cm. 
     The controlled system  2 A is fluorescent lamp type light emitting diode (LED) lighting equipment. In particular, the detection device  3  of the controlled system  2 A 22  detects, through functions of a thermopile, a temperature distribution in plural areas (herein, nine areas) resulting from division of the room α, and wirelessly transmits heat source data indicating presence and absence of heat sources. The controlled system  2 X 11  is an air conditioner. 
     The wireless router  6  receives the heat source data transmitted from the detection device  3 , and transmits the heat source data to the control content management system  9  via a communication network  7 . The communication network  7  is constructed of a local area network (LAN), and a part of the communication network  7  may include the Internet. 
     Based on the heat source data and the like transmitted from the wireless router  6 , the control content management system  9  generates control data indicating control contents for control of the controlled systems  2 A and  2 X, and transmits the control data to the controlled systems  2 A and  2 X 11 . Based on the control data, the controlled system  2 A executes LED lighting control. Based on the control data, the controlled system  2 X 11  executes control of temperature, humidity, air flow power, and air flow direction. That is, the controlled system  2 A 22  not only detects the temperature distribution in the room α, but also executes LED lighting control within the controlled system  2 A 22 . 
     Further, in the room  60  , there are a mobile terminal  7 A and a power source tap  2 T 1  that are used personally by a user A, and a mobile terminal  7 B and a power source tap  2 T 2  that are used personally by a user B. These mobile terminals are, for example, smartphones. Hereinafter, an arbitrary one of the mobile terminals  7 A and  7 B will be referred to as a “mobile terminal  7 ”. Further, an arbitrary one of the power source taps  2 T 1  and  2 T 2  will be referred to as a “power source tap  2 T”. For example, by using the mobile terminal  7 A, the user A requests the control content management system  9  to adjust the control content for a controlled system. Thereby, the control content management system  9  adjusts the degree of lighting control for each controlled system  2 A, temperature of each controlled system  2 X, and the like, by transmitting the control data with the adjusted control contents to the controlled systems  2 A and  2 X. 
     Further, the control content management system  9  is able to manage power consumption of the controlled systems  2 A and  2 X and the power source taps  2 T. The control content management system  9  is able to obtain power consumptions of the predetermined controlled systems  2 A and  2 X and power source taps  2 T, from an electricity meter. The control content management system  9  may directly obtain the power consumption, from the electricity meter to the predetermined controlled systems  2 A and  2 X and power source taps  2 T. In this case, the power source taps  2 T are each a power source tap with a wattmeter, and each transmit a personal use target identification (ID) for identification of itself and a power consumption, to the control content management system  9 , via the local area network (LAN). 
     Further, the user A is able to obtain consumption data indicating the user A&#39;s power consumption in a fixed time period (for example, one month) from the control content management system  9 , by accessing the control content management system  9  from the user A&#39;s mobile terminal  7 A. 
     Outline of Controlled System 
     Next, by use of  FIG. 2 , the controlled system  2 A and an equipment body for installation of the controlled system  2 A will be described.  FIG. 2  is an external appearance configuration diagram in a case where a controlled system is fluorescent lamp type LED lighting equipment. 
     As illustrated in  FIG. 2 , the controlled system  2 A 22  serving as the fluorescent lamp type LED lighting equipment is a straight tube type lamp  130 , and is able to be attached to an equipment body  120  installed around a central portion of the ceiling β of the room α illustrated in  FIG. 1 . At both end portions of the equipment body  120 , a socket  121   a  and a socket  121   b  are respectively provided. Among these, the socket  121   a  has power supply terminals ( 124   a   1  and  124   a   2 ) that supply power to the LED lamp  130 . Further, the socket  121   b  also has power supply terminals ( 124   b   1  and  124   b   2 ) that supply power to the LED lamp  130 . Thereby, the equipment body  120  is able to supply power from a power source to the LED lamp  130 . 
     Furthermore, the LED lamp  130  has a light transmissive cover  131 , bases ( 132   a  and  132   b ) provided respectively at both end portions of this light transmissive cover  131 , and the detection device  3  inside the light transmissive cover  131 . Among these, the light transmissive cover  131  is formed of, for example, a resin material, such as acrylic resin, and is provided to cover a light source inside the light transmissive cover  131 . 
     Further, the base  132   a  has terminal pins ( 152   a   1  and  152   a   2 ), which are respectively connected to the power supply terminals ( 124   a   1  and  124   a   2 ) of the socket  121   a , provided therein. Furthermore, the base  132   b  has terminal pins ( 152   b   1  and  152   b   2 ), which are respectively connected to the power supply terminals ( 124   b   1  and  124   b   2 ) of the socket  121   b,  provided therein. By installation of the LED lamp  130  in the equipment body  120 , power is able to be respectively supplied from the terminal pins ( 152   a   1 ,  152   a   2 ,  152   b   1 , and  152   b   2 ) via the power supply terminals ( 124   a   1 ,  124   a   2 ,  124   b   1 , and  124   b   2 ) from the equipment body  120 . Thereby, the LED lamp  130  emits light to outside via the light transmissive cover  131 . Moreover, the detection device  3  is operated by the power supplied from the equipment body  120 . 
     Hardware Configuration of Power Control System 
     Hereinafter, a hardware configuration of the detection device  3  and the control content management system, which are main parts forming the power control system, will be described. 
     Hardware Configuration of Detection Device 
     Next, by use of  FIG. 3 , a hardware configuration the detection device will be described.  FIG. 3  is a hardware configuration diagram of the detection device. The detection device  3  includes a wireless module  301 , an antenna I/F  302 , an antenna  302   a,  a sensor driver  304 , a temperature distribution sensor  311 , an illuminance sensor  312 , a temperature and humidity sensor  313 , a device controller  315 , and a bus line  310 , such as an address bus or a data bus, for electrically connecting these components. 
     Among these, the wireless module  301  is a part for performing wireless communication, is able to perform communication according to a communication mode, such as that of Bluetooth (registered trademark), Wi-Fi, or ZigBee, and realizes wireless communication with an external device via the antenna I/F  302  and the antenna  302   a.  The communication mode may be, not only of wireless communication, but may be of wired communication, such as that with an Ethernet (registered trademark) cable or that of power line communications (PLC). The wireless module  301  operates under control by a communication control program. 
     The temperature distribution sensor  311  is a thermopile type sensor that detects a temperature distribution in the room α by detecting infrared light. 
     The illuminance sensor  312  is a sensor that detects illuminance in the room α. The temperature and humidity sensor  313  is a sensor that detects temperature and humidity in the room α. 
     The sensor driver  304  is a circuit that drives the temperature distribution sensor  311 , the illuminance sensor  312 , and the temperature and humidity sensor  313 , and further generates, from temperature distribution data output from the temperature distribution sensor  311 , heat source data indicating presence and absence of heat sources. Functions of the sensor driver  304  may be implemented by software. The device controller  315  is a circuit for performing lighting control for an LED if the device controller  315  is provided in the controlled system  2 A. Further, the device controller  315  is a circuit for performing control of air flow rate and the like of the air conditioner if the device controller  315  is provided in the controlled system  2 X 11 . These circuits are operated by a program that operates under control by software (for example, a detection control program stored in a memory, such as a RAM). The controlled systems  2 A other than the controlled system  2 A 22  each include the wireless module  301 , the antenna I/F  302 , the antenna  302   a,  the bus line  310 , and the device controller  315 , of the configuration illustrated in  FIG. 3 . 
     Hardware Configuration of Mobile Terminal 
     Next, a hardware configuration of a mobile terminal will be described.  FIG. 4  is a hardware configuration diagram of a mobile terminal. 
     As illustrated in  FIG. 5 , a smartphone, which is an example of the mobile terminal  7 , includes a CPU  701 , a ROM  702 , a RAM  703 , an EEPROM  704 , a CMOS sensor  705 , an acceleration and azimuth sensor  706 , a media I/F  708 , and a GPS receiving unit  709 . 
     Among these, the CPU  701  controls operation of the whole mobile terminal  7 . The ROM  702  stores therein a program that is used: by the CPU  701 ; or in driving of the CPU  701 ; such as an IPL. The RAM  703  is used as a work area of the CPU  701 . The EEPROM (electrically erasable and programmable ROM)  704  performs reading or writing of various data, such as a program for mobile terminals, according to control by the CPU  701 . The CMOS (complementary metal oxide semiconductor) sensor  705  acquires image data by imaging a subject according to control by the CPU  701 . The acceleration and azimuth sensor  706  is any of various sensors, such as an electromagnetic compass that detects terrestrial magnetism, a gyrocompass, and an acceleration sensor. The media I/F  708  controls reading or writing (storage) of data from and into a recording medium  707 , such as a flash memory. The GPS receiving unit  709  receives a GPS signal from a GPS satellite. 
     Further, the smartphone includes a telecommunication circuit  711 , a camera  712 , an imaging element I/F, a microphone  714 , a speaker  715 , a sound input and output I/F, a display  717 , an external device connection I/F  718 , a short-range communication circuit  719 , an antenna  719   a  of the short-range communication circuit, and a touch panel  721 . 
     Among these, the telecommunication circuit  711  is a circuit that communicates with another device via the communication network  2 , such as a mobile communication network. The camera  712  is one type of built-in imaging means that acquire image data by imaging a subject according to control by the CPU  701 . The imaging element I/F  713  is a circuit that controls driving of the camera  712 . The microphone  714  is one type of built-in sound collecting means that input sound. The sound input and output I/F  716  is a circuit that processes input and output of a sound signal between the microphone  714  and the speaker  715  according to control by the CPU  701 . The display  715  is one type of display means, such as those of liquid crystal or organic EL, which display an image of a subject, various icons, and the like. The external device connection I/F  718  is an interface for connecting various external devices. The short-range communication circuit  719  is a communication circuit of NFC (registered trademark), Bluetooth (registered trademark), or the like. The touch panel  721  is one type of input means, through which the smartphone is operated, by a user pressing down on the display  717 . 
     Further, the bus line  710  is an address bus, a data bus, or the like, for electrically connecting the components, such as the CPU  701 , illustrated in  FIG. 5 . 
     The mobile terminal  7  may also be, instead of a smartphone, a notebook PC, a tablet terminal, a smartwatch, a portable telephone, a portable game console, or the like. 
     Further, each of the above described programs may be distributed by being recorded on a computer readable recording medium as a file in an installable format or an executable format. Examples of the recording medium include a compact disc recordable (CD-R), a digital versatile disk (DVD), a Blu-ray Disc, and an SD card. 
     Hardware Configuration of Control Content Management System 
     Next, a hardware configuration of the control content management system will be described.  FIG. 5  is a hardware configuration diagram of the control content management system. 
     The control content management system  9  is formed of a computer. The control content management system  9  includes: a CPU  901  that controls operation of the whole control content management system  9 ; a ROM  902  that stores therein a program used in driving of the CPU  901 , such as an initial program loader (IPL); a RAM  903  that is used as a work area of the CPU  901 ; an HD  904  that stores therein various data, such as a positional information management program; a hard disk drive (HDD)  905  that controls reading or writing of various data from and into the HD  904  according to control by the CPU  901 ; a media I/F  907  that controls reading or writing (storage) of data from and into a recording medium  906 , such as a flash memory; a display  908  that displays thereon various types of information, such as a cursor, a menu, a window, characters, or an image; a network I/F  909  for performing data communication by use of the communication network  7 ; a keyboard  911  including plural keys for input of characters, numerical values, various instructions, and the like; a mouse  912 , through which selection and execution of various instructions, selection of targets to be processed, movement of the cursor, and the like are performed; a CD-ROM drive  914  that controls reading or writing of various data from and into a compact disc read only memory (CD-ROM)  913 , which is an example of an attachable and detachable recording medium; and a bus line  910 , such as an address bus or a data bus, for electrically connecting the above components. 
     Functional Configuration of Power Control System 
     Next, by use of  FIG. 6 , a hardware configuration of the controlled system  2 A 22  including the detection device  3 , the controlled system  2 A 11  ( 2 X), and the control content management system  9  will be described.  FIG. 6  is a functional configuration diagram of the power control system. 
     Functional Configuration of Controlled System  2 A 22   
     Firstly, a functional configuration of the controlled system  2 A 22  will be described. The controlled system  2 A 22  is formed of the detection device  3  and a controlled device  20 . Further, the detection device  3  has, as functions or means, a transmitting and receiving unit  31 , a detecting unit  32 , a determining unit  33 , a generating unit  34 , and a control unit  35 . The controlled device  20  is, for example, the LED lamp  130 , which is a target of lighting control. 
     In the detection device  3 , the transmitting and receiving unit  31  is a function or means implemented by being operated by commands according to a program in the wireless module. For example, the transmitting and receiving unit  31  transmits and receives data to and from the control content management system  9  via the communication network  2 . 
     The detecting unit  32  is a function or means implemented by operation of the sensors  311 ,  312 , and  313 . For example, the detecting unit  32  detects a temperature distribution of areas in a predetermined space. 
     The determining unit  33  is a function or means implemented by operation of the sensor driver  304 . For example, the determining unit  33  determines whether a temperature in a predetermined area is in a predetermined range (for example, 30° C. to 35° C.) 
     The generating unit  34  is a function or means implemented by operation of the sensor driver  304 . For example, based on a result of determination by the determining unit  33 , the generating unit  34  generates heat source data indicating presence and absence of heat sources. 
     The control unit  35  is a function or means implemented by operation of the device controller  315 . For example, based on control data transmitted from the control content management system  9 , the control unit  35  generates a control signal to be output to the controlled device  20 . 
     Functional Configuration of Controlled System  2 A 11   
     Next, a functional configuration of the controlled system  2 A 11  will be described. The controlled system  2 A 11  is formed of a communication device  5  and a controlled device  20 . Further, the communication device  5  has, as functions or means, a transmitting and receiving unit  51  and a control unit  55 . The controlled device  20  is, for example, a light emitting function of an LED, which is a target of lighting control. In the case of the controlled system  2 X 11  serving as an air conditioner, the controlled device  20  is: a compressor of the air conditioner that controls temperature, humidity, air flow power, and air flow direction; or the like. 
     In the communication device  5 , the transmitting and receiving unit  51  is a function or means implemented by being operated by commands according to a program in the wireless module. The transmitting and receiving unit  51  is a function or means similar to the above described transmitting and receiving unit  31 , and thus description thereof will be omitted. 
     The control unit  55  is a function or means implemented by operation of the device controller  315 . The control unit  55  is a function or means similar to the above described control unit  35 , and thus description thereof will be omitted. 
     Functional Configuration of Control Content Management System 
     Next, a functional configuration of the control content management system will be described. The control content management system  9  has a transmitting and receiving unit  91 , a collating unit  92 , a generating unit  94 , and a storage and reading processing unit  99 . Each of these units is a function or means implemented by being operated by commands from the CPU  901  according to the positional information management program expanded on the RAM  903  from the HD  904 . Further, the control content management system  9  has a storage unit  9000  that is formed of the RAM  903  and HD  904  illustrated in  FIG. 5 . Further, the storage unit  9000  has a layout management DB  9001 , a control content management DB  9002 , an adjustment degree management DB  9003 , a consumption management DB  9004 , a user management DB  9005 , an adjustment target management DB  9006 , and an adjustment range management DB  9007 , constructed therein. 
     Layout Management DB 
     Next, by use of  FIG. 7 , the layout management DB  9001  will be described. In the layout management DB  9001 , layout information of controlled systems as illustrated in  FIG. 7(A) , and layout information of a room as illustrated in  FIG. 7(B)  are managed.  FIG. 7(A)  is a conceptual diagram of layout information of controlled systems, and  FIG. 7(B)  is a conceptual diagram of layout information of a room. 
     Areas of the layout information illustrated in  FIG. 7(A)  represent areas divided by wavy lines or solid lines on an actual layout of the room α illustrated in  FIG. 7(B) . 
     Further, as illustrated in  FIG. 7(A) , in the layout information of the controlled systems, the single room α is divided into 54 areas, and a control target ID for identification of the controlled system serving as LED lighting equipment is managed for each of these areas. When a control target ID of one of these areas starts with “2”, the area is on the second floor, and the block on the upper left side with the next digit of the control target IDs of the areas therein being “a” correspond to nine areas in  FIG. 1 . That is,  FIG. 1  represents a part of the room α, and the room α is divided into six blocks represented by a, b, c, d, e, and f in their control target IDs. Furthermore, each of these blocks is divided into nine areas, and thus the room α is divided into a total of 54 areas. This division is just an example, and the room α may be divided into any number of blocks, and each block may be divided into any number of areas other than nine areas. 
     Further, in  FIG. 7(A) , control target IDs  2 x 11 ,  2 x 12 ,  2 x 21 , and  2 x 22  are respectively control target IDs for identification of controlled systems  2 X 11 ,  2 X 12 ,  2 X 21 , and  2 X 22  serving as air conditioners. Although the controlled systems  2 X 12 ,  2 X 21 , and  2 X 22  are not illustrated in  FIG. 1 , the controlled systems  2 X 12 ,  2 X 21 , and  2 X 22  are respectively installed on the ceiling β where  2 x 12 ,  2 x 21 , and  2 x 22  are illustrated in  FIG. 7(A) . That is, on the ceiling β of the room α, four air conditioners are installed. 
     Further,  FIG. 7(B)  illustrates the actual layout where desks and chairs have been arranged. In  FIG. 7(B)  also, the same room as the room in  FIG. 7(A)  has been divided into 54 areas. That is, the position of each area in  FIG. 7(B)  is the same as the position of that area in  FIG. 7(A) . In  FIG. 7(B) , the lower side on the plane of paper is the corridor γ side, and the upper side on the plane of paper is the window side. 
     Control Content Management DB 
     Next, by use of  FIG. 8 , the control content management DB  9002  will be described. As illustrated in  FIG. 8(A) , in the control content management DB, a control content management table related to air conditioning equipment, such as an air conditioner, and a control content management table related to lighting equipment, such as an LED, are managed. In each of these control content management tables, a control content for the controlled device  20  is managed in association with each piece of heat source presence or absence information. 
     In  FIG. 8(A) , for example, when the heat source presence or absence information is “1” indicating that there is a heat source, since there is a person in that area, the temperature of the air conditioner is set to 24° C. In contrast, when the heat source presence or absence information is “0” indicating that there is no heat source, since there is no person in that area, for energy saving, the temperature is set to +3° C. (that is, 27° C.) in summer and to −23° C. (that is, 22° C.) in winter. These settings 24° C. and ±3° C. are just an example, and may be 25° C. and ±4° C., or the like, instead. 
     Further, for example, when the heat source presence or absence information is “1” indicating that there is a heat source, since there is a person in that area, the degree of lighting control is set to 100% for maximization of light quantity of the LED. In contrast, when the heat source presence or absence information is “0” indicating that there is no heat source, since there is no person in that area, for energy saving, the light quantity of the LED is decreased a little to 60%. These settings 100% and 60% are just an example, and may be 90% and 50%, or the like instead, as long as the degree of lighting control for the heat source “1” is higher than the degree of lighting control for the heat source “0”. Further, a control content may correspond to humidity, air flow rate, air flow direction, or the like, instead of temperature. 
     Adjustment Degree Management Table 
     Next, by use of  FIG. 9 , the adjustment degree management DB  9003  will be described. In the adjustment degree management DB  9003 , an adjustment degree management table as illustrated in  FIG. 9  is managed. In this adjustment degree management table, for each user ID: an adjustment date and time; an adjustment target ID and an adjustment degree for lighting adjustment; and an adjustment target ID and an adjustment degree for air conditioning adjustment, are managed in association with one another. Among these, each user ID is an example of user identification information for identification of a user. Each adjustment date and time indicates the date and time when the user adjusted the control content for lighting or the control content for air conditioning by using a mobile terminal. Each adjustment target ID is an example of adjustment target identification information for identification of a target adjusted by the user. Each adjustment degree represents the degree of lighting control for lighting equipment, and represents the degree of change of temperature for air conditioning equipment. 
     For example, the uppermost record in the adjustment degree management table (see  FIG. 9 ) is for management of the fact that a user of a user ID, “U001”, requested the degree of lighting control for an adjustment target of an adjustment target ID, “L301”, to be decreased by 10%, at 10:00 on Jan. 10, 2016, by using the mobile terminal  7 , even in a case where the control content management system  9  had controlled, based on the control content management table (see  FIG. 8 ), the degree of lighting control to be 100% since the user A is present in the room α. 
     Consumption Management Table 
     Next, by use of  FIG. 10 , the consumption management DB  9004  will be described. In this consumption management DB  9004 , a consumption management table as illustrated in  FIG. 10  is managed. In this consumption management table, power consumption target IDs and power consumptions in a fixed time period (for example, one month) are managed in association with each other. Among these, there are two types of power consumption target IDs, which are adjustment target IDs and personal use target IDs. An adjustment target ID indicates the same content as the adjustment target ID in the adjustment degree management table (see  FIG. 9 ). A personal use target ID is an example of personal use target identification information for identification of a device personally used by a user, like, for example, the power source tap  2 T. 
     User Management Table 
     Next, by use of  FIG. 11 , the user management DB  9005  will be described. In this user management DB  9005 , a user management table as illustrated in  FIG. 10  is managed. In this user management table, user IDs, user names, passwords, adjustment range IDs, and personal use target IDs are managed in association with one another. Among these, the user IDs are the same as the user IDs in the adjustment degree management table (see  FIG. 9 ). An adjustment range ID is an example of adjustment range identification information indicating a range of control targets, for which a user is able to adjust control contents. The personal use target IDs are the same as the personal use target IDs in the consumption management table (see  FIG. 10 ). For example, for a device used by an individual and unable to be adjusted by a user through use of the mobile terminal  7 , like the power source tap  2 T; the personal use target ID is managed, instead of the adjustment range. 
     Adjustment Target Management Table 
     Next, by use of  FIG. 12 , the adjustment target management DB  9006  will be described. In the adjustment target management DB  9006 , an adjustment target management table related to air conditioning equipment, such as air conditioners, as illustrated in  FIG. 12(A) , and an adjustment target management table related to lighting equipment, such as LEDs, as illustrated in  FIG. 8(B) , are managed. In each of these adjustment target management tables, adjustment target IDs, adjustment target names, and control target IDs are managed in association with one another. Among these, the adjustment target IDs are the same as the adjustment target IDs in the adjustment degree management table (see  FIG. 9 ). The adjustment target names are names of adjustment targets represented by the adjustment target IDs. The control target IDs are the same as the control target IDs indicated by the layout information (see  FIG. 7(A) ). As illustrated in  FIG. 12(A)  and (B), plural control target IDs are associated with a single adjustment target ID. Thereby, for example, as illustrated in  FIG. 12(A) , when a user selects a single adjustment target, air conditioning equipment represented by plural control target IDs associated with that adjustment target is adjusted simultaneously. 
     Adjustment Range Management Table 
     Next, by use of  FIG. 13 , the adjustment range management DB  9007  will be described. As illustrated in  FIG. 13 , in the adjustment range management DB  9007 , for each adjustment range ID, an adjustment range name and adjustment target IDs are managed in association therewith. Among these, the adjustment range IDs are an example of adjustment range identification information for identification of adjustment ranges. The adjustment target names are names of adjustment ranges indicated by the adjustment range IDs. The adjustment target IDs are the same as the adjustment target IDs in the adjustment target management table (see  FIG. 12 ). 
     According to this embodiment, an administrator of the control content management system  9  is able to register an adjustment range of each user by performing predetermined input and selection on a registration screen  1000  for adjustment ranges in the control content management system  9 , as illustrated in  FIG. 14 .  FIG. 14  is a diagram illustrating an example of the registration screen for adjustment ranges. 
     For example, in  FIG. 14 , a range of adjustment targets adjustable by a user is registered with the control content management system  9  when the administrator performs predetermined input into an entry field  1001  for a user ID to be registered or an entry field  1002  for a user name to be registered and into a user password entry field  1003 , selects a predetermined adjustment range name  1110  from a pulldown menu  1100  of plural adjustment range names, and presses down a “Register” button. Thereby, the user is able to adjust control contents for adjustment targets in the user&#39;s own adjustment range. A current adjustment range field  1011  is a field where an adjustment range name of a user is displayed, when an adjustment range has been registered already and the administrator inputs a user ID or a user name and a password and presses down a “Search” button  1022 , the user corresponding to the input user ID or user name. Further, if the administrator presses down a “Delete” button  1022  in a state where the adjustment range name has been displayed, the adjustment range that has been registered already is deleted. 
     Functional Configuration of Control Content Management System 
     Next, by use of  FIG. 6 , a functional configuration of the control content management system  9  will be described. 
     For example, the transmitting and receiving unit  91  illustrated in  FIG. 6  receives detected data from the detection device  3 , and transmits control data to the detection device  3 . 
     The collating unit  92  collates, for example, the later described layout information illustrated in  FIG. 7(A)  with later described heat source data illustrated in  FIG. 17 . 
     The generating unit  84  generates, for example, control data indicating degrees of lighting control for the controlled systems  2 A and  2 X. 
     For example, the storage and reading processing unit  99  reads data from a storage unit  8000 , and stores data into the storage unit  8000 . 
     Processing or Operation of Power Control System 
     Hereinafter, by use of  FIG. 15  to  FIG. 24 , processing or operation of the power control system will be described.  FIG. 15  is a sequence diagram illustrating processing of the power control system.  FIG. 16(A)  is a conceptual diagram illustrating a temperature distribution, and  FIG. 16(B)  is a conceptual diagram of heat source data indicating presence and absence of heat sources.  FIG. 17  is a conceptual diagram of heat source data indicating presence and absence of all of heat sources in one room. 
     Disclosed herein is processing where the controlled systems  2 A 22 ,  2 A 11 , and the like control lighting, by the control content management system  9 : generating, based on various data detected by the controlled system  2 A 22  illustrated in  FIG. 1 , control data for control of the controlled systems  2 A 22 ,  2 A 11 , and the like; and transmitting the control data to the controlled systems  2 A 22 ,  2 A 11 , and the like. For simplification of the explanation, among the controlled systems  2 A and  2 X, processing of the controlled system  2 A 22  including the detection device  3 , and the controlled system  2 A 11  including the communication device  5  will be described. 
     Firstly, as illustrated in  FIG. 15 , the detecting unit  32  of the controlled system  2 A 22  that is lighting equipment detects a temperature distribution of the areas in the room α (Step S 21 ). The determining unit  33  then determines whether or not the temperature in each area is in a predetermined range (for example, 30° C. to 35° C.), and the generating unit  34  generates heat source data based on a result of this determination (Step S 22 ). 
     By use of  FIG. 16 , the generation of the heat source data will be described. When a temperature distribution of nine areas is in a state illustrated in  FIG. 16(A)  as a result of the detection of the temperature in each area by the detecting unit  32 , the generating unit  34  generates heat source data as illustrated in  FIG. 16(B) . That is, the heat source data are represented by heat source presence or absence information indicating presence and absence of heat sources, and an area with a temperature equal to or higher than 30° C. is represented by “1”, and an area with a temperature less than 30° C. is represented by “0”. 
     Further, the detecting unit  32  of the controlled system  2 A 22  detects illuminance, temperature, and humidity, around the controlled system  2 A 22  (Step S 23 ). The transmitting and receiving unit  31  then transmits the detected data to the control content management system  9  (Step S 24 ). The detected data include the control target ID for identification of the controlled device  20  of the controlled system  2 A 22 , the heat source data generated through Step S 22 , and temperature and humidity data and illuminance data representing results detected through Step S 23 . Thereby, the transmitting and receiving unit  91  of the control content management system  9  receives the detected data. Data in a state where the transmitting and receiving unit  91  has combined together the heat source data transmitted from the blocks are illustrated in  FIG. 17 .  FIG. 17  is a conceptual diagram of heat source data indicating presence and absence of all of heat sources in one room. For example, the heat source data illustrated in  FIG. 16(B)  constitute the first block on the upper left in  FIG. 17 . 
     Subsequently, the storage and reading processing unit  59  of the control content management system  9  reads, from the layout management DB  9001 , the layout information illustrated in  FIG. 7(A)  (Step S 25 ) The collating unit  92  then collates the layout information illustrated in  FIG. 7(A)  with the heat source data illustrated in  FIG. 17  (Step S 26 ). According to this collation, from the heat source data, for example, “1” is, that is, “there is a heat source”, at the position (2a11) of the controlled system in the layout information. 
     Subsequently, by searching through the control content management DB  9002  with “1” and “0” being search keys indicating presence and absence of heat sources in the heat source data, the storage and reading processing unit  59  of the control content management system  9  reads degrees of lighting control corresponding thereto (Step S 27 ). 
     Subsequently, by searching through the adjustment target management table (see  FIG. 12 ) with the adjustment target ID being a search key, the adjustment target ID having been received through Step S 24 , the storage and reading processing unit  59  reads an adjustment target ID corresponding thereto (Step S 28 ). By searching through the adjustment degree management table (see  FIG. 9 ) with the adjustment target ID being a search key, the adjustment target ID having been read through Step S 28 , the storage and reading processing unit  59  then reads adjustment degrees of a fixed time period (for example, one month) in the past (Step S 29 ). 
     The generating unit  84  then generates control data indicating the control content for the controlled system  2 A 11  (Step S 30 ). In this case, for example, control data indicating the control content that has been adjusted are generated by addition of the average value of the past adjustment degrees in the control content management table (see  FIG. 8(B) ) to the control content retrieved at Step S 27 . For the controlled system  2 X serving as an air conditioner, the generating unit  84  generates control data indicating temperature. 
     As described above, since the control content management system  9  not only determines a control content according to presence or absence of a heat source, but also determines the final control content by causing past adjustment degrees from users to be reflected therein, an effect of enabling lighting control matching the actual conditions more is able to be achieved. 
     Subsequently, the transmitting and receiving unit  51  respectively transmits the control data to the controlled systems  2 A 22  and  2 A 11  (Steps S 31 - 1  and S 31 - 2 ). In response, the transmitting and receiving unit  31  in the detection device  3  of the controlled system  2 A 22  receives the control data. Further, the transmitting and receiving unit  51  in the communication device  5  of the controlled system  2 A 11  receives the control data. 
     Subsequently, in the controlled system  2 A 22 , the control unit  35  of the detection device  3  generates, based on the control data, a control signal to be output to the controlled device  20  serving as an LED lamp (Step S 32 - 1 ), and outputs the control signal to the controlled device  20  (Step S 33 - 1 ). Thereby, the light quantity of the controlled device  20  serving as the LED lamp is controlled (Step S 34 - 1 ). Similarly, in the controlled system  2 A 11 , the control unit  55  of the communication device  5  generates, based on the control data, a control signal to be output to the controlled device  20  serving as an LED lamp (Step S 32 - 2 ), and outputs the control signal to the controlled device (Step S 33 - 2 ). Thereby, the light quantity of the controlled device  20  serving as the LED lamp is controlled (Step S 34 - 2 ). 
     For example, if past adjustment degrees are not available, or the average of past adjustment degrees is 0, since in  FIG. 16(A) , “0” indicates that there is no heat source directly under the controlled system  2 A 22 , the control content for the controlled system  2 A 22  will be a degree of lighting control of 60% according to  FIG. 8 . On the contrary, since in  FIG. 16(A) , “1” indicates that there is a heat source directly under the controlled system  2 A 11 , the control content for the controlled system  2 A 11  will be a degree of lighting control of 100% according to  FIG. 8 . Thereby, if a heat source is detected due to presence of a person, the light quantity of the LED is set to the maximum, and if a heat source is not detected due to absence of a person, the light quantity of the LED is decreased, and thus energy saving is able to be realized. 
     Further, for example, if past adjustment degrees are available and the average of these past adjustment degrees is −10, since in  FIG. 16(A) , “0” indicates that there is no heat source directly under the controlled system  2 A 22 , the control content for the controlled system  2 A 22  will be an adjustment degree of 60% according to  FIG. 8 , but the control content after adjustment will become 50%. On the contrary, since in  FIG. 16(A) , “1” indicates that there is a heat source directly under the controlled system  2 A 11 , the control content for the controlled system  2 A 11  will be a degree of lighting control of 100% according to  FIG. 8 , but the control content after adjustment will become 90%. 
     Thereby, since the control content management system  9  not only determines a control content according to presence or absence of a heat source, but also causes past adjustment degrees from users to be reflected therein (Steps S 28  and S 29 ), generates control data indicating the final control content (Step S 30 ), and transmits the control data to the controlled system  2 A 22  or the like (Step S 31 - 1  or S 31 - 2 ), an effect of enabling lighting control matching the actual conditions more is able to be achieved. 
     Next, by use of  FIG. 18  to  FIG. 20 , adjustment processing for a control content by a user will be described.  FIG. 18  is a sequence diagram illustrating adjustment processing for a control content.  FIG. 19  is a screen transition diagram for a mobile terminal upon lighting adjustment.  FIG. 20  is a screen transition diagram for a mobile terminal upon air conditioning adjustment. Explained herein will be a case where, as illustrated in  FIG. 1 , the user A adjusts control contents for the controlled systems ( 2 A 11 ,  2 A 12 ,  2 A 13 ,  2 A 21 ,  2 A 22 ,  2 A 23 ,  2 A 31 ,  2 A 32 , and  2 A 33 ) that are control targets in an adjustment range altogether by using the user A&#39;s own mobile terminal  7 A. For simplification of explanation,  FIG. 18  illustrates adjustment processing for a control content for the controlled system  2 A 11 . 
     Firstly, when an application for adjustment is started up in the mobile terminal  7 A through operation by the user A, the display control unit  74  causes an initial screen  7100  to be displayed, as illustrated in  FIG. 19(A)  (Step S 41 ). When the user A presses down a “Lighting Adjustment” icon, an accepting unit  72  accepts start of lighting adjustment, and as illustrated in  FIG. 19(B) , the display control unit  74  causes an adjustment target selection screen  7120 , which depicts a layout diagram of a room for selection of an adjustment target, to be displayed (Step S 42 ). 
     Subsequently, when the user A selects an adjustment target from the layout diagram of the room, the accepting unit  72  accepts the adjustment target, and as illustrated in  FIG. 19(C) , the display control unit  74  causes an adjustment degree setting screen  7130 , which is for setting of an adjustment degree, to be displayed (Step S 43 ). This adjustment degree setting screen  7130  has a layout diagram  7131  of the room depicting the adjustment target, an adjustment degree setting section  7132 , a “Return” button  7133  for return to the previous screen, and a “Determine” button  7134  for determination of a set adjustment target and adjustment degree. One memory of the adjustment degree setting section  7132  represents, for example, a degree of lighting control of 10%. 
     Subsequently, when the user A sets an adjustment degree in the adjustment degree setting section  7132 , and presses down the “Determine” button  7134 , the accepting unit  72  accepts the determination (Step S 44 ). Thereby, the transmitting and receiving unit  71  of the mobile terminal  7 A transmits adjustment request data to the control content management system  9  (Step S 45 ). The adjustment request data include the user ID of the user A of the mobile terminal  7 A that is the transmission source, the adjustment target ID accepted at Step S 43 , and the adjustment degree accepted at Step S 44 . Thereby, the transmitting and receiving unit  91  of the control content management system  9  receives the adjustment request data. 
     Subsequently, by searching through the adjustment target management table (see  FIG. 12 ) with the adjustment target ID being a search key, the adjustment target ID having been received through Step S 45 , the storage and reading processing unit  99  of the control content management system  9  reads control target IDs corresponding thereto (Step S 46 ). 
     Subsequently, the storage and reading processing unit  99  associates the adjustment request data (the user ID, the adjustment target ID, and the adjustment degree) received at Step S 45 , with the adjustment date and time indicating the date and time when the transmitting and receiving unit  71  received the adjustment request data, and stores and manages the associated data as a new record in the adjustment degree management table (see  FIG. 9 ) (Step S 47 ). The generating unit  94  then generates adjustment data for adjustment of the control content of the controlled device  20  of the controlled system  2 A 11  (Step S 48 ). The adjustment data include the adjustment degree received at Step S 45 . 
     Subsequently, the transmitting and receiving unit  91  of the control content management system  9  transmits adjustment data to the detection device  3  of each of the controlled systems  2 A indicated by the control target IDs read at Step S 46  (Step S 49 ). Illustrated herein for simplification of explanation is a case where the adjustment data are transmitted to the controlled system  2 A 11 , among the controlled systems  2 A indicated by the control target IDs read at Step S 46 . Thereby, the transmitting and receiving unit  31  of the detection device  3  of the controlled system  2 A 11  receives the adjustment data. 
     Subsequently, in the controlled system  2 A 11 , the control unit  35  of the detection device  3  generates, based on the adjustment data, an adjustment signal to be output to the controlled device  20  serving as an LED lamp (Step S 50 ), and outputs the adjustment signal to the controlled device  20  (Step S 51 ). Thereby, the light quantity of the controlled device  20  serving as the LED lamp is adjusted (Step S 52 ). 
     With respect to  FIG. 18 , adjustment of lighting control has been described; and similar processing is executed for adjustment of air conditioning.  FIG. 20  illustrates an example of screens for adjustment of air conditioning. Among these,  FIG. 20(A) , (B), and (C) respectively correspond to  FIG. 19(A) , (B), and (C). Further, reference numerals  7220 ,  7230 ,  7231 ,  7232 ,  7233 , and  7234  respectively correspond to the reference numerals  7120 ,  7130 ,  7131 ,  7132 ,  7133 , and  7134 . 
     As described above, the control content management system  9  achieves an effect of enabling lighting control matching the actual conditions more, because after a control content is determined according to presence and absence of a heat source, adjustment data for adjustment of the control content are generated based on a request (Step S 45 ) from a user (Step S 48 ), and the adjustment data are transmitted to the controlled system  2 A 11  or the like (Step S 49 ). 
     Next, by use of  FIG. 21  and  FIG. 22 , processing for display of power consumption will be described. FIG.  21  is a sequence diagram illustrating the processing for display of power consumption.  FIG. 22  is a screen transition diagram of a mobile terminal upon display of electric power consumption. 
     Firstly, when an application for adjustment is started up in the mobile terminal  7 A through operation by the user A, the display control unit  74  causes an initial screen  7100  to be displayed, as illustrated in  FIG. 22(A)  (Step S 61 ). When the user A presses down a “Visualization” icon, the accepting unit  72  accepts a request for power consumption data (Step S 62 ). Thereby, the transmitting and receiving unit  71  of the mobile terminal  7 A transmits consumption request data to the control content management system  9  (Step S 63 ). The consumption request data include the user ID of the user A of the mobile terminal  7 A that is the transmission source thereof. Thereby, the transmitting and receiving unit  91  of the control content management system  9  receives the consumption request data. 
     Subsequently, by searching through the user management table (see  FIG. 11 ) with the user ID being a search key, the user ID having been received through Step S 63 , the storage and reading processing unit  99  of the control content management system  9  reads an adjustment range ID and a personal use target ID corresponding thereto (Step S 64 ). By searching through the adjustment range management table (see  FIG. 13 ) with the adjustment range ID being a search key, the adjustment range ID having been read at Step S 46 , the storage and reading processing unit  99  reads control target IDs corresponding thereto (Step S 65 ). 
     Subsequently, by searching through the consumption management table (see  FIG. 10 ) with the personal use target ID and the control target IDs being search keys, the personal user target ID having been read at Step S 46 , the control target IDs having been read at Step S 47 , the storage and reading processing unit  99  reads power consumptions corresponding thereto (Step S 66 ). By executing data processing, such as graphing, based on the power consumptions, the generating unit  94  generates consumption data (Step  67 ). 
     Subsequently, the transmitting and receiving unit  91  of the control content management system  9  transmits the consumption data to the mobile terminal  7 A that is the transmission source at Step S 63  (Step S 68 ). Thereby, the transmitting and receiving unit  71  of the mobile terminal  7 A receives the consumption data. 
     Subsequently, as illustrated in  FIG. 22(B) , the display control unit  73  of the mobile terminal  7 A displays a consumption data display screen  7320  (Step S 69 ). This consumption data display screen  7320  has a layout diagram, power consumption, and the like, displayed thereon. Further, the consumption data display screen  7320  has a “Return” button  7323  for return to the initial screen  7100 , and a “Details” button  7324  for advancement to a detailed consumption data screen  7330  illustrated in  FIG. 22(C) , displayed thereon. 
     When the user A presses down the “Details” button  7324 , the accepting unit  72  accepts the press-down, and the display control unit  74  displays the detailed consumption data screen  7330  illustrated in  FIG. 22(C)  (Step S 70 ). This detailed consumption data screen  7330  has more detailed information displayed thereon. Further, the detailed consumption data screen  7330  has a “Return” button  7333  for return to the consumption data display screen  7320 , and a “Change” button  7334  for change of the year and month of the power consumption, displayed thereon. 
     As described above, since in the control content management system  9 , consumption data are generated and transmitted to the mobile terminal  7 , a user is able to visually grasp how much the user&#39;s own adjustment of a control content has contributed to energy saving, the consumption data being for representation, through numerical values, a graph, and the like, of not only a power consumption of the power source tap  2 T that is a target of personal use and not a target of adjustment, but also power consumptions of a group of lighting equipment and air conditioning equipment that are targets of adjustment. Thereby, the user&#39;s awareness of energy saving is able to be improved, and the user is encouraged to take action for adjustment of control contents for further energy saving. 
     As a result of the association between the user IDs and the adjustment range IDs in the user management table (see  FIG. 11 ), as well as the association between the adjustment range IDs and the adjustment target IDs in the adjustment degree management table (see  FIG. 13 ), the user IDs are associated with the adjustment target IDs, but the association is not limited to this example. For example, in the user management table (see  FIG. 11 ), by replacement of the adjustment range IDs with the adjustment target IDs, the user IDs may be directly associated with the adjustment target IDs. 
     Main Effects of Embodiment 
     As described above, according to this embodiment, the control content management system  9  achieves an effect of enabling lighting control matching the actual conditions more, because not only a control content is determined according to presence or absence of a heat source, but also past adjustment degrees from users are caused to be reflected therein (see Steps S 28  and S 29 ), control data indicating the final control content (see Step S 30 ) are generated, and the control data are transmitted to the controlled system  2 A 22  or the like (see Step S 31 - 1  or S 31 - 2 ). 
     Further, the control content management system  9  achieves an effect of enabling lighting control matching the actual conditions more, because after a control content is determined according to presence or absence of a heat source, adjustment data for adjustment of the control content are generated based on a request (see Step S 45 ) from a user (see Step S 48 ), and the adjustment data are transmitted to the controlled system  2 A 11  or the like (see Step S 49 ). 
     Further, since in the control content management system  9 , consumption data are generated (see Step S 67 ) and transmitted to the mobile terminal  7  (see Step S 68 ), a user is able to visually grasp how much the user&#39;s own adjustment of a control content has contributed to energy saving, the consumption data being for representation, through numerical values, a graph, and the like, of not only a power consumption of the power source tap  2 T that is a target of personal use and not a target of adjustment, but also power consumptions of a group of lighting equipment and air conditioning equipment that are targets of adjustment. Achieved thereby is an effect of enabling the user&#39;s awareness of energy saving to be improved, and the user to be encouraged to take action for adjustment of control contents for further energy saving. 
     REFERENCE SIGNS LIST 
     
         
           1  POWER CONTROL SYSTEM 
           2 A 11  CONTROLLED SYSTEM 
           2 A 22  CONTROLLED SYSTEM 
           2 X 11  CONTROLLED SYSTEM 
           3  DETECTION DEVICE 
           5  COMMUNICATION DEVICE 
           6  WIRELESS ROUTER 
           7  COMMUNICATION NETWORK 
           8  CONTROL CONTENT MANAGEMENT SYSTEM 
           20  CONTROLLED UNIT 
           31  TRANSMITTING AND RECEIVING UNIT 
           32  DETECTING UNIT 
           33  DETERMINING UNIT 
           34  GENERATING UNIT 
           35  CONTROL UNIT 
           51  TRANSMITTING AND RECEIVING UNIT 
           55  CONTROL UNIT 
           91  TRANSMITTING AND RECEIVING UNIT (EXAMPLE OF TRANSMITTING MEANS AND EXAMPLE OF RECEIVING MEANS) 
           92  COLLATING UNIT 
           94  GENERATING UNIT (EXAMPLE OF GENERATING MEANS) 
           99  STORAGE AND READING PROCESSING UNIT 
           8000  STORAGE UNIT 
           9001  LAYOUT MANAGEMENT DB 
           9002  CONTROL CONTENT MANAGEMENT DB (EXAMPLE OF CONTROL CONTENT MANAGEMENT MEANS) 
           9003  ADJUSTMENT DEGREE MANAGEMENT DB (EXAMPLE OF ADJUSTMENT DEGREE MANAGEMENT MEANS) 
           9004  CONSUMPTION MANAGEMENT DB (EXAMPLE OF CONSUMPTION MANAGEMENT MEANS) 
           9005  USER MANAGEMENT DB (EXAMPLE OF USER MANAGEMENT MEANS) 
           9006  ADJUSTMENT TARGET MANAGEMENT DB (EXAMPLE OF ADJUSTMENT TARGET MANAGEMENT MEANS) 
           9007  ADJUSTMENT RANGE MANAGEMENT DB (EXAMPLE OF ADJUSTMENT RANGE MANAGEMENT MEANS) 
       
    
     CITATION LIST 
     Patent Literature 
     Patent Literature 1: Japanese Patent No. 4340925