JP2010273269A - Wireless management control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless management control system having advantages capable of managing and controlling a plurality of systems in association with one another based on personal ID information and the like. <P>SOLUTION: This wireless management control system 100 includes wireless transmitters 1, 3 and systems 2, 4 each including a wireless receiver 60. The wireless transmitter 1 includes a wireless module 50 alternately repeating a communication mode and a standby mode, and a power source section 40. The power source section 40 includes a secondary battery 42, a solar cell 41, and a charge circuit 43 for controlling power supply from the solar cell 41 to the secondary battery 42 and power supply from the secondary battery 42 to the wireless module 50. The charge circuit 43 supplies power from the solar cell 41 to the secondary battery 42 in a period of the standby mode. The systems 2, 4 are operatively controlled by being associated with each other by ID numbers, operation signals and stop signals transmitted from the wireless transmitters 1, 3. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a radio management control system used in the security field or the like.

  Conventionally, operation of security-related equipment such as entrance / exit gates, surveillance cameras, entrance / exit systems for specific rooms, activation and access to office automation equipment such as printers, copiers, personal computers and servers, lockers In order to manage the operation of office fixtures such as cabinets, personal authentication using an IC card in which an IC (integrated circuit) is incorporated in a card such as an employee ID card or an employee ID card is widely performed.

  In particular, for example, in Non-Patent Document 1 and Non-Patent Document 2, different security cards and keys that existed for each facility or device are replaced with one IC card, and the IC card is used. In addition, security systems have been introduced to manage entry / exit in offices and specific rooms, output management of printers, startup of personal computers and access to digital information on servers, and operation management of office equipment such as lockers.

Dai Nippon Printing Co., Ltd. website [Search on March 15, 2009], Internet <URL: http://www.dnp.co.jp/jis/news/2005/050207.html> SSFC homepage [March 16, 2009 search], Internet <URL: http://www.ssfc.jp/content01.html>

  By the way, in the conventional security system, for example, when an important document or file is taken out of a specific room, an IC tag and an IC card (employee card) attached to the important document or file are registered by a reader. (E.g., when such an operation is not performed, a warning sound is emitted to prevent unauthorized removal). Although the specific method for registering the IC card at that time with the reader is not clearly described in the above-mentioned Non-Patent Document 1 and Non-Patent Document 2, the operator (individual) probably uses a non-contact IC card. It is presumed that a method of reading the information on the IC card close to the reader is adopted.

  However, in the method in which the operator reads the card information by bringing the IC card close to the reader in this way, each (device) system such as a security-related device, an OA device, an office fixture, or the like to be operated or operated is used. Since each operator needs to perform an IC card reading operation each time, based on the individual identification information read from the IC card, a plurality of systems are managed and controlled in relation to each other, It has been difficult to control system operations and operations based on information from a plurality of operators.

  Therefore, the present invention has been made in view of such circumstances, and can manage and control a plurality of systems in association with each other based on personal ID information, and further, the operation and operation of these systems. It is an object of the present invention to provide a wireless management control system that can easily perform the above control based on ID information of a plurality of operators.

  In order to solve the above-described problems, a wireless management control system according to the present invention includes a power supply unit including a power generation element and a power storage device, a first wireless module including a signal processing circuit, a high-frequency circuit, and an antenna, and power supplies thereof. A radio receiver that includes a radio transmitter that transmits ID information, a signal processing circuit, a high-frequency circuit, and a second radio module that includes an antenna. A plurality of systems capable of receiving ID information transmitted from the wireless transmitter, and the operation and / or stop of the plurality of systems is performed in association with the ID information.

  In the wireless management control system configured as described above, in the wireless transmitter, the power generated by the power generation element is stored in the power storage device to supply power (that is, the self-power generation type that does not require battery replacement). The ID information registered (stored) in advance is wirelessly transmitted from the wireless module at any time. The transmitted ID information is received by, for example, the second wireless module provided in each of the plurality of systems at a predetermined signal strength.

  Since the activation and / or deactivation of the plurality of systems is performed in association with the received ID information, for example, the first system among the plurality of systems uses the ID information transmitted from the wireless transmitter. When received or not received, control is first performed to activate or deactivate the first system, and then or simultaneously, the first system is activated based on the activated or deactivated state of the first system. It is possible to manage and control a plurality of systems in association with each other, such as operating or stopping a second system different from the above system.

  In this case, the wireless transmitter transmits, to the first system among the plurality of systems, a first control signal that activates or deactivates the first system, and associates the first control signal with the plurality of systems. You may make it transmit the 2nd control signal which operates or stops the 2nd system to the 2nd system among systems.

  Specifically, the wireless transmitter may control the first system and / or the second system based on the illuminance in the power generation element. More specifically, for example, the wireless transmitter stops the transmission of the ID information when the power generation element becomes a predetermined illuminance (for example, 5 Lux) or less, and the first control signal and the second control are stopped. Sending a signal. As an example, “illuminance” can be detected (further calculated or evaluated) based on a voltage generated by the power generation element, and illuminance measurement means other than the power generation element may be provided.

  In this case, more specifically, it is preferable that the storage case has a predetermined opacity.

  Here, the “predetermined opacity” means that in the wireless transmitter, it is impossible to visually determine from the outside that the power supply unit and the first wireless module are housed inside the housing case. When the illuminance on the outer surface is 50 Lux or more, the surface of the power generating element of the power supply unit accommodated in the accommodation case has translucency that can ensure the illuminance of 5 Lux.

  In this way, since the power supply unit and the first wireless module housed inside the housing case cannot be seen from the outside through the housing case, the character information printed on the outer surface of the housing case and the printed image Since information such as information can be clearly read and discriminated, it is particularly useful when the wireless transmitter is of a card type such as an employee ID card or an employee ID card.

  In other words, in the wireless transmitter, the light transmittance of the housing case may be 10% to 50%. Here, the method for measuring the “light transmittance” is generated by causing a white light source disposed 30 cm away from an arbitrary solar cell (light emitting element) connected to an ammeter to emit light and generating an electromotive force of the solar cell. Measure the current value (reference current value). Next, the material piece of the housing case is arranged on the front surface (the surface facing the white light source) of the solar cell so as to cover the solar cell, and the white light source is emitted with the same light emission amount, and the reference current value is measured. Measure the current value in the same way at the same voltage as the time (target current value). A value representing the target current value with respect to the reference current value as a percentage is set as the “light transmittance” of the housing case.

  According to the inventor's research, it has been found that if this light transmittance is less than 10%, wireless transmission from the first wireless module cannot be performed, while if this light transmittance exceeds 50%, It was confirmed that the inside of the storage case could be seen through, which hindered interpretation and discrimination of the display (printing and printing) on the outer surface of the storage case.

  Further, in the wireless management control system according to the present invention, since ID information is given to each of a plurality of systems by wireless transmission, it is necessary for each operator to read the ID information for each operation. Therefore, it is possible to reliably and easily control the operation and operation of each system based on information of a plurality of operators.

  In this respect, the wireless management control system of the present invention includes a plurality of wireless transmitters that transmit different ID information, and the operation and / or stoppage of the plurality of systems is included in the plurality of ID information. This is preferably done in association.

  According to the wireless management control system of the present invention, a plurality of systems having a wireless receiver can receive ID information transmitted from the wireless transmitter, and the operation and / or stop of the plurality of systems is performed by the ID. Since it is performed in association with information, it is possible to manage and control a plurality of systems in association with each other based on personal ID information, and to control the operation and operation of these systems by a plurality of operators. This can be easily performed based on the ID information.

It is a functional block diagram which shows notionally the structure of suitable one Embodiment of the radio | wireless management control system by this invention. 3 is a timing chart of intermittent communication according to a preferred embodiment of a wireless management control system according to the present invention.

  Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. Further, the positional relationship such as up, down, left and right is based on the positional relationship shown in the drawings unless otherwise specified. Furthermore, the dimensional ratios in the drawings are not limited to the illustrated ratios. Further, the following embodiments are exemplifications for explaining the present invention, and are not intended to limit the present invention only to the embodiments. Furthermore, the present invention can be variously modified without departing from the gist thereof.

  FIG. 1 is a functional block diagram showing a configuration of a preferred embodiment of a radio management control system according to the present invention. The wireless management control system 100 includes at least one (two in the drawing) wireless transmitters 1 and 3 and a plurality (two in the drawing) of systems 2 (first system) each having a wireless receiver 60. And system 4 (second system). Thus, the radio management control system 100 is a kind of radio communication system.

  Among these components, the wireless transmitters 1 and 3 have the same configuration, and are owned and held for each individual such as an employee or an employee. Information signals and control signals are transmitted and received.

  Hereinafter, the wireless transmitter 1 will be described as an example. The wireless transmitter 1 includes a power supply unit 40 and a wireless module 50 (first wireless module) housed in a housing case 10 having a card or plate shape, for example. The power supply unit 40 includes a solar battery 41 (power generation element), a secondary battery 42 (power storage device), and a charging circuit 43. The wireless module 50 includes an antenna 20 and a transmission module 30. The transmission module 30 includes a signal processing circuit 31 and a high frequency circuit 32.

  The signal processing circuit 31 includes a semiconductor device such as a CPU and a memory IC, and performs control for suppressing power consumption, output processing of an ID number (corresponding to an individual identification number: ID information), and the like. In the memory IC, an ID number and a communication format are stored in advance. The ID number is unique identification information assigned to uniquely identify the wireless transmitter. The communication format conforms to a predetermined communication protocol (for example, a communication protocol for a 400 MHz band specific power-saving radio). Various memories such as a nonvolatile memory and a volatile memory can be applied as the memory IC.

  Further, the CPU reads the communication format together with the ID number from the memory IC, and intermittently modulates the modulation signal of a predetermined interface format (for example, UART serial interface format) modulated at a predetermined transfer rate (for example, 9600 bps) to the high frequency circuit 32. Output regularly and periodically. For example, an 8-bit microcomputer can be used as the CPU.

  Furthermore, the signal processing circuit 31 performs intermittent communication as shown in a timing chart in FIG. 2 as control for suppressing power consumption. In such intermittent communication, an ID number is output in a predetermined communication format during a transmission period (for example, 15 msec) that operates as a communication mode in a predetermined transmission cycle (for example, 15-second cycle), and other standby modes (sleep mode) ) In the sleep period (for example, 1485 msec), the operations of the signal processing circuit 31 and the high frequency circuit 32 shift to a standby state. The signal processing circuit 31 and the high frequency circuit 32 suppress the power consumption of the secondary battery 42 by alternately repeating the communication mode and the standby mode.

  The high-frequency circuit 32 includes passive components such as a chip inductor, a chip capacitor, and a chip resistor, and active components such as a semiconductor device such as a transistor. The high-frequency circuit 32 receives the modulation signal from the signal processing circuit 31 and modulates the transmission signal including the ID number of the wireless transmitter 1 (for example, a binary FSK modulation signal in the 300 MHz band) according to the communication format. The antenna 20 converts the transmission signal generated by the high frequency circuit 32 into an electromagnetic wave and radiates it. The electromagnetic wave radiated from the antenna 20 is designed to comply with a weak wireless standard having a fundamental frequency of 315 MHz, for example.

  The solar cell 41 is a power generation element that converts light energy (light energy such as sunlight or illumination light) into DC power. The housing case 10 that houses each part (the antenna 20, the transmission module 30, and the power source part 40) of the wireless transmitter 1 is made of, for example, a resin material such as white polycarbonate and has the predetermined opacity described above. Although each part of the wireless transmitter 1 cannot be visually recognized from the outside, the solar battery 41 is configured to absorb light energy.

  Note that the power generation element is not limited to the solar battery 41, and may be any photovoltaic power generation element that converts light energy into electrical energy. For example, a vibration power generation element that converts vibration energy into electrical energy, A thermoelectric conversion element that converts thermal energy into electrical energy, an electromagnetic induction power generation element that converts electromagnetic energy into electrical energy, and the like may be mounted together.

  The secondary battery 42 is a power storage device that stores electric power supplied to the signal processing circuit 31 and the high frequency circuit 32. The secondary battery 42 is, for example, a lithium ion battery, and outputs a voltage of, for example, DC 3V by rating. The secondary battery 42 with the rated voltage consumes power in the range of about 1.8V to 3.3V, depending on the minimum operating voltage level in the signal processing circuit 31 and the high frequency circuit 32. The power storage device is not limited to the secondary battery 42, and may be a capacitor, for example.

  The charging circuit 43 controls power supply from the solar battery 41 to the secondary battery 42 and power supply from the secondary battery 42 to the transmission module 30. The charging circuit 43 monitors the function of preventing the backflow of current from the secondary battery 42 to the solar battery 41 and the terminal voltage of the secondary battery 42, stops charging the secondary battery 42 during overcharge, It has a function of stopping overdischarge of the secondary battery 42 during discharge. Specifically, the charging circuit 43 lengthens the transmission cycle or temporarily stops wireless communication until the secondary battery 42 is sufficiently charged. Further, a protection function for preventing inflow of overcurrent to the transmission module 30 may be added to the charging circuit 43.

  The charging circuit 43 controls the above-described power supply based on the logical value of the control signal CTL output from the signal processing circuit 31. As described above, the transmission module 30 always performs intermittent communication in which the communication mode and the standby mode are alternately repeated. During the transmission period that operates as the communication mode, the transmission module 30 is supplied with operating power (power necessary for wireless transmission) from the secondary battery 42 to the transmission module 30 and from the solar battery 41 to the secondary battery 42. During the sleep period in which the logic value of the control signal CTL is controlled so that charging power is not supplied and operates as a standby mode, the transmission module 30 transmits standby power (consumed during standby) from the secondary battery 42 to the transmission module 30. The control signal CTL is controlled so that the charging power is supplied from the solar battery 41 to the secondary battery 42.

  By such control, the power of the secondary battery 42 consumed by the transmission module 30 during the communication mode can be supplemented from the solar battery 41 to the secondary battery 42 during the standby mode. Further, since the impedance of the secondary battery 42 during the standby mode period is lower than the impedance of the secondary battery 42 during the communication mode period, there is an advantage that the secondary battery 42 can be charged more easily than when it is constantly charged. .

  Assuming that 15 mA current is consumed in the communication mode and 1.0 μA current is consumed in the standby mode, the average consumption current consumed by intermittent communication with a duty of 0.1% is 16 μA. Here, when the experimental data indicating the relationship between the received light illuminance of the solar cell 41 and the generated current is acquired, during normal use in the office (for example, when the wireless communication devices 1 and 3 are stored in the breast pocket), Illuminance of about 100 Lux is obtained, and the generated current of the solar cell 41 obtained by this degree of illuminance is about 16 μA. By arranging the wireless transmitters 1 and 3 in an environment where appropriate illuminance can be obtained, the power consumption of the wireless transmitters 1 and 3 (operating power consumed during the communication mode and consumed during the standby mode) The total power with the standby power) can be sufficiently supplemented by the solar cell 41. As a result, it is possible to provide the wireless transmitter 1 that eliminates the need for battery replacement and has no restriction on the communication time.

  Moreover, while changing the thickness (thickness of the surface side which the solar cell 41 opposes) of the storage case 10 (product made from white polycarbonate) variously, the light transmittance is measured with the measuring method mentioned above, and those various thicknesses Experiments were also conducted on whether or not wireless transmission from the wireless transmitters 1 and 3 using the storage case 10 was possible and on the visibility of the inside of the storage case 10. The results are summarized in Table 1 below. Accordingly, when the thickness of the storage case 10 is 1.5 mm and the light transmittance is 8%, wireless transmission from the wireless transmitters 1 and 3 cannot be performed, and the thickness of the storage case 10 is 0.15 mm. When the light transmittance is 55%, the inside of the housing case 10 can be seen through, and when printing or the like is displayed on the outer surface of the housing case 10, it is confirmed that the reading and discrimination are hindered. .

  Next, the wireless receiver 60 is, for example, an electronic device having a wireless communication function mounted on or connected to each of the systems 2 and 4, and includes a wireless module 70 (second wireless module) and a CPU 80. The wireless module 70 includes an antenna 71, a high frequency circuit 72, and a signal processing circuit 73. The ID number included in the transmission signal radiated as a radio wave from the radio transmitters 1 and 3 is received by the antenna 71 of each radio receiver 60, demodulated by the high frequency circuit 72, and decoded by the signal processing circuit 73. Then, it is output to the CPU 80 in a predetermined interface format (for example, UART serial interface format).

  The CPU 80 authenticates the wireless transmitter 1 based on the ID number received by the wireless module 70. For example, the systems 2 and 4 include security-related equipment such as the aforementioned entrance / exit gate, surveillance camera, room entrance / exit system, office equipment such as printers, copy machines, personal computers, servers, etc., lockers, cabinets, etc. In addition, office infrastructure systems such as lighting equipment and air-conditioning equipment, and building systems such as elevators can be cited. When the user carrying the wireless transmitter 1 moves, the wireless transmitters 1 and 3 and the systems 2 and 4 When the radio receivers 60 and 60 are separated from each other by a certain distance, the systems 2 and 4 stop operating (lock), and the radio transmitters 1 and 3 and the radio receivers 60 and 60 are within a certain distance. System 2 and 4 are activated (unlocked; strictly speaking, including being ready for operation (operation ready state) without actually operating).

  Alternatively, locking and unlocking may be reversed as necessary, for example, depending on the security level, the system 2, 4 is activated only for individuals with a specific ID number (for example, access to a specific server). And the case where the operation of the entrance door to a specific room is prohibited.

  A more specific aspect of the radio management control system 100 is exemplified as follows. First, when the system 2 is an office air-conditioning equipment system and the system 4 is an office security equipment system, the wireless transmitters 1 and 3 can be used when the illuminance of the solar battery 41 is, for example, 5 Lux or less (such a situation For example, when an individual who owns and holds the wireless transmitters 1 and 3 stores the wireless transmitters 1 and 3 in a predetermined dark place (such as in a desk drawer or an entrance / exit storage case) when returning home In this case, the transmission of the ID number in the timing chart shown in FIG. 2 is stopped. At the same time, the wireless transmitters 1 and 3 transmit a signal (first control signal) for stopping the air conditioning operation to the air conditioning system of the system 2. The air conditioning equipment system of the system 2 that has received this signal stops the air conditioning around the individual corresponding to the ID number that is not received (ie, the individual who owns the wireless transmitters 1 and 3), or in the office All the air conditioning operations can be stopped when the ID number transmission from the predetermined number of personnel or all of the wireless transmitters 1 and 3 cannot be received and a signal for stopping the air conditioning operation is received. .

  Further, the wireless transmitters 1 and 3 stop transmitting the ID number and transmit a signal for stopping the operation of the air conditioning equipment system of the system 2 to the security equipment system of the system 4, for example, for the security monitoring. A signal (second control signal) for starting the operation of the device is transmitted (a similar signal may be transmitted from the system 2 to the system 4 as an auxiliary). In this case, the security device system of the system 4 displays the video (security video) of the entrance / exit area to the room where the individual corresponding to the ID number not received (the individual who owns and holds the wireless transmitters 1 and 3) is working. An alarm can be issued if a suspicious person is detected by taking a picture or opening / closing the door of the room. Further, when a signal for starting the operation of the security device system is received from a predetermined number of personnel or all of the wireless transmitters 1 and 3 in the office, it is possible to start the operation of all the security devices and to be wary. .

  In the wireless management control system 100 as described above, the systems 2 and 4 are provided with a plurality of wireless receivers 60, which are deployed at appropriate locations in the office or living room (for example, for each predetermined section range). Can be kept. Further, as the system 2, an office lighting device system may be used instead of or in addition to the air conditioning device system.

  As another example, the system 2 can be an office (building) elevator system. In this case, as described above, when the illuminance in the solar cell 41 becomes 5 Lux or less, the wireless transmitters 1 and 3 stop the transmission of the ID number and operate the elevator device system of the system 2 to operate. A stop signal (first control signal) is transmitted. The elevator equipment system of the system 2 that has received this signal determines, for example, that all personnel on the predetermined floor (floor) have disappeared based on the ID number not received, and stops the operation of the elevator on that floor. (Do not stop, do not press the stop instruction button on the floor, etc.). At this time, if the system 4 is a security device system, the operation of the security device on the floor can be started based on the control signal from the wireless transmitters 1 and 3 (in addition, from the system 2) A similar signal may be sent to the system 4).

  As still another example, the system 2 is an office lighting device system and the system 4 is an office OA device system. In this case, the wireless transmitters 1 and 3 are, for example, when the illuminance in the solar cell 41 exceeds 5 Lux, for example (for example, such a situation is that the individual who owns and holds the wireless transmitters 1 and 3 A signal that starts transmission of the ID number in the timing chart shown in FIG. 2 and starts operation of the lighting system of the system 2 is assumed when carrying the wireless transmitters 1 and 3 at the time of going to work. (First control signal) is transmitted.

  The lighting device system of the system 2 that has received the ID number and its operation start signal is, for example, around the place where the individual corresponding to the received ID number (the individual who owns the wireless transmitters 1 and 3) works or Lighting equipment in the room can be turned on. The wireless transmitters 1 and 3 start the OA device system of the system 4 based on the ID number and the operation start signal of the lighting device system of the system 2 (second control signal). The OA device system that received the signal and started the operation of the OA device (copy machine, server, etc.) that can be used by the individual who owns and holds the wireless transmitters 1 and 3 (provides power supply). Can start).

  According to the wireless management control system 100 configured as described above, the plurality of systems 2 and 4 having the wireless receiver 60 can receive the ID numbers transmitted from the wireless transmitters 1 and 3. 2 and 4 are operated and / or stopped in association with the ID number, so that the systems 2 and 4 are connected to each other based on the ID number of the person who owns (holds) the wireless transmitters 1 and 3. It can be managed and controlled in relation to each other. Further, based on the ID numbers from the plurality of wireless transmitters 1 and 3, it is possible to easily control the operations and operations of the systems 2 and 4 in association with a plurality of individuals.

  Further, since the power supply unit 40 and the wireless module 50 having the solar battery 41 are accommodated inside the accommodation case 10 having a predetermined opacity, information such as characters and images is displayed on the outer surface of the accommodation case 10 such as a card or a plate. In addition, printing and printing can be performed so as to be easily visible. Moreover, communication of information is sufficiently possible with a self-power generation type that does not require battery replacement. Specifically, the power of the secondary battery 42 consumed by the wireless module 50 during the communication mode is replenished from the solar battery 41 to the secondary battery 42 during the standby mode, thereby limiting the communication time. Wireless communication without any problem is possible.

  As described above, in the wireless management control system of the present invention, a plurality of systems having a wireless receiver can receive ID information transmitted from the wireless transmitter, and the activation and / or suspension of the plurality of systems can be performed. Since this is performed in association with the ID information, it is possible to manage and control a plurality of systems in association with each other based on the personal ID information, and to control the operation and operation of these systems. Since it can be easily performed based on the operator's ID information, it can be widely used for articles, devices, apparatuses, systems, various devices, etc. used in various wireless communications, including the security field, and their production, manufacture, etc. And it can be used effectively.

  DESCRIPTION OF SYMBOLS 1,3 ... Wireless transmitter, 2 ... 1st system, 4 ... 2nd system, 10 ... Housing case, 20 ... Antenna, 30 ... Transmission module, 31 ... Signal processing circuit, 32 ... High frequency circuit, 40 ... Power supply , 41 ... solar cell (power generation element), 42 ... secondary battery (power storage device), 43 ... charging circuit, 50 ... wireless module (first wireless module), 60 ... wireless receiver, 70 ... wireless module (first) 2 wireless module), 71 antenna, 72 high frequency circuit, 73 signal processing circuit, 100 wireless management control system.

Claims (7)

A power supply unit including a power generation element and a power storage device, a first wireless module including a signal processing circuit, a high-frequency circuit, and an antenna, and a storage case in which the power supply unit and the first wireless module are stored. A wireless transmitter for transmitting ID information;
A plurality of systems having a wireless receiver including a second wireless module having a signal processing circuit, a high-frequency circuit, and an antenna, and capable of receiving the ID information transmitted from the wireless transmitter;
With
The activation and / or deactivation of the plurality of systems is performed in association with the ID information.
Wireless management control system. When the first system of the plurality of systems receives or does not receive the ID information, the first system is activated or deactivated, and the operating state or deactivation of the first system is performed. Activating or deactivating a second system of the plurality of systems based on a state;
The radio management control system according to claim 1. The wireless transmitter transmits, to the first system among the plurality of systems, a first control signal that activates or deactivates the first system, and associates the plurality of the plurality of systems with the first control signal. Sending a second control signal to activate or deactivate the second system to a second system of the system;
The radio management control system according to claim 2. The wireless transmitter stops transmission of the ID information based on illuminance in the power generation element, and transmits the first control signal and the second control signal.
The wireless management control system according to claim 3. The storage case has a predetermined opacity;
The radio management control system according to any one of claims 1 to 4. The light transmittance of the housing case is 10% to 50%.
The radio management control system according to any one of claims 1 to 4. A plurality of the wireless transmitters for transmitting different ID information,
The operation and / or stop of the plurality of systems is performed in association with a plurality of the ID information.
The radio management control system according to any one of claims 1 to 6.

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