JP2009011582A - Visual light illumination remote control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote control system capable of providing an environmental condition most appropriate for a user in real time by remote control via a communication network. <P>SOLUTION: In the visual light illumination remote control system, safe visual light illumination providing services are provided by detecting an environmental condition of the visual light illumination most appropriate for the user by a sensor 14 and performing remote control of a device for generating a 1/f fluctuation signal via the communication network 13, in a remote control system in which a remote control terminal 12 controls a client terminal 11 via the communication network 13 to have the client terminal provide illumination providing services on the basis of a database including information related to a recipe for defining an illuminating light to be used for visual light illumination providing services. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  As a part of telemedicine via a communication network, the present invention controls the control of visible light illumination from a remote or local state in consideration of the user's environmental state, psychology and physiological state, The present invention relates to a remote control system that can be provided with high reliability and safety by utilizing a medical diagnostic device and a database.

  Conventionally, methods for remotely controlling the luminance, luminous intensity, illuminance, light quantity, etc. of illumination via a communication network have been studied (for example, see Patent Document 1). Conventional lighting is limited to use of various LEDs individually and individually for lighting or traffic lights, or the use of white LEDs alone, and has not been used for healing effects.

On the other hand, there is a growing demand for general users and mentally ill patients to provide a “healing environment” based on information from reliable and reliable medical institutions. ing. Although means for realizing healing has been proposed (see, for example, Patent Documents 2 and 3), it is not based on the authentication of a medical institution, and there are strong entertainment factors. A service that makes it easy to provide a comfortable "healing" from a remote location where it is difficult to provide such an environment easily when the patient's residence is far away or a patient with a gait disorder Demand is increasing.
JP 2001-297886 A JP 2002-291895 A JP 2002-172172 A

  By exchanging visible light illumination control codes with each other, there has been no means for remotely controlling various colors and brightness of the visible light in an optimal manner and taking into account the user's environmental conditions.

  Therefore, an object of the present invention is to provide a remote control system that can provide, in real time, an environmental condition of visible light illumination most appropriate for a user by remote control via a communication network.

  The remote control system for visible light illumination according to the present invention detects the environmental conditions of visible light illumination most appropriate for the user by using a sensor, and remotely controls a device that generates a 1 / f fluctuation signal via a communication network. A safe and visible light illumination service is provided.

  Specifically, the remote control system for visible light illumination according to the present invention is based on a database including information related to a recipe that defines illumination light used for a visible light illumination providing service. In the remote control system in which the client terminal is controlled to execute the illumination providing service via the client terminal, the client terminal notifies the remote control terminal of a physiological state detected by a sensor that detects a physiological state. In accordance with the client terminal state notification information transmitting means to be transmitted as information and the visible light control information received from the remote control terminal, the brightness for each color or the brightness of a single color is controlled so that the time distribution has various 1 / f patterns. Service execution means for executing a visible light illumination providing service provided as a remote control, and the remote control At the end, when receiving the status notification information from the remote control terminal database storage means for storing the database and the client terminal status notification information transmission means, the remote control terminal database storage means is referred to, and based on the recipe, Remote control terminal service control means for generating visible light control information for executing the visible light illumination providing service according to status notification information, and the visible light control information generated by the remote control terminal service control means Visible light control information transmitting means for transmitting to the client terminal.

  By providing a function that can feed back the psychological state of a user or patient as electronic information and transfer it to a hospital or other facility in the system, a visible light illumination providing service that accurately considers the user's state The system to be provided can be constructed.

  In the remote control system for visible light illumination according to the present invention, the client terminal transmits client geographical position information to the remote control terminal, and the geographical position transmitted by the remote control terminal. Client terminal authentication means for authenticating the correct position information, wherein the remote control terminal transmits its own geographical position information to the client terminal, and the transmission of the client terminal Remote control terminal authentication means for authenticating geographical position information to be generated, and the remote control terminal service control means generates the visible light control information when authentication by the remote terminal authentication means is established. The service execution means, when the authentication by the client terminal authentication means is established, the visible light control information transmission means In accordance with the visible light control information to be transmitted, it is preferable to perform the visible light illumination provided services. According to the present invention, it is possible to realize a visible light medical service in which a mutual authentication mechanism between a hospital side and a patient side can be implemented with high reliability and speed by utilizing network equipment and GPS information.

  In the visible light illumination remote control system according to the present invention, the client terminal stores client terminal database storage means for storing a database including information related to a recipe that defines illumination light used for the visible light illumination providing service; When the authentication by the client terminal authentication unit is established, the client terminal database storage unit is referred to, and based on the recipe, the visible light illumination providing service according to the physiological state detected by the sensor is executed. Client terminal service control means for generating visible light control information, and the service execution means is configured to control the visible light generated by the client terminal service control means when authentication by the client terminal authentication means is established. According to the information, provide the visible light illumination service It is preferable that the row. The visible light illumination providing service close to the user's preference can be provided without being limited to the visible light illumination based on the control from the hospital side.

  In the remote control system for visible light illumination according to the present invention, when the visible light control information transmitting means transmits the visible light control information, the client terminal position information transmitting means controls the remote control of its own geographical position information. It is preferable that the remote control terminal location information transmission means repeatedly transmits its geographical location information to the client terminal repeatedly. Even after mutual authentication is performed, by continuing to perform authentication, it becomes possible to perform irradiation control of visible light that is safer and more reliable.

  ADVANTAGE OF THE INVENTION According to this invention, the visible light illumination provision service by the visible light illumination from a remote can be provided by order-made for each individual, utilizing a network equipment effectively. Furthermore, the mechanism of the visible light remote control system is very effective even for severely disabled persons and elderly persons who are difficult to go to the hospital, especially difficult to move.

Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiment described below is an example of the configuration of the present invention, and the present invention is not limited to the following embodiment.
(Embodiment 1)
FIG. 1 is a configuration diagram of a visible light illumination remote control system according to the first embodiment. FIG. 2 is a configuration diagram illustrating an example of a client terminal and a remote control terminal. The remote control system for visible light illumination shown in FIGS. 1 and 2 includes a remote control terminal 12 arranged in a control center 82 such as a hospital, a network 13, and a client terminal 11 arranged in a client user house 81. It is a major component. The remote control terminal 12 controls the client terminal 11 via the communication network 13 to cause the client terminal 11 to execute the illumination providing service.

  A remote control terminal 12 is disposed in a control center 82 such as a hospital. The installation location of the remote control terminal 12 is not limited to the control center 82 such as a hospital, and illumination light is installed in the management center facility. In the client user house 81, the client terminal 11, the sensor 14, and the lighting device 15 are arranged. The client terminal 11 and the remote control terminal 12 are communicatively connected via a communication network 13.

  The sensor 14 detects the physiological state of the human body. The physiological state is the physiological information of the human body that makes it possible to provide mental “healing”. The sensor 14 is, for example, a magnetoencephalogram measuring device (MEG), a heart rate measuring device, or an electroencephalogram (EEG) that measures a magnetic signal generated from the brain. The brain activation status and relaxation status can be measured from the electroencephalogram using alpha waves (8 to 13 Hz). The sensor 14 may measure a physiological state of the body such as a pulse wave measuring device or optical topography. In functional magnetic resonance imaging (fMRI), blood oxygen levels can be measured, which part of the brain is particularly active can be determined in real time, for example, when you want food In addition, it is possible to specify the parts of various emotions that show height. In addition, taking advantage of the feeling that aversion is a sense developed to protect yourself from illness, research to measure “comfortable” emotions by measuring these senses with fMRI is also underway. .

  Conventionally, brain waves have been used in psychology and psychiatry as information for objectively measuring various human conditions. A person's state that can be identified by an electroencephalogram includes a state of awakening and a state of sleeping. At the time of awakening, the eyes open and excited state can be identified by observing the appearance of β waves. Further, the closed eye and the resting state can be identified by observing the appearance of α waves. With regard to the sleep state, it is known that the depth of sleep can be identified by observing the appearance of characteristic waves such as an aneurysm, spindle wave, and slow wave. For this purpose, it is considered preferable to utilize an electroencephalogram.

  Furthermore, in addition to medical diagnostic devices such as electroencephalograms, magnetoencephalogram measuring devices, pulse wave measuring devices, fRMI, etc., in addition to environmental sensors (temperature sensors, humidity sensors, atmospheric pressure sensors, acceleration sensors, illuminance sensors, etc.) ), The patient transmits the latest living space information measured in real time and the physiological and psychological information of the human body to the hospital via the network, and the hospital is based on this notification information. It is possible to create an optimum recipe for visible light control. Monitor patient status and environmental conditions in real time, and based on the results, perform or change the control of visible light remotely, in real time, and while performing these controls However, it is possible to provide a function for improving the reliability of remote control by repeatedly performing the authentication operation at all times.

  The visible light remote control system according to the first embodiment preferably further includes a sensor (not shown) that detects a change in the environment. By detecting a change in the environment, it is possible to change the fluctuation to a “form close to the natural state”. Changes in the environment are, for example, temperature, atmospheric pressure, and wind pressure.

  The remote control terminal 12 causes the illumination providing service to be executed based on a database including information related to a recipe that defines the illumination light used for the visible light illumination providing service. The remote control terminal 12 includes a remote control terminal database storage unit 31 for storing a database, a remote control terminal service control unit 32, and a visible light control information transmission unit 33. The client terminal 11 includes client terminal state notification information transmission means 22 and service execution means 23.

  The remote control terminal database storage means 31 stores a database including information related to a recipe that defines the illumination light used for the visible light illumination providing service. For example, it is a database for each user that stores a database for each of user A and user B and a database for each disease shown in FIG. Moreover, it is the database for every disease shown in FIG. FIG. 3 shows an example of a recipe that defines illumination light. FIG. 3A shows a configuration example of the most general recipe data in which individual 1 / f patterns and individual luminances can be set for various color types. FIG. 3B shows an example of the simplest recipe data configuration for setting the same 1 / f pattern and the same brightness for each color type. The configuration of recipe data for visible light control is different for each user ID, password, GPS information, color type, color type, or data field (1 / f pattern 1, 1 / f pattern 2, 1 / f pattern 3, etc.) and fields (luminance 1, luminance 2, luminance 3) that can be controlled individually or individually for each color type. When creating these pieces of information, it is necessary to use a control program on the hospital side, and recipe data may be configured using appropriate parameters. Furthermore, when the patient has a specific disease at the user's home, it is possible to provide a data field for enabling visible light irradiation in consideration of the condition. FIG. 3 shows various configuration examples of the control recipe data described so far, but is not limited to this form.

  The sensor 14 detects a physiological state. The client terminal state notification information transmitting unit 22 transmits the physiological state detected by the sensor 14 to the remote control terminal 12 as state notification information. When receiving the state notification information from the client terminal state notification information transmitting unit 22, the remote control terminal service control unit 32 refers to the remote control terminal database storage unit 31, and provides visible light illumination according to the state notification information based on the recipe. Generate visible light control information to execute the service. The visible light control information transmission unit 33 transmits the visible light control information generated by the remote control terminal service control unit 32 to the client terminal 11. The service execution unit 23 executes the visible light illumination providing service by controlling the luminance so that the time distribution has various 1 / f patterns according to the visible light control information received from the remote control terminal 12. The illumination device 15 generates illumination light according to the output of the service execution unit 23. Since the illumination device 15 emits illumination light according to the visible light control information, the illumination devices 15A and 15B of the user A and the user B shown in FIG. Can generate illumination light.

  The illuminating device 15 is an apparatus that generates illuminating light with brightness such that the time distribution of brightness has various 1 / f patterns, which is controlled by visible light control information. The illumination device 15 is, for example, various LED light sources. The illumination device 15 controls the luminance of illumination light having a predetermined wavelength, and generates illumination light having a 1 / f pattern whose luminance time distribution corresponds to visible light control information. The predetermined wavelength is, for example, a wavelength for each color such as red, blue, or yellow. Moreover, it is preferable that the illuminating device 15 is provided with the light source of the wavelength of multiple types of color. For example, it is preferable to provide a light source with wavelengths of three kinds of colors of red, blue, and yellow. In this case, the illumination device 15 generates illumination light having such luminance that the time distribution of luminance for each color has various 1 / f patterns.

  As shown in FIG. 1, the visible light control device preferably includes visible light control devices 41A and 41B for each of the lighting devices 15A and 15B. The visible light control device controls the wavelength or luminance of the illumination light generated by the illumination device 15, and controls the luminance time distribution to have various 1 / f patterns. The visible light control device is separate from the lighting device in FIG. 1, but may be integrated.

  With the above configuration, a mental healing effect can be made possible from a remote or nearby client terminal 11 by effectively and individually controlling visible light having various colors. For example, between the hospital side and the patient side, between the illumination light management center facility and the general user's house, by utilizing network equipment and GPS information etc., and incorporating a mutual authentication mechanism, it is safe and quick, An order-made visible light illumination environment suitable for each individual can be provided with high reliability and at low cost, and can be realized as a mental medical service.

  In the visible light remote control system shown in FIG. 1, it is further preferable that the client terminal position information acquisition unit 16 is disposed in the client user house 81 and the remote control terminal position information acquisition unit 17 is disposed in the control center 82. In this case, as shown in FIG. 2, the client terminal 11 includes client terminal position information transmission means 25, client terminal authentication means 26, and client terminal database storage means 27. Further, as shown in FIG. 2, the remote control terminal 12 includes a remote control terminal position information transmission unit 35 and a remote control terminal authentication unit 36.

  The client terminal position information acquisition unit 16 acquires the geographical position information of the client terminal 11 by the satellite positioning system. The client terminal position information transmission unit 25 transmits the geographical position information of the client terminal 11 to the remote control terminal 12. The remote control terminal authentication unit 36 refers to the remote control terminal database storage unit 31 and authenticates the geographical position information transmitted by the client terminal 11. The remote control terminal service control means 32 generates visible light control information when authentication by the remote terminal authentication means 36 is established.

  On the other hand, the remote control terminal position information acquisition means 17 acquires the geographical position information of the remote control terminal 12 by the satellite positioning system. The remote control terminal position information transmission means 35 transmits the geographical position information of the remote control terminal 12 to the client terminal 11. The client terminal authentication means 26 refers to the client terminal database storage means 27 that stores a database including authentication information such as the position information of the remote control terminal 12 and authenticates the geographical position information transmitted by the remote control terminal 12. . The service execution unit 23 executes the visible light illumination providing service according to the visible light control information transmitted from the visible light control information transmission unit 33 when the authentication by the client terminal authentication unit 26 is established.

  If the client terminal 11 is a stationary terminal, the client terminal position information acquisition unit 16 acquires, for example, the position information of the patient user home 81 of the patient. If the remote control terminal 12 is a stationary terminal, the remote control terminal position information acquisition unit 17 acquires the position information of the control center 82, for example. The position information is, for example, the latitude and longitude on the earth. The position information may include height information. If the accuracy of the position information is high, the position information for authentication can be changed depending on the installation location of the antenna, so that impersonation of a third party can be prevented and the password can be applied for authentication. For this reason, the accuracy of the position information is preferably 1 m or less, and more preferably 100 mm or less.

  As shown in FIG. 3, the remote control terminal database storage means 31 preferably contains GPS information in addition to the user ID and password. The GPS information may be position information obtained by a satellite positioning system or various information received from a satellite. The remote control terminal 12 can perform mutual authentication with the user client by always authenticating the position information on the information transmission side (transmission side) (see, for example, Japanese Patent Application No. 2006-291131). In addition to the mutual authentication method using position information, it is preferable to combine with a public key authentication method. At the user client's home, after mutual authentication with the remote hospital, the hospital side selects and sends out the appropriate recipe information for each individual user from the database for each user, Alternatively, appropriate recipe information can be sent by selecting from a database specific to each disease.

  The client terminal database storage unit 27 stores authentication information for authenticating the remote control terminal 12. About authentication information, since it mutually authenticates with the remote control terminal 12, it is preferable to store the thing similar to the authentication information stored in the remote control terminal database storage means 31. FIG.

  A method has been proposed for combining the GPS information and the database to mutually authenticate the position information of the remote control terminal 12 that is the information transmission side (transmission side) (see Japanese Patent Application No. 2006-291131). At this time, as information exchanged between the client terminal 11 and the remote control terminal 12, the luminance is controlled according to the color of the LED light source with respect to the visible light control information, and the 1 / f fluctuation pattern is medically Using a database and personal information, each user can be provided on an individual order basis. In other words, a system that utilizes GPS information as authentication information has been devised, but after mutual authentication using position identification information such as GPS information, visible light illumination can be made personally tailored for personal preference and medical purposes. In response, it can be implemented in combination with a mechanism that can be safely provided remotely.

  The client terminal 11 can provide an order-made visible light illumination providing service to a plurality of users A and users B in the client user house 81 based on the recipe data. In the visible light control information transmitted via the network 13 from the control center 82 side such as a hospital, it is preferable that position information is incorporated in addition to the user ID and password. At the user client 81, the received visible light control information is decoded by the client terminal 11 and the decoder, and thereafter, irradiation of visible light is controlled for each individual user based on the recipe included in the visible light control information. can do. Even when there are a plurality of users in one client user house 81, the above-mentioned control is possible in the same manner.

  In addition to the conventional simple visible light illumination, the visible light remote control system according to the present embodiment can individually control various LED light sources by adding personal preference and medically guaranteed 1 / f fluctuations. A simple device that can be installed at the user's home, and this control device is remotely connected via a network. The provision of visible light illumination, which is one of the telemedicine services, can be effectively combined on the network 13 by combining GPS information, medical database, public key, P2P network technology, etc. at low cost. Further, if the information is already obtained, it is possible to use the information by separating it from the network.

  In the present embodiment, when the visible light control information transmitting means 33 transmits visible light control information, the client terminal position information transmitting means 25 repeatedly transmits its geographical position information to the remote control terminal 12, The remote control terminal position information transmitting means 35 preferably transmits its own geographical position information to the client terminal 11 repeatedly. The visible light control information transmission unit 33 and the client terminal position information transmission unit 25 repeatedly transmit the position information, so that the client terminal authentication unit 26 and the remote control terminal authentication unit 36 perform authentication as needed.

  Whether or not the visible light remote control system according to the present embodiment is information from a properly registered institution when a safe and reliable medical institution provides a visible light information type and a fluctuation type. Can be used for the first time after mutual authentication when the user or patient's client user house 81 side receives the visible light control information and is provided with the visible light illumination control information using the network 13. Therefore, it can be used under safe usage conditions.

  In addition to simple visible light illumination by the illumination device 15, a simple device capable of individual control of the illumination device 15 by adding personal preference and medically guaranteed 1 / f fluctuation is provided by the client terminal 11 to the client user. This is a highly reliable, difficult to achieve with the conventional medical system after the appropriate authentication using the location information etc. is mutually established via the network 13 remotely installed in the house 81 The provision of visible light illumination, which is one of the safe telemedicine services, can be constructed on the network 13 by combining GPS information, medical database, public authentication key, P2P network technology, etc. effectively and inexpensively. In addition, if the information is already obtained by another means on the client terminal 11 side, this information is used to separate the information in the same facility or in the room from the external network 13. It can also be used.

  The visible light remote control system according to the present embodiment can safely realize psychotherapy with a high healing effect by remote control from an authenticated medical institution or the like by taking a step from the conventional simple visible light illumination. This means can be similarly provided for services that provide a comfortable visible light illumination environment or the like in the room space for important customers in a hotel. Furthermore, the database information for visible light control provided by each medical institution can be used effectively between each other after mutual authentication of the medical institution. It can be used for society.

  An apparatus capable of generating an existing fragrance or medicine is connected to the client terminal 11 on the client user's house 81 side, and the database stored in the remote control terminal database storage means 31 provided by the control center 82 such as a medical institution is used. Using the information, it is possible to use the network 13 together with the above-described separate apparatus, which enables the medical institution to perform the remote medical care safely and reliably using the network 13, and can be used together. For the first time, it is possible to dramatically improve convenience and reliability for medical care.

  According to the visible light remote control system according to the present embodiment, it is difficult to realize with the conventional visible light irradiation system, and the medical service by the reliable and safe remote visible light illumination is used for the network equipment. It can be realized for the first time by effectively using GPS and combining highly accurate and inexpensive GPS information, public encryption methods, sensors, and the like appropriately and effectively and using them on an individual order basis. Further, the mechanism disclosed in the present embodiment is not limited to visible light illumination, but can also be used to control devices that can provide drugs, fragrances, music, video information, etc. at the user's home. According to the present embodiment, not only telemedicine but also a “healing” environment suitable for relaxation can be provided to customers from a remote location. In addition, using aromatherapy therapists and appropriate medicines for patients with asthma, etc. in conjunction with visible light illumination, these controls are mutually authenticated under the responsibility of doctors and medical institutions. It is possible to implement it safely after it has been carried out reliably, and it is possible to carry out after confirming the safety between doctors and patients under secure network management, so the reliability of telemedicine is dramatically improved. It becomes possible to raise.

(Embodiment 2)
FIG. 4 is a configuration diagram of the remote control system for visible light illumination according to the second embodiment. The configuration of the visible light remote control system shown in FIG. 4 is almost the same as that of FIG. 1, but differs in that a switching device 43 is provided in FIG.

  The switching device 43 performs switching control for switching as needed independently in the user client house, regardless of recipe information of a control center (parent device) such as a hospital. Based on the data received via the environmental monitoring sensors 18-1 and 18-2, the sensor data is processed and has a format equivalent to the visible light control information sent from the hospital side via the network 13. Convert to data format. In this way, it is possible to perform control using a unique sensor circuit without being limited to visible light illumination based on control from the hospital side.

  The switching device 43 can be provided separately from the client terminal 11. FIG. 4 shows an example in which the connection is made between the client terminal 11 and the decoder 42. The switching device 43 may be built in the client terminal 11.

  When a safe and reliable medical institution provides the information type and fluctuation type of visible light, whether or not the information is from a normally registered institution, the network 13 is used to determine whether the information is from a user or patient. Even when the client terminal 11 installed on the side receives the visible light control information transmitted from the remote control terminal 12 and provides the visible light illumination control information, it can be used for the first time after mutual authentication. Even on the surface, it has the feature that it can be used under the perfect use conditions. Furthermore, even after mutual authentication has been performed, by continuously performing authentication, there is a feature that irradiation control of visible light can be performed more safely and safely.

  FIG. 5 is a configuration diagram illustrating an example of a client terminal and a remote control terminal according to the present embodiment. In the remote control system for visible light illumination according to the present embodiment, in addition to the remote control system for visible light illumination according to the first embodiment, the client terminal 11 further includes client terminal service control means 28 corresponding to the switching device 43, Is provided.

  The client terminal authentication means 26 refers to the client terminal database storage means 27 that stores a database including authentication information such as the position information of the remote control terminal 12 and authenticates the geographical position information transmitted by the remote control terminal 12. . The service execution unit 23 executes the visible light illumination providing service according to the visible light control information transmitted from the visible light control information transmission unit 33 when the authentication by the client terminal authentication unit 26 is established.

  In this embodiment, the client terminal database storage unit 27 further stores a database including information related to a recipe that defines illumination light used for the visible light illumination providing service. When the sensor 14 detects the physiological state, the client terminal service control unit 28 refers to the client terminal database storage unit 27 and executes a visible light illumination providing service according to the physiological state detected by the sensor 14 based on the recipe. To generate visible light control information. The service execution unit 23 executes a visible light illumination providing service according to the visible light control information generated by the client terminal service control unit 28. The illumination device 15 generates illumination light according to the visible light control information.

  Here, the client terminal service control means 28 preferably generates visible light control information when the authentication by the client terminal authentication means 25 is established. Alternatively, the service execution unit 23 preferably executes the visible light illumination providing service according to the visible light control information generated by the client terminal service control unit 28 when the authentication by the client terminal authentication unit 26 is established.

  The service execution unit 23 executes the visible light illumination providing service according to the visible light control information generated by the client terminal service control unit 28 when the authentication by the client terminal authentication unit 26 is established. The illumination device 15 generates illumination light according to the visible light control information.

  FIG. 6 is a configuration diagram of another form of the visible light remote control system according to the second embodiment. The visible light remote control system shown in FIG. 6 is different from the visible light remote control system shown in FIG. 4 in that irradiation of illumination light by the user A's visible light LED is “electronic candle”. It is also possible to create a “healing space” by utilizing this control method for “objects” that generate light such as “electronic candles”. In order to realize an "electronic candle" with properties close to those of an actual candle, in addition to a control method that realizes 1 / f fluctuations that simulate color, brightness, and natural fluctuations, for example, the door of a house has been opened. Thus, “change in atmospheric pressure” is detected using the sensor 18-1, “temperature” is detected using the sensor 18-2, or “wind pressure” is changed using another sensor (not shown). By adding the above, it is possible to temporarily change the fluctuation to “a form close to the natural state”.

  FIG. 7 is an example of a lighting device in the visible light remote control system according to the first and second embodiments. The illumination device 15 shown in FIG. 7 has a configuration in which the visible light control device 41A or 41B shown in FIG. 1 is integrated. In addition, a configuration example when a decoder 42 is connected to the outside of the client terminal 11 is shown. In the present embodiment, among the visible light control information sent from the remote control terminal 12, the user ID, password, and GPS information are used for mutual authentication as already described.

  The client terminal 11 includes color type 1, color type 2, color type 3, luminance type 1 luminance 1, color type 2 luminance 2, color type 3 luminance 3, color type 1 1 The visible light control information including the / f pattern, the color type 1 / f pattern, and the color type 3 1 / f pattern is received. After receiving the control information, the client terminal 11 uses the decoder 42 including the microcomputer control circuit to decode the control code included in the transmitted data of the parameters of luminance, color, and 1 / f fluctuation, and then visible light illumination. Can be controlled.

  The control mechanism according to the present embodiment is a client terminal that uses a secure visible light illumination service to effectively utilize a network using GPS information and a public encryption system, and further generates a 1 / f fluctuation signal using a microcomputer. 11 or a device and a circuit for controlling a LED according to a signal generated by the device and realizing control of illumination light emitted from the LED, and a database for storing a control pattern of visible light illumination suitable for an individual All of the technologies can be realized by effectively combining and using them.

  The decoder 42 controls the illumination device 15 based on the received visible light control information. The illuminating device 15 has a direct-current power supply or an alternating-current power supply for normal LED lighting, and can emit colors such as red, blue, and green. By connecting the output of the decoder 42 to the power supply portion for each color and modulating the color light with the designated 1 / f fluctuation, individual 1 / f fluctuation illumination is generated for each color. be able to. Furthermore, these 1 / f illuminations can be blended according to the visible light control information that the brightness adjustment individually gives to the variable resistors.

FIG. 8 is an example of a decoder that uses a microcomputer (such as a processor) in the illumination devices according to the first and second embodiments. The decoder 42 accumulates user ID information and recipe information as input information in an input buffer, sequentially reads out the data, and emits light of various colors based on a recipe analysis program created in advance. It is possible to instruct which kind of 1 / f fluctuation pattern is to be selected and which luminance is to be given to the LED light to be emitted. At this time, it is necessary to incorporate a circuit capable of generating various 1 / f pattern signals in the decoder 42 in advance. The 1 / f pattern includes, for example, intermittent chaos. As an example of one pattern representing 1 / f fluctuation, when intermittent chaos is used, there is a method of calculating the luminance value of the LED from time to time according to the following equation.
(A) When 0 <X (t) <0.5 X (t + 1) = X (t) + 2X (t) ²
(B) 1> when X (t + 1) of X (t) ≧ 0.5 = X (t) -2 (1-X (t)) 2
Here, the luminance X (t + 1) (maximum value 1) at time (t + 1) is determined by the luminance X (t) one unit time before. For example, the unit time is set to an interval of 0.1 msec to 1 sec. The change of the fluctuation pattern as the illumination can be realized also by changing.

  FIG. 9 newly feeds back status notification information from the client terminal 11 side to the remote control terminal 12 (hospital side) with respect to the configuration of the visible light remote control system according to the first and second embodiments. This is an embodiment for interactively realizing visible light control. In the configuration example shown in FIG. 9, the physiological information of the human body in the client user's house 81 is obtained from the brain waves (electrical signals) generated from the brain using the sensor 14 that detects a physiological state such as an electroencephalogram measuring device. By measuring the value, it is possible to more accurately grasp the activation status and relaxation status of the brain by identifying alpha waves (8 to 13 Hz). Further, a pulse wave measuring device, a magnetoencephalogram measuring device, a heart rate measuring device, fMRI or optical topography is used as the sensor 14, and the remote control terminal 12 determines the physiological state data in real time to a remote hospital or the like. It can be transmitted through the network 13. By performing this feedback promptly, it becomes possible for the patient at the client user's house 81 to remotely return the illumination light recipe that makes the patient comfortable.

  By utilizing this mechanism, for example, it is possible to create a space (hereinafter referred to as a healing space) that leads a person to a resting state by visually stimulating the person by presenting a light pattern. In order to realize this, by monitoring the α wave in the electroencephalogram by the sensor 14, it is determined whether or not the pattern of the irradiated light surely gives an effect to a person to rest (hereinafter referred to as relaxation effect). The remote control terminal 12 monitors in real time, makes automatic determination objectively, and utilizes the means to transmit the information to the hospital side via the network 13, so that it can be more appropriate according to the different conditions of individuals It is possible to construct a feedback system in which a light pattern that is considered to have a relaxing effect can be selected from a database stored in the remote control terminal database storage means of the remote control terminal 12.

  In general, the appearance of alpha waves is monitored by passing an electroencephalogram measured at the occipital electrodes O1 and O2 of the international 10-20 electrode placement method through an 8-13 Hz alpha wave bandpass filter to obtain a power spectrum, which is generally a steady state of the electroencephalogram. This is preferably done by determining whether the average power for at least 20 seconds considered to have exceeded a certain threshold. However, since the level of the power spectrum in the α-wave band in a state of resting eyes by the user generally varies among individuals, it is preferable to select an appropriate threshold value for each user. Therefore, before using this system, the user measures the brain waves in the resting closed eye state and other states, and sets the intermediate value of the power spectrum level of the α wave band in both states to the α wave. It is preferable that the threshold value for determining appearance is determined and recorded in a database, and this threshold value is used as an index. FIG. 10 shows a processing flow for determining the α wave appearance determination threshold described above, and FIG. 11 shows an embodiment for determining the appearance of α waves using the database.

  The determination of the α wave appearance determination threshold will be described with reference to FIG. In step S111, the electroencephalogram when the user is at rest and in other states is measured. For example, the measurement is performed by the sensor 14 described in FIG. In step S112, the α wave band power is calculated from the brain wave measured in step S111. In step S113, a threshold value between the state when the eyes are at rest and the state when the eyes are not at rest is calculated. In step S114, the threshold value calculated in step S113 is registered in a database including information related to a recipe that defines the illumination light used for the visible light illumination providing service. When providing the visible light illumination providing service, a recipe is created using a newly registered threshold value.

  The appearance determination of the α wave will be described with reference to FIG. In step S211, the user's brain waves are measured. For example, measurement is performed by the sensor 14 of FIG. In step S212, the α wave band power is calculated from the brain wave measured in step S211. In step S213, the α wave band power calculated in step S212 is compared with a threshold value registered in advance by referring to a database in which threshold values are registered. By comparison, it is determined whether or not the eyes are at rest. If the α wave band power exceeds the threshold as a result of the comparison, the process proceeds to step S214, and if the α wave band power does not exceed the threshold, the process proceeds to step S215. In step S214, a message indicating that the eyes are at rest is output. In step S215, a message indicating that the subject is not in a resting closed eye state is output.

  On the other hand, regarding the change in the heart beat, the change can be recognized as a potential change caused by the beat and measured by an electrocardiograph or an electroencephalograph. Alternatively, a change in pressure of blood pushed out with pulsation can be measured and measured using an optical sensor or the like with a pulse wave meter or the like. In general, the speed of pulsation is controlled by the autonomic nervous system, and the autonomic nervous system is composed of sympathetic nerves and parasympathetic nerves and is known to have an antagonistic action. It is known that sympathetic nerves prevail when a person is excited, resulting in small and fast beats. On the other hand, it is known that when calming down, the sympathetic nerves prevail, resulting in a large and slow pulsation. In general, the speed of pulsation can be known by measuring the peak interval (RR interval) of the measured pulsation waveform and calculating the reciprocal of the interval between adjacent peaks. Since the peak of the pulsation waveform by the electrocardiograph is prominent as compared with other portions, it is possible to easily determine the threshold for detecting the peak. For example, a high-pass filter having a cut-off frequency of about 10 Hz is used in advance to remove a gentle fluctuation of the waveform due to noise or the like, and then about half of the maximum value of the waveform is set as a threshold value. It is possible to detect the peak time.

  In the case of a pulse wave meter, the speed of pulsation can be obtained by the same process as described above using the peak value of the second-order differential value (acceleration pulse wave) of the measured waveform. In general, there are individual differences in the speed of pulsation at rest depending on the user.Before using this proposed system, users of hospital facilities, etc. It is desirable to measure the pulsation value, determine the middle value of the pulsation speed in both states as the pulsation speed threshold for resting determination, and record it in the database . FIG. 12 shows an example of a processing flow for determining a threshold for determining a resting state based on an electrocardiogram or a pulse wave, and FIG. 13 shows an example of a flow for determining a resting state based on an electrocardiogram or a pulse wave.

  The determination of the resting state determination threshold will be described with reference to FIG. In step S311, electrocardiograms or pulse waves in the user's resting state and other states are measured. For example, the measurement is performed by the sensor 14 described in FIG. In step S312, the speed of pulsation is calculated from the electrocardiogram or pulse wave measured in step S311. In step S313, a threshold value when the rest state and the rest state are not calculated. In step S314, the threshold calculated in step S313 is registered in a database including information related to a recipe that defines illumination light used for the visible light illumination providing service. When providing the visible light illumination providing service, a recipe is created using a newly registered threshold value.

  The rest state determination will be described with reference to FIG. In step S411, the user's electrocardiogram or pulse wave is measured. For example, measurement is performed by the sensor 14 of FIG. In step S412, the speed of pulsation is calculated from the electrocardiogram or pulse wave measured in step S411. In step S413, the beat speed calculated in step S412 is compared with a threshold value registered in advance by referring to a database in which threshold values are registered. By comparison, it is determined whether or not a resting state is reached. As a result of comparison, if the speed of pulsation exceeds the threshold value, the process proceeds to step S414, and if the speed of pulsation does not exceed the threshold value, the process proceeds to step S415. In step S414, a message indicating that the subject is not in a resting closed eye state is output. In step S415, a message indicating that the patient is in a resting state is output.

  According to the above-described method, the measured or acquired user's physiological state data, etc. is transferred to a facility such as a hospital via a network, and in the hospital, the physiological state of the user or patient is determined. It can be performed.

  Note that the threshold database for state determination stores data via the network, and the acquired data can be used wherever it exists. Needless to say, it may be used by a person or in a hospital.

  In this way, various measurement results at the user client's home are transmitted in real time to the remote control center (master control device), and the remote master control device sends the measurement results to the user's home based on the reception results. A visible light control device, etc. can be changed interactively and in real time via a network in real time to change the contents of visible light control that is radiated by the visible light control device at the user's home, thereby providing a medical effect. It is possible to improve. For example, in a hospital, it is possible to adjust a light pattern for leading to a resting state based on information on a user's current state, and an example of an adjusting method is shown below. Regarding the light pattern adjustment method, color adjustment and brightness (luminance or luminance) can be assumed as elements to be controlled. Regarding the adjustment of brightness and color, the light pattern can be made by LEDs of the three primary colors, red, green and blue, and the brightness and color can be changed by adjusting the brightness of each. Can do.

  The intensity of each of the red, green, and blue colors is represented by symbols RS, GS, and BS, respectively. This value is preferably set to 0 when the luminance is 0, and the other luminances are divided into arbitrary three levels, and for example, it is preferable to adjust in four levels of the minimum value 1, the intermediate value 2, and the maximum value 3. Regarding the adjustment of temporal change, it is possible to control the brightness of each of the three primary colors of red, green, and blue to be kept constant regardless of the time and when the temporal change is accompanied. is there. For example, the use of a 1 / f fluctuation rhythm generated by the intermittent chaos method for adjustment of temporal change is considered as an example, but is not limited thereto. Here, taking the case of intermittent chaos as an example, the parameter update cycle is represented by the symbol F. This value is set to 4 when the period is infinite (when there is no time change), and the other periods are divided into three arbitrary stages, and adjusted in four stages: minimum value 1, intermediate value 2, maximum value 3. It is possible.

  Below, an example of the adjustment method is shown. For example, in the adjustment of biological signals and light patterns, the light pattern is a “healing space for guiding a person to a resting state by means of biological signals such as the power spectrum level of the electroencephalogram α wave band and the speed of pulsation. It is preferable to make adjustment by the following four methods.

(1) An example of a method for adjusting the power spectrum and brightness / color of the α wave band of an electroencephalogram A method of adjusting according to the following steps is conceivable.
Step 1: As initial settings, GS = 1, BS = 0, and RS = 0. The reason for starting from green light is that, in color therapy, it is generally said that green is effective for rest.
Step 2: It is determined whether the eye is in a closed eye state based on the level of the power spectrum in the α wave band. Step 2 is repeated if the eyes are at rest.
Step 3: If GS <3, go to Step 2 with GS = GS + 1.
Step 4: If BS <3, set BS = BS + 1 and GS = 0 and proceed to Step 2.
Step 5: If RS <3, set RS = RS + 1, GS = 0, BS = 0 and proceed to Step 2.

(2) An example of a method for adjusting the speed of pulsation, brightness, and color It is considered that adjustment is performed according to the following steps.
Step 1: As initial settings, GS = 1, BS = 0, and RS = 0. The reason for starting with green light is that green is said to have a calming effect in color therapy.
Step 2: It is determined whether the person is at rest based on the speed of pulsation. If it is resting, repeat step 2.
Step 3: If GS <3, go to Step 2 with GS = GS + 1.
Step 4. : If BS <3, set BS = BS + 1 and GS = 0 and proceed to Step 2.
Step 5: If RS <3, set RS = RS + 1, BS = 0, BS = 0 and proceed to Step 2.

(3) An example of a method of adjusting the power spectrum and temporal change of the α wave band of the brain wave A method of adjusting according to the following steps is conceivable.
Step 1: As an initial setting, F = 1.
Step 2: It is determined whether the eye is in a closed eye state based on the level of the power spectrum in the α wave band. Step 2 is repeated if the eyes are resting and closed.
Step 3: If F <3, shift to Step 2 with F = F + 1.

(4) An example of a method for adjusting the speed of pulsation and temporal change A method of adjusting according to the following steps is conceivable.
Step 1: As an initial setting, F = 1.
Step 2: It is determined whether the user is in a resting state based on the level of the power spectrum in the α wave band. If it is resting, repeat step 2.
Step 3: If F <3, shift to Step 2 with F = F + 1.

  Similarly, the above four adjustment methods can be freely selected by a user of a hospital side facility or the like (a controller of visible light) and performed in any order.

  Furthermore, it is also possible to implement a plurality of adjustment methods as a series of flows by incorporating any other number of adjustment methods after step 2 of each adjustment method. For example, by incorporating the adjustment of the pulsation speed and temporal change after the step 2 of the adjustment of the pulsation speed and the brightness / color, the adjustment of the pulsation speed and the brightness / color and the pulsation speed It is possible to adjust the temporal change as a series of processing flows. In addition, the power spectrum and brightness / brightness / brightness / brightness / brightness / brightness / brightness / color of the brain wave are incorporated into the power spectrum / brightness / color adjustment after step 2 of the adjustment. Similarly, it is possible to perform the color adjustment, the speed of pulsation, and the brightness / color adjustment as a series of flows. Furthermore, an integration method can also be arranged in series after a step 2 of one adjustment method, or one of the adjustment methods to be incorporated after step 2 of another adjustment method. However, the present invention is not limited to the above example.

  The information notification data returned from the client user's home when performing this series of processing includes user ID, password (PASS), GPS information, measurement device type 1, measurement data 1, device type 2, and measurement data. It is preferable that mutual authentication is performed every time feedback is performed. By combining this mutual authentication, it is possible to highly secure the medical treatment related to remote visible light illumination, and this authentication operation requires notification of change information from the relevant recipe data and user client. Even in the absence of a problem, it is desirable in terms of reliability to perform it periodically. In FIG. 14, the structural example of the visible light control information for notifying the state from a client user terminal is shown.

  FIG. 15 shows a signal sequence example when interactive control is performed between the client terminal 11 and the remote control terminal 12. In step S611, the client terminal 11 determines whether there is a visible light control request. Step S611 is repeated as needed. In step S612, the client terminal 11 determines whether there is a medical diagnostic apparatus. The medical diagnostic apparatus is, for example, the sensor 14 shown in FIG. If it is determined in step S612 that there is a medical diagnostic apparatus, the process proceeds to step S613. If it is determined in step S612 that there is no medical diagnostic apparatus, the process proceeds to step S614. In step S613, the client terminal 11 creates data including state notification information from the physiological state from the medical diagnostic apparatus.

  In step S614, the client terminal 11 transmits control request data for requesting visible light control information to the remote control terminal 12. The control request data preferably includes identification information (ID), password, position information, and GPS information of the client terminal 11 in addition to the status notification information. After step S614, the process proceeds to step S615 and step S511.

  In step S511, the remote control terminal 12 repeatedly determines whether control request data has been received from the client terminal 11. If it is determined that the control request data has been received, the process proceeds to step S512. In step S512, the remote control terminal 12 authenticates the client terminal 11 that is the transmission source of the control request data.

  In step S513, the remote control terminal 12 determines whether or not the authentication is successful. The authentication can be performed using various authentication information such as position information, GPS information, and password, in addition to authentication with a renewal key. If the authentication is not successful, the remote control terminal 12 proceeds to step S514. In step S514, the remote control terminal 12 blocks communication with the client terminal 11 that has not been successfully authenticated, and proceeds to step S511. If the authentication is successful, the remote control terminal 12 proceeds to step S515.

  In step S515, the remote control terminal 12 determines whether or not the status notification information is included in the control request data from the client terminal 11. When the state notification information is not included, the remote control terminal 12 proceeds to step S516. In step S516, the remote control terminal 12 reads recipe data suitable for the client terminal 11 from the database. Then, the process proceeds to step S518. In step S515, when the state notification information is included, the remote control terminal 12 proceeds to step S517.

  In step S517, the remote control terminal 12 creates analysis of status notification information and creation of visible light control information based on the analysis program and database. In step S518, the remote control terminal 12 transmits the visible light control information created in step S516 or step S517 to the client terminal 11. The remote control terminal 12 preferably transmits information such as identification information ID, password, and GPS information together with the visible light control information.

  In step S615, the client terminal 11 repeatedly determines whether or not the visible light control information from the remote control terminal 12 has been received. In step S616, the client terminal 11 authenticates the remote control terminal 12 that is the transmission source of the visible light control information. For the authentication, for example, various authentication methods such as identification information ID, position information, GPS information, and public key cryptography can be used. After step S616, the process proceeds to step S617.

  In step S617, the client terminal 11 determines whether or not the authentication is successful. In step S617, if the authentication is not successful, the process proceeds to step S618, and if the authentication is successful, the process proceeds to step S619. In step S618, the client terminal 11 blocks communication with the remote control terminal 12 that has not been successfully authenticated. In step S619, the client terminal 11 controls and provides the luminance for each color or the luminance of the single color so that the time distribution has various 1 / f patterns according to the visible light control information received from the remote control terminal 12. Execute visible light illumination provision service. For example, the visible light control device (reference numerals 41A and 41B in FIG. 1) of the client user's house 81 is activated to decode the control data and irradiate visible light based on the designated recipe.

  By performing control according to this sequence example on both sides, it is possible to send the optimal recipe data for visible light irradiation taking into account the current state of the patient, and constant bi-directional transfer of these information By carrying out in a cycle, it becomes possible for the patient side to change the state of the recipe for visible light to be given interactively in real time.

  In addition to the signals from various environmental sensors, the device types included in the visible light control information transmitted from the above patient's home include an electroencephalogram measuring device, a pulse wave measuring device, optical topography, or fMRI. A device is assumed. On the hospital side, after appropriate analysis processing is performed based on these measurement data, a visible light recipe is searched and a visible light control signal is transmitted to the patient's home.

  FIG. 16 shows an extended example of the embodiment shown in FIG. In the embodiment of FIG. 9, the recipe data basically shows a configuration example regarding how to control visible light in the user's home or how to control it remotely. is there. At this time, a system that can handle sufficient patients by modulating the visible light of interest with a 1 / f fluctuation signal, independently of remotely controlled information, according to individual preferences. Therefore, it is necessary to provide a circuit that can be selected independently from the visible light control information from the hospital side.

  In addition, the system is configured so that a music signal can be superimposed on visible light, or a video signal that gives a comfortable and appropriate effect to the healing of a patient can be superimposed on visible light of another color. It is possible as well. In this case, as described above, the “electronic candle” that gives the optimum 1 / f fluctuation by utilizing the information acquired by the indoor or environment sensor is used by the visible light LED having a specific color. It is possible to realize this as well.

  Further, in general, when a visible light LED propagates a signal, it is necessary to extend a reach distance by performing appropriate modulation. As a modulation method, PPM (Pulse Position Modulation), OFDM (Orthogonal Frequency) Various schemes such as Division Modulation have been put into practical use, but it is necessary to appropriately select one that meets the characteristics of the transmitting LED and the receiving photodiode. FIG. 16 shows, as an example, a case where the irradiation distance can be extended from several meters to several tens of meters using PPM. When the analog signal is PPM-modulated, the receiving side performs PWM (Pulse Width Modulation) modulation and can easily realize decoding.

  In the present invention, when providing a remote medical treatment or a healing environment, the control of visible light illumination from a remote or local state is considered in consideration of the environmental state, psychological state, physiological state, etc. of the user. Effective use of various medical diagnostic devices, household simple medical instruments, etc., and various sensors, etc. for users with high reliability and safety It can be used for services for providing "comfort" and the like.

It is a block diagram of the remote control system for visible light illumination which concerns on Embodiment 1. FIG. It is a block diagram which shows an example of the client terminal and remote control terminal which concern on Embodiment 1. It is an example of the recipe which prescribes | regulates illumination light. It is a block diagram of the remote control system for visible light illumination which concerns on Embodiment 2. FIG. It is a block diagram which shows an example of the client terminal and remote control terminal which concern on Embodiment 2. It is a block diagram of another form of the visible light remote control system which concerns on Embodiment 2. FIG. It is an embodiment of the illuminating device in the visible light remote control system which concerns on Embodiment 1 and Embodiment 2. FIG. 4 is an example of a decoder that uses a microcomputer (such as a processor) in the lighting apparatus according to the first and second embodiments. It is a 1st Example of the visible light remote control system which concerns on Embodiment 1 and Embodiment 2. FIG. It is an example of the processing flow for determination of the threshold value for alpha wave appearance determination. It is an example of the flow for the appearance determination of alpha wave using a database. An example of the determination processing flow of the threshold value for rest state determination by an electrocardiogram or a pulse wave is shown. An example of the flow of rest state determination by an electrocardiogram or a pulse wave is shown. The structural example of the visible light control information for notifying the state from a client user terminal is shown. An example of a signal sequence when interactive control is performed between the client terminal 11 and the remote control terminal 12 is shown. It is 2nd Example of the visible light remote control system which concerns on Embodiment 1 and Embodiment 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Client terminal 12 Remote control terminal 13 Communication network 14 Sensor 15 Illuminating device 16 Client terminal position information acquisition means 17 Remote control terminal position information acquisition means 18 Sensor 22 Client terminal state notification information transmission means 23 Service execution means 25 Client terminal position information transmission Means 26 Client terminal authentication means 27 Client terminal database storage means 28 Client terminal service control means 31 Remote control terminal database storage means 32 Remote control terminal service control means 33 Visible light control information transmission means 35 Remote control terminal position information transmission means 36 Remote control Terminal authentication means 41 Visible light control device 42 Decoder 43 Switching device 44 Processing circuit 81 Client user's house 82 Control center of hospital etc.

Claims (4)

A remote control terminal controls the client terminal via a communication network and executes the illumination providing service on the client terminal based on a database including information related to a recipe that defines the illumination light used for the visible light illumination providing service. In the remote control system
The client terminal is
Client terminal state notification information transmitting means for transmitting a physiological state detected by a sensor for detecting a physiological state to the remote control terminal as state notification information;
Service execution means for executing a visible light illumination providing service that controls and provides the luminance for each color or the luminance of a single color so that the time distribution has a 1 / f pattern according to the visible light control information received from the remote control terminal And comprising
The remote control terminal is
Remote control terminal database storage means for storing the database;
When receiving the status notification information from the client terminal status notification information transmitting means, refer to the remote control terminal database storage means and execute the visible light illumination providing service according to the status notification information based on the recipe Remote control terminal service control means for generating visible light control information of
Visible light control information transmitting means for transmitting the visible light control information generated by the remote control terminal service control means to the client terminal;
A remote control system for visible light illumination. The client terminal is
Client terminal position information transmitting means for transmitting its geographical position information to the remote control terminal;
Client terminal authentication means for authenticating geographical location information transmitted by the remote control terminal, and
The remote control terminal is
Remote control terminal position information transmitting means for transmitting its geographical position information to the client terminal;
Remote control terminal authentication means for authenticating geographical location information transmitted by the client terminal, and
The remote control terminal service control means generates the visible light control information when authentication by the remote terminal authentication means is established,
The service execution unit executes the visible light illumination providing service according to the visible light control information transmitted from the visible light control information transmission unit when authentication by the client terminal authentication unit is established. The remote control system for visible light illumination according to claim 1. The client terminal is
Client terminal database storage means for storing a database including information related to a recipe that defines illumination light used for a visible light illumination providing service;
When the authentication by the client terminal authentication unit is established, the client terminal database storage unit is referred to, and based on the recipe, the visible light illumination providing service according to the physiological state detected by the sensor is executed. Client terminal service control means for generating visible light control information,
The service execution means executes the visible light illumination providing service according to visible light control information generated by the client terminal service control means when authentication by the client terminal authentication means is established. Item 3. The remote control system for visible light illumination according to Item 2. When the visible light control information transmitting means transmits visible light control information,
The client terminal location information transmitting means repeatedly transmits its geographical location information to the remote control terminal,
The remote control system for visible light illumination according to claim 2 or 3, wherein the remote control terminal position information transmitting means repeatedly transmits its geographical position information to the client terminal.

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