KR100956790B1 - Room lighting control system using an wire-less communication - Google Patents

Abstract

PURPOSE: An indoor lamp control system using wireless communications, capable of controlling the radiation of a lamp through the wireless communications is provided to control the indoor lamp using a lamp group and recognition code binding through wireless communications. CONSTITUTION: Each lamp has a wireless communications function and a lamp control function. A relay network performs wireless communication with a lighting device through an access point. The relay network performs wired communication with the lighting device through a switching hub. A management computer(MC) performs the transmission of the illumination control signal and updates setting data through the transit network. A user computer transmits the illumination control signal through the transit network with the corresponding lamp.

Description

Room lighting control system using an wire-less communication

The present invention relates to an indoor lighting control system, and more particularly, wireless communication for recognizing a unique identification code (ID) of a lamp and controlling light emission of a lamp using wireless communication based on the identification code. It relates to an indoor lighting control system used.

Lamps have been developed using incandescent bulbs, fluorescent lamps or various lamps such as LEDs. The lighting may be manufactured as a lighting device for personal use, and several lighting lights may be installed as a lighting device in a large place such as an office. An environment in which lighting lamps are arranged in a wide place such as an office and blinks in groups of a plurality of lighting lamps is called a multiple lighting environment.

Since the above-described conventional multi-lighting environment does not provide an individual switching function for each lamp, lighting of lights for unnecessary positions is generated, and since the lamps do not have the function of individually controlling the illumination, they are unnecessary according to the position. There is a case of maintaining a bright illuminance.

Of course, the wall switch for flashing the lights in groups for the control of the lights in a multi-light environment, and the function of turning off the lights in unnecessary positions are added. However, it is cumbersome for a user of an office to operate a wall switch in an individual lighting position, so that the lighting is not turned on and off efficiently.

As in the conventional case described above, unnecessary or excessive lighting is generated in a multiple lighting environment, and accordingly, there is a problem in that economic losses such as enormous energy loss and shortening of lifespan of a lamp and a lamp are generated.

The present invention provides an indoor lighting control system using a wireless communication capable of controlling lighting individually or in groups in a multiple lighting environment in configuring an indoor lighting control system.

The present invention provides a monitoring and interface environment for controlling individual or group lighting by binding unique recognition codes of lighting lamps in a multiple lighting environment, and remotely controlling individual or group lighting.

An indoor lighting control system using wireless communication according to the present invention includes at least one lighting group including a plurality of lighting lamps, and each of the lighting lamps wirelessly transmits at least its own identification code. A lighting device having a lamp control function of controlling a light emission state of a lamp in response to a transmitted lighting control signal and pre-stored setting data; A relay network including an access point and a switching hub linked to each other, wherein the relay network makes wireless communication with the lighting device and performs wired communication through the switching hub; A master control program connected to the switching hub and providing a master interface for performing individual and group control functions for the lamps, the master control program being coupled to the identification code for the lamps; The additional data has the authority to store and change the additional data to be the setting data, wherein the additional data includes group data determined according to a position, position data corresponding to its own position, and sensor data about a setting state of the sensors owned by the position data. And at least one of scene data corresponding to illuminance to be emitted at turn-on and schedule data for a turn-on / off schedule, wherein the master control program transmits the lighting control signal generated by an operation of the master interface of a manager. And updating the setting data. A management computer executing through a relay network; And are connected to the management computer through the switching hub, and are connected to each of the lamps through the access point, and share a database of the management computer to perform individual and group control functions for the lamps. And a user control program providing a user interface, wherein the user control program comprises: a user computer for transmitting a lighting control signal generated by a user's manipulation of the user interface to a corresponding lamp through the relay network. It is characterized by.

Here, the lamp is a lamp; Perform wireless communication with the relay network, store its own identification code and the setting data, and determine a light emission state of the lamp using the illumination control signal and the driving signal generated according to the setting data transmitted by the wireless communication. Outputting for control, and transmitting data on the light emission state of the lamp corresponding to the driving signal to the management computer through the relay network, wherein the identification code is synchronized with the operation of the built-in ID feed switch. A wireless converter transmitted to the management computer via a network; And a driving circuit driving the lamp by any one of a current driving method and a voltage driving method, wherein the driving is controlled by the driving signal of the wireless converter.

The wireless converter may include: a wireless transceiver for performing wireless communication with the relay network; A memory unit for storing the setting data; An ID sending switch providing an on / off signal; The micro control outputs the identification code stored in the internal memory through the wireless transceiver by the turn-on of the ID transmission switch, and outputs a driving signal according to the setting data of the memory unit and an illumination control signal transmitted through the wireless transceiver. Unit; And an interface unit for transmitting a signal between the micro control unit and the driving circuit.

In addition, the above-mentioned lighting lamp is provided with at least one or more of the illuminance sensor for detecting the brightness of the ambient, the temperature sensor for detecting the ambient temperature and the human body sensor for detecting the proximity of the human body, the enable of the sensor Controlled by the setting data of the wireless converter, it is preferable that the sensing signal of the sensor is transmitted to the wireless converter through the driving circuit and then to the management computer via the relay network.

The ID sending switch may be configured as any one of a contact switch and a reed switch.

In addition, wireless communication between the lighting device and the access point may be performed by a Zigbee communication method.

The control unit may further include a control unit connected to the management computer through the access point and the switching hub and connected to the lamps arranged in the respective lamp groups through the access point. Here, the control unit is preferably provided with the user control program for providing the user interface for performing the individual and group control function for the lights by sharing the database of the management computer.

On the other hand, the indoor lighting control system using a wireless communication according to the present invention includes at least one lamp group including a plurality of lamps, each of the lamps and the wireless communication function for transmitting at least its own identification code wirelessly; A lighting device having a lamp control function of controlling a light emission state of a lamp in response to a lighting control signal transmitted wirelessly and pre-stored setting data; And a master control program connected to the lighting device in wireless communication and providing a master interface for performing individual and group control functions for the lamps, wherein the master control program recognizes the recognition of the lamps. Has the authority to store and change the code and additional data coupled thereto as the setting data, wherein the additional data includes group data determined according to a position, position data corresponding to its own position, and a setting state of sensors belonging to it. At least one or more of sensor data, scene data corresponding to illuminance to be emitted upon turn-on, and schedule data for turn-on / off schedules, wherein the master control program comprises: the illumination generated by an operation of the master interface of a manager Transmission of control signals and the setting data And it characterized in that it comprises a; the control unit to perform the update.

On the other hand, the indoor lighting control system using a wireless communication according to the present invention, at least one lamp group including a plurality of lamps, each of the lamps wireless communication function for transmitting at least its own identification code wirelessly A lighting device having a lamp control function in which a light emission state of the lamp is controlled in response to a lighting control signal transmitted wirelessly and pre-stored setting data; And a master control program connected to the lighting device remotely in two-way communication, the master control program providing a master interface for performing individual and group control functions for the lamps. Have the authority to store and change the identification code and additional data coupled thereto as the setting data, wherein the additional data includes group data determined according to a location, location data corresponding to its own location, and sensors belonging to its own location. And at least one of sensor data for a set state, scene data corresponding to illuminance to be emitted at turn-on, and schedule data for a turn-on / off schedule, wherein the master control program is generated by an operation of the master interface of an administrator. Transmission of the illumination control signal and the description And it characterized in that it comprises a; a remote controller to perform the updates of the data.

According to the indoor lighting control system using the wireless communication according to the present invention, by the unique recognition code binding of the individual lights, the control of each lamp or each group is possible through the wireless communication, the power by unnecessary or excessive lighting in a multiple lighting environment Losses can be prevented and there is an effect of improving the life of lamps and lamps by preventing the use of unnecessary or excessive lamps.

In addition, remote monitoring through wireless communication and control of individual or group lights, etc. are made through the interface, there is an effect that can easily manage multiple lighting environment.

Indoor lighting control system using a wireless communication according to the present invention can be implemented based on a relay network that combines wired communication and wireless communication, consisting of a set-top box can be implemented using a controller for controlling lighting by wireless communication. This can be done remotely using a remote controller.

First, a configuration of an embodiment performed based on a relay network combining wired communication and wireless communication will be described with reference to FIG. 1.

Referring to FIG. 1, lighting groups A and BC D are disposed as a lighting device for multiple lighting, and each lighting group A, B, C and D includes a plurality of lighting units L1, L2, L3, and the like. L4). Each lamp group (A, B, C, D) is disposed corresponding to the area divided into a large area such as an office, each lamp (L1) included in each lamp group (A, B, C, D) , L2, L3, and L4 are also arranged at preset positions in the corresponding area.

The plurality of lamps L1, L2, L3, and L4 included in each of the lamp groups A, B, C, and D may use the commercial AC power supply 110V from the corresponding power switches SA, SB, SC, and SD. To 220V), and flickering is controlled by turning on / off the corresponding power switches SA, SB, SC, and SD. Typically, the power switch (SA, SB, SC, SD) may be composed of a contact type switch, may be installed in the aisle or the wall of the entrance, but may be distributed in consideration of the convenience of use according to the designer's intention. have.

Here, each of the lamps (L1, L2, L3, L4) has a wireless communication function and a light control function according to the configuration of Figure 2 to be described later, each of the lamp groups (A, B, C, D) are the same or mutually Other numbers of lights may be included as lighting devices.

On the other hand, the relay network (N) is configured to support communication for lighting control, the relay network (N) includes an access point (AP) and a switching hub (SH) linked to each other, the access point (AP) Wireless communication with each lamp (L1, L2, L3, L4) included in each lamp group (A, B, C, D), the switching hub (SH) is a wired management computer (described below) The wired communication between the MC, the user computer (UC) and the access point (AP) is relayed. Here, the switching hub (SH) may be configured to implement a local area network (LAN) based on the Internet protocol, but may be configured to perform serial wired communication based on RS-232 or RS-485 communication protocol as necessary. Can be.

The management computer MC connected to the switching hub SH is an individual and a group-by-group for the lamps L1, L2, L3, L4 arranged in the lamp groups A, B, C, and D. It is provided with a master control program which provides a master interface for performing control functions. The user computer UC is connected to the switching hub SH like the management computer MC. Here, the user computer UC is connected to the management computer MC through the switching hub SH, and the respective lighting groups A, B, C through the switching hub SH and the access point AP. Connected to the lights (L1, L2, L3, L4) arranged in, D), by sharing the database of the management computer (MC) by individual and group for the lights (L1, L2, L3, L4) And a user control program providing a user interface for performing a control function.

In addition, the control unit CU may be further provided as shown in FIG. 4, and the control unit CU may include a user control program such as a user computer UC, an access point AP and a switching hub SH. Is connected to the management computer (MC), and to the lamps (L1, L2, L3, L4) arranged in the respective lamp groups (A, B, C, D) through the access point (AP). do. A plurality of control units (CU) can be operated according to the user's convenience.

In the above-described configuration of FIG. 1, a configuration of a lighting lamp will be described in detail with reference to FIG. 2.

The lamp includes a lamp 10, a driving circuit 12, and a wireless converter 14, and at least one illumination sensor 16, a temperature sensor 17, and a human body sensor 18 may be configured as necessary.

The lamp 10 is driven by one of current driving and voltage driving, and emits light by a pulse or direct current power provided from the driving circuit 12, and controls illuminance by a current supplied from the driving circuit 12. Can be.

The drive circuit 12 may include conventional ballasts, rectifier circuits, smoothing circuits, and power factor correction circuits, and may include pulse width modulation (PWM) circuits when controlling the lamp 10 with pulses, which are conventional. Since it corresponds to the range to be implemented as an example and detailed description of the detailed description will be omitted.

In addition, the driving circuit 12 controls the current supplied to the lamp 10 by the driving signal provided from the wireless converter 14, and the illuminance sensor 16, the temperature sensor 17 and the human body sensor 18 When configured, the control of illuminance and blinking may be performed by these sensing signals, and the control of the driving circuit 12 by the sensing signal falls within a range that is normally implemented, and thus, the description of the detailed description and the operation description will be omitted. do. On the other hand, the driving circuit 12 serves to transmit the sensing signals of the illuminance sensor 16, the temperature sensor 17 and the human body sensor 18 to the wireless converter 14, the illuminance sensor 16 is the ambient brightness The sensor is a sensor for sensing, the temperature sensor 17 is a sensor for sensing the lamp or the ambient temperature, the human body sensor 18 is a sensor composed of a kind of proximity sensor for detecting the presence or absence of the human body.

Each enable of the illumination sensor 16, the temperature sensor 17, and the human body sensor 18 may be controlled by setting data of the wireless converter 14.

Meanwhile, the wireless converter 14 may be configured as shown in FIG. 3, and the wireless converter 14 wirelessly transmits and binds its own identification code corresponding to an illumination lamp and wirelessly from the relay network N. It has a lamp control function for outputting a drive control signal for controlling the light emitting state of the lamp 10 in response to the transmitted light control signal and the pre-stored setting data. In addition, the wireless converter 14 transmits data on the light-emitting state of the lamp 10 corresponding to the drive signal to the management computer MC through the relay network N, and the identification code is a built-in ID transmission switch ( In synchronization with the operation of 28), it is transmitted to the management computer MC through the relay network N. FIG.

The above-described binding means that the unique recognition code of the lamp, that is, the unique recognition code set in the wireless converter 14, is registered so that the flashing control can be performed. Here, the identification code may correspond to a product number or an arbitrarily recorded serial number of the wireless converter 14.

The wireless converter 14 includes a micro control unit 20, an interface unit 22, a memory unit 24, a wireless transmission / reception unit 26, and an ID transmission switch 28.

Here, the wireless transceiver 26 may perform wireless communication with the access point AP of the relay network N in a ZigBee manner, and the sensor signal and the driving signal output from the micro control unit 20. It transmits the data corresponding to the by the wireless communication, and transmits the drive control signal and the updated setting data transmitted from the access point (AP) of the relay network (N) to the micro control unit (20).

The memory unit 24 stores the setting data, updates and stores the updated setting data transmitted from the micro control unit 20 to the previously stored setting data, and provides the stored data to the micro control unit 20. do.

In addition, the ID transmission switch 28 may provide an ON / OFF signal for ID transmission, and may be configured as a contact switch or a lead that is turned on or off magnetically in close proximity.

The micro control unit 20 may have a nonvolatile internal memory (not shown) such as a flash memory, and may store a unique identification code therein, and the identification code stored in synchronization with the turn-on of the ID transmission switch 28. Is transmitted through the wireless transceiver 26. The micro control unit 20 outputs the driving signal according to the setting data and the lighting control signal transmitted through the wireless transceiver 26, and generates and outputs the driving signal by first applying the weight to the lighting control signal. . In addition, the micro control unit 20 outputs the sensor signal transmitted from the interface unit 22 through the wireless transceiver 26.

The interface unit 22 transfers signals such as driving signals and sensor signals between the micro control unit 20 and the driving circuit 12.

As described above, an embodiment according to the present invention is configured, and thus the control operation will be described.

The master control program is set up and provided in the management computer MC for the lighting control operation, and the user control program is set up and provided in the user computer UC.

The master control program is to provide a master interface for performing individual and group control functions for the lamps L1, L2, L3, L4. The master control program has the authority to store and change the identification code for the lamps L1, L2, L3, and L4 and additional data coupled thereto as setting data, and the additional data includes group data determined by the position and the lamp itself. At least one or more of the position data corresponding to the position of the sensor, the sensor data of the setting state of the sensors such as lighting, the scene data corresponding to the illuminance to be emitted at turn-on, and the schedule data for the turn-on / off schedule In addition, the master control program transmits the illumination control signal generated by the operation of the master interface of the manager and updates the setting data via the relay network (N).

In addition, the user control program is connected to each of the lamps L1, L2, L3, and L4 through the access point AP, and shares the database of the management computer MC so that the lamps L1, L2, L3, It provides a user interface for performing individual and group control functions for L4). The user control program transmits the lighting control signal generated by the manipulation of the user's interface to the corresponding lamp through the relay network N.

First, the master control program may provide a main interface as shown in FIG. 5. Referring to FIG. 5, the main interface window 100 may be “monitored”, “placed”, “master control”, or “schedule” by a button function. , "Sensor control", "setting" and "login" as the lower interface. "Monitoring" provides an interface (Fig. 6) for monitoring the status of each lamp, "Batching" provides an interface (Fig. 7) for monitoring the status of the placement of each lamp, and "Master Control" , An interface for group or individual lighting and scene control (FIG. 8), " schedule " provides an interface (FIG. 9) for monitoring an illumination schedule of each lamp, and " sensor control " Provides an interface for control for enabling / disabling (FIG. 10), " setting " provides an interface for modifying and storing an initial or preset state of each lamp (FIG. 11). "Login" provides an interface for logging in with the information given by the master or user who is an administrator. Here, the master and the user are preferably set differently from each other, more preferably, the master may have a right to change setting data, and the user may have some rights of on and off and lighting control.

The interface for monitoring the state of each lamp of FIG. 6 includes a window 110 having a configuration in which a unique code (ID), a user, a randomly assigned code, a light state, a set group, and a communication state are displayed by list for each light. Can be.

In addition, an interface for monitoring the arrangement of each lamp of FIG. 7 may be provided with a window 122 that displays a state where the lamps are arranged on a map of an area in which a multiple lighting environment is provided, and through this window 122. The lamp may be selected, and additional information such as a unique code (ID) of the selected lamp, a user, an arbitrarily assigned code, and a group may be displayed through a separate window 120, and the location information of the selected information may be displayed. A function that can be changed through item-specific activation of 120 may be provided.

In addition, the interface of FIG. 8 may provide an interface for total, group or individual lighting and scene control, and a window 130 for controlling all, group or individual lighting, and a button 134 for on / off may be provided. In addition, a window 132 for controlling scene control by level and a button 136 for activating scene control may be provided, and a window 138 for selecting a whole, a group, or an individual may be provided. A popup window 139 may be provided for group and individual selection.

In addition, the interface of FIG. 9 may provide a window 140 having a function of monitoring an illumination schedule of each lamp and adjusting a schedule, and a window 142 providing a function of collective on-off function and seasonal brightness adjustment. Can be.

In addition, the interface of FIG. 10 may provide a window 144 for enabling / disabling a sensor of each lamp and controlling the disable of each sensor.

In addition, the interface of FIG. 11 may provide a window 150 and buttons 152 having an interface for modifying and storing an initial setting state or a preset state, and a function for modifying and storing individual settings. have.

The above-described interface of FIGS. 5 to 11 may be provided by the master control program of the management computer MC, and the interface that may be provided by the user control program of the user computer UC is FIGS. 5 to 11. Some or all of the setting functions may be masked and deactivated according to a difference in authority between a master who is an administrator and a user, so that the user of the user computer may The control program allows you to use limited functions such as turn on / off or illumination control of individual or group lights.

According to the above-described configuration, an office in which lighting devices are installed for multiple lighting may be set as a group in which lighting lights are divided into areas, such as a conference room, an office space, a corridor, and the like, and a map matching the office is provided to provide a meeting room on a map. Lamps, office space lights, hallway lights can be mapped, and the identification code of each light is sent out by the operation of the ID discharging switch 28 by binding at the time of installation of the initial light so that the data of the management computer MC can be mapped. It can be registered in the base, and additionally, additional setting data connected to the recognition code by the administrator can be joined and stored.

And, the setting data set in the management computer (MC) is transmitted to the lamp through wireless communication, the lamp can be stored by the new function at turn-on to maintain a constant illuminance or seasonal brightness by storing the transmitted setting data.

As described above, the office in which the lighting device for the multiple lighting is installed can use only the conference room lighting by using the interface provided by the master control program of the management computer MC or the interface provided by the user control program of the user computer UC. Lighting control by group that turns off or lowers the illumination of the corridor is wirelessly managed, and even in office spaces, lighting of unattended seats can be turned off individually to save power.

Embodiment according to the present invention is configured as a set-top box as shown in Figure 12 can be carried out using a controller for controlling the lighting by wireless communication, in this case wireless communication is made between the lamp and the controller.

Here, the lighting device is the same as the embodiment of Figs. 1 to 11, and only the wireless communication target is changed to the control unit (CU), and the same reference numerals are used and duplicated descriptions are omitted.

In addition, the control unit CU of FIG. 12 is connected to the lighting apparatus by wireless communication and includes a master control program that provides a master interface for performing individual and group control functions for the lightings. The same or similar interface as the master control program of the management computer MC of FIG. 1 can be provided.

As shown in FIG. 13, the control unit CU of FIG. 12 includes a microcontrol unit (MCU) 160, a wireless transmitter / receiver 162, a memory 164, a keypad 166, and a monitor 168. 164 stores a master control program and setting data, keypad 166 provides keys for interface operation, monitor 168 displays an interface, and wireless transceiver 162 communicates with a lighting device in ZigBee wireless. The MCU 160 performs control by a master control program stored in the memory 164.

On the other hand, the embodiment according to the present invention can be implemented using a remote controller as shown in Figure 14, in this case wireless communication is made between the lamp and the remote controller.

Here, the lighting apparatus is the same as the embodiment of FIGS. 1 to 11 and only the wireless communication target is changed to the remote controller (RU), and thus the same reference numerals are used, and duplicate descriptions are omitted.

In addition, the control unit (CU) of FIG. 14 may be connected to the lighting device in a Zigbee, Bluetooth, or infrared communication manner, and provides a master control program for providing a master interface for performing individual and group control functions for the lights. The master control program may provide an interface identical or similar to that of the master control program of the management computer MC of FIG. 1.

Therefore, according to the present invention, since it is possible to perform indoor lighting through wireless communication in a space such as an office in which multiple lights are made, and lighting is managed by binding a unique recognition code, lighting can be controlled individually, group, or as a whole, and thus unnecessary. In addition, there is an effect that can prevent the power loss due to excessive lighting, and thus can be expected to improve the life of the lamp and the lamp.

In addition, you can wirelessly monitor and control the status of entire, group, or individual lights remotely, making it easy to manage multiple lights.

1 is a block diagram showing a preferred embodiment of a room lighting control system using wireless communication according to the present invention,

2 is a block diagram showing the configuration of the lamp of FIG.

3 is a block diagram showing the configuration of the wireless converter of FIG.

4 is a block diagram showing another embodiment of an indoor lighting control system using wireless communication according to the present invention;

5 is a diagram illustrating a main interface provided by a master control program;

6 is a diagram illustrating an interface for "monitoring",

7 is a diagram illustrating an interface for "deployment",

8 is a diagram illustrating an interface for "master control",

9 is a diagram illustrating an interface for a "schedule",

10 is a diagram illustrating an interface for "sensor control",

11 is a diagram illustrating an interface for "setting",

12 is a block diagram showing another embodiment of an indoor lighting control system using wireless communication according to the present invention;

13 is a block diagram of the controller of FIG. 12,

14 is a block diagram showing another embodiment of a room lighting control system using wireless communication according to the present invention.

Claims (14)

And at least one lamp group including a plurality of lamps, each of the lamps corresponding to at least a wireless communication function for wirelessly transmitting its own identification code and a lamp corresponding to a pre-stored setting data and an illumination control signal transmitted wirelessly. An illumination device having a lamp control function in which a light emission state of the light is controlled; A relay network including an access point and a switching hub linked to each other, wherein the relay network makes wireless communication with the lighting device and performs wired communication through the switching hub; A master control program connected to the switching hub and providing a master interface for performing individual and group control functions for the lamps, the master control program being coupled to the identification code for the lamps; The additional data has the authority to store and change the additional data to be the setting data, wherein the additional data includes group data determined according to a position, position data corresponding to its own position, and sensor data about a setting state of the sensors owned by the position data. And at least one of scene data corresponding to illuminance to be emitted at turn-on and schedule data for a turn-on / off schedule, wherein the master control program transmits the lighting control signal generated by an operation of the master interface of a manager. And updating the setting data. A management computer executing through a relay network; And Connected to the management computer through the switching hub, connected to each of the lamps through the access point, and sharing a database of the management computer to perform individual and group control functions for the lamps. And a user control program providing a user interface, wherein the user control program includes a user computer for transmitting a lighting control signal generated by a user's manipulation of the user interface to a corresponding lamp through the relay network. Indoor lighting control system using a wireless communication. The method of claim 1, wherein the lamp, lamp; Perform wireless communication with the relay network, store its own identification code and the setting data, and determine a light emission state of the lamp using the illumination control signal and the driving signal generated according to the setting data transmitted by the wireless communication. Outputting for control, and transmitting data on the light emission state of the lamp corresponding to the driving signal to the management computer through the relay network, wherein the identification code is synchronized with the operation of the built-in ID feed switch. A wireless converter transmitted to the management computer via a network; And And a driving circuit for driving the lamp by any one of current driving and voltage driving, the driving being controlled by the driving signal of the wireless converter. The method of claim 2, wherein the wireless converter, A wireless transceiver for performing wireless communication with the relay network; A memory unit for storing the setting data; An ID sending switch providing an on / off signal; The micro control outputs the identification code stored in the internal memory through the wireless transceiver by the turn-on of the ID transmission switch, and outputs a driving signal according to the setting data of the memory unit and the illumination control signal transmitted through the wireless transceiver. Unit; And And an interface unit configured to transmit a signal between the micro control unit and the driving circuit. The method according to claim 2 or 3, The lamp includes at least one or more of an illuminance sensor for detecting the brightness of the surroundings, a temperature sensor for sensing the ambient temperature, and a human body sensor for detecting the proximity of the human body as a sensor. Controlled by data, and the sensing signal of the sensor is transmitted to the wireless converter through the driving circuit and then transmitted to the management computer via the relay network. The method of claim 3, wherein The ID transmission switch is a room lighting control system using a wireless communication consisting of any one of a contact switch and a reed switch. The method of claim 1, Wireless communication between the lighting device and the access point is indoor lighting control system using a wireless communication performed by a Zigbee communication method. The method of claim 1, And a control unit connected to the management computer through the access point and the switching hub and connected to the lamps arranged in the respective groups of lamps via the access point, wherein the control unit is configured to manage the management unit. And a user control program for providing a user interface for performing individual and group control functions for the lamps by sharing a computer database. And at least one lamp group including a plurality of lamps, each of the lamps corresponding to at least a wireless communication function for wirelessly transmitting its own identification code and a lamp corresponding to a pre-stored setting data and an illumination control signal transmitted wirelessly. An illumination device having a lamp control function in which a light emission state of the light is controlled; And A master control program connected to the lighting device in wireless communication and providing a master interface for performing individual and group control functions for the lamps, wherein the master control program includes the identification code for the lamps. And the authority to store and change additional data coupled thereto as the setting data, wherein the additional data is stored in the group data determined according to the position, the position data corresponding to the position of the user, and the setting state of the sensors. At least one of sensor data, scene data corresponding to illuminance to be emitted at turn-on, and schedule data for a turn-on / off schedule, wherein the master control program is configured to control the lighting generated by an operation of the master interface of a manager. Signal transmission and up of the setting data Interior lighting control system using a wireless communication terminal is characterized by having a; the control unit to perform a byte. The method of claim 8, wherein the lamp, lamp; Perform wireless communication with the control unit, store its own identification code and the setting data, and determine the light emission state of the lamp by using the illumination control signal transmitted by the wireless communication and the driving signal generated according to the setting data. A wireless converter which is output for control and transmits data on the light-emitting state of the lamp corresponding to the drive signal to the control unit, wherein the recognition code is transmitted to the control unit in synchronization with an operation of a built-in ID feed switch. ; And And a driving circuit for driving the lamp by any one of current driving and voltage driving, the driving being controlled by the driving signal of the wireless converter. The method of claim 9, wherein the wireless converter, A wireless transceiver for performing wireless communication with the control unit; A memory unit for storing the setting data; An ID sending switch providing an on / off signal; The micro control outputs the identification code stored in the internal memory through the wireless transceiver by the turn-on of the ID transmission switch, and outputs a driving signal according to the setting data of the memory unit and an illumination control signal transmitted through the wireless transceiver. Unit; And And an interface unit configured to transmit a signal between the micro control unit and the driving circuit. The method according to claim 9 or 10, The lamp includes at least one or more of an illuminance sensor for detecting the brightness of the surroundings, a temperature sensor for sensing the ambient temperature, and a human body sensor for detecting the proximity of the human body as a sensor. Controlled by data, the sensing signal of the sensor is transmitted to the wireless converter through the driving circuit and then to the control unit indoor lighting control system using wireless communication. The method of claim 10, The ID transmission switch is a room lighting control system using a wireless communication consisting of any one of a contact switch and a reed switch. The method of claim 8, Wireless communication between the lighting device and the control unit is indoor lighting control system using a wireless communication performed by a Zigbee communication method. And at least one lamp group including a plurality of lamps, each of the lamps corresponding to at least a wireless communication function for wirelessly transmitting its own identification code and a lamp corresponding to a pre-stored setting data and an illumination control signal transmitted wirelessly. An illumination device having a lamp control function in which a light emission state of the light is controlled; And A master control program connected to the lighting device remotely in two-way communication and providing a master interface for performing individual and group control functions for the lamps, wherein the master control program is configured to provide the Has the authority to store and change the identification code and the additional data coupled thereto as the setting data, wherein the additional data is set for group data determined according to a position, position data corresponding to its own position, and sensors having its own And at least one or more of sensor data for a state, scene data corresponding to illuminance to be emitted at turn-on, and schedule data for a turn-on / off schedule, wherein the master control program is generated by an operation of the master interface of an administrator. Transmission and setting of lighting control signals Interior lighting control system using a wireless communication terminal is characterized by having a; the remote controller to perform the updates of the data.

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