KR101348580B1 - Control method and system for one's eyes leading lamp by remote control - Google Patents

Abstract

Disclosed are a method and a system for controlling an optical guidance lamp by performing remote control. The method for controlling a master optical guidance lamp and one or more slave optical guidance lamps remotely controlled by a control server includes a step of registering ID and RF channel information in the control server; a step of installing the master optical guidance lamp and the slave optical guidance lamps on the site; a step of transmitting control information on an LED module with the control server; a step in which the master optical guidance lamp broadcasts the control information with the slave optical guidance lamp; and a step in which the master optical guidance lamp and the slave optical guidance lamps are turned off according to the transmitted control information. Therefore, a sight and safety of a driver and a pedestrian are obtained, and a load, generated when the optical guidance lamps are controlled by integrally controlling and managing the optical guidance lamp, is minimized through remote control. The safety of an administrator is obtained, and personal costs are reduced as the optical guidance lamp wirelessly transmits state information to the control server when the optical guidance lamp is malfunctioned. Additional works for connecting a cable are omitted, and initial costs for installing the optical guidance lamp are reduced when the optical guidance lamp is changed. [Reference numerals] (100) Control server; (200) Master optical guidance lamp; (300) Slave optical guidance lamp; (AA,BB,CC) End; (S205) Master optical guidance lamp and the slave optical guidance lamp ID and channel information registration; (S210) Installating at a sight; (S215) 3G network information setting; (S220) ID and RF radio channel setting; (S225) Transmission of the optical guidance lamp ID and channel information registration information; (S230) Requesting of the installation stae information of the slave optical guidance lamp; (S235) Installing at the sight; (S240) ID and RF radio channel regitration; (S245) Transmission of the booting information of the slave optical guidance lamp; (S250) Transmission of the slave optical guidance lamp booting information reception positive response transmission; (S255) Store the installation state information of the slave optical guidance lamp; (S260) Request the installation state information of the optical guidance lamp; (S265) Transmission request of the installation state information of the optical guidance lamp; (S270) Transmission of LED module control information; (S275) LED module control information broadcast; (S280) Flicker according to the LED module control information

Description

Control method and system for one's eyes leading lamp by remote control}

The present invention relates to a gaze induction light control method and system using a remote control, and more particularly, a gaze induction light control method and system using a remote control that can secure the safety and visibility of the driver or guardian by wireless remote control of the gaze induction light. It is about.

Eye-guided lights are safety facilities to ensure the safety of drivers or pedestrians.

Such eye-guided lights are provided in plural at a constant price in a road or sidewalk so that a driver or a pedestrian can easily recognize a center line or a segmented lane of a road when driving or walking at night, in bad weather or in a habitual fog area.

In general, a gaze induction light reflects light or emits light to recognize a driver or a pedestrian. In the case of an induction light that reflects light, it reflects a headlight of a vehicle to recognize information to a driver. Or, in the fog region, the transmittance of the headlights of the vehicle is lower than that of sunlight, making it difficult to recognize the information.

On the other hand, the gaze induction light that emits light is provided with a light including an LED module so that a driver or a pedestrian can identify the light, and is connected by a cable, where the gaze induction light malfunctions or the battery is discharged. If a problem occurs with respect to the operation of the administrator, it is cumbersome that the administrator must individually check or manage the induction of the problem.

In addition, when the manager checks or manages the induction of the eyes, there is a problem that it is difficult to secure the personal safety of the worker in that the eyes are mainly installed on the road, labor costs are incurred, and when the eyes of the eyes are instructed to flash, Multiple eye-guided lights do not receive blinking signals at the same time and cannot be controlled at once.

In addition, since the cable for connecting the eye-guided lights must be buried and connected with a plurality of eye-guided lights, the initial installation cost is excessively generated, and when a single eye-guided light needs to be replaced, the cable is disconnected and connected. Another problem is that additional work is required.

The present invention has been made to solve the above problems, the object of the present invention is to ensure the visibility and safety of the driver and pedestrian using the LED module, and to control and manage the gaze induction through a remote control, In case of malfunction of eyesight induction, eyesight induction transmits the status information wirelessly to the control server to secure manager's safety and reduce labor cost, and minimize the load that is generated when controlling many eyes induction by remote control. The present invention provides a method and system for controlling the eye induction using remote control.

In accordance with an embodiment of the present invention, a master gaze induction lamp and at least one slave gaze induction lamp are controlled remotely by a control server, and the master gaze induction lamp and the at least one slave gaze induction lamp may be used. Registering the ID and the RF channel information with the control server; Installing the master eye-guided light and the at least one slave eye-guided light in the field; Inputting the ID and the RF channel information to the master eye induction lamp and the at least one slave eye induction lamp; Transmitting, by the control server, control information for the LED module provided in the master eye guidance light and the at least one slave eye guidance light to the master eye guidance light through a 3G communication module; The master gaze induction light broadcasting the control information to the at least one slave gaze induction light through an RF communication module; And flashing, according to the received control information, the master gaze induction lamp and the at least one slave gaze induction lamp.

And, the installation step, the step of installing the master gaze induction; Setting network information with the control server in the master eye induction; Setting the ID and the RF channel information to the master eye induction; Transmitting, by the control server, the ID and RF channel information to the master eye induction via the 3G communication module; Requesting, by the master eye guidance light, installation state information of the at least one slave eye guidance light through the RF communication module; Installing the at least one slave eye guidance light after the master eye guidance light is installed; Registering the ID and the RF channel information with the at least one slave gaze induction; Transmitting, by the at least one slave eye guidance light, boot information to the master eye guidance light through the RF communication module; And transmitting, by the master eye guidance light, the acknowledgment according to the reception of the boot information to the at least one slave eye guidance light through the RF communication module.

In addition, the installation step, the step of installing the at least one slave gaze induction; Registering the IC and RF channel information with the at least one slave gaze induction; Transmitting boot information of the at least one slave gaze induction via the RF communication module; Installing the master eye guidance light after the at least one slave eye guidance light is installed; Setting network information with the control server in the master eye induction; And transmitting, by the control server, the ID and RF channel information through the 3G communication module to the master gaze induction.

In addition, the master gaze induction light and the at least one slave gaze induction light, so that the LED module provided in the master gaze induction light and the at least one slave gaze induction light flashes simultaneously according to the control information transmitted from the control server. Time synchronization may further include.

The time synchronization may include: transmitting, by the control server, a reference time of the control server to the master eye induction; Receiving, by the master eye induction, the reference time; In the master gaze induction, the control server checks the first transmission time for transmitting the reference time and the first reception time for receiving the reference time, and through the difference between the first transmission time and the first reception time. Calculating a first time deviation required for transmitting information between the control server and the master eye induction; Correcting the time of the control information received from the control server, based on the first time deviation, by the master gaze induction; Receiving, by the at least one slave eye guidance light, the reference time from the master eye guidance light; A second transmission time in which the master eye guidance light transmits the reference time to the at least one slave eye guidance light, and a second reception in which the at least one slave eye guidance light receives the reference time in the at least one slave eye guidance light. Checking a time and calculating a second time deviation for transmitting information between the master eye induction lamp and the at least one slave eye induction lamp based on a difference between the second transmission time and the second reception time; Correcting, by the at least one slave gaze induction lamp, the time of the control information received from the master gaze induction lamp based on the second time deviation; The master gaze induction lamp and the at least one slave gaze induction lamp to cause the LED module to blink in accordance with the time of the corrected control information; The time of the control information, the control server is a master gaze induction lamp It may be a time when the LED module included in the transmitted control information is blinking.

And, the control server, the first request step of requesting the status information of the master eye guidance light and the at least one slave eye guidance light to the master eye guidance light. A second requesting step, wherein the master eye-guided light transmits the first request to the at least one slave eye-guided light; Transmitting, by the at least one slave eye guidance light, the response to the status information to the master eye guidance light; And transmitting, by the master gaze induction, state information about the first request and the second request to the control server.

The state information may include information on whether the RF communication module such as the master eye induction lamp and the at least one slave eye induction lamp is malfunctioning, brightness and malfunction of the LED module, the master eye induction lamp, and the at least one slave eye induction lamp. It may be information on whether the power supply unit including the prepared solar cell module and a battery malfunctions, information on the state of charge and charge amount of the power supply unit, and information regarding entering or exiting a power saving mode due to a low voltage of the power supply unit.

On the other hand, in the eye guidance light control system in which the master eye guidance light and at least one slave eye guidance light are remotely controlled by the control server, the ID and RF channel information of the master eye guidance light and the at least one slave eye guidance light are registered, and the master A control server including a 3G communication module for transmitting and receiving information with a gaze induction lamp, and transmitting control information for the LED module provided in the master gaze induction lamp and the at least one slave gaze induction lamp; Installed in the field, the ID and RF channel information registered in the control server is input, and includes the 3G communication module and RF communication module for transmitting and receiving information with the control server and the at least one slave gaze induction, An LED module for induction, and receiving the control information from the control server, broadcasting the at least one slave gaze induction lamp, and flashing the master gaze induction lamp according to the control information; And an RF communication module installed at a site, registered with the control server, inputting ID and RF channel information, and transmitting and receiving information with the master eye induction lamp. An LED module for eye induction is provided. And at least one slave eye induction lamp that is broadcast from the eye induction lamp and flashes according to the control information.

As a result, the visibility and safety of the driver and pedestrians can be secured, and the load generated when controlling a plurality of eye-guided lights by controlling and managing the eye-guided lights collectively through remote control can be minimized. In case of a problem, the line of sight induces wireless transmission of status information to the control server, ensuring safety of the manager and reducing labor costs. Can be reduced.

1 is a view showing a control system of eye induction, etc. according to an embodiment of the present invention;
2 is a block diagram showing the configuration of a control server according to an embodiment of the present invention;
3 is a block diagram illustrating a configuration of a master eye-guided light according to an embodiment of the present invention;
4 is a block diagram illustrating a configuration of a slave eye induction lamp according to an embodiment of the present invention;
5 is a flowchart illustrating a gaze induction control method using a remote control according to an embodiment of the present invention;
6 is a flowchart illustrating a gaze induction control method using a remote control according to another embodiment of the present invention;
7 is a flowchart illustrating a time synchronization method between a control server and a master eye induction using a remote control according to an embodiment of the present invention; and
8 is a flowchart illustrating a time synchronization method between a master gaze induction lamp and a slave gaze induction lamp using a remote control according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a view showing a control system of the eye induction lamp according to an embodiment of the present invention. The eye induction light control system using the remote control according to the present embodiment is constructed of a control server 100, a master eye induction light 200, and a slave eye induction light 300.

The control server 100 transmits and receives information with the master gaze induction lamp 200 through 3G communication, and controls and manages the master gaze induction lamp 200 and the slave gaze induction lamp 300.

In the control server 100, information such as ID, 3G network information, and RF channel information of the master gaze induction lamp 200 and the slave gaze induction lamp 300 are registered.

When the master eye guidance light 200 and the slave eye guidance light 300 are installed, the control server 100 transmits the registered ID, 3G network information, and channel information to the master eye guidance light 200, and the master eye guidance light, etc. Maintains a 3G communication state with the 200 to transmit and receive information.

At this time, the ID is a unique number of the master gaze induction light 200 and the slave gaze induction light 300, the destination of the information when the control server 100 transmits and receives information with the master gaze induction light 200 and the slave gaze induction light 300 And source.

The channel information is a frequency band used when the master gaze induction lamp 200 and the slave gaze induction lamp 300 transmit and receive information.

In addition, the control server 100 requests the master gaze induction light 200 and the master gaze induction light 200 and the installation information of the master gaze induction light 200 and the slave gaze induction light 300, and then the master gaze induction light 200 and the slave gaze induction light 300. And manage whether or not a problem such as a malfunction occurs with respect to the operation of the), and transmits a signal so that the master eye induction lamp 200 and the slave eye induction lamp 300 may blink.

At this time, the installation information, the ID, 3G network information and RF channel information set in the master gaze induction lamp 200 and the slave gaze induction lamps 300 installed in a predetermined position, the ID registered in the control server 100, 3G network information And information for confirming whether it is the same as the RF channel information.

In addition, the control server 100, in order to minimize the load generated when collecting the state information of the master gaze induction light 200 and the slave gaze induction light 300, or process and control the collected state information, the slave gaze induction light Without receiving and transmitting a signal to and from the 300, the master eye-guided light 200 and the slave eye-guided light 300 receive information related to the operation and control through the master eye-guided light 200.

The above state information includes a master, including whether the master eye-guiding light 200 and the slave eye-guiding light 300 are installed, communication status, malfunction, brightness of the LED module, operation of the LED module, and charging status of the power supply. It may be said that all the information to be checked for the normal operation of the gaze induction light 200 and the slave gaze induction light 300.

On the other hand, the master gaze induction light 200 is to transmit and receive information with the control server 100 and the slave gaze induction light 300, and is provided to ensure the safety and visibility of the driver and pedestrians, the vision of the driver and pedestrians at night and bad weather It is installed in the center line or the section lane of the road which is located in the area where it is difficult to secure or in the fog habit area.

When the master gaze induction lamp 200 is installed, the master gaze induction lamp 200 is set with ID and RF channel information of the 3G network information and the slave gaze induction lamp 300 registered in the control server 100.

In addition, when the master gaze induction lamp 200 includes a plurality of slave gaze induction lamps 300 as illustrated, the master gaze induction lamp 300 receives information from a plurality of slave gaze induction lamps 300 and receives a slave from the control server 100. Control information of the eye induction lamp 300 is collectively transmitted to the plurality of slave eye induction lamps 300.

In addition, the master gaze induction light 200, the information transmission and reception with the slave gaze induction light 300 is made only with the master gaze induction light 200 in order to prevent the overload by the information processing in the control server 100, through this The master eye guidance light 200 serves as a bridge between the control server 100 and the slave eye guidance light 300.

In the illustrated example, the master gaze induction lamp 200 has been described as being configured as one, but this is merely an example for convenience of description, and the slave gaze induction lamp 300 may be provided in plural, as in the master gaze. Induction light 300 may also be provided in plurality, of course, when a plurality of master eye-guided light 200 is provided, it may be implemented to receive a batch of control information from the control server 100.

Specifically, a plurality of master gaze induction lamps 200 are provided in the single control server 100, and the plurality of master gaze induction lamps 200 may be connected to a plurality of slave gaze induction lamps 300 individually.

On the other hand, the slave gaze induction light 300, and transmits and receives information with the master gaze induction light 200, and is provided to ensure the safety and visibility of the driver and pedestrians, like the master gaze induction light 200, the driver at night and bad weather And it is installed on the center line or the division lane of the road located in the area difficult to secure the visibility of the pedestrian or the fog habit area, the slave gaze induction light 300 may be provided in plurality, if provided in plurality, the interval set by the user Can be placed.

The slave gaze induction lamp 300 does not transmit and receive the control information transmitted from the control server 100 and the state information of the slave gaze induction lamp 300 requested by the control server 100 to the control server 100. Received through the eye induction lamp (200).

2 is a block diagram showing the configuration of the control server 100 according to an embodiment of the present invention. The control server 100 is constructed of a 3G communication module 110, the control unit 120 and the storage unit 130.

3G communication module 110, the control server 100 requests the master gaze induction light 200 to the master gaze induction light 200 and the state information of the master gaze induction light 200, or the master gaze induction light ( 200).

The control unit 120 processes the information transmitted and received by the control server 100 with the master gaze induction lamp 200 and allows the master gaze induction lamp 200 and the slave gaze induction lamp 300 to operate according to the processed result. For the purpose of controlling the 3G communication module 110 and the storage unit 130.

If the control unit 120 needs to transmit the flashing information of the master gaze induction light 200 and the slave gaze induction light 300 or the request for the status information of the master gaze induction light 200 and the slave gaze induction light 300, the 3G communication module ( By transmitting the blinking information to 110, the 3G communication module 110 controls to transmit the blinking information to the master eye induction lamp (200).

When the state information is transmitted from the master eye induction lamp 200, the controller 120 receives the state information through the 3G communication module 110.

The storage unit 130 stores IDs, 3G network information, and RF channel information of the master gaze induction lamp 200 and the slave gaze induction lamp 300, and controls the master gaze induction lamp 200 and the slave gaze induction lamp 300. Stores preset information.

In the above, it is assumed that the control server 100 includes a 3G communication module, but this is merely an example for convenience of description, and the master eye guidance light 200 and the slave eye guidance light 300 in the control server 100. In order to prevent the overload of the control server 100 in the process of processing the information for controlling the separate communication server by providing a separate communication server may be linked with the control server 100, a separate communication server If provided, the 3G communication module is not included in the control server 100 may be implemented to be provided in a separate communication server, of course.

3 is a block diagram illustrating a configuration of a master eye-guided light 200 according to an embodiment of the present invention. The master gaze induction lamp 200 is constructed of a 3G communication module 210, a control unit 220, a storage unit 230, an RF communication module 240, an LED module 250, and a power supply unit 260.

The 3G communication module 210 is for transmitting and receiving information with the control server 100, and allows the master eye guidance light 200 to be remotely controlled with the control server 100 wirelessly.

Specifically, the 3G communication module when the information request signal for checking the installation information and status information of the master gaze induction light 200 and the slave gaze induction light 300 through the 3G communication module 110 of the control server 100 is transmitted. Received via 210.

In addition, the 3G communication module 210 transmits the processed information according to the requested signal to the 3G communication module 110 of the control server 100.

The control unit 220 is for processing and controlling information transmitted and received with the control server 100 and the slave gaze induction light 300, based on the processed information 3G communication module 210, storage unit 230, The RF communication module 240, the LED module 250, and the power supply unit 260 are controlled.

When the control unit 220 receives the control information signal of the LED module 250 from the control server 100 through the 3G communication module 210, the control unit 220 receives the received control information signal from the RF communication module 240 and the LED module 250. The ID, 3G network information, and RF channel information of the master gaze induction lamp 200 may be stored in the storage unit 230, and the stored ID, 3G network information, and RF channel information may be set.

In addition, the controller 220 transmits the information stored in the storage 230 to the control server 100 only when there is a request for information transmission from the control server 100.

Then, the controller 220 checks the state of charge and the amount of charge of the power supply unit 260, and if it is determined that the power of the identified power supply unit 260 is not enough to operate the LED module 250 is the LED module 250 The power saving mode signal is transmitted to the LED module 250 to enter the power saving mode. For example, when the power of the power supply unit 260 is lowered below the preset power, the LED module 250 may transmit a signal to operate in the power saving mode. At this time, the power saving mode is to lower the amount of power used in the LED module 250 or lower the amount of power supplied to the LED module 250 by lowering the brightness of the LED module 250 than the previously set brightness. Can be.

In addition, the controller 220 controls the power supply unit 260 to charge the electric energy, and the charged electric energy may be supplied to the master eye induction lamp 300.

And, the control unit 220, when the master gaze induction light 300 receives the information from the control server 100, the sending time and the master gaze induction light 300, the information is transmitted from the control server 100 receives the information Differences can arise in the time received. To this end, the master eye induction lamp 300 should be operated based on a result for calculating time synchronization, and calculated based on the calculated formula. This may be described in detail with reference to FIGS. 7 and 8 which will be described later with respect to time synchronization in the same manner as the slash gaze induction lamp 300.

When the information is transmitted to the plurality of slave gaze induction lamps 300, the time at which the information transmitted to the plurality of slave gaze induction lamps 300 arrives at the plurality of slave gaze induction lamps 300 is the plurality of slave gaze induction lamps 300. Since there is a difference for each of them, a formula for time synchronization can be calculated, and the execution time according to the information transmitted for each of the plurality of slave gaze induction lamps 300 can be varied based on the result value calculated according to the calculated formula. . In this regard it will be described in more detail in Figures 7 and 8 to be described later.

In the above, the information received from the control server 100 has been described as the control information of the LED module 250, but this is merely an example for convenience of description, and remote control such as installation information and status information as described above. It may be said that all the information necessary for proper operation of the eye induction used.

On the other hand, the storage unit 230, the ID of the master gaze induction lamp 200 registered in the control server 100, 3G network information and RF channel information, the slave gaze induction lamp 300 transmitted from the slave gaze induction lamp 300 The installation state and boot state information, and the control information of the master gaze induction lamp 200 and the slave gaze induction lamp 300 received from the control server 100 is stored.

The RF communication module 240 is for the master gaze induction lamp 200 and the slave gaze induction lamp 300 located at a short distance to transmit and receive information. In the present invention, the RF communication module 240 uses a transmission / reception frequency of 447Mhz. It is assumed that this is an example for convenience of description and the transmission / reception frequency may be changed.

At this time, the master gaze induction lamp 200 transmits and receives information with the slave gaze induction lamp 300 through the RF communication module 240, not the 3G communication module 210, the control server 100 and the slave gaze induction lamp ( It will act as a bridge between 300).

The LED module 250 is provided to secure the view of the driver and the pedestrian, receives control information from the controller 220, operates according to the received information, and may be adjusted in five levels of brightness to adjust brightness. have. The control information in the above means the brightness, blinking cycle, operating time, power saving mode, etc. of the LED module 250, but not limited to this, all information for the user to change the operation state of the LED module 250. Can be.

The power supply unit 260 is provided to supply power to operate the master eye induction lamp 200, and includes a solar cell module 261 and a battery 260.

The solar cell module 261 is provided to generate electrical energy so that the master eye-guided lamp 200 can be operated. The solar module 261 collects solar light, converts the collected solar light into electrical energy, and converts the converted electrical energy. Transfer to battery 260.

In addition, the solar cell module 261 may be tilted by the controller 220 to maximize the solar light collecting area and transmit information on the converted electric energy to the controller 200.

Meanwhile, the battery 263 accumulates the electric energy transmitted from the solar cell module 261 and transmits the stored electric energy to the LED module 250 so that the LED module 250 can be operated, and the master eye Induction lamp 200 supplies the power required to operate.

In the above description, the master eye induction lamp 200 is constructed of the 3G communication module 210, the control unit 220, the storage unit 230, the RF communication module 240, the LED module 250, and the power supply unit 260. It is assumed, but this is merely an example for convenience of explanation, and in addition to the above configuration, in order to check and monitor the situation information such as traffic information and accident information of the location where the master gaze induction lamp 200 is installed, the master gaze induction ( 200 may be implemented to be provided with a camera, a black box, a sensor box, of course.

4 is a block diagram illustrating a configuration of a slave eye induction lamp 300 according to an exemplary embodiment of the present invention.

The slave gaze induction lamp 300 transmits and receives information with the master gaze induction lamp 200, receives the requested information from the control server 100 through the master gaze induction lamp 200, and operates according to the request information. The slave eye guidance light 300 is constructed of an RF communication module 310, a control unit 320, a storage unit 330, a power supply unit 340, and an LED module 350.

The RF communication module 310 is a communication module for transmitting and receiving information with the master gaze induction lamp 200 located at a short distance, and transmits and receives a 447 MHz transmission / reception frequency like the RF communication module 210 of the master gaze induction lamp 200 described above. It was assumed to use. This, too, like the master eye induction lamp 200 is merely an example for convenience of description and the transmission / reception frequency may be changed.

At this time, since the slave gaze induction lamp 300 provided with the RF communication module 310 cannot transmit / receive information with the 3G communication module 110 of the control server 100, all transmitted from the control server 100 Information and all information of the slave gaze induction light 300 is transmitted and received only with the master gaze induction light 200 provided with the RF communication module 260, it is possible to minimize the overload of the control server 100.

The control unit 320 processes the information received from the master eye guidance light 200, and according to the result value of the information processed above, the RF communication module 310, storage unit 330, power supply unit 340 and LED module Control 350.

In addition, the controller 320 processes the LED module 350 control information signal received from the master eye-guiding light 200 through the RF communication module 310 and transmits the control information signal to the LED module 350, and the control server 100. The ID and RF channel information of the slave gaze induction lamp 300 registered in the storage unit 230 may be stored.

In addition, the controller 320 allows the information stored in the storage unit 330 to be transmitted to the master gaze induction lamp 200 only when there is a request for information transmission from the master gaze induction lamp 200. That is, the slave gaze induction lamp 300 transmits and receives information through the master gaze induction lamp 200 without directly transmitting and receiving information with the control server 100.

In addition, the controller 320 checks the state of charge and the amount of charge of the power supply unit 340, and if it is determined that the power of the identified power supply unit 340 is not sufficient to operate the LED module 350, the LED module 350 is activated. The power saving mode signal is transmitted to the LED module 350 to enter the power saving mode. For example, when the power of the power supply unit 340 is lowered below the preset power, the LED module 350 may transmit a signal to operate in the power saving mode. At this time, the power saving mode is to lower the amount of power used in the LED module 350 or lower the amount of power supplied to the LED module 350 by lowering the brightness of the LED module 350 than the previously set brightness. can do.

In addition, the control unit 320 controls the power supply unit 340 to charge the electric energy, so that the charged electric energy can be supplied to the slave gaze induction lamp (300).

In addition, the control unit 320, like the control unit 220 of the master eye induction lamp 200, calculates a formula for time synchronization, and allows the slave eye induction lamp 300 to operate according to the calculated result value. Also to be described in more detail in Figures 7 and 8 to be described later.

On the other hand, the storage unit 330 stores the ID and RF channel information of the slave gaze induction lamp 300 registered in the control server 100, and stores the control information received through the master gaze induction lamp 200.

The power supply unit 340 generates and supplies electrical energy so that the slave eye induction lamp 330 can operate, and includes a solar cell module 341 and a battery 343.

The solar cell module 341 collects sunlight, converts the collected sunlight into electrical energy, and transfers the converted electrical energy to the battery 343. The tilt control may be performed by the controller 320 to maximize the solar light collecting area of the solar cell module 341, and may transmit information about the converted electric energy to the controller 320.

Meanwhile, the battery 343 accumulates the electric energy transmitted from the solar cell module 341 and transmits the stored electric energy to the LED module 350 so that the LED module 350 can be operated, and the master eye induction lamp and the like. 300 supplies the power needed to operate.

In the illustrated example, it is assumed that only one slave gaze induction lamp 300 is provided, but this is merely an example for convenience of description, and as illustrated in FIG. 1, a plurality of slave gaze induction lamps 300 are provided. Can be implemented.

In addition, when a plurality of slave gaze induction lamps 300 are provided, the plurality of slave gaze induction lamps 300 receive status information from the master gaze induction lamp 200 collectively or receive control information of the LED module 350. Of course it can.

In addition, when a plurality of slave gaze induction lamps 300 are provided, the plurality of slave gaze induction lamps 300 may be controlled by receiving information collectively from the master gaze induction lamp 200.

In this case, it takes a long time for the plurality of slave gaze induction lamps 300 to receive information from the master gaze induction lamp 200. Specifically, the master gaze induction lamp 200 displays the LED module 350 control information for each slave gaze. Differences occur between the time transmitted to the induction lamp 300 and the time when each of the slave gaze induction lamps 300 receives the control information of the LED module 350, as well as each of the slave eyes receiving the control information of the LED module 350. The reception time does not match between the induction lamps 300. Here, the control information of the LED module 350 is information in which the LED module 350 blinks.

For example, the slave eye induction lamp 300 which receives the LED module 350 control information for the first time from the master eye induction lamp 200 is called a first slave eye induction lamp, and the LED module 350 from the master eye induction lamp 200. Assuming that the slave gaze induction light 300 receiving the control information last is the second slave gaze induction light, the time when the first slave gaze induction light receives the LED module 350 control information and the second slave gaze induction light are the LED modules. 350, the time for receiving the control information is not the same and a difference occurs.

Specifically, when the master gaze induction lamp 200 receives a signal to turn on the LED modules 250 and 350 from the control server 100, the master gaze induction lamp 200 turns on the LED module 250, the LED module ( The signal to turn on 350 is collectively transmitted to the first slave eye induction lamp and the second slave eye induction lamp.

In this case, since the LED module 250 of the master gaze induction lamp 200 is turned on first, the LED module 350 is sequentially turned on in the order of the first slave gaze induction lamp and the second slave gaze induction lamp, thereby ensuring the safety of drivers and pedestrians. Difficult to do In particular, when the LED modules 250 and 350 are blinking with a short flashing cycle, the LED modules 250 and 350 may increase the confusion to drivers and pedestrians, thereby threatening safety.

Therefore, time synchronization is required to simultaneously operate the LED module 250 of the master eyelight induction lamp 200 and the LED modules 350 of the plurality of slave eyelight induction lamps 300. This is the same even when a plurality of master gaze induction lamps 200 receiving control information from the control server 100 are provided as described above.

A description of the time synchronization will be described in detail with reference to FIGS. 7 and 8 to be described later.

5 is a flowchart illustrating a gaze induction control method using a remote control according to an embodiment of the present invention.

The control server 100, the ID, 3G network information and RF channel information to be given to the master gaze induction light 200 and the slave gaze induction light 300 before the master gaze induction light 200 and the slave gaze induction light 300 are installed. It is stored in the storage unit 130 (S205).

The master eye induction lamp 200 is installed at a predetermined site (S210).

Master gaze induction lamp 200, 3G network information is set to be remotely controlled by the control server 100 via the 3G communication module 210 (S215).

The ID and RF channel information of the slave gaze induction lamp 300 stored in the storage 130 of the control server 100 are stored and set in the storage 230 of the master gaze induction lamp 200 (S220).

The control server 100 transmits the information registered with the ID, 3G network information, and the RF channel information of the master gaze induction lamp 200 and the slave gaze induction lamp 300 to the master gaze induction lamp 200 (S225).

The master eye guidance light 200 requests the slave eye guidance light 300 to install state information of the slave eye guidance light 300 (S230).

The slave gaze induction lamp 300 is installed at a predetermined site (S235).

The ID and RF channel information of the slave gaze induction light 300 stored in the storage 130 of the control server 100 are stored in the storage 330 of the slave gaze induction light 300 (S240).

The slave eye guidance light 300 transmits the boot information of the slave eye guidance light 300 to the master eye guidance light 200 through the RF communication module (S245).

The master eye guidance light 200 transmits an Ack signal indicating that the boot information of the slave eye guidance light 300 is received through the RF communication module 310 to the slave eye guidance light 300 (S250).

The master eye guidance light 200 stores the installation state information of the received slave eye guidance light 300 in the storage 230 (S255).

The control server 100 requests the installation information of the master gaze induction lamp 200 and the slave gaze induction lamp 300 to the master gaze induction lamp 200 through the 3G communication module 110 (S260).

The master gaze induction lamp 200 controls the installation state information of the master gaze induction lamp 200 and the installation state information of the slave gaze induction lamp 300 stored in the storage unit 230 through the 3G communication module 210. It transmits to (S265).

The control server 100 controls the LED module 250 control information of the master gaze induction lamp 200 and the LED module 350 control information of the slave gaze induction lamp 300 through the 3G communication module 110. ) And transmit (S270).

The master eye guidance light 200 transmits the control information of the LED module 350 of the slave eye guidance light 300 received from the control server 100 through the RF communication module 240 to the slave eye guidance light (S275). In this case, when there are a plurality of slave eye induction lamps 265, the MR eye induction lamp 100 may collectively transmit control information of the LED module 35 to the plurality of slave eye induction lamps 300.

The LED module 250 of the master gaze induction lamp 200 and the LED module 350 of the slave gaze induction lamp 300 blink in accordance with the control information received from the control server 100 (S280).

6 is a flowchart illustrating a gaze induction control method using a remote control according to another embodiment of the present invention.

The control server 100, the master gaze induction light 200 and the slave gaze induction light 300 to the ID, 3G network information and RF channel information to be assigned to the determined master gaze induction light 200 and the slave gaze induction light 300 It is stored in the storage unit 130 before being installed (S305).

Slave gaze induction light 300 is installed at a predetermined site (S310).

The ID and RF channel information of the slave gaze induction light 300 stored in the storage 130 of the control server 100 are stored in the storage 330 of the slave gaze induction light 300 (S315).

The slave eye guidance light 300 transmits the boot information of the slave eye guidance light 300 to the master eye guidance light 200 through the RF communication module 310 (S320).

The master eye induction lamp 200 is installed at a predetermined site (S325).

3G network information is set to be remotely controlled by the control server 100 through the 3G communication module 210 (S330).

The control server 100 transmits the information registered with the ID, 3G network information, and the RF channel information of the master gaze induction light 200 and the slave gaze induction light 300 to the master gaze induction light 200 (S335).

The master eye induction light 200 requests the installation state information of the slave eye induction light 300 to the slave eye induction light 300 through the RF communication 240 (S340).

The slave gaze induction light 300 transmits installation state information stored in the storage unit 330 of the slave gaze induction light 300 through the RF communication 310 (S345).

The master eye guidance light 200 stores the installation state information of the received slave eye guidance light 300 in the storage 230 (S350).

The control server 100 requests the installation state information of the master gaze induction light 200 and the slave gaze induction light 300 to the master gaze induction light 200 through the 3G communication module 110 (S355).

The master gaze induction lamp 200 controls the installation state information of the master gaze induction lamp 200 and the installation state information of the slave gaze induction lamp 300 stored in the storage unit 230 through the 3G communication module 210. Transfer to (S360).

The control server 100 controls the LED module 250 control information of the master gaze induction lamp 200 and the LED module 350 control information of the slave gaze induction lamp 300 through the 3G communication module 110. In step S365).

The master eye guidance light 200 transmits control information of the LED module 350 of the slave eye guidance light 300 received from the control server 100 through the RF communication module 240 to the slave eye guidance light (S370). In this case, when there are a plurality of slave eye induction lamps 265, the MR eye induction lamp 100 may collectively transmit control information of the LED module 35 to the plurality of slave eye induction lamps 300.

The LED module 250 of the master gaze induction lamp 200 and the LED module 350 of the slave gaze induction lamp 300 blink in accordance with the control information received from the control server 100 (S375).

On the other hand, the time synchronization, by setting the time of the control server 100, the master gaze induction lamp 200 and the plurality of slave gaze induction lamps 300, the master gaze induction lamp receiving the time information from the control server 100 200 and the plurality of gaze induction lamps 300 which receive time information from the master gaze induction lamp 200 receive the time transmitted from the control server 100 later than the actual time due to the time difference required for information transmission. A time difference occurs between the server 100, the master eye induction lamp 200, and the plurality of slave eye induction lamps 300.

That is, for example, the master gaze induction lamp 200 takes 1 second to receive information from the control server 100, and the slave gaze induction lamp 300 takes 1 second to receive information from the master gaze induction lamp 200. When the control server 100 transmits time information at 7 o'clock and the control server 100 transmits information to the master eye induction lamp 200 at 7 o'clock, the current time is 7 o'clock, the master eye induction lamp 200 ) Receives the information of 7 o'clock at 7: 1 second, the 7 o'clock is set to 7 o'clock in the master eye induction lamp 200.

Then, when the master gaze induction light 200 transmits information that the current time is 7:00 at 7: 1 second to the slave gaze induction light 300, the slave gaze induction light 300 receives the information that is 7:00 at 7: 2 seconds. Since it is received, the slave gaze induction lamp 300 is set to 7 o'clock and 2 o'clock.

As described above, when the master gaze induction lamp 200 and the slave gaze induction lamp 300 that do not perform time synchronization receive control information for turning on the LED modules 250 and 350 at 7:00 from the control server 100, the control is controlled. Based on the time of the server 100, the master eye induction lamp 200 is turned on at 7: 1 second, and the slave eye induction lamp 300 is turned on at 7: 2 seconds.

Therefore, the master eye induction lamp 200 and the at least one slave eye induction lamp 300 should be set to the same time as the control server 100 so that the LED module is turned on at the same time.

Hereinafter, time synchronization will be described in detail with reference to FIGS. 7 to 8.

7 is a flowchart illustrating a time synchronization method between the control server 100 and the master eye guidance light 200 using a remote control according to an embodiment of the present invention.

The control server 100 transmits a reference signal to the master eye guidance light 200 through the 3G communication module 110 (S400). In this case, the reference signal is a signal for calculating the time required for the master eye induction lamp 300 to receive information from the control server 100, and the reference signal includes a transmission time when the control server 100 sends the reference signal. Included. At this time, the transmission time is the same as the reference time of the control server 100 for time synchronization. For example, when the control server 100 transmits the reference signal at 7:00, the transmission time and the reference time are at 7:00.

If the reference signal transmission number is not five times (S410-N), in order to narrow the error range of the reference signal reception time of the master eye induction lamp 200 and calculate accurate data, the control server 100 uses the 3G communication module. Through reference to 110, the reference signal is transmitted to the master eye-guided light 100 (S400). In this case, the number of transmissions is merely an example for convenience of description, and the number of transmissions may be set to more than five times or less than five times.

On the other hand, when the reference signal transmission count is five times (S410-Y), it ends.

The master eye guidance light 200 checks the transmission time and the reception time of the reference signal sent from the control server 100 (S420). Each time a reference signal is received, the transmission time and reference signal for which each reference signal is sent are checked.

The master gaze induction lamp 300 calculates a time synchronization formula between the control server 100 and the master gaze induction lamp 300 based on the received reference signal and stores it in the storage unit (S430).

Then, the master gaze induction lamp 200 is time-synchronized so that the master gaze induction lamp 200 can be set to the same time as the control server 100 according to the formula calculated in S430 (S440). For example, when the master gaze induction lamp 300 is set to one second later than the control server 100 according to the formula calculated above, the master gaze induction lamp 200 sets a time of 6:59:59. It will be set to hours. Of course, this is only an example, and when receiving the information of 7 o'clock, the master eye-guided light 300 may be implemented to set the time to 7: 1 second based on the information of the received 7 o'clock.

The control server 100 controls the LED module 250 control information and the LED module 350 control information of the slave eye guidance light 300 to the master eye guidance light 200 through the 3G communication module 110. In step S450). At this time, the control information is the flashing time and the flashing period of the LED module 250, the flashing time is the time that the LED module 250, 350 is turned on or off, the flashing period is the LED module 250, 350 is turned on and off It means a certain time difference between the time. For example, if the blinking period is 2 seconds, it turns off when 2 seconds have elapsed after being turned on, and is turned on again after 2 seconds has elapsed after being turned off.

Then, the LED module 250 of the master gaze induction lamp 200 is operated according to the control information at the synchronized time (S445).

Specifically, when the control server 100 transmits time information to the master gaze induction lamp 200, the time for the control server 100 to transmit time information as described above and the time for the master gaze induction lamp 200 to receive time information. For example, when a time difference of 1 second occurs between the control server 100 and the master gaze induction light 200, when the control information is transmitted so that the LED module 250 is turned on at 7:00, time synchronization is not completed master As described above, since the gaze induction lamp 200 is set to 7: 1 second as described above, the LED module 250 is turned on at 7: 1 second.

However, when the master gaze induction lamp 200 completes the time synchronization as described above, since it is set to the same time as the control server 100, the LED of the master gaze induction lamp 200 at 7 on the basis of the control server 100. Module 250 can be turned on.

In the illustrated example, it is assumed that the step of transmitting the control information is after time synchronization is completed, but the control information may be implemented to be transmitted from the control server 100 to the master gaze induction lamp 200 before time synchronization is performed.

FIG. 8 is a flowchart illustrating a time synchronization method between a master gaze induction lamp 200 and a slave gaze induction lamp 300 using a remote control according to an embodiment of the present invention, which is the control server 100 and the master described with reference to FIG. 7. The time between the master gaze induction lamp 200 and the slave gaze induction lamp 300 is set in the same principle as the time synchronization between the gaze induction lamp 200.

The master eye guidance light 200 transmits a reference signal to the slave eye guidance light 300 through the RF communication module 240 (S500). At this time, the reference signal is a signal for calculating the time required for the slave gaze induction light 300 to receive information from the master gaze induction light 200, and the reference signal is transmitted by the master gaze induction light 200 to send a reference signal. Time is included. For example, when the time when the master eye-guided light 200 transmits the reference signal is 7:00, the transmission time and the reference time are 7:00.

If the reference signal transmission frequency is not five times (S510-N), in order to calculate the correct data by narrowing the error range of the reference signal reception time of the slave gaze induction lamp 300, the master gaze induction lamp 200 performs RF communication. Through the module 240, the reference signal is transmitted to the slave eye induction lamp 300 (S500). In this case, the number of transmissions is merely an example for convenience of description, and the number of transmissions may be set to more than five times or less than five times.

On the other hand, when the reference signal transmission count is five times (S510-Y), it ends.

The slave eye guidance light 300 checks the time and reception time at which the reference signal sent from the master eye guidance light 200 is transmitted (S520). Each time a reference signal is received, the transmission time and reference signal for which each reference signal is sent are checked.

The slave gaze induction light 300 calculates a time synchronization formula between the master gaze induction light 200 and the slave gaze induction light 300 based on the received reference signal, and stores the time synchronization formula in operation S530.

Then, the slave gaze induction lamp 300 is time-synchronized so that the time is set equal to the master gaze induction lamp 200 based on the formula calculated in S530 (S540). For example, when the time is set to 1 second later than the master eye-guided light 200 according to the formula calculated above, the slave eye-guided light 300 may measure 6:59:59. It will be set to hours. Of course, this is like the master eye-guided light 200, it is merely an example, and on the contrary, when the 7-hour information is received, the slave eye-guided light 300 is set to 7: 1 second based on the received information of 7 o'clock. It may be implemented.

The master gaze induction lamp 200 slaves the control information of LED modules 250 and 350 of the master gaze induction lamp 200 and the slave gaze induction lamp 300 received from the control server 100 through the RF communication module 240. Transmission to the eye-guided light 300 (S550). At this time, the control information is the flashing time and the flashing period of the LED module 250, 350, the flashing time is the time that the LED module 250, 350 is turned on or off, the flashing period is the LED module 250, 350 is lit And it means a constant time difference between the time off. For example, if the blinking period is 2 seconds, it turns off when 2 seconds have elapsed after being turned on, and is turned on again after 2 seconds has elapsed after being turned off.

Then, the LED modules 250 and 350 of the master gaze induction lamp 200 and the slave gaze induction lamp 300 operate according to the control information at the synchronized time (S560).

Specifically, when the master gaze induction lamp 200 transmits time information to the slave gaze induction lamp 300, the time between the control server 100 transmitting the time information and the time when the master gaze induction lamp 200 receives the time information. For example, when a time difference of 1 second occurs, when the control information is transmitted so that the LED module 350 lights up at 7:00 from the master gaze induction lamp 200 to the slave gaze induction lamp 300, the slave whose time synchronization is not completed. As described above, since the gaze induction lamp 300 is set to 7: 1 seconds as 7, the LED module 350 is turned on at 7: 1 seconds.

However, when the slave gaze induction lamp 300 completes the time synchronization as described above, since it is set to the same time as the control server 100, the slave gaze induction lamp 300 at 7:00 on the basis of the time of the control server 100. LED module 350 can be turned on.

In the embodiment of the present invention, the control server 100 and the master eye guidance light 200 transmit and receive information through the 3G communication module, the master eye guidance light 200 and the slave eye guidance light 300 through the RF communication module 447Mhz It is assumed that the information is transmitted and received using the frequency band, but this is merely an example for convenience of explanation, and the control server 100 and the master eye guidance light 200 transmit and receive information, or the master eye guidance light 200. And if the slave gaze induction lamp 300 is used for communication module or transmission and reception frequency band for transmitting and receiving information will be seen to be within the technical scope of the present invention.

In addition, in order to perform time synchronization, the control server 100 has a reference time. For this purpose, the control server 100 allows a reference time for time synchronization to be preset, or a separate communication unit is provided to the user. The standard time provided may be received and the received standard time may be set as the reference time.

In addition, the master gaze induction lamp 200 and the slave gaze induction lamp 300 are operated by receiving only control information from the control server 100 without time synchronization. Of course, the control server 100 may be received together with the standard time received from the user so that the same time can be set.

In addition, the control server 100, the master gaze induction lamp 200 and the slash gaze induction lamp 300 according to the present embodiment transmits and receives information in real time according to the Real-Time processing system (RTS) method You can also send and receive.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

100: control server 110: 3G communication module
120: control unit 130: storage unit
200: master eye guidance light 210: 3G communication module
220: control unit 230: storage unit
240: RF communication module 250: LED module
260: power supply unit 261: solar cell module
263: battery 300: slave eye guidance light
310: RF communication module 320: control unit
330: storage unit 340: power unit
341 solar cell module 343 battery
350: LED module

Claims (8)

In a gaze induction light control method in which a master gaze induction light and at least one slave gaze induction light are remotely controlled by a control server,
Registering ID and RF channel information of the master eye guidance light and the at least one slave eye guidance light, in the control server;
Installing the master eye-guided light and the at least one slave eye-guided light in the field;
Inputting the ID and the RF channel information to the master eye induction lamp and the at least one slave eye induction lamp;
Transmitting, by the control server, control information for the LED module provided in the master eye guidance light and the at least one slave eye guidance light to the master eye guidance light through a 3G communication module;
The master gaze induction light broadcasting the control information to the at least one slave gaze induction light through an RF communication module;
The master gaze induction light and the at least one slave gaze induction light are time-synchronized to simultaneously blink the LED module provided in the master gaze induction light and the at least one slave gaze induction light according to the control information transmitted from the control server. Becoming; And
And flashing the master eye induction lamp and the at least one slave eye induction lamp according to the received control information.
The time synchronization step,
Transmitting, by the control server, a reference time of the control server to the master eye induction;
Receiving, by the master eye induction, the reference time;
In the master gaze induction, the control server checks the first transmission time for transmitting the reference time and the first reception time for receiving the reference time, and through the difference between the first transmission time and the first reception time. Calculating a first time deviation required for transmitting information between the control server and the master eye induction;
Correcting the time of the control information received from the control server, based on the first time deviation, by the master gaze induction;
Receiving, by the at least one slave eye guidance light, the reference time from the master eye guidance light;
A second transmission time in which the master eye guidance light transmits the reference time to the at least one slave eye guidance light, and a second reception in which the at least one slave eye guidance light receives the reference time in the at least one slave eye guidance light. Checking a time and calculating a second time deviation for transmitting information between the master eye induction lamp and the at least one slave eye induction lamp based on a difference between the second transmission time and the second reception time;
Correcting, by the at least one slave gaze induction lamp, the time of the control information received from the master gaze induction lamp based on the second time deviation; And
And causing the LED module to blink according to the time of the master control lamp and the at least one slave eye guide lamp to the corrected control information.
The time of the control information is a gaze induction lamp control method, characterized in that the time that the LED module included in the control information transmitted to the master gaze induction, such as the control server blinks. The method of claim 1,
The installation step,
Installing the master eye guidance light;
Setting network information with the control server in the master eye induction;
Setting the ID and the RF channel information to the master eye induction;
Transmitting, by the control server, the ID and RF channel information to the master eye induction via the 3G communication module;
Requesting, by the master eye guidance light, installation state information of the at least one slave eye guidance light through the RF communication module;
Installing the at least one slave eye guidance light after the master eye guidance light is installed;
Registering the ID and the RF channel information with the at least one slave gaze induction;
Transmitting, by the at least one slave eye guidance light, boot information to the master eye guidance light through the RF communication module; And
And transmitting, by the master eye guidance light, the acknowledgment according to the reception of the boot information to the at least one slave eye guidance light through the RF communication module. The method of claim 1,
The installation step,
Installing at least one slave eye induction lamp;
Registering the ID and the RF channel information with the at least one slave gaze induction;
Transmitting boot information of the at least one slave gaze induction via the RF communication module;
Installing the master eye guidance light after the at least one slave eye guidance light is installed;
Setting network information with the control server in the master eye induction; And
And transmitting, by the control server, the ID and RF channel information to the master eye guidance light through the 3G communication module. delete delete The method of claim 1,
A first requesting step, wherein the control server requests status information of the master eye induction lamp and the at least one slave eye induction lamp from the master eye induction lamp;
A second requesting step, wherein the master eye-guided light transmits the first request to the at least one slave eye-guided light;
Transmitting, by the at least one slave eye guidance light, the response to the status information to the master eye guidance light; And
And transmitting, by the master gaze induction lamp, the state information on the first request and the second request to the control server. The method according to claim 6,
The status information may include:
A solar cell module and a battery provided in the RF communication module such as the master eye induction lamp and the at least one slave eye induction lamp, the brightness and malfunction of the LED module, the master eye induction lamp and the at least one slave eye induction lamp, The control method of the eye induction lamp, characterized in that whether the power supply unit malfunctions, including information on the state of charge and charge amount of the power supply unit, and entering or exiting the power saving mode by the low voltage of the power supply unit. In the eye guidance light control system, wherein the master eye guidance light and at least one slave eye guidance light are controlled remotely by a control server,
ID and RF channel information of the master eye induction lamp and the at least one slave eye induction lamp are registered, and include a 3G communication module for transmitting and receiving information with the master eye induction lamp, and the master eye induction lamp and the at least one slave eye. Transmitting control information for the LED module provided in the induction lamp, and transmitting a reference time to the master gaze induction light so that the LED module provided in the master gaze induction light and the at least one slave gaze induction light blinks at the same time according to the control information. Control server;
Installed in the field, the ID and RF channel information registered in the control server is input, and includes the 3G communication module and RF communication module for transmitting and receiving information with the control server and the at least one slave gaze induction, An LED module for induction is provided, receives the control information from the control server, broadcasts it to the at least one slave eye induction lamp, and blinks according to the control information, and the at least one slave eye according to the control information. Receiving the reference time from the control server to blink at the same time as the induction lamp, and confirms the first transmission time the control server has transmitted the reference time and the first reception time received the reference time, the first transmission time And a first time required for transmitting information with the control server through the difference in the first reception time. Calculate a difference, correct the time of the control information received from the control server based on the first time deviation, perform time synchronization, and transmit the reference time to the at least one slave eye induction; A master gaze induction lamp blinking with time of the corrected control information; And
Installed in the field, the ID and RF channel information registered in the control server is input, and includes an RF communication module for transmitting and receiving information with the master eye guidance light, LED module for eye guidance is provided, the master eye The control information is broadcasted from an induction lamp, and blinks according to the control information, and receives the reference time from the master eye induction lamp to blink simultaneously with the master eye induction lamp according to the control information. A second transmission time for transmitting the time and a second reception time for receiving the reference time, and a second time required for information transmission with the master eye induction through a difference between the second transmission time and the second reception time. 2 time deviations are calculated, and are transmitted from the master eye induction, etc. based on the second time deviations. At least one slave Line guide light is performed by the time synchronization correcting the time of the control information, and flashes according to the time of the corrected control information; includes,
The time of the control information, the gaze induction light control system, characterized in that the time that the LED module included in the control information transmitted to the master gaze induction, such as flashing.

Images