KR20170101830A - Data line structure and method for data transmission between lighting socket and lights - Google Patents

Abstract

The present invention relates to a data line structure and a method, capable of data transmission between a lighting socket and a lighting device which can provide an interface capable of communications and easy connection between devices. The data line structure is applied to a multidata signal transmission device through a smart VLC lighting device, wherein the smart VLC lighting device comprises: a smart LED lighting device (100) operated in accordance with a control signal of a control server to transmit a multidata signal towards a smart device located nearby through visible light communication and connected to another neighboring LED lighting device through a short-range wired/wireless communication network to perform two-way data communication; a control server (200) connected to the smart LED lighting device (100) though a long-range wired/wireless communication network to control operations of the smart LED lighting device; and a separable interface (300) individually connecting an AC power source and a DC power source, respectively when connection is made between a lighting socket (119) of a socket-type VLC module (110a) of the smart LED lighting device (100) and a bulb (129) for a lighting device of a VLC module (120a) of a lighting device packaging type. Therefore, an image sensor reception performance through a camera of the smart device can be improved, indoor location identification can be realized, and the data line structure can be widely compatibly applied to an LED lighting device including an LED socket structure, an LED street light lighting device cover structure, and an LED fluorescent lighting device cover structure.

Description

TECHNICAL FIELD [0001] The present invention relates to a data line structure and a method for data transmission between a lighting socket and a luminaire,

The present invention can be widely applied to an LED lighting fixture composed of an LED socket structure, an LED street light fixture cover structure, an LED fluorescent light fixture cover structure, and a socket with a socket thread to form a data communication interface. It is possible to transmit and receive multi data signals to and from neighboring smart devices by creating communication, and it is also possible to use a smart VLC which can be connected to another neighboring smart LED lighting device and a nearby wired / wireless communication network (visible light, RF, To a data line structure and method that enable data transmission between a lighting socket and a luminaire that can be applied to a multi-data signal transmission device through a lighting device.

Generally, a conventional lighting device or a lighting infrastructure and a communication device are separated, and it is necessary to study a technique of utilizing light used in a lighting infrastructure or the like as communication. Recently, research on visible light communication technology using illumination light has been actively studied. At this time, the value of technical use of LED illumination is increasing.

For example, the technology of visible light communication using LED lamp is the latest communication technology that combines communication with digital LED lighting, which is visible light. It is a communication technology that modulates the light to the LED lamp lighting device, And establishing an environment capable of providing multimedia communication services.

As wired / wireless voice communication and internet service become common, various short distance wireless communication technologies are being developed for improved information communication and LED lamp lighting device emitting visible light wavelength (380 ~ 780nm) A visible light communication technology has been highlighted.

Conventional visible light communication devices using such LED lights have a short transmission distance of several meters and transmission speeds of 100 Mb / s or less.

However, to be used for next-generation indoor wireless communication beyond conventional RF communication, the transmission speed can be increased to 1 Gb / s or higher, and in order to use it for wireless LAN, it is urgent to develop a device that increases the transmission distance to 10 m or more It is true.

In addition, there is a problem in that it is impossible to form a data network in conjunction with another LED lamp, a neighboring LED lamp, and a smart device, and it is impossible to provide location information of a positioning point.

In addition, when a visible light communication configuration and a wired / wireless network module are simultaneously configured on one LED lamp, there is a problem that the bulb is heavy and heavy, and the manufacturing cost is high.

In addition, it may not be economical to change all the lighting in case of a real or ankle building where a dedicated switch or receiver is required to apply the communication to the lighting. There is a desperate need for a technology capable of using existing lighting sockets or lighting while allowing communication.

Korean Patent Publication No. 10-2012-0080055

In order to solve the above-described problems, the present invention combines an LED lamp control device and an integrated driver for LED lamp control and communication into an LED lighting device so as to network the multi data signal, and the LED data information based on the smart device image sensor The position information of the positioning point can be generated as a visible light ID data communication signal through the light emission of the LED lamp and can be accurately emitted to the smart device so that the performance of the image sensor reception through the camera of the smart device LED socket structure, LED streetlight luminaire cover structure, LED fluorescent lamp lid cover, etc. can be obtained. In addition, it is possible to recognize the indoor location even if the smart device is changed to another indoor space in real time. Widely used in LED lighting fixtures made of structure The object of the present invention is to provide a data line structure that enables data transmission between a lighting socket and a luminaire applied to a multi-data signal transmission device through a smart VLC lighting device compatible with the present invention.

It is another object of the present invention to provide a communication control device for communication implementation in a separate device and to provide an easy interface with a separate communication control device for a lamp for a luminaire, A method for enabling data transmission between a lighting socket and a luminaire that can be used as an interface capable of easy connection.

In order to achieve the above object, a data line structure that enables data transmission between a socket for illumination and a luminaire according to the present invention is driven according to a control signal of a control server, and transmits a multi data signal through a visible light communication A smart LED lighting fixture connected to another neighboring smart LED lighting fixture and a wired / wireless local area network for bidirectional data communication; A control server connected to the smart LED lighting fixture and a remote wired / wireless communication network to control operation of the smart LED lighting fixture; And a separate interface for separately connecting the AC power source and the DC power source for connection between the lighting socket of the socket type VLC module of the smart LED lighting apparatus and the lamp unit of the lamp type packaged VLC module, Signal transmission apparatus.

As described above, according to the present invention, it is possible to incorporate an integrated driver for LED lamp control and communication into an LED lamp socket in an implant-coupled structure, thereby reducing the slim volume and the manufacturing cost to less than 60% , It is possible to build up a single network network by constructing data related to peripheral LED lamps and smart devices that have not existed before, to improve data transmission speed by 70%, and to improve the performance of image sensor reception through a smart device camera It is possible to improve the indoor position information of the user by 70% compared to the conventional one, and it is possible to improve the indoor space of the LED socket structure, the LED streetlight lamp cover structure , LED fluorescent lighting fixture cover structure, LED lighting fixture There.

A data line structure that enables data transmission between the lighting socket and the luminaire of the present invention and a method of enabling data transmission between the lighting socket and the luminaire are such that a separate communication control device is added between the existing socket and the lamp, There is an advantage in that the communication operation is performed by adding a simple interface with the communication control device to the bulb.

1 is a configuration diagram showing components of a multi-data signal transmission apparatus 1 through a smart VLC lighting apparatus according to the present invention,
2 is a block diagram showing components of a socket VLC module according to the present invention,
3 is a block diagram illustrating components of a first LED lamp according to the present invention,
4 is a block diagram illustrating components of a first smart LED data control module according to the present invention;
5 is an external perspective view showing components of a socket type VLC module according to the present invention,
6 is an exploded perspective view showing internal components of a socket VLC module according to the present invention,
7 is a block diagram illustrating components of a first multi-control module according to the present invention,
8 is a diagram illustrating an embodiment in which the Vdd grounding unit, the ground terminal, and the data connection terminal of the socket interface forming unit according to the present invention are paired with the socket connection and the Vdd grounding terminal, the ground terminal, and the data connection terminal of the data transmission interface forming unit ,
9 is a block diagram showing components of a lamp packaged VLC module according to the present invention,
10 is a block diagram showing components of a second LED lamp according to the present invention,
11 is a block diagram illustrating components of a second smart LED data control module according to the present invention,
12 shows an embodiment in which the second lighting apparatus main body according to the present invention is composed of a streetlight lamp cover 121a for a car,
Fig. 13 shows an embodiment in which the second lighting apparatus main body according to the present invention is constituted by a street lamp lid cover 121b for indoors,
14 shows an embodiment in which the second lighting apparatus main body according to the present invention is constituted by the walking backlight cover 121c,
15 is a block diagram showing the components of a second multi-control module according to the present invention,
16 is a flowchart illustrating a method of controlling a smart LED lighting apparatus according to an exemplary embodiment of the present invention. Referring to FIG. 16, a smart LED lighting apparatus according to an exemplary embodiment of the present invention is driven according to a control signal of a control server to transmit a multi data signal through a visible light communication to a smart device located nearby, In an embodiment that illustrates receiving a signal,
17 is a view illustrating an embodiment in which a second visible light transmitting / receiving module according to the present invention is driven according to a control signal of a second data receiving control module to form a visible light communication network with a neighboring smart device to transmit a multi data signal.
18 is a perspective view of a data line structure for enabling data transmission between a lighting socket and a lamp for a lighting fixture according to the present invention;
Fig. 19 is a sectional view for explaining the connection structure between the lighting socket and the lamp for the lamp shown in Fig. 18; Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. And is provided to fully convey the scope of the invention to those skilled in the art, and the present invention is defined by the claims.

It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. &Quot; comprises " and / or "comprising" when used in this specification is taken to specify the presence or absence of one or more other components, steps, operations and / Or add-ons. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, Visible Light Communication (VLC) described in the present invention is a communication using a visible light region visible to the human eye and uses information such as an incandescent lamp and a fluorescent lamp to be replaced with a light emitting diode (LED) Which is a new information and communication technology that transmits and reuses information.

The basic concept of the visible light communication technology is the same as digital communication in that data is converted into a combination of 0 and 1 to transmit information, but light is turned off when data is '0' Is switched to ON and blinking or lightening is performed in accordance with the brightness.

Also, the multi-data signal according to the present invention receives the control signal of the remote control server through the remote wired / wireless communication and receives the control signal of the remote control server through the LED light Signal data, position information of positioning point, visible light ID data communication signal, association data through network network with smart device, and AP position data for receiving big data.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing components of a multi-data signal transmission apparatus 1 through a smart VLC lighting apparatus according to the present invention, which is composed of a smart LED lighting apparatus 100 and a control server 200 .

First, the smart LED lighting fixture 100 according to the present invention will be described.

The smart LED lighting apparatus 100 is driven in accordance with a control signal of the control server to transmit a multi data signal through a visible light communication to a smart device located in the vicinity and to be connected to another neighboring smart LED lighting apparatus through a local wireless communication network So as to perform bidirectional data communication.

It consists of a socket VLC module 110 and a lamp packaged VLC module 120.

Here, the short-range wired / wireless communication network is composed of visible light, RF, Zigbee, Bluetooth, and a wired network.

[Socket type VLC Module 110)

As shown in FIG. 5, the socket-type VLC module 110 has an LED socket structure. The socket-type VLC module 110 forms a data communication interface with a socket thread and generates visible light communication through LED light, And transmits and receives multi data signals.

As shown in FIG. 2, the first illuminator main body 111, the first LED lamp 112, and the first smart LED data control module 113 are configured.

First, the first illuminator main body 111 according to the present invention will be described.

The first illuminating device main body 111 protects and supports each device from external pressure.

As shown in Fig. 6, this is constituted by a socket guide head 111a and a socket support 111b.

The socket guide head portion 111a is formed in a disk drum shape and guided to include a socket of an LED lamp while being coupled thereto, thereby protecting the socket guide head portion 111a from external pressure and supporting each device. This forms a storage space therein.

The socket support base 111b is formed in a disc shape having a layered structure. The socket ground plane of the female thread is formed in the inner end space of the layered structure. The first power supply unit is connected to the rear end of the socket support base 111b, When the socket of the LED lamp is grounded, it serves to supply the power to the tap of the LED lamp.

The first illuminator main body is connected to the first LED lamp by socket connection toward the front end of the socket support.

Second, the first LED lamp 112 according to the present invention will be described.

The first LED lamp 112 is located on one side of the front end face of the socket support of the first illuminator body and is driven according to the multi data signal of the first smart LED data control module to emit LED light, And transmits / receives multi-data information to another smart device.

As shown in FIG. 3, the first transparent diffusion plate 112a, the first LED module 112b, the LED socket 112c, and the nipple 112c are formed.

The first transparent diffusion plate 112a has an elliptical structure to diffuse light generated from the first LED module to the outside to emit light.

The first LED module 112b is located in a space inside the transparent diffusion plate and is driven according to the multi data signal transmitted from the data transmission interface to transmit the LED light to the transparent diffusion plate.

It consists of visible light LEDs all having the same characteristics.

Among them, LED 1 transmits a synchronous pulse and LED 2 is used to transmit data.

The LED socket 112c is located at a rear end side of the first LED module and is grounded with the female thread of the LED socket support while supporting the first LED module for emitting light, .

As shown in Fig. 6, this includes a data transfer interface forming unit 112c-1.

As shown in FIG. 8, the data transfer interface forming unit 112c-1 is formed with a Vdd ground terminal, a ground terminal, and a data connection terminal on one side of the male thread to be mated with the socket interface forming unit 113c When the socket interface forming part 113c is paired with the socket, the multi-data signal is received from the socket interface forming part 113c to drive the first LED module.

8, a Vdd ground terminal, a ground terminal, and a data connection terminal made of a ferrite material are formed on the male thread, and the Vdd ground terminal, the ground terminal, and the ground terminal of the socket interface forming portion 113c, When the data connection terminals are fused and grounded, the LED socket and the socket support are recognized as one customized set, and the multi-data signal of the first smart LED data control module is received from the socket interface forming portion 113c. At this time, the multi-data signal includes all of the LED emission signal data, the position information data of the positioning point, the visible light ID data communication signal, the association data via the network with the smart device, and the AP position data for receiving the big data.

On the contrary, when the LED socket and the socket support are combined without forming the data transfer interface forming unit consisting of the Vdd ground terminal, the ground terminal, and the data connection terminal in the male thread of the LED socket, only LED light emission .

The cap 112d is located at the rear end of the LED socket and receives power from the socket support to transmit the power to the LED socket.

Third, the first smart LED data control module 113 according to the present invention will be described.

The first smart LED data control module 113 is installed in the first lighting device body as an implant structure and controls the first LED lamp according to the control data signal transmitted from the control server, Transmits the multi-data signal to the device, and connects with other neighboring smart LED lighting device to the nearby wired / wireless communication network, thereby performing bi-directional data communication.

As shown in FIG. 4, the first power supply unit 113a, the first multi control module 113b, the socket interface forming unit 113c, and the first transmitting / receiving unit 113d.

Here, the short-range wired / wireless communication network is composed of visible light, RF, Zigbee, Bluetooth, and a wired network.

The first power supply unit 113a is located at a rear end of the socket support, and receives power from the power line to supply power to the devices.

The first multi control module 113b is installed as a pin socket type in a detachable structure in a base internal space between the socket support and the first power supply unit and is installed in a smart device located near by a visible light communication generated in the first LED module And transmits the multi data signal to the neighboring smart LED lighting device and the bidirectional data communication by connecting to the nearby wired / wireless communication network.

As shown in FIG. 7, the first power control module 113b-1, the first data reception control module 113b-2, the first visible light transmission / reception module 113b-3, Module 113b-4, and a first LED control driver module 113b-5.

Here, the short-range wired / wireless communication network is composed of visible light, RF, Zigbee, Bluetooth, and a wired network.

The first power control module 113b-1 controls the power supplied through the first power connection unit and supplies the power to each device.

It consists of a constant voltage regulator IC.

The constant-voltage regulator IC converts the input voltage into a constant voltage suitable for each device.

The first data reception control module 113b-2 receives the multi-control data through the wired / wireless communication with the control server and transmits the multi-control data to the first visible light transmission / reception module.

Here, wired / wireless communication is composed of wired communication composed of PLC (Power Line Communication), RS232 / RS485 / RS422, and wireless communication composed of Zigbee communication, infrared communication, and Bluetooth communication.

The first visible light transmission / reception module 113b-3 receives the multi-control data from the first data reception control module, and receives the Vdd ground terminal, the ground terminal, and the data connection terminal of the socket interface formation unit paired with the data transmission interface formation unit The LED socket and the socket support are recognized as one customized set and the multi-data signal is transmitted to the first LED control driver module 113b-5, and then the first LED lamp is controlled to transmit the visible light communication And transmits and receives a multi-data signal to and from a smart device located near by.

It is composed of a first visible light transmitter and a first visible light receiver.

The first visible light transmitting unit transmits the multi data signal to the first LED control driver module and transmits the multi data signal to the smart device located near by the visible light communication generated in the first LED lamp.

The first visible light receiver receives a response data signal corresponding to a multi-data signal transmitted from a smart device located near by visible light communication through visible light communication.

The first local area network zone forming interface module 113b-4 forms a local area network with neighboring smart devices and smart LED lighting devices through the wireless connection of the first transceiver and transmits / receives multi data signals.

The first LED control driver module 113b-5 receives the multi-data signal from the first visible light transmission / reception module 113b-3 and controls the first LED lamp.

It consists of a first pulse generator, a first A / D (Analog-to-Digital) converter, and a first LED controller.

The first pulse generator generates a pulse at a predetermined period.

At this time, the generated pulse is supplied to a first A / D (Analog-to-Digital) converter and a first LED controller to be used as a synchronization pulse. The synchronizing pulse is transmitted to the receiver by modulating the output light of the first LED lamp through the current drive circuit.

The first analog-to-digital (A / D) converter A / D converts an analog input signal to be transmitted and generates a non-return-to-zero (NRZ) data bit string to be transmitted to a first LED controller .

The first LED control unit converts NRZ data received from the first A / D converter into a high-to-low signal corresponding to "1" in each bit time, and "0" to-high ", modulates the output light of the first LED lamp through the current drive circuit, and transmits the modulated light to the socket interface forming unit through the socket-grounded data transmission interface forming unit to the first LED lamp.

That is, when the code is converted such that the time occupied by the High state and the time occupied by the Low state within one bit time are each set to be 50%, the average light of the first LED lamp The power is always kept constant.

As a result, in the visible light communication, the first LED lamp does not cause a flicker and maintains a constant illumination state.

In the visible light communication, the average optical power output from the first LED lamp is expressed by the following equation (1).

Here, P ₁ (t) represents the light output of the first LED lamp modulated with the synchronizing pulse. T denotes the period of the pulse,? ₁ denotes the pulse width, and P _{1 , m} denotes the amplitude of the pulse.

Then, the optical output of the first LED lamp modulated with the data bits for transmitting the multi-data signal through the visible light communication is operated as follows.

That is, if the bit stream is sequentially transmitted in the order from left to right within one cycle T and the 8-bit transmission data is set to "00010001" as an example, "0" is "low-to-high" And "1" is changed to "high-to-low". When one bit time is τ ₂ , the high state and the low state in each bit occupy 0.5 ㅧ τ ₂ .

Τ _s is the time at which data transmission is stopped to perform the A / D conversion process in the first LED lamp and the D / A conversion process in the receiver (eg, image sensor) of the smart device, The duration of the sync pulse is set shorter than this time.

And the amplitude of the data bit is P _{2 ,} m, the average optical power radiated from the first LED lamp is expressed by the following equation (2).

The socket interface forming unit 113c forms a Vdd ground terminal, a ground terminal, and a data connection terminal on one side of the female thread of the socket support so as to be paired with the data transfer interface forming unit so that the paired data transfer interface forming unit is grounded And transmits the multi-data signal received from the multi-control module to the data transfer interface.

8, a plurality of Vdd ground terminals and ground terminals formed on the second socket of male thread are grounded to a plurality of Vdd ground terminals and ground terminals formed on the first socket of the female thread, The signal at the time of grounding is set to "1 ", and the signal at the time of no grounding is set to" 0 ", so that the interface between the hard socket type interface forming unit and the data transfer interface forming unit is controlled.

As shown in FIG. 6, the first transceiver 113d is formed in a ring-like structure between the socket guide head portion of the first illuminator main body and the socket supporter, so that the neighboring another smart LED illuminator and the near- .

In addition, the first smart LED data control module 113 according to the present invention includes a socket forming unit that forms a socket branch.

Wherein the socket branch face forming portion is formed with at least one female threaded socket in the socket support of the first luminaire body so as to additionally set an identification ID each time one or more female threaded sockets branch, When the data transfer interface forming unit is grounded to the socket, the multi data signal transmitted from the multi control module is transmitted to the data transfer interface forming unit.

[ Luminaire packaged type VLC Module 120)

The package type VLC module 120 includes a LED streetlight lamp cover structure and an LED fluorescent lamp lid cover structure. The lamp module is formed as a package module on one side of the inner space of the lamp cover to generate visible light communication through LED light, And transmits and receives multi data signals.

As shown in FIG. 9, the second illuminator main body 121, the second LED lamp 122, and the second smart LED data control module 123 are configured.

First, the second illuminating device main body 121 according to the present invention will be described.

The second illuminator main body 121 is composed of a lamp cover and protects and supports each device from external pressure.

As shown in Fig. 12, it may be constituted by a streetlight lamp lid cover 121a for a car or a street lamp lid cover 121b for a street lamp as shown in Fig. 13, or as shown in Fig. 14 And a lighting lamp cover 121c for walking.

Second, the second LED lamp according to the present invention will be described.

The second LED lamp 122 is positioned at one side of the lower surface of the luminaire cover of the second illuminator main body and is driven according to a control signal of the second smart LED data control module to emit LED light.

As shown in FIG. 10, this is constituted by a second transparent diffusion plate 122a and a second LED module 122b.

The second transparent diffusion plate 122a has a rectangular or elliptical structure, And diffuses light generated from the LED module to the outside to emit light.

The second LED module 122b is located in a space inside the first transparent diffusion plate and is driven according to the multi data signal transmitted from the second smart LED data control module to transmit the LED light to the first transparent diffusion plate do.

It consists of visible light LEDs all having the same characteristics.

Among them, LED 1 transmits a synchronous pulse and LED 2 is used to transmit data.

Third, the second smart LED data control module 123 according to the present invention will be described.

The second smart LED data control module 123 is located in the inner space of the first luminaire main body and controls the second LED lamp according to the control signal of the multi data signal transmitted from the control server, Transmits the multi-data signal to a nearby smart device, and connects the neighboring smart LED lighting device to a nearby wired / wireless communication network to perform bidirectional data communication.

11, the second power supply unit 123a, the second multi control module 123b, and the second transmission / reception unit 123c.

Here, the short-range wired / wireless communication network is composed of visible light, RF, Zigbee, Bluetooth, and a wired network.

The second power supply unit 123a is located on one side of the side of the luminaire cover of the second illuminator main body, and receives power from the electric line to supply power to each device.

The second multi control module 123b is installed in a space inside the luminaire cover of the second illuminator main body and controls the second LED module to transmit the multi data signal to the smart device located near by the visible light communication, It connects with other smart LED lighting fixtures to the near-by wired / wireless communication network and provides bi-directional data communication.

15, the second power control module 123b-1, the second data reception control module 123b-2, the second visible light transmission / reception module 123b-3, the second near- Module 123b-4, and a second LED control driver module 123b-5.

Here, the short-range wired / wireless communication network is composed of visible light, RF, Zigbee, Bluetooth, and a wired network.

The second power control module 123b-1 controls the power supplied through the second power connection part and supplies the power to each device.

It consists of a constant voltage regulator IC.

The constant-voltage regulator IC converts the input voltage into a constant voltage suitable for each device.

The second data reception control module 123b-2 receives the multi-control data through the wired / wireless communication with the control server and transmits the multi-control data to the second visible light transmission / reception module.

Here, wired / wireless communication is composed of wired communication composed of PLC (Power Line Communication), RS232 / RS485 / RS422, and wireless communication composed of Zigbee communication, infrared communication, and Bluetooth communication.

The second visible light transmitting / receiving module 123b-3 is driven according to the control signal of the second data receiving control module to transmit the multi data signal to the second LED control driver module 123b-5, And transmits and receives a multi-data signal to and from a smart device located near by using visible light communication.

This is composed of a second visible light transmitter and a second visible light receiver.

The second visible light transmitter transmits the multi data signal to the second LED control driver module and transmits the multi data signal to the smart device located near by the visible light communication generated in the second LED lamp.

The second visible light receiver receives a response data signal corresponding to the multi-data signal transmitted from the smart device located near by visible light communication through visible light communication.

The second local area network zone forming interface module 123b-4 forms a local area network with neighboring smart devices and smart LED lighting devices through the wireless connection of the second transceiver unit, thereby transmitting and receiving multi data signals.

The second LED control driver module 123b-5 receives the multi-data signal from the second visible light transmission / reception module 123b-3 and controls the second LED lamp.

It consists of a second pulse generator, a second A / D (Analog-to-Digital) converter, and a second LED controller.

The second pulse generator generates a pulse at a predetermined period.

At this time, the generated pulse is supplied to a second A / D (Analog-to-Digital) converter and a second LED controller to be used as a synchronization pulse. The synchronizing pulse is transmitted to the receiver by modulating the output light of the second LED lamp through the current drive circuit.

The second analog-to-digital (A / D) converter A / D converts an analog input signal to be transmitted and generates a non-return-to-zero (NRZ) data bit string to the second LED controller .

The second LED control unit converts NRZ data received from the second A / D converter into a high-to-low signal corresponding to "1" in each bit time, "0" to-high ", modulates the output light of the second LED lamp through the current drive circuit, and transmits the modulated output light to the second LED lamp through the electric line.

The second transceiver 123c protrudes from one side of the luminaire cover of the second luminaire main body and serves to connect to another neighboring smart LED luminaire with a nearby wired / wireless communication network.

Next, the control server 200 according to the present invention will be described.

The control server 200 is connected to a smart LED lighting device and a remote wired / wireless communication network, and controls the operation of the smart LED lighting device.

It consists of a PC or tablet.

The control server 200 is connected to a plurality of smart LED lighting devices located in a grouped visible light transmitting / receiving local zone in a state where the visible light transmitting / receiving local zones are grouped by location and space, : 1, it sets the unique visible light ID data communication signal including the location information of the positioning point through the remote wired / wireless communication network, adjusts the brightness of the smart LED lighting device according to the purpose and environment, And then displays the smart LED lighting fixture in which the failure has occurred on the indoor map screen of the smart device.

Hereinafter, a specific operation of the apparatus for transmitting a multi-data signal through the smart VLC lighting apparatus according to the present invention will be described.

First, in the control server 200, the visible light transmitting / receiving local zones are grouped by location and space, and are connected to a plurality of smart LED lighting apparatuses located in the grouped visible light transmitting / receiving local zone, And establishes a unique visible light ID data communication signal including position information of the positioning point at a 1: 1 through a remote wired / wireless communication network.

Next, the control server 200 transmits the multi data signal to the smart LED lighting device connected to the remote wired / wireless communication network.

Next, as shown in FIG. 16, the smart LED lighting apparatus 100 is driven in accordance with the control signal of the control server to transmit a multi-data signal through visible light communication to a smart device located in a short distance, And receives a corresponding response data signal from the smart device.

Next, the smart LED lighting apparatus 100 is driven according to a control signal of the control server, and is connected to another neighboring smart LED lighting apparatus through a local wired / wireless communication network to transmit / receive multi data signals while performing bidirectional data communication.

Finally, the control server checks whether there is a malfunction in the smart LED lighting fixture formed with the visible light transmission / reception local zone, and then displays the smart LED lighting fixture with the failure on the indoor map screen of the smart device.

Hereinafter, a concrete operation of the socket VLC module 110 and the lamp packaged VLC module 120 among the multi data signal transmission devices using the smart VLC lighting device according to the present invention will be described.

[Socket type VLC Module 110)

First, the first power supply unit 113a receives power from a wired line and supplies power to each device.

This controls the power supplied from the first power control module 113b-1 of the first multi control module 113b through the first power connection part and supplies the power to each device.

Next, the first data reception control module receives the multi-control data through the wired / wireless communication with the control server and transmits the multi control data to the first visible light transmission / reception module.

Next, the first visible light transmission / reception module 113b-3 receives the multi-control data from the first data reception control module and receives the Vdd ground terminal, the ground terminal, and the data connection of the socket interface forming unit paired with the data transfer interface forming unit When the terminals are fused and grounded, the LED socket and the socket support are recognized as one customized set, and the multi-data signal is transmitted to the first LED control driver module 113b-5.

Next, the mobile terminal 100 transmits and receives the multi-data signal through the first transmission / reception unit 113d by connecting the neighboring smart LED lighting apparatus to the nearby wired / wireless communication network.

Next, the first LED control driver module 113b-5 receives the multi-data signal from the first visible light transmitting / receiving module 113b-3 and controls the first LED lamp.

Next, the multi-data signal is transmitted through the visible light communication from the first LED lamp toward the smart device located in the vicinity.

Finally, the first visible light transmitting / receiving module 113b-3 receives the response data signal corresponding to the multi-data signal transmitted from the smart device located near by the visible light communication.

[ Luminaire packaged type VLC Module 120)

First, the second power supply unit 123a receives power from the wired line, and supplies power to each device.

The second power control module 123b-1 of the first multi-control module 113b controls the power supplied through the second power connection part and supplies the power to each device.

Next, the second data reception control module 123b-2 receives the multi-control data through the wired / wireless communication with the control server and transfers the multi-control data to the second visible light transmission / reception module.

17, the second visible light transmitting / receiving module 123b-3 is driven in accordance with a control signal of the second data receiving control module to form a visible light communication network with a neighboring smart device, .

Next, as shown in FIG. 17, the smart device and the smart LED lighting device neighboring to each other and the local network zone are formed in the second local area network zone forming interface module 123b-4 through the wireless connection of the second transmitting and receiving part, And transmits / receives a data signal.

Next, the second LED control driver module 123b-5 receives the multi-data signal from the second visible light transmitting / receiving module 123b-3 and controls the second LED lamp.

Next, as shown in FIG. 17, the second LED lamp transmits the multi-data signal through the visible light communication to the smart device located in the vicinity.

In addition, the second visible light transmitting / receiving module 123b-3 receives the response data signal corresponding to the multi-data signal transmitted from the smart device located near by the visible light communication.

Hereinafter, a data line structure and a method for enabling data transmission between a lighting socket and a luminaire included in the smart LED lighting fixture 100 according to the present invention will be described.

The data line structure and method for enabling data transmission between the lighting socket and the luminaire described in this embodiment may be the same or very similar to those described above. Accordingly, in FIGS. 18 and 19, like reference numerals can be given to the components described above, and explanations thereof will be partially omitted in order to avoid redundant description.

18 is a perspective view of a data line structure that enables data transmission between the lighting socket and the luminaire according to the present invention, and Fig. 19 is a cross-sectional view illustrating the connection structure between the lighting socket and the luminaire shown in Fig. 18 .

18 and 19, a smart LED lighting fixture 100 having a data line structure that enables data transmission between a lighting socket and a luminaire includes the socket type VLC module 110a, the lamp packaged VLC module 120a, .

6, the socket type VLC module 110a and the lamp packaged VLC module 120a support a method of adding a separate communication control device between the existing socket and the bulb, Can be implemented as a separate apparatus. For example, the lighting socket 119 of the socket type VLC module 110a and the light bulb 129 (e.g., an LED lamp capable of communicating with the LED lighting) of the lamp packaged VLC module 120a are provided with a communication control device (Hereinafter, referred to as a 'removable interface 300') for easy connection with a smart LED data control module (hereinafter, referred to as a 'smart LED data control module').

The detachable interface 300 of the present invention can be configured to accommodate existing socket standards (e. G., E26, etc.) without requiring modifications to the structure of the bulb socket, And communication data lines 355 and 356.

The detachable interface 300 is disposed at the opposite end of the diffuser plate 122c of the bulb 129 for the luminaire of the packaged VLC module 120a of the luminaire and has a light bulb portion 330 ).

The detachable interface 300 includes a tip portion 340 disposed at an end surface of the lamp stem 330 and formed to be insulated from the lamp stem 330.

The detachable interface 300 includes a DC contact portion (not shown) formed between the lamp stopper 330 and the body of the lamp for lamp 129 and formed in a circular ring shape so as to be insulated from the lamp stopper 330 320). The circular ring shape can continue to be connected even if the rotation is performed.

The detachable interface 300 includes a ground portion 310 spaced from the DC contact portion 320 toward the diffusion plate 122c and formed in a circular ring shape to be insulated from the DC contact portion 320.

The detachable interface 300 includes an outer thread 119a that is formed to protrude from the outer surface facing the bulb 129 for the luminaire and can be screwed into the mounting hole 11 of the mounting structure 10 such as a wall, And a metal tube portion 331 disposed on the inner circumferential surface of the formed lighting socket 119 and having a female thread corresponding to the socket standard and connected to one side of the AC power source.

The detachable interface 300 includes an elastic seat portion 341 connected to the other side power line of the AC power source and provided at the center of the inner end surface of the lighting socket 119.

The lamp stopper 330 can be screwed into the metal tube 331 in the same manner as a general lamp installation method. At this time, the elastic seating portion 341 contacts the tip portion 340 of the bulb 129 for the luminaire. As a result, the AC power can be supplied to the bulb 129 for the luminaire.

The DC power supply or data communication is performed through the data lines 355 and 356 for DC communication of the detachable interface 300.

The detachable interface 300 includes data lines 355 and 356 for DC communication between the socket type VLC module 110a and the lamp packaged VLC module 120a. The DC communication data lines 355 and 356 are connected to a pair of extension terminals 311 and 321 from a printed circuit board 123d for smart LED data control module mounted inside the socket VLC module 110a.

Here, the extension terminals 311 and 321 are formed on one side of the data lines 355 and 356 for DC communication, and are formed as resilient pieces grounded on the ground terminal of the printed circuit board 123d for the smart LED data control module, And the other end of the DC communication data lines 355 and 356 is connected to the DC 5V power terminal of the printed circuit board 123d for the smart LED data control module A second extension terminal 321 connected to the first extension terminal 311 and having a length longer than a length of the first extension terminal 311 and contacting the DC contact portion 320 of the bulb 129 for a lamp, . The data line 355 on one side of the data lines 355 and 356 for DC communication is used as an actual data line and the data line 356 on the other side is used as a DC ground so that stable communication with the communication control device It can be possible.

Communication between the socket type VLC module 110a and the lamp packaged VLC module 120a can be performed separately from the AC power supply through the DC communication data lines 355 and 356. [

Also, the lamp packaged VLC module 120a can be easily replaced.

Thus, the socket standard of the present invention can be configured by adding a DC communication data line 355, 356 for communication while using a standard socket as it is.

Since the ground portion 310, the DC contact portion 320, the lamp vertex portion 330, and the tip end portion 340 are insulated with an insulating material, the AC power source and the DC power source can be separated from each other.

The ring-shaped DC contact portion 320 and the ground portion 310 in which the end portions of the first extension terminal 311 and the second extension terminal 321 are in contact with each other also have separate cover portions ). ≪ / RTI >

Also, a method for enabling data transmission between the illumination socket and the luminaire of the present invention is accomplished by screwing the luminaire 129 of the luminaire packaged VLC module 120a to the illumination socket 119 of the socket VLC module 110a .

A method for enabling data transmission between the illumination socket and the luminaire of the present invention is such that in the screwing stage the tip 340 of the luminaire bulb 129 contacts the resilient seating portion 341 of the illumination socket 119 And the lamp star portion 330 of the lamp bulb 129 contacts the metal tube portion 331 of the lighting socket 119 to energize the AC power source.

A method for enabling data transmission between the illumination socket and the luminaire of the present invention is characterized in that the DC contact portion 320 of the lamp 129 for the luminaire is moved in the process of screwing, And a first line connecting step of contacting the second extending terminal 321 of the lighting socket 119.

Also, a method for enabling data transmission between the lighting socket and the luminaire of the present invention is such that after the first line connecting step, the subsequent threading causes the ground portion 310 of the luminaire bulb 129 to be connected to the lighting socket 119 And a second line connecting step of contacting the first extension terminal 311 of the first extension terminal.

With this method, it is possible to provide a data line structure, that is, a data line structure for an illumination bulb, which enables data transmission between a lighting socket and a luminaire enabling communication while maintaining the standard for an existing socket.

In addition, according to the present invention, the lamp 129 for a luminaire can be used for illumination, as well as on / off control or color control via radio according to the configuration included in the communication controller, (ID), which is built in or communicated through communication, and receives location information and peripheral information through the transmitted data, and is applicable to various indoor location-based services.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the scope of the present invention, but are intended to be illustrative, and the scope of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas which are equivalent or equivalent thereto should be interpreted as being included in the scope of the present invention.

1: Multi-data signal transmission device 100: Smart LED lighting device
110: socket type VLC module 111: first illuminator main body
112: first LED lamp 113: first smart LED data control module
120: lamp package type VLC module 200: control server
300: detachable interface 310: ground part
320: DC contact part 330:
340: leading edge 355,356: data line for DC communication

Claims (13)

A smart LED lighting device which is driven in accordance with a control signal of the control server to transmit a multi data signal through a visible light communication to a smart device located in the vicinity and to be connected to another neighboring smart LED lighting device through a wired / A mechanism 100;
A control server (200) connected to the smart LED lighting fixture (100) through a remote wired / wireless communication network to control operation of the smart LED lighting fixture;
When an AC power source and a DC power source are separately connected to each other for connection between the lighting socket 119 of the socket type VLC module 110a of the smart LED lighting fixture 100 and the lamp 129 for the lamp of the lamp package type VLC module 120a And a detachable interface (300) for connecting the multi-data signal transmission device
A data line structure that enables data transmission between a lighting socket and a luminaire.
The method of claim 1, wherein the smart LED lighting fixture (100)
A socket type VLC module 110 for forming a data communication interface by pairing with a socket thread and generating visible light communication through LED light emission to transmit and receive a multi data signal to and from a neighboring smart device,
LED streetlight luminaire cover structure and LED fluorescent lamp lid cover structure, which is formed as a package module on one side of the inner space of the luminaire cover, and generates visible light communication through LED light to send and receive multi data signals to neighboring smart devices. A module 120
A data line structure that enables data transmission between a lighting socket and a luminaire.
The method of claim 2, wherein the socket-type VLC module (110)
A first illuminating device main body 111 for protecting and supporting each device from external pressure,
And is driven in accordance with the multi data signal of the first smart LED data control module so as to emit LED light and transmit the multi data information to the neighboring another smart device through the visible light communication, A first LED lamp 112 for transmitting and receiving the light,
The first LED lamp is controlled in accordance with a control signal transmitted from the control server to transmit the multi data signal to the smart device located near by the visible light communication, And a first smart LED data control module 113 which is connected to other smart LED lighting fixtures via a local wired / wireless communication network and performs bidirectional data communication
A data line structure that enables data transmission between a lighting socket and a luminaire.
4. The system of claim 3, wherein the first smart LED data control module (113)
A first power supply unit 113a located at a rear end side of the socket support and receiving power from the electric line and supplying power to each device,
A pin socket type detachable structure in a base inner space between the socket support and the first power supply unit to transmit the multi data signal toward the smart device located near by the visible light communication generated in the first LED module, A first multi-control module 113b for connecting to another smart LED lighting fixture via a local wired / wireless communication network for bidirectional data communication,
A Vdd ground terminal, a ground terminal, and a data connection terminal are formed on one side of the female thread of the socket support so as to be paired with the data transfer interface forming part, and when the socket of the paired data transfer interface forming part is grounded, A socket interface forming unit 113c for transferring the data to the data transfer interface,
And a first transmission / reception unit 113d formed in a ring-like structure between the socket guide head unit of the first lighting apparatus main body and the socket support and connecting to another neighboring smart LED lighting fixture through a local wired / wireless communication network
A data line structure that enables data transmission between a lighting socket and a luminaire.
4. The system of claim 3, wherein the first smart LED data control module (113)
One or more female threaded sockets are formed in the socket support of the first illuminator body so that the identification ID is further set each time one or more female threaded sockets are branched, And a face forming part that is a socket branch for transmitting the multi data signal received from the multi control module to the data transfer interface forming part
A data line structure that enables data transmission between a lighting socket and a luminaire.
5. The apparatus of claim 4, wherein the first multi-control module (113b)
A first power control module 113b-1 for controlling the power supplied through the first power connection unit and supplying the power to each device,
A first data reception control module 113b-2 for receiving the multi-control data through the wired / wireless communication with the control server and transmitting the multi-control data to the first visible light transmission / reception module,
When the multi-control data is received from the first data reception control module and the Vdd ground terminal, the ground terminal, and the data connection terminal of the socket interface forming unit paired with the data transfer interface forming unit are grounded by fitting, the LED socket and the socket support And transmits the multi data signal to the first LED control driver module 113b-5. Then, the first LED lamp is controlled to transmit / receive the multi data signal to / from the smart device located near by the visible light communication A first visible light transmission / reception module 113b-3,
A first local area network zone formation interface module (113b-4) for transmitting / receiving multi data signals by forming a local area network with neighboring smart devices and smart LED lighting devices through a wireless connection of the first transceiver unit,
And a first LED control driver module (113b-5) for receiving the multi-data signal from the first visible light transmitting / receiving module (113b-3) and controlling the first LED lamp
A data line structure that enables data transmission between a lighting socket and a luminaire.
[3] The apparatus of claim 2, wherein the lamp packaged VLC module (120)
A second illuminator main body 121 formed of a lamp cover for protecting and supporting each device from external pressure,
A second LED lamp 122 positioned at one side of the lower surface of the luminaire cover of the second illuminator main body and driven according to a control signal of the second smart LED data control module to emit LED light,
The second LED lamp is controlled according to the control signal of the multi data signal transmitted from the control server to transmit the multi data signal to the smart device located near by the visible light communication And a second smart LED data control module 123 for connecting to another neighboring smart LED lighting device via a local wired / wireless communication network for bi-directional data communication
A data line structure that enables data transmission between a lighting socket and a luminaire.
8. The method of claim 7, wherein the second smart LED data control module (123)
A second power supply unit 123a located on one side of the side of the luminaire cover of the second lighting apparatus main body and supplying power to each device through the wired line,
The second LED module is installed in a space inside the luminaire cover of the second lighting device body and transmits the multi data signal to the smart device located near by the visible light communication through the second LED module, A second multi-control module 123b for performing bidirectional data communication by connecting the first multi-
And a second transmitting and receiving part 123c protruding from one side of the outside of the luminaire cover of the second illuminating device main body and connecting the other smart LED lighting device to the nearby wired and wireless communication network
A data line structure that enables data transmission between a lighting socket and a luminaire.
9. The apparatus of claim 8, wherein the second multi-control module (123b)
A second power control module 123b-1 for controlling the power supplied through the second power connection unit and supplying the power to each device,
A second data reception control module 123b-2 for receiving the multi-control data through the wired / wireless communication with the control server and transmitting the multi-control data to the second visible light transmission / reception module,
Data signal is transmitted to the second LED control driver module 123b-5 in accordance with the control signal of the second data reception control module, and the second LED lamp is controlled to transmit the multi data signal to the smart device A second visible light transmission / reception module 123b-3 for transmitting / receiving the multi data signal,
A second local area network zone forming interface module 123b-4 for transmitting and receiving a multi data signal by forming a local area network with a smart device and a smart LED lighting device neighboring through a wireless connection of the second transceiver,
And a second LED control driver module 123b-5 that receives the multi-data signal from the second visible light transmitting / receiving module 123b-3 and controls the second LED lamp
A data line structure that enables data transmission between a lighting socket and a luminaire.
The method of claim 1, wherein the removable interface (300)
A lamp stopper 330 disposed at an opposite end of the diffuser plate 122c of the bulb 129 for the lamp of the lamp packaged VLC module 120a and having a male screw on the outer circumferential surface corresponding to the socket standard;
A tip portion 340 disposed at an end surface of the lamp vertex 330 and formed to be insulated from the lamp vertex 330;
A DC contact part 320 disposed between the lamp light part 330 and the lamp body 129 and formed in a circular ring shape so as to be insulated from the lamp light part 330; And
And a ground portion 310 spaced from the DC contact portion 320 toward the diffusion plate 122c and formed in a circular ring shape so as to be insulated from the DC contact portion 320
A data line structure that enables data transmission between a lighting socket and a luminaire.
11. The system of claim 10, wherein the removable interface (300)
A lighting socket (not shown) formed to protrude from the outer surface facing the bulb 129 for the lamp and having an outer thread 119a that can be screwed into the installation hole 11 of the installation structure 10 such as a wall, a ceiling, A metal tube portion 331 disposed on an inner circumferential surface of the socket body 119 and having a female thread corresponding to the socket standard and connected to one side of the AC power source;
An elastic seat part (341) connected to the other electric wire of the AC power source and provided at the center of the inner end surface of the lighting socket (119); And
A printed circuit board for a smart LED data control module mounted inside the socket type VLC module 110a as the data communication lines 355 and 356 for DC communication between the socket VLC module 110a and the lamp packaged VLC module 120a, And a pair of extension terminals 311 and 321 connected to the connection terminal 123d
A data line structure that enables data transmission between a lighting socket and a luminaire.
12. The apparatus of claim 11, wherein the extension terminals (311, 321)
And is formed as a resilient piece grounded to the ground terminal of the printed circuit board 123d for the smart LED data control module and the ground portion 310 of the lamp unit A first extension terminal 311 contacting the first extension terminal 311,
Is connected to the DC 5V power supply terminal of the printed circuit board 123d for the smart LED data control module and has a length longer than the length of the first extension terminal 311 Includes a second extension terminal (321) formed in an elastic shape and contacting the DC contact portion (320) of the bulb (129) for the luminaire
A data line structure that enables data transmission between a lighting socket and a luminaire.
A control server 200 for controlling the operation of the smart LED lighting fixture 100 and a lighting socket 119 of the socket type VLC module 110a of the smart LED lighting fixture 100. [ And a lamp unit (129) of a lamp packaged VLC module (120a), the method comprising the steps of:
Screwing the bulb 129 of the luminaire packaged VLC module 120a to the lighting socket 119 of the socket VLC module 110a;
The tip portion 340 of the bulb 129 of the bulb contacts the resilient seating portion 341 of the lighting socket 119 and the lamp bulb portion 330 of the bulb 129 Contacting the metal tube portion (331) of the socket (119) to energize the AC power supply;
The DC contact portion 320 of the bulb 129 for the lamp is brought into contact with the second extension terminal 321 of the lighting socket 119 during the screwing step or during the end of the screwing step 1 line connection step; And
After the first line connecting step, the second line connecting step in which the ground portion 310 of the bulb 129 for the luminaire contacts the first extending terminal 311 of the lighting socket 119 due to the subsequent screwing, Including;
A method for enabling data transmission between a lighting socket and a luminaire.

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