WO2018004381A1

WO2018004381A1 - Devices and methods for optical transmission of data in an led screen

Info

Publication number: WO2018004381A1
Application number: PCT/RU2017/000009
Authority: WO
Inventors: Алексей Викторович ШТОРМ
Original assignee: Алексей Викторович ШТОРМ
Priority date: 2016-06-28
Filing date: 2017-01-11
Publication date: 2018-01-04
Also published as: RU2628230C1

Abstract

The invention relates to devices for presenting changing information material on display devices and can be used for producing devices for showing an outdoor video commercial. The technical result consists of simplifying the assembly of LED screens, increasing the reliability with which data is transmitted to LED modules and reducing the effects of electromagnetic interference on the signal being transmitted. An LED screen, using optical data transmission along fibre optic guides, consists of segments. Each segment of the LED screen comprises a video controller and several LED modules, positioned along the length of fibre optic guides. The LED modules and the video controllers have optical transmitter-receivers, which are joined to each other by the fibre optic guides. Data is transmitted from a video controller to the LED modules via the optical transmitter-receivers, along the fibre optic guides.

Description

Devices and methods for optical data transmission in the LED screen

The group of inventions relates to the field of devices for the presentation of changing information material, as well as to the field of devices or schemes for controlling indicator devices and can be used to create devices for the demonstration of outdoor video advertising.

From the current level of technology known Method and device

electro-optic connection of video wall modules (EP0604719A1, G06F 3/14, G09F 9/35, H04N 9/12, 28.12.1992). The video wall device is characterized by the fact that each video module incorporates two optical

transceiver. Data is transmitted from the central controller via video modules sequentially. Video modules perform the function

repeaters, transmitting a signal along the chain. The optical signal enters the optical receiver of the video module, is converted into an electrical signal, then again is converted into an optical signal and transmitted through the optical transmitter to the next video module. Disadvantages: two transceivers are installed on each video module, which increases the cost and reduces reliability; data is transmitted through a chain of video modules, which reduces the reliability of the video wall: when a single video module fails, all video modules that follow it in the chain stop working; double

the conversion of the optical signal into electrical and back in each video module reduces the reliability and speed of information transfer;

the increase in the time delay of signal propagation after each video module in the chain reduces the overall bandwidth of the communication line; due to the external location of the data transmission channel, it is necessary to contend with external optical interference; Due to the external location of the data transmission channel, it is necessary to combat the pollution of optical

transceivers.

Modern LED screens consist of LED modules that are connected in a line of LED modules in series using flat cables. The signal from the video controller passes through the lines

LED modules connected by cables.

Due to the large length of the connecting lines and high frequencies, various distortions in the transmitted signal are possible; the same distortions appear in the image broadcast by the screen. There is also the problem of the reliability of the LED screen when the LED modules are connected in series. When one of the LED modules fails, the entire chain of LED modules located behind it also stops working.

LED screens due to the large number of external cable connections require a lot of manual assembly operations, which makes it difficult to organize mass automated production.

With optical data transmission from the video controller to the final

LED module has a problem determining the position

LED module inside the LED screen. For the formation of the correct image on the surface of the LED screen

the video controller must have location information

LED modules inside the LED screen.

The tasks that this invention is directed to are: simplifying the assembly of LED screens; improving the reliability of data transmission to LED modules; reducing the influence of electromagnetic interference on the transmitted signal; determining the position of the LED modules inside the LED screen for optical data transmission to the LED modules.

The tasks are solved as follows

The LED screen with optical data transmission over optical fibers consists of one or more segments. Each segment of the LED screen contains at least one video controller (1) and several LED modules (3). LED modules (3) and video controllers (1) contain optical transceivers (2). Optical data transfer between

video controllers (1) and LED modules (3) are carried out through optical transceivers (2), which are combined with the help of light guides (6). The video controller (1) transmits the optical signal to each LED module (3) directly without retransmitting through other

LED modules (3). Optical transceivers (2) contain a light emitter with an optical signal modulator and a light receiver with an optical signal demodulator. Optical transceivers (2) can be made in the form of removable modules that are connected to

video controller (1) and LED modules (3) or as integrated into the printed circuit boards (9) of the LED modules (3) and

video controller (1) electronic components. The light guides (6) may have various shapes and designs: the light guide (6) may be a tube with reflective walls containing holes for accommodating optical transceivers (2); the light guide (6) may be a rod of complex shape made of a transparent material with a high refractive index; the light guide (6) may be a channel with reflective walls, on the open side of which optical transceivers (2) of LED modules (3) are placed; The light guide (6) can is a sheet of a translucent material with a high refractive index.

For LED screens with optical data transmission via optical fibers (6), the positions of the LED modules (3) over the optical fibers (6) can be determined in the following way. The method is based on the weakening

light intensity with increasing distance to the source,

LED modules (3) are placed along the light guide (6), a video controller (1) is placed from one of the ends of the light guide (6). The video controller (1) with the help of the built-in optical transceiver (2) successively measures the intensity of the light flux from the transceivers (2) of each LED module (3), compares the measurement results, and sorts according to the intensity: lower intensity corresponds to the most remote LED module (3 ). Measurement of intensity can be done in various ways: at the time of measuring the intensity, the light emitter of the optical transceiver (2) does not transmit data; Measurement is performed simultaneously with the transmission of a digital signal from the LED module (3) to the video controller (1). Various methods can also be used to control the sequence of measuring the intensity of an optical signal: the controller (1) sends an command via an optical transceiver (2) to one of its known

LED modules (3) in response to which the LED module (3) generates a test signal; the sequence of measuring the intensity of the optical signal of the LED modules (3) is implemented with the help of a lesson

LED modules (3) optical channel, without control from

video controller (1), in this case the LED module number (3) is encoded in the light flux of the emitted signal.

The LED screen with optical data transmission inside the segment housing consists of one or more segments, each segment contains

video controller (7) and several LED modules (3). LED modules (3) and video controllers (7) contain optical transceivers (2). Optical transceivers (2) of the video controller (7) and LED modules (3) are located inside the segment housing (5), which serves as a light guide and a protective screen from external light sources.

Optical data transmission takes place inside the segment housing (5) between the optical transceivers (2) of the video controller (7) and the optical transceivers (2) of the LED modules (3). The segment body (5) is made of an opaque material, which does not allow external optical interference to affect data transmission.

Optical transceivers (2) LED modules (3) and

video controller (7) are arranged in such a way that they have a direct optical connection with each other. The video controller (7) can have a built-in video camera with which it can determine the location of the LED modules (3) inside the segment housing (5). Optical

transceivers (2) of the LED modules (3) and the video controller (7) may not have direct optical communication with each other, in this case the optical signal is transmitted through reflection from the walls of the segment body (5), and the inner surface of the segment body (5) can be covered

reflective coating to more effectively reflect the optical signal and improve data transmission.

For LED screens with optical signal transmission inside the segment housing (5), the position of the LED module (G) inside the segment housing (5) can be determined using a video camera. The video controller (7) is placed inside the segment body (5), opposite the back surface of the LED modules (3), on which the optical

transceivers (2). Video controller (7) via built-in

The transceiver (2) sends to each LED module (3) a command that changes the intensity of the light emitted by the transceiver (2) of this LED module (3). A video camera is embedded in the video controller (7), which photographs the back surface of the LED modules (3), then during the processing of the photo, the position of the current LED module (3) is determined based on the different intensity of its optical transceiver (2) on the intensity of the optical transceivers (2 ) the remaining LED modules (3). At the time of light emission by the transceiver (2) of the selected LED module

(3) transceivers (2) of the remaining LED modules (3) can be turned off or can emit weak light, this will make it easier

recognition of the position of the LED modules (3) using software tools. There is also a way to determine the position of the LED module (3) within a segment using a database. When assembling the segments, the positions of the LED modules (3) with unique identifiers of the LED modules are recorded in the central database. When turned on

video controller (1, 7) requests the LED modules (3) of the segment to have their unique identifiers; if the positions of the LED modules (3) with such unique identifiers are not in the memory of the video controller (1, 7), these positions are requested from the central database and stored in memory video controller (1, 7). When replacing the LED module (3) inside the segment, the video controller (1, 7) checks the list of unique identifiers of the LED modules (3) from the memory and the list of unique identifiers obtained from the LED modules (3) of the segment. If one of the LED modules (3) has changed its unique identifier, then the unique

The identifier of the new LED module (3) is matched with the position of the unique identifier of the missing LED module (3).

Connection to the central database can be done via

The Internet. A query to the central database can be made.

directly from the video controller (1, 7) of the segment or via the screen controller.

Brief Description of the Drawings

In figures 1-2 shows the device of the led module (3).

The LED module (3) consists of a printed circuit board (9), from the front side of which LEDs (4) are soldered, on the back side of which an optical transceiver (2) is placed.

Figures 3-5 depict an LED screen device with optical data transmission over optical fibers. The screen consists of several light guides (6). The LED modules (3) are installed on the optical fibers in such a way that the optical transceivers (2) are located inside the optical fibers (6).

At the bottom of the screen is a video controller (1) with several optical transceivers (2) and a processor (10) that controls the data transfer process. Optical transceivers of the video controller (1) are placed one in each fiber (6). Thus, in each fiber (6), an isolated channel of optical data transmission is formed. During operation of the LED screen, the video controller (1) communicates with the LED modules (3) using light pulses, passing through the light guides (6) from the optical transceivers (2) of the video controller (1) to the optical transceivers (2) of the LED modules (3).

In figures 6-9 shows the device of the LED screen with optical data transmission inside the body of the segment. The screen consists of a segment housing (5), LED modules (3) located on the front surface of the segment housing (5), and a segment cover (8) on which

video controller (7). The video controller (7) includes an optical transceiver (2) and a processor (10) that controls the data transfer process. Optical transceivers (2) of the LED modules (3) are placed inside the segment housing (5), opposite them is the optical transceiver (2) of the video controller (7). During the operation of the LED screen, the video controller (7) communicates with the LED modules (3) using light pulses,

Segments (5) propagating inside the body from optical

transceivers (2) video controller (7) to optical

transceivers (2) LED modules (3).

List of figures

1. LED module, front view.

2. LED module, rear view.

3. Video controller LED screen with multiple optical transceivers.

4. LED screen with optical data transmission over optical fibers, front view.

5. LED screen with optical data transmission over optical fibers, top view.

6. LED screen with optical data transmission inside the segment body, front view.

7. LED screen with optical data transmission inside the segment body, rear view with the cover removed.

8. Segment housing cover with video controller. 9. The device of the LED screen with optical data transmission inside the body segment.

10. Line of LED modules with a light guide in the form of a channel with

reflective walls.

11. Screen segment with a light guide in the form of a sheet of translucent material with a high refractive index.

12. Line of LED modules with a light pipe in the form of a tube with

reflective walls and with holes to accommodate optical transceivers.

13. Segment of the screen with a light guide in the form of a rod of complex shape from

translucent material with a high refractive index.

The list of elements depicted in the figures

1. Video controller with multiple optical transceivers.

2. Optical transceiver.

3. LED module.

4. LED.

5. The body of the LED screen segment.

6. Light tube for optical data transmission.

7. Video controller with optical transceiver.

8. Cover segment of the LED segment.

9. Printed circuit board LED module.

10. The processor.

Device

video controller (1) and LED modules (3) or as

integrated into the printed circuit boards (9) of the LED modules (3) and

video controller (1) electronic components. The light guides (6) may have various shapes and designs: the light guide (6) may be a tube with reflective walls containing holes for accommodating optical transceivers (2); the light guide (6) can be a rod of complex shape made of a translucent material with a high refractive index; the light guide (6) may be a channel with reflective walls, on the open side of which optical transceivers (2) of LED modules (3) are placed; The light guide (6) can is a sheet of a translucent material with a high refractive index.

Optical transceivers (2) LED modules (3) and

transceivers (2) LED modules (3) and video controller (7) may not have direct optical communication with each other, the optical signal in this case is transmitted through reflection from the walls of the segment body (5), and the inner surface of the segment body (5) can be covered

The device is manufactured as follows:

The LED screen with optical data transmission over optical fibers (FIG. 4) consists of segments. The screen segment is a frame with

optical fibers placed on its surface (6), LED modules (3) and video controllers (7). The frame can be made using standard industrial thin sheet metal processing methods (bending, coordinate punching, laser cutting). The frame can be printed on the AOR printer. The frame can also be made of plastic (plastic molding) or composite materials. Long optical fibers (6) in the form of a tube (Fig. 12) or a channel (Fig. 10) can be manufactured by extrusion of aluminum or plastic, if necessary, after extrusion, can

milling to form mounting holes and holes for the placement of optical transceivers (2). A light reflecting coating may be applied to the optical fibers (6). Light guides (6) of

translucent plastic with a large refractive index can have different shapes and different manufacturing methods. The light guide (6) in the form of a translucent sheet (Fig. 11) can be made from a single sheet by laser cutting plastic. The light guide (6) in the form of a translucent rod of complex shape (Fig. 13) can be made by plastic molding or cut from a single translucent sheet by laser cutting.

The LED screen with optical data transmission inside the segment body (Fig. 6) consists of segments. Each segment has a housing (5), on the front surface of which LED modules (3) are placed, inside the segment housing (5) there is a video controller (7). Behind the body of the segment is closed with a lid (8). The segment body (5) and the segment cover (8) can be manufactured using standard industrial thin sheet metal processing methods (bending, coordinate punching, laser cutting).

The body of the segment (5) can be printed on the AOR printer. The body of the segment (5) can also be made of plastic by injection molding.

LED modules (3) are printed circuit boards (9) with

LEDs soldered in front (4) and other electronic elements .

soldered in the back. LED modules (3) are manufactured using standard industrial electronics assembly methods. The LED modules (3) can be capped to protect against moisture and closed on the front side with perforated plastic covers to protect the LED modules from damage. Video controllers (7) are electronic boards that are manufactured using standard industrial electronics assembly methods.

The operation of the device is as follows:

light intensity with increasing distance to the source,

LED modules (3) optical channel, without control from

For LED screens with optical signal transmission inside the segment housing (5), the position of the LED module (G) inside the segment housing (5) can be determined using a video camera. The video controller (7) is placed inside the segment body (5), opposite the back surface of the LED modules (3), on which the optical transceivers (2). The video controller (7), via the built-in transceiver (2), sends to each LED module (3) a command that changes the intensity of the light emitted by the transceiver (2) of this LED module (3). A video camera is embedded in the video controller (7), which photographs the back surface of the LED modules (3), then during the processing of the photo, the position of the current LED module (3) is determined based on the different intensity of its optical transceiver (2) on the intensity of the optical transceivers (2 ) the remaining LED modules (3). At the time of light emission by the transceiver (2) of the selected LED module (3), the transceivers (2) of the remaining LED modules (3) can be turned off or can emit weak light, this will allow

recognition of the position of the LED modules (3) using software tools.

There is also a way to determine the position of the LED module (3) within a segment using a database. When assembling the segments, the positions of the LED modules (3) with unique identifiers of the LED modules are recorded in the central database. When turned on

video controller (1, 7) requests the LED modules (3) of the segment to have their unique identifiers; if the positions of the LED modules (3) with such unique identifiers are not in the memory of the video controller (1, 7), these positions are requested from the central database and stored in memory video controller (1, 7). When replacing the LED module (3) within the segment, the video controller (1, 7) checks the list of unique identifiers of the LED modules (3) from the memory and the list of unique identifiers received from the LED modules (3) of the segment. If one of the LED modules (3) has changed its unique identifier, then the unique identifier of the new LED module (3) is matched with the position of the unique identifier of the missing LED module (3).

Connection to the central database can be done via

The Internet. A query to the central database can be made.

Claims

Formula

1. The device of the LED screen with optical data transmission

LED modules are characterized by the fact that the LED screen consists of one or more segments, each segment contains one or more video controllers and one or more LED modules, each LED module and each video controller contains one or more optical transceivers, optical transceivers of the video controller and LED modules they are combined by one or more optical fibers, through which optical data transmission between optical transceivers and video monitors is performed Oller and optical transceivers LED modules.

2. The device of the LED screen with optical data transmission

LED modules for optical fiber according to claim 1 is characterized by the fact that the light guide is a pipe with reflective walls,

containing openings for accommodating optical transceivers.

3. LED display device with optical data transmission

LED modules for optical fibers according to claim 1 is characterized by the fact that the fiber is a rod of complex shape, made of a translucent material with a high refractive index.

4. LED display device with optical data transmission

LED modules for optical fiber according to claim 1 is characterized by the fact that the optical fiber is a channel with reflective walls, on the open side of which optical optical transceivers of LED modules are placed.

5. The device of the LED screen with optical data transmission

LED modules for optical fiber according to claim 1 is characterized by the fact that the fiber is a sheet of translucent material with a large refractive index.

6. The device led screen with optical data transmission

LED modules for optical fiber according to claim 1 is characterized in that the optical transceiver contains a light emitter with an optical signal modulator and a light receiver with an optical signal demodulator.

7. The device led screen with optical data transmission

LED modules on fiber according to claim 1 is characterized by the fact that Optical transceivers are made in the form of removable modules that connect to the video controller and LED modules.

8. The device led screen with optical data transmission

to light-emitting diode modules in accordance with clause 1, characterized by the fact that optical transceivers are implemented as LED modules integrated into printed circuit boards and a video controller of electronic units.

9. The device led screen with optical data transmission

LED modules by fiber according to claim 1 is characterized by the fact that the video controller transmits an optical signal to each LED module directly, without retransmission through other LED modules.

10. LED display device with optical data transmission

LED modules inside the segment housing are characterized in that the LED screen consists of one or more segments, each segment contains a video controller and one or more LED modules, LED modules and video controllers contain one or more

optical transceivers, optical transceivers

video controller and LED modules are located inside the segment housing, which performs the functions of the light guide and protective screen from external light sources, inside the segment housing between the optical transceivers of the video controller and optical

Transceivers of LED modules provide optical data transmission.

11. The device led screen with optical data transmission

LED modules inside the segment housing according to claim 10 is characterized by the fact that the inner surface of the segment housing is covered with a reflective coating to more effectively reflect the optical signal and improve data transmission.

12. The device of the LED screen with optical data transmission to the LED modules inside the chassis of the segment according to claim 10 is characterized in that the optical transceivers of the LED modules and the video controller do not have direct optical communication with each other, the optical signal

transmitted through reflection from the hull walls of the segment.

13. The device of the LED screen with optical data transmission to LED modules inside the segment housing according to claim 10 is characterized by the fact that the segment housing is made of an opaque material, which does not allow external optical interference to affect data transmission.

14. The device of the LED screen with optical data transmission to the LED modules inside the segment housing according to claim 10 is characterized in that the optical transceivers of the LED modules and the video controller are arranged in such a way that they have a direct optical connection with each other.

15. The device of the LED screen with optical data transmission to LED modules inside the segment housing according to claim 10 is characterized by the fact that the video controller has a built-in video camera with which it determines the location of the LED modules inside the segment housing.

16. The method of determining the position of the LED module throughout the fiber is characterized by the fact that it is based on attenuating the intensity of the luminous flux with increasing distance to the source, the LED modules are placed along the fiber, the video controller is located at one of the fiber ends, the video controller using the integrated optical transceiver the light flux from the transceivers of each LED module, the measurement results are compared, and sorted in with answer with

intensity: lower intensity corresponds to the most distant LED module.

17. The method for determining the position of the LED module during the optical fiber according to claim 16 is characterized in that at the time of measuring the intensity, the light emitter of the optical transceiver does not transmit data.

18. The method of determining the position of the LED module during the optical fiber according to claim 16 is characterized in that the measurement is performed simultaneously with the transmission of the digital signal from the LED module to the video controller.

19. The method for determining the position of the LED module throughout the optical fiber according to claim 16 is characterized in that for controlling

optical signal intensity measurement sequence

the video controller sends the command through an optical transceiver to one of the LED modules known to it, in response to which

LED module gives test signal.

20. The method of determining the position of the LED module during the optical fiber according to claim 16 is characterized in that the sequence of measuring the intensity of the optical signal of the LED modules is implemented by using LED modules of the optical channel without

control from the video controller, in this case in the light stream

The emitted signal encodes the LED module number.

21. The method of determining the position of the LED module inside the segment housing using a video camera is characterized in that the video controller is located inside the segment housing, opposite the rear surface of the LED modules that host the optical

transceivers, the video controller sends a command to each LED module that changes the light intensity of the transceiver of this LED module, a video camera that photographs the back surface of the LED modules is built into the video controller, then during the photo processing the position of the current LED module is determined based on the different luminous intensity its optical

transceiver from optical intensity

transceivers of other LED modules.

22. The method of determining the position of the LED module inside the segment housing using a video camera according to claim 21 is characterized in that at the time of light emission by the transceiver of the selected LED module, the transceivers of the other LED modules are turned off.

23. The method of determining the position of the LED module inside the segment housing using a video camera according to claim 21 is characterized by the fact that at the time of light emission by the transceiver of the selected LED module, the transceivers of the other LED modules emit weak light, this allows for easier recognition of the position of the LED modules using software.

24. The method of determining the position of the LED module within the segment using the database is characterized by the fact that when assembling the segments, the positions of the LED modules with unique identifiers

LED modules are stored in the central database, when turned on, the video controller requests the LED modules of the segment to

unique identifiers if the positions of the LED modules with such unique identifiers are not in the memory of the video controller, these positions are requested from the central database and stored in memory

video controller.

25. The method of determining the position of the LED module within a segment using the database of clause 24 is characterized in that when replacing the LED module inside the segment, the video controller checks the list of unique identifiers of LED modules from memory and the list of unique identifiers obtained from the LED modules of the segment if one of LED module has changed its unique identifier, the unique identifier of the new LED module is matched with the position of the unique identifier missing retractable LED module.

26. The method for determining the position of the LED module within a segment using the database of clause 24 is characterized in that the connection to the central database occurs via the Internet.

27. The method for determining the position of the LED module within a segment using the database of clause 24 is characterized in that the request to the central database can be made from a video controller.

28. The method of determining the position of the LED module within a segment using the database of clause 24 is characterized in that a request to a central database can be made via a screen controller.