RU184635U1 - LED screen device with waveguide data transmission - Google Patents

Abstract

The utility model relates to the field of devices for presenting changing information material and can be used to create devices for demonstrating outdoor video ads. A microwave LED data transmission screen consists of one or more segments. Each segment of the LED screen contains at least one video controller and several LED modules. LED modules and video controllers contain microwave transceivers. Wireless data transmission between video controllers and LED modules is carried out using microwave radiation, which is transmitted through the waveguides from the video controller of the segment to the LED modules and vice versa. The utility model improves the reliability of data transmission. 13 p. Fs, 8 ill.

Description

The invention relates to the field of devices for presenting changing information material, as well as to the field of devices or circuits for controlling indicator devices and can be used to create devices for demonstrating outdoor video ads.

State of the art

A portable LED screen device is known from the prior art (RU 2411590, G09F 19/22, G09F 13/08, 02/27/2009). The device contains several LED modules placed in space in such a way that each module forms a fragment of the image in space corresponding to its location. Collapsible modules contain connection strips to which the rulers with LEDs are attached, an LED power supply and an electronics unit, including a microcontroller that supplies control signals in accordance with a fragment of the image. The electronics node of the module contains a control device that transmits information about the displayed image fragment via wireless communication lines. Disadvantages: it is necessary to ensure high bandwidth of the wireless communication channel due to the fact that all screen modules are controlled by one controller; with large screen sizes, the device has low noise immunity; there is the possibility of hacking the system through a wireless communication channel and unauthorized broadcasting of arbitrary images; when using conventional wireless access points for video broadcasting, it is difficult to ensure accurate synchronization of the video stream, image quality is reduced due to the fact that certain parts of the image are displayed at different times.

Disadvantages of Existing Solutions

Modern LED screens consist of LED modules, which are connected in a line of LED modules in series using flat cables. The signal from the video controller passes through the lines of LED modules connected by cables. Due to the large length of the connecting lines and high frequencies, various distortions may appear in the broadcast signal, the same distortions appear in the image broadcast by the screen.

LED screens have many connecting wires and connectors that transmit data. The number of detachable contacts in LED screens can reach several thousand per square meter. As you know, one of the main reasons for reducing the reliability of complex electronic systems is the low reliability of the connectors connecting various electronic components. The more pluggable contacts, the lower the reliability of the electronic system. To ensure high reliability of data transmission in LED screens, high-quality and expensive connectors are used, this significantly increases the cost of the screen.

There is also a problem of the reliability of the LED screen when connecting LED modules in series. If 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, this makes it difficult to organize mass automated production.

In LED screens with wireless data transmission to LED modules, problems arise with ensuring the noise immunity of wireless communication channels, as well as the security of information transfer through these communication channels.

The tasks to which this invention is directed are:

reducing the number of contacts inside the LED screen to increase reliability; simplification of assembly of LED screens; improving the reliability of data transmission to LED modules; reducing the influence of external electromagnetic interference on the transmitted signal; exclusion of the possibility of hacking wireless communication channels.

The tasks are solved as follows

A microwave LED data transmission screen 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 microwave transceivers (2). Wireless data transmission between video controllers (1) and LED modules (3) is carried out through microwave transceivers (2), the signal from which passes through waveguides (5).

Microwave transceivers (2) comprise microwave transmitters and receivers. Microwave transceivers (2) can be made in the form of: removable modules that are connected to the video controller (1) and LED modules (3); in the form of LED modules (3) integrated into printed circuit boards (6) and video controllers (1) of electronic units; in the form of remote units connected to LED modules (3) and video controllers (1) using cables.

Microwave transceivers (2) may contain one antenna for receiving and transmitting a signal or separate antennas, one of which serves to transmit a microwave signal, and the other serves to receive a microwave signal. Antennas for microwave transceivers (2) can be implemented as tracks of printed circuit boards or as elements soldered to a printed circuit board. Antennas for microwave transceivers (2) can be connected to LED modules and video controllers via cables.

The waveguides (5) are made of a material that reflects microwave radiation well and can have various shapes and designs: the waveguide (5) can be implemented in the form of a tube containing holes (8) located opposite the microwave transceivers (2) of the LED modules (3) ; the waveguide (5) can be implemented in the form of a tube with a longitudinal slit (9) located opposite the microwave transceivers (2) of the LED modules (3); the waveguide (5) can be implemented in the form of a channel, on the open side of which are located microwave transceivers (2) of LED modules (3); the waveguide (5) can be implemented as a product of complex shape made using 3D printing, with one or more channels for transmitting microwave radiation located inside; waveguides (5) can have a complex nonlinear shape.

The device of the LED screen with microwave data transmission to the LED modules through the waveguides provides several technical results.

The decrease in the number of contacts inside the LED screen is due to the fact that the connectors are replaced with wireless transceivers, which generally have no contacts. Reliability of data transmission is increased due to the fact that wireless data exchange is used, unlike a contact connection, the wireless connection is not affected by deformations due to temperature changes, humidity changes, chemical reactions of contact oxidation. In addition, with wireless communications, direct communications of the transmitter and receiver without intermediaries are used, which increases reliability.

Screens with wired connections use serial connection of modules with cables (the signal passes sequentially through several modules and several cables). This reduces the reliability of data transmission due to the fact that a failure can occur in any element of the data transmission chain.

Bidirectional communications through transceivers can also significantly increase reliability, since after receiving data, the screen module sends back a confirmation of receipt of data, if confirmation was not received, data transmission may be repeated.

The simplification of the assembly of LED screens also occurs due to the use of wireless data transmission, since wires are excluded from the device. Without wires, you can simply put the module back in place, without having to properly connect the cables and check the contacts.

Electromagnetic interference is reduced due to the use of waveguides, the waveguide walls do not allow electromagnetic interference to penetrate. The exclusion of the possibility of hacking wireless communication channels is due to the fact that data is transmitted through closed communication channels inside the waveguides, which, unlike open wireless networks, does not allow an attacker to remotely connect to the device and crack it without physical access to it.

Brief Description of the Drawings

In figures 1-2, the device of the LED module (3) is shown. The LED module (3) consists of a printed circuit board (6), on the front side of which LEDs (4) are soldered, on the back side of which a microwave transceiver (2) is placed.

In figures 3-5, the device of the LED screen with microwave data transmission along the waveguides (5) is shown. The screen consists of several waveguides (5). LED modules (3) are mounted on the waveguides in such a way that the microwave transceivers (2) are located opposite the longitudinal slots (9) of the waveguides (5). At the bottom of the screen is a video controller (1) with several microwave transceivers (2) and a processor (7), which controls the data transfer process. The microwave transceivers (2) of the video controller (1) are placed one at the beginning of each waveguide (5). Thus, an isolated microwave data transmission channel is formed in each waveguide (5). During operation of the LED screen, the video controller (1) communicates with the LED modules (3) by modulating the microwave signal passing through the waveguides (5) from the microwave transceivers (2) of the video controller (1) to the microwave transceivers (2) of the LED modules (3) .

Figures 6-8 depict various embodiments of waveguides (5).

List of Shapes

1. LED module, front view.

2. LED module, rear view.

3. Video controller with several microwave transceivers.

4. LED screen with microwave data transmission along waveguides, front view.

5. LED screen with microwave data transmission along waveguides, top view.

6. A line of LED modules with a waveguide in the form of a channel.

7. A line of LED modules with a waveguide in the form of a pipe with holes for transmitting a microwave signal.

8. LED screen with a complex waveguide.

List of items depicted in the figures

1. Video controller with several microwave transceivers.

2. Microwave transceiver.

3. LED module.

4. LED.

5. Waveguide for microwave data transmission.

6. The printed circuit board of the LED module.

7. The processor.

8. The hole in the waveguide for transmitting a microwave signal.

9. The longitudinal gap.

Device

A microwave LED data transmission screen 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 microwave transceivers (2). Wireless data transmission between video controllers (1) and LED modules (3) is carried out through microwave transceivers (2), the signal from which passes through waveguides (5).

Microwave transceivers (2) comprise microwave transmitters and receivers. Microwave transceivers (2) can be made in the form of: removable modules that are connected to the video controller (1) and LED modules (3); in the form of LED modules (3) integrated into printed circuit boards (6) and video controllers (1) of electronic units; in the form of remote units connected to LED modules (3) and video controllers (1) using cables.

Microwave transceivers (2) may contain one antenna for receiving and transmitting a signal or separate antennas, one of which serves to transmit a microwave signal, and the other serves to receive a microwave signal. Antennas microwave transceivers (2) can be implemented as tracks of printed circuit boards or in the form of elements soldered to a printed circuit board. Antennas for microwave transceivers (2) can be connected to LED modules and video controllers via cables.

The waveguides (5) are made of a material that reflects microwave radiation well and can have various shapes and designs: the waveguide (5) can be implemented in the form of a tube containing holes (8) located opposite the microwave transceivers (2) of the LED modules (3) ; the waveguide (5) can be implemented in the form of a tube with a longitudinal slit (9) located opposite the microwave transceivers (2) of the LED modules (3); the waveguide (5) can be implemented in the form of a channel, on the open side of which are located microwave transceivers (2) of LED modules (3); the waveguide (5) can be implemented as a product of complex shape made using 3D printing, with one or more channels for transmitting microwave radiation located inside; waveguides (5) can have a complex nonlinear shape.

The device is manufactured as follows:

The LED screen with microwave data transmission along waveguides (Fig. 4) consists of segments. The screen segment is a frame with waveguides (5) located on its surface with LED modules (3) and video controllers (1).

The frame can be manufactured using existing industrial methods for processing sheet metal (bending, coordinate punching, laser cutting). The frame can be printed on a 3D printer. The frame can also be made of plastic (plastic molding) or composite materials.

The waveguides (5) in the form of a pipe (Fig. 7) or channel (Fig. 6) can be produced by extrusion of aluminum, copper or another metal, if necessary, milling can be performed after extrusion to form mounting holes and holes for the microwave signal of microwave transceivers ( 2). A waveguide (5) of any complex shape can be printed using a 3D printer or manufactured on a milling machine using the milling of a single piece of metal.

LED modules (3) are printed circuit boards (6) with front-mounted LEDs (4) and other electronic elements located at the back. LED modules (3) are manufactured using standard industrial electronics assembly methods. The video controller (1) is also an electronic board, which is manufactured using standard industrial electronic assembly methods.

Microwave transceivers (2) can be made in the form of LED modules (3) and video controllers (2) integrated into printed circuit boards of electronic units or as separate electronic boards.

The operation of the device is as follows:

The screen controller receives data for video broadcasting from a central server and divides it into fragments corresponding to the control area of each individual video controller (1). Further, these fragments are transmitted to video controllers (1) using wired or wireless communication channels.

Video controllers (1) in turn split the incoming video broadcast data into fragments intended for individual LED modules (3). After that, video controllers (1) carry out microwave transmission of video broadcast fragments to LED modules (3).

Microwave data transmission is carried out through waveguides (5) through microwave transceivers (2). Microwave transceivers (2) of the video controller (1) during operation modulate the outgoing microwave signal using the input data stream. The microwave signal is emitted from the microwave transceiver (2) of the video controller (1), passes through the waveguide and is received using the microwave transceivers (2) of the LED modules (3).

Microwave transceivers (2) of LED modules (3) demodulate the incoming microwave signal, extracting video stream data for broadcasting. Next, the LED module controllers (3) convert the incoming signal into a sequence of pulses that control the LED drivers. The LED drivers, based on the control signal, regulate the current flowing through the LEDs (4) of the LED modules (3), thereby forming a video image on the surface of the LED module (3).

Claims (13)

1. The device of the LED screen with microwave data transmission to the LED modules through the waveguides is characterized in 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 have one or more microwave transceivers, microwave transceivers of video controllers and LED modules carry out microwave data transmission on one or more waveguides m 2. The device of the LED screen with microwave data transmission to the LED modules through the waveguides according to claim 1 is characterized in that the waveguides are tubes containing openings located opposite the microwave transceivers of the LED modules. 3. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the waveguides are tubes with longitudinal slots located opposite the microwave transceivers of the LED modules. 4. The device of the LED screen with microwave data transmission to the LED modules through the waveguides according to claim 1 is characterized in that the waveguides are channels, on the open sides of which are placed the microwave transceivers of the LED modules. 5. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the waveguides are made of a material that reflects microwave radiation well. 6. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the microwave transceivers contain one antenna, which serves to transmit and receive a microwave signal. 7. The device of the LED screen with microwave data transmission to the LED modules through the waveguides according to claim 1 is characterized in that the microwave transceivers contain a separate antenna that serves to transmit a microwave signal, and a separate antenna that serves to receive a microwave signal. 8. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the microwave transceivers are made in the form of removable modules that are connected to video controllers and LED modules. 9. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the microwave transceivers are implemented as LED modules and electronic controllers integrated into the printed circuit boards. 10. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the microwave transceivers are implemented in the form of remote units connected to the LED modules and video controllers using cables. 11. The device of the LED screen with microwave data transmission to the LED modules along the waveguides according to claim 1 is characterized in that the antennas of the microwave transmitters are implemented as tracks of the printed circuit board. 12. The device of the LED screen with microwave data transmission to the LED modules along the waveguides according to claim 1 is characterized in that the antennas are implemented in the form of elements soldered to the printed circuit boards. 13. The device of the LED screen with microwave data transmission to the LED modules by waveguides according to claim 1 is characterized in that the antennas are connected to the LED modules and video controllers via cables.

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