JP2007180642A - High definition image serial data transmission apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology of carrying out high definition image transmission for a presentation in a conference room or an auditorium, for information display, and for an event hall or the like. <P>SOLUTION: Three kinds of R, G, B (red, green, blue) color signals and a control signal are converted into serial signals and transmitted up to a data transmission place by using one optical fiber cable 11. The signals are wirelessly transmitted from the data transmission place to a data receiving place by using a light beam 13. A receiver side converts and reproduces the serial signals. When many high definition display apparatuses 22 or the like are in particular located in the event hall or the like and a video signal is transmitted to them, the transmission place has been limited so far to a place very close to the display apparatuses 22 or the like. Since the transmission place is located on one place in the event hall in the technology disclosed herein and the video signal can be transmitted to each display apparatus wirelessly therefrom, constraints in the design of a facility can be eliminated. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a high-definition image serial data transmission apparatus having a function of wirelessly transmitting high-definition digital image data using a light beam.

In recent years, display panels such as XGA (eXtended Graphics Array) and WXGA (Wide eXtended Graphics Array) have appeared due to high definition of monitors, and DVI (Digital Visual Interface) and the like have been standardized as an interface. Moreover, HDTV (high-definition television) is gradually penetrating in television (Patent Document 1).
JP 2005-130358 A

By the way, the above technique has the following problems to be solved.
In order to transmit a digital high-definition image signal using an interface of the DVI standard, three kinds of color signals of R, G, and B (red, green, and blue) and a control signal are transmitted in parallel. However, an electric cable for transmitting such a signal can only be about 10 meters at the maximum. If it exceeds that, the transmission delay between the signals becomes significant, and synchronization cannot be achieved. On the other hand, (1) presentations in conference rooms and auditoriums, (2) information displays, and (3) event venues require transmission capabilities of several tens of meters. This can be solved by E / O-converting the three types of color signals and control signals and transmitting them using optical fibers. However, if as many as four optical fiber cables are required for temporary use, the equipment cost becomes high, and the degree of freedom is reduced due to restrictions on wiring design. Wireless transmission using radio waves requires an enormous bandwidth.
The present invention has been made to solve the above-described problems, and provides a high-definition image serial data transmission apparatus that can flexibly respond to the installation location by combining an optical fiber cable and an optical wireless transmission / reception module. The purpose is to do.

In each embodiment of the present invention, the above-described problems are solved by the following configurations.
<Configuration 1>
A serializer that converts digital image data into high-definition image serial data, a driver circuit that converts the high-definition image serial data into an optical signal, an optical fiber cable that transmits an optical signal output from the driver circuit, and the optical fiber A high-definition image serial data transmission device comprising: an optical wireless transmission module that converts an output of a cable into a light beam.

  Digital image data input from a data source is converted into high-definition image serial data and transmitted to a transmission location using an optical fiber cable. Can be transmitted. Moreover, 1-to-N transmission can be performed freely. Further, since the signal is transmitted from the transmission place by the light beam, complicated installation work of the optical fiber cable to the receiving device is not required. Therefore, the receiving device and the display can be arranged in a free layout at an event venue or a lecture.

<Configuration 2>
An optical wireless receiver module that receives the optical beam transmitted after converting the high-definition image serial data obtained from the digital image data into an optical signal, and outputs the optical signal, and the optical wireless receiver module outputs the optical signal A high-definition image comprising: a receiving circuit that restores the high-definition image serial data from an optical signal; and a conversion circuit that reversely converts the high-definition image serial data into digital image data output from the data source. Serial data transmission device.

  Configuration 1 is a transmission device and configuration 2 is a reception device. High-definition image serial data can be converted back into digital image data output from a data source.

<Configuration 3>
A serializer that converts digital image data into high-definition image serial data, a driver circuit that converts the high-definition image serial data into an optical signal, an optical fiber cable that transmits an optical signal output from the driver circuit, and the optical fiber An optical wireless transmission module that converts the output of the cable into an optical beam, an optical wireless reception module that receives the optical beam and obtains the optical signal, and the high-definition image serial from the optical signal output by the optical wireless reception module A high-definition image serial data transmission apparatus comprising: a receiving circuit for restoring data; and a conversion circuit for inversely converting the high-definition image serial data into digital image data output from the data source.

  Configuration 3 includes a transmission device and a reception device.

<Configuration 4>
4. The high-definition image serial data transmission device according to any one of configurations 1 to 3, wherein a wavelength of an optical signal transmitted through the optical fiber cable and a wavelength of the light beam are the same. Data transmission equipment.

  If the wavelength of the optical signal transmitted through the optical fiber cable is the same as the wavelength of the light beam, the receiving side can use simple optical components. Therefore, the cost of the system can be reduced.

  In the present invention, three types of color signals of R, G, and B (red, green, and blue) and a control signal are converted into a serial signal and transmitted to a data transmission location using a single optical fiber communication path. Wireless transmission is performed using a light beam from the data transmission location to the reception location. On the receiving side, the serial signal is converted into digital image data and reproduced. In particular, when a large number of high-definition displays are arranged in an event venue and video signals are transmitted to these, the transmission location has been limited to a location very close to the display so far. In the present invention, since a transmission place is provided at one place of the event venue, and a video signal can be transmitted to each display from there wirelessly, there is no restriction on the design of the equipment. This can also be used in a case where an image signal is transmitted to a projector using a personal computer in a conference room or the like. Hereinafter, embodiments of the present invention will be described in detail for each example.

FIG. 1 is a schematic diagram illustrating a high-definition image serial data transmission apparatus according to the first embodiment.
The transmission unit 10 is equipped with a DVD recorder, a computer, and the like that supply a data source. Furthermore, a device for converting these output signals into high-definition image serial data and supplying them to the optical fiber cable 11 is mounted. Details of the internal structure will be described later with reference to FIG. In this example, two transmission locations are provided, and the optical wireless transmission module 12 and the optical wireless transmission module 14 are arranged, respectively. Both have exactly the same function. Then, the light beam 13 and the light beam 15 are transmitted.

  For example, a transmission place is secured in a place where the inside of the event hall can be widely viewed. The optical wireless transmission modules 12 and 14 are disposed here. Then, the transmission unit 10 and the optical wireless transmission modules 12 and 14 are connected by the optical fiber cable 11. The optical wireless receiver modules 20, 30, and 25 are arranged at an arbitrary place in the venue. Then, the optical axes of the optical wireless transmission module 12 and the optical wireless reception modules 20 and 30 are aligned. Further, the optical axes of the optical wireless transmission module 14 and the optical wireless reception module 25 are aligned. Now you are ready to send and receive.

  A reception unit 21 is connected to the optical wireless reception module 20. A display 22 is connected to the receiving unit 21. A reception unit 31 is connected to the optical wireless reception module 30. A liquid crystal projector 32 is connected to the receiving unit 31. A reception unit 26 is connected to the optical wireless reception module 25. A display 27 is connected to the receiving unit 26. The display 22 and the display 27 reproduce and display the data source supplied on the transmission side. The liquid crystal projector 32 projects the image onto a wall surface or a screen (not shown). Thus, for example, high-definition images can be displayed at various locations in the event venue. The reach of the light beam 13 and the light beam 15 is several tens of meters. Therefore, a high-definition image can be transmitted wirelessly anywhere in a wide venue.

FIG. 2 is a block diagram showing details of the transmission unit 10.
The transmission unit 10 includes a digital conversion circuit (hereinafter referred to as a digital video interface circuit) 41 (DVI-I Receiver: TMDS receiver), a serializer 42 (DVI to Serial), and a driver circuit (hereinafter referred to as a laser driver) 43.

  The digital video interface circuit 41 receives digital image data RGB, CLK signal, DDC (Display Data Channel) signal and other control signals, and controls the parallel RGB signals and CLK, DE, HSync, VSync, CTL0 Convert to ~ 3. The output signal of the digital video interface circuit 41 is input to the serializer 42.

  The serializer 42 converts the input signal into serial data. The laser driver 43 modulates the laser light with the serial signal output from the serializer 42 and guides it to the optical fiber cable 11. The optical fiber cable 11 is connected to the optical wireless transmission module 12. The optical wireless transmission module 12 transmits the light beam 13 that transmits the output light of the optical fiber cable 11 to a space at a certain radiation angle toward the reception unit 21.

  The optical fiber cable 11 is preferably a multimode fiber (MMF). MMF has an advantage that the optical diameter of the optical coupler for introducing and extracting optical signals may be lower than that of single mode fiber (SMF). If a 1 to N star coupler is arranged on the output side of the laser driver 43, the output signal can be distributed to N optical fiber cables. Therefore, N optical wireless transmission modules 12 and 14 can be connected to the end.

FIG. 3 is a block diagram showing details of the receiving unit 21.
The receiving unit 21 is connected to the optical wireless receiving module 20 via an optical fiber cable 51. The reception unit 21 includes an optical / electrical conversion element 52 (PD), a conversion circuit (hereinafter referred to as deserializer) 53 (Serial to DVI), and a reception circuit (hereinafter referred to as digital video interface circuit) 54 (DVI Xmitter). The optical wireless receiver module 20 condenses the light beam 13 transmitted by the optical wireless transmitter module 12 (FIG. 2) with a lens at a certain distance and guides it to the optical fiber cable 51.

  The optical / electrical conversion element 52 is a circuit that receives an optical signal output from the optical wireless reception module 20 through the optical fiber cable 51 and performs O / E conversion. The deserializer 53 is a circuit that receives serial image data output from the optical / electrical conversion element 52 and outputs parallel RGB signals and CLK, DE, HSync, VSync, and CTL0 to CTL3 that control them. The digital video interface circuit 54 is a circuit that receives the output of the deserializer 53 and converts it into a TMDS signal defined by the DVI-I standard. This signal includes digital image data RGB, a CLK signal, a DDC signal, and other control signals.

  The laser beam has safety standards defined by IEC60825. The allowable optical power of Class 1M depends on the wavelength. The 1.5 μm band light is safe even at 10 times the power compared to the 800 nm band or 1.3 μm band light. Therefore, if the wavelength of the light beam is selected in the 1.5 μm band, it can be transmitted with 10 times the optical power in the case of optical wireless transmission. This is very advantageous in terms of system design. Therefore, the wavelength of the light beam is preferably in the 1.5 μm band. Further, it is desirable that the wavelength of the optical signal transmitted through the optical fiber cable 11 and the wavelength of the light beam 13 are the same.

  This eliminates the need for a circuit for converting an optical signal into an optical beam between the optical fiber cable 11 and the optical wireless transmission module 12 in FIG. Only an optical connection device is sufficient. Further, in FIG. 3, a circuit for converting a light beam into an optical signal is not required between the optical wireless reception module 20 and the optical fiber 51. Only an optical connection device is sufficient. As shown in FIG. 1, when a plurality of optical wireless reception modules 20 and 30 are arranged in the irradiation range of one light beam 13, a plurality of the same signals can be received simultaneously.

With the above configuration, the following effects can be expected.
First, it enables long-distance communication that was impossible with conventional metal communication. In addition, for serial data transmission, signals can be transmitted using only a single optical fiber cable. In addition, the skew between signals as in parallel transmission does not become a problem, which is advantageous for long-distance transmission. Furthermore, wireless transmission of uncompressed digital image data, which has been impossible until now because a huge band is required, is possible. Therefore, transmission in a place where cable laying work is not easy has become possible. In addition, image data transmission at the event venue can be easily constructed. Since a single optical fiber cable is used as a transmission medium, a 1 to n transmission, which has been impossible until now, becomes possible by using a fiber coupler.

1 is a schematic diagram illustrating a high-definition image serial data transmission apparatus according to Embodiment 1. FIG. 2 is a block diagram showing details of a transmission unit 10. FIG. It is a block diagram which shows the detail of a receiving unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Transmission unit 11 Optical fiber cable 12 Optical wireless transmission module 13 Optical beam 14 Optical wireless transmission module 15 Optical beam 20 Optical wireless reception module 21 Reception unit 22 Display 25 Optical wireless reception module 26 Reception unit 27 Display 30 Optical wireless reception module 31 Reception Unit 32 LCD projector

Claims (4)

A serializer that converts digital image data into high-definition image serial data;
A driver circuit for converting the high-definition image serial data into an optical signal;
An optical fiber cable for transmitting an optical signal output from the driver circuit;
A high-definition image serial data transmission apparatus comprising: an optical wireless transmission module that converts an output of the optical fiber cable into a light beam. An optical wireless receiver module that receives the light beam transmitted after converting the high-definition image serial data obtained from the digital image data into an optical signal, and obtains the optical signal;
A receiving circuit for restoring the high-definition image serial data from the optical signal output by the optical wireless receiving module;
A high-definition image serial data transmission device, comprising: a conversion circuit that reversely converts the high-definition image serial data into digital image data output from the data source. A serializer that converts digital image data into high-definition image serial data;
A driver circuit for converting the high-definition image serial data into an optical signal;
An optical fiber cable for transmitting an optical signal output from the driver circuit;
An optical wireless transmission module for converting the output of the optical fiber cable into a light beam;
An optical wireless receiver module that receives the optical beam and obtains the optical signal;
A receiving circuit for restoring the high-definition image serial data from the optical signal output by the optical wireless receiving module;
A high-definition image serial data transmission device, comprising: a conversion circuit that reversely converts the high-definition image serial data into digital image data output from the data source. The high-definition image serial data transmission apparatus according to any one of claims 1 to 3,
A high-definition image serial data transmission apparatus, wherein a wavelength of an optical signal transmitted through the optical fiber cable and a wavelength of the light beam are the same.

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