KR200244696Y1 - Digital Vidio Signal Interface Module For Transmitting Long Distance - Google Patents

Abstract

The present invention relates to a digital video signal interface module capable of long-distance transmission capable of remote cable distance between a computer having a digital video output and a monitor having a digital video input. To this end, the laser driver 30 and the laser diode 38 for receiving the digital video signals (R, G, B, Clock) output from the computer 1 and convert them into respective laser signals; A photodiode (39) for receiving each laser signal and restoring it into an electrical signal, and a photo-diode (PD) amplifier (32) for amplifying and transmitting the signal of each photodiode (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; A power line 40 and a ground line 41 installed between the computer 1 and the LCD monitor 2 along the optical fiber 37 to supply power to the laser driver 30 and the PD amplifier 32. );

Description

Digital video signal interface module capable of long distance transmission {Digital Vidio Signal Interface Module For Transmitting Long Distance}

The present invention relates to a video cable between a computer and a monitor, and more particularly, a digital video signal interface module capable of remote transmission capable of remotely connecting a cable between a computer having a digital video output and a monitor having a digital video input. It is about.

In general, video signals output from a computer are analog or digital. Analogue methods have traditionally been widely applied to CRT monitors, and digital methods have been widely applied to monitors such as LCDs. Therefore, when using an LCD monitor in a computer having only analog video output, the A-D converter had to be used in the middle.

However, with the recent popularization of LCD monitors, many computers that output digital video signals have begun to appear. Thus, it is possible to enjoy the image as a clean digital signal without a separate A-D converter.

However, in the case of the digital interface method, since the frequency is a high frequency of several hundred MHz to several GHz, when the distance between the computer main body and the LCD monitor is about 5 meters or more, a signal cannot be transmitted. Therefore, in the case of a monitor installed in a ship, a train, a medical device, an outdoor display board, a department store, an elevator, and the like, a separate amplifier is used when the distance between the computer body and the monitor is about 5 meters to several tens of meters or more.

1 is a configuration diagram of a system configured to transmit a digital video signal distantly conforming to a DVI (Digital Visual Interface) interface specification in a conventional computer.

As shown in Fig. 1, the system is composed of a computer 1 capable of outputting a digital video signal, an amplifier 4, a receiver 5, and an LCD monitor 2. One end of the first digital dedicated line 7 is connected to a video output terminal (not shown) of the computer 1, and the other end is connected to the amplifier 4. The amplifier 4 amplifies the digital signal using the external power supply 6 and then generates signals of R (Red), G (Green), B (Blue), and C (Clock). The receiver 5 adjusts the R, G, B, and C signals to the rated level by using the external power source 6 and transmits the R, G, B, and C signals to the LCD monitor 2 through the second digital dedicated line 10. Fast R, G, B and C signals are transmitted via the BNC line (8).

In addition, the DDC (Data Display Channel) signal for transmitting the information of the monitor 2 to the computer 1 is composed of DDC clock, DDC data and HPD (Hot Plug Detect) for checking the connection state. This DDC signal is connected between the amplifier 4 and the receiver 5 via a separate DDC line 9 with large attenuation. If necessary, the digital projector 3 may be used instead of or in combination with the LCD monitor 2. By using the above method, the distance between the amplifier 4 and the receiver 5 can be several meters to several tens of meters.

However, in the conventional system as described above, the amplifier 4 and the receiver 5 require an external power supply 6, two digital dedicated lines 7 and 10, four BNC lines 8, and a DDC. There are problems such as the need for the composite DDC line (9), the system is complicated and there are many components and the manufacturing cost is high, the installation is inconvenient and takes up a lot of space.

2 is a block diagram of a case where all signals for all digital interfaces are configured with light prior to realizing the system of the present invention. As shown in FIG. 2, the system is largely composed of a computer 1, a transmitter 21, an optical fiber 27, a receiver 23, and an LCD monitor 2.

The R, G, B, C, DDC data, and DDC clocks (6 channels) output from the computer 1 are converted into optical signals by the six laser diodes 28 by the laser driver 20, respectively. The converted optical signal is transmitted to a long distance through six optical fibers 27. The six photodiodes 29 restore the received optical signals to electrical signals, and the photo-diode amplifiers 22 amplify the weak electrical signals to a predetermined voltage. The amplified signal is transferred to the LCD monitor 2 and displayed.

On the other hand, since information on the specifications of the LCD monitor 2 must be transmitted to the computer 1 through the DDC, a separate two-channel laser driver 26 and a laser diode 28 are provided in the receiver 23, and the transmitter ( 21 is provided with a separate two-channel PD amplifier 24. In addition, two separate optical fibers are used for signal transmission.

In order to convert all the signals into optical signals as described above, eight strands of optical fibers are required, resulting in a combination of a six-channel system and a two-channel system. In this case, not only does the production cost increase, but the DDC signal is a low frequency of 100 kHz, and the speed is too low for signal transmission by light.

In addition, the DVI (Digital Visual Interface) specification, a type of digital interface, requires HPD (Hot Plug Detect) functionality in Windows 95 and later operating systems. This HPD function is achieved by the detection of DC 5V, the system of Figure 2 is difficult to support this structure. That is, in order to support the HPD function in the system of FIG. 2, a separate signal should be inserted into another channel and transmitted, and the receiver may be configured to detect it using a microcomputer. However, this method has a disadvantage of complicated structure and cost increase.

As another problem, in the digital interface standard such as DVI, DFP, LVDS, there is an inconvenience of having to supply power from the outside to operate each functional element of the receiver because there is no spare pin for power supply from the monitor. .

Accordingly, the present invention has been made to solve the above problems, the first object of the present invention is a digital video signal interface module capable of remote transmission capable of transmitting a digital video signal at a long distance using an optical element and an optical fiber To provide.

A second object of the present invention is to provide a digital video signal interface module capable of remote transmission that can supply power to a laser driver and a PD amplifier without a separate power supply by embedding a copper wire connected to a power source other than an optical fiber in a cable.

A third object of the present invention is to provide a digital video signal interface module capable of long-distance transmission that minimizes EMI emission by supplying power to a laser driver from a transmission connector and powering a PD amplifier from a receiving connector.

An object of the present invention as described above, the laser driver 30 and the laser diode 38 for receiving the digital video signal (R, G, B, Clock) output from the computer 1 and converts it into respective laser signals; A photodiode (39) for receiving each laser signal and restoring it into an electrical signal, and a photo-diode (PD) amplifier (32) for amplifying and transmitting the signal of each photodiode (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; A power line 40 and a ground line 41 installed between the computer 1 and the LCD monitor 2 along the optical fiber 37 to supply power to the laser driver 30 and the PD amplifier 32. It can be achieved by a digital video signal interface module capable of remote transmission, characterized in that it comprises a.

In addition, the object of the present invention as described above,

A laser driver 30 and a laser diode 38 for receiving the digital video signals R, G, B, and Clock output from the computer 1 and converting them into respective laser signals; A photodiode (39) for receiving the respective laser signals and restoring the electrical signal, and a PD amplifier (32) for amplifying and transmitting the signals of the photodiodes (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; Information transmission means provided between the computer (1) and the LCD monitor (2) along the optical fiber (37) to transmit information data about the LCD monitor (2) to the computer (1); A power line 40 provided between the computer 1 and the LCD monitor 2 along the optical fiber 37 to supply power to the laser driver 30, the PD amplifier 32, and the transmission means; And a ground line 41, which can be achieved by a digital video signal interface module capable of remote transmission.

The information transmission means is connected to a Hot Plug Datection (HPD) line 44 for checking a connection state of the data display channel (DDC) data line 42, the DDC clock line 43, and the monitor 2. It is preferable that it is comprised.

In addition, the DDC data line 42 and the DDC clock line 43 may be shielded, respectively.

Moreover, it is most preferable that the shielded DDC data line 42 or DDC clock line 43 have a thickness of 28 AWG or more.

The thickness of the power supply line 40, ground line 41 and HPD line 44 is preferably 24 AWG or more.

The purpose of the present invention as described above,

A laser driver 30 and a laser diode 38 for receiving the digital video signals R, G, B, and Clock output from the computer 1 and converting them into respective laser signals; A photodiode (39) for receiving the respective laser signals and restoring the electrical signal, and a PD amplifier (32) for amplifying and transmitting the signals of the photodiodes (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; A first power line 73 and a first ground line 74 for supplying power from the computer 1 to the laser driver 30; And a second power line 75 and a second ground line 76 for supplying power from the monitor 2 to the PD amplifier 32. Can be achieved.

In addition, the second power supply line 75 may pass through an NC (No Connect) pin between the PD amplifier 32 and the monitor 2.

In addition, the optical fiber 37 is preferably one of four channels of DVI (Digital Visual Interface) standard or five channels of LVDS () standard.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

1 is a configuration diagram of a system configured for transmitting a digital video signal over a long distance in a conventional computer;

2 is a block diagram of a case where all signals for all digital interfaces are composed of light prior to realizing the system of the present invention;

3 is an external perspective view of a digital video signal interface module capable of remote transmission according to the present invention;

4 is a block diagram of a digital video signal interface module capable of remote transmission according to a first embodiment of the present invention;

5, 6, and 7 are various cross-sectional views of the cable of the interface module shown in FIG.

8 is a block diagram of a digital video signal interface module capable of remote transmission according to a second embodiment of the present invention;

9 and 10 are various cross-sectional views of the cable of the interface module shown in FIG.

11 is a block diagram of a digital video signal interface module capable of remote transmission according to a third embodiment of the present invention;

12 is a cross-sectional view of the cable of the interface module shown in FIG.

<Short Description of Main Reference Signs>

1: computer, 2: LCD monitor,

3: digital projector, 4: amplifier,

5: receiver, 6: external power,

7: first digital dedicated line, 8: BNC line,

9: DDC line, 10: second digital dedicated line,

20, 26: laser driver, 21: transmitting unit,

22, 24: PD amplifier, 23: receiver,

27, 37: optical fiber, 28: laser diode,

29: photodiode, 33: transmitting connector,

35: receiving connector, 40, 73, 75: power line,

41, 74, 76: ground wire, 42: DDC data line,

43: DDC clock line, 44: HPD line,

50, 60, 70: cable, 51, 61, 71: jacket.

Hereinafter, with reference to the accompanying drawings to describe the embodiment of the present invention in detail.

In the present invention, 'distance' is defined as a distance between the main body of the computer and the monitor ranging from about 5 meters to hundreds of meters to be used consistently.

3 is an external perspective view of a digital video signal interface module capable of remote transmission according to the present invention. As shown in FIG. 3, a transmission connector 33 for a computer 1 and a reception connector 35 for a monitor are provided at both ends of the cables 50, 60, and 70 of about 10 meters to several hundred meters. Table 1 below shows detailed information of each pin used for the connectors 33 and 35 shown in FIG.

pin signal pin signal pin signal One T.M.D.S. Data 2- 9 T.M.D.S. Data 1- 17 T.M.D.S. Data 0- 2 T.M.D.S. Data 2+ 10 T.M.D.S. Data 1+ 18 T.M.D.S. Data 0+ 3 T.M.D.S. Data 2/4 shield 11 T.M.D.S. Data 1/3 shield 19 T.M.D.S. Data 0/5 Shield 4 T.M.D.S. Data 4- 12 T.M.D.S. Data 3- 20 T.M.D.S. Data 5- 5 T.M.D.S. Data 4+ 13 T.M.D.S. Data 3+ 21 T.M.D.S. Data 5+ 6 DDC Clock 14 + 5V 22 T.M.D.S. Clock shield 7 DDC data 15 Ground (for + 5V) 23 T.M.D.S. Clock + 8 No connect 16 Hot Plug Detect 24 T.M.D.S. Clock

Here, TMDS is a coding algorithm of DVI (Digital Visual Interface), and there are other DFP type connectors.

4 is a block diagram of a digital video signal interface module capable of remote transmission according to a first embodiment of the present invention. As shown in FIG. 4, the block diagram is largely comprised of the computer 1, the transmission connector 33, the optical fiber 37, the receiving connector 35, and the LCD monitor 2. As shown in FIG.

Computer (1) is a computer running Windows 95, 98, Me, 2000, NT, etc. operating system R (Red), G (Green), B (Blue), C (Clock), + 5V Vcc, ground (Ground), DDC data, DDC clock, and HPD output stage.

Inside the transmission connector 33, a laser driver 30 for inputting each of the R, G, B, and C signals through a comparator to drive four laser diodes 38 is provided. The laser driver 30 is driven by the power supply line 40 and the ground line 41 of Vcc passing through the same cable 50 instead of depending on an external power source. The DDC data line 42, the DDC clock line 43, and the HPD line 44 pass through the transmission connector 33 in addition to the power supply line 40 and the ground line 41.

The cable 50 has a length ranging from several meters to several hundred meters, and has four channel optical fibers 37 and five channel lead wires therein. The four-channel optical fiber 37 is for transmitting R, G, B, and C signals, respectively, and the five-wire lead wires are the power supply line 40, the grounding line 41, the DDC data line 42, and the DDC clock, respectively. It is used as the line 43 and the HPD line 44.

Inside the receiving connector 35, each R, G, B, C signal is input through four photodiodes 39 and a comparator, restored to an electrical signal, and then amplified by a signal having a predetermined voltage. 32). The driving of the PD amplifier 32 is performed through the power supply line 40 and the ground line 41 of Vcc passing through the same cable 50, rather than depending on an external power supply. The DDC data line 42, the DDC clock line 43, and the HPD line 44 pass through the receiving connector 35 in addition to the power supply line 40 and the ground line 41.

Hereinafter, the operation of the interface module illustrated in FIG. 4 will be described.

In the DVI (Digital Visual Interface) method, the graphic signal consists of four channels: red (R), green (G), blue (B), and reference signal clock (C). Able signals and control signals are mixed and transmitted on each channel. Therefore, four signals are output from the main body of the computer 1 using the standard connector of DVI. These four signals are composed of differential signals for noise reduction and generate laser modulation signals to drive the four laser diodes 38 by the laser driver 30 which receives them.

This digital laser signal is focused on the optical fiber 37 and transmitted up to several hundred meters and then transmitted to the corresponding photodiode 39 of the receiving connector 35. The photodiode 39 restores the input optical signal to an electrical signal having a weak voltage. At this time, since the electrical signal is very weak at the level of several tens of kHz, it is amplified by the predetermined voltage (about 150 mV) in the PD amplifier 32 and transmitted to the LCD monitor 2. At the same time, by generating a differential signal, it is reproduced as an electric signal of the same level as the digital signal output from the computer 1.

Data relating to the monitor such as the manufacturer, maximum resolution, frequency band, serial number, etc. of the LCD monitor 2 is transferred from the monitor 2 to the computer 1 via the DDC. The data thus transmitted causes the graphics card (not shown) of the computer 1 to display an image in an optimal state.

If the computer 1 is turned on and the monitor 2 is turned off, there is a power line 40 and a ground line 41 which are transmitted from the computer 1 to the monitor 2 so that the above operation can be performed. Typically, 5 volts, 1 amp of power (about 5 Watts) are output from the graphics card (not shown) of the computer 1. By the way, since the power required by the monitor 2 is usually 1 Watt or less, about 4 Watts of power is generated extra. This extra power of 4 Watts drives the laser driver 30 and the PD amplifier 32.

5, 6, and 7 are various cross-sectional views of the cables 50a, 50b, and 50c of the interface module shown in FIG. As shown in FIG. 5, the cable 50a has four channels of optical fiber 37 separately separated from other lines, and is separately shielded. The shielded DDC data line 42, the DDC clock line 43, and the power line ( 40, the ground wire 41, and the HPD 44 pass through. The outermost jacket is thickly layered with a jacket 51 for protecting the inner wires, and an inner side of the outer cover is aluminum tape 53 attached for the shield.

The reason for using the shielded DDC lines 42 and 43 is as follows. The + 5V of the power supply line 40 should be 4.75V or more at the monitor end, and DDC data and clock should be + 3V or more in standard mode. Since the power of the power supply line 40 is a direct current, it can satisfy the condition as a general lead wire. In the case of DDC, since the maximum frequency is 100 KHz in the standard mode, a shielded wire must be used in order to suppress the signal attenuation and send it farther than 100 meters.

The cable 50b shown in FIG. 6 is characterized in that the optical fiber 37 passes along with other wires. In addition, in Fig. 7, the power supply line 40 and the grounding line 41 are aggregated together with the four-channel optical fiber 37, and are passed through.

8 is a block diagram of a digital video signal interface module capable of remote transmission according to a second embodiment of the present invention. If the operating system of the computer 1 is not Windows but another operating system (for example, Unix, Linux, DOS, etc.), the DDC becomes unnecessary. Therefore, as shown in FIG. 8, the DDC clock, the DDC data, and the HPD line are omitted.

As a result, only four channels of R, G, B, and C optical fibers, and two channels of lead wires of Vcc and Ground pass through the transmission connector 33, the cable 60, and the reception connector 35. 9 and 10 are various cross-sectional views of the cable of the interface module shown in FIG. As shown in Figs. 9 and 10, the cable 60a has only six channels and is relatively small in diameter because it is surrounded by the jacket 61. In FIG. 9, the optical fiber 37, the power line 40, and the ground line 41 pass through the cable 60a together without being separated. In FIG. 10, the optical fiber 37 includes the power line 40 and the ground line 41. It is divided with respect to and passes through the cable 60b.

11 is a block diagram of a digital video signal interface module capable of remote transmission according to a third embodiment of the present invention. In a very strict EMI field such as a medical device, only the pure optical fiber 37 is required as a transmission medium for the cable 70. At this time, the power supply of the laser driver 30 and the PD amplifier 32 is configured as shown in FIG.

As shown in FIG. 11, Vcc and ground output from the computer 1 are connected to the power source of the laser driver 30 through the first power line 73 and the first ground line 74. Then, the power supply of the PD amplifier 32 is connected as follows. That is, the power inside the monitor is supplied to the PD amplifier 32 through the unused NC pin in [Table 1]. At this time, the pin specifications of the receiving connector 35 are shown in [Table 2].

pin signal pin signal pin signal One T.M.D.S. Data 2- 9 T.M.D.S. Data 1- 17 T.M.D.S. Data 0- 2 T.M.D.S. Data 2+ 10 T.M.D.S. Data 1+ 18 T.M.D.S. Data 0+ 3 T.M.D.S. Data 2/4 shield 11 T.M.D.S. Data 1/3 shield 19 T.M.D.S. Data 0/5 Shield 4 T.M.D.S. Data 4- 12 T.M.D.S. Data 3- 20 T.M.D.S. Data 5- 5 T.M.D.S. Data 4+ 13 T.M.D.S. Data 3+ 21 T.M.D.S. Data 5+ 6 DDC Clock 14 + 5V 22 T.M.D.S. Clock shield 7 DDC data 15 Ground (for + 5V) 23 T.M.D.S. Clock + 8 + 5V 16 Hot Plug Detect 24 T.M.D.S. Clock

12 is a cross-sectional view of the cable 70 of the interface module shown in FIG. As shown in FIG. 12, the cable 70 has four channels of optical fiber 37 surrounded by a jacket 71, and no separate lead wire passes. Therefore, EMI requirements can be more faithfully satisfied.

The connector used in the digital video signal interface module capable of long-distance transmission of the present invention can use the Open LDI, P & D, and DFP standards as well as the DVI standard.

In addition, the shielded DDC data line 42 or DDC clock line 43 has a thickness of at least 28 AWG or more, and the thickness of the power supply line 40, the ground line 41, and the HPD line 44 is at least 24 AWG. It is ideal that there is no distortion of the signal even at a long distance.

The digital video signal interface module capable of remote transmission as described above has the following characteristics.

That is, since the DDC, which is a monitor information exchange path, is made in both directions between the computer and the monitor, a problem arises in that a plurality of channels are required to transmit and receive light. In addition, the transmission frequency of the DDC is up to 100KHz in the standard mode, which is a low frequency for optical transmission. Therefore, according to the present design and configuration, it is possible to construct an optical transmission system of an efficient digital graphic interface together with an optical fiber of a data line.

In addition, it is possible to construct a digital video interface module by using a minimum optical fiber (4 channels in the DVI standard, 5 channels in the LVDS standard), and economical construction is possible. It has the advantage of being easy to use at a cost. In other words, it can be used by connecting a computer and a monitor without an external power source.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Therefore, the scope of the utility model registration claims attached will include such modifications or variations that fall within the spirit of the present invention.

Claims (9)

A laser driver 30 and a laser diode 38 for receiving the digital video signals R, G, B, and Clock output from the computer 1 and converting them into respective laser signals; A photodiode (39) for receiving each laser signal and restoring it into an electrical signal, and a photo-diode (PD) amplifier (32) for amplifying and transmitting the signal of each photodiode (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; A power line 40 and a ground line 41 installed between the computer 1 and the LCD monitor 2 along the optical fiber 37 to supply power to the laser driver 30 and the PD amplifier 32. A digital video signal interface module capable of remote transmission, comprising: a. A laser driver 30 and a laser diode 38 for receiving the digital video signals R, G, B, and Clock output from the computer 1 and converting them into respective laser signals; A photodiode (39) for receiving the respective laser signals and restoring the electrical signal, and a PD amplifier (32) for amplifying and transmitting the signals of the photodiodes (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; Information transmission means provided between the computer (1) and the LCD monitor (2) along the optical fiber (37) to transmit information data about the LCD monitor (2) to the computer (1); A power line 40 provided between the computer 1 and the LCD monitor 2 along the optical fiber 37 to supply power to the laser driver 30, the PD amplifier 32, and the transmission means; And a ground wire (41). The digital video signal interface module capable of remote transmission, characterized in that it comprises a. The method of claim 2, wherein the information transmitting means is a Hot Plug Datection (HPD) line for checking a connection state of a data display channel (DDC) data line 42, a DDC clock line 43, and the monitor 2; A digital video signal interface module capable of remote transmission, characterized in that it is composed of (44). 4. The digital video signal interface module of claim 3, wherein the DDC data line 42 and the DDC clock line 43 are shielded, respectively. 5. The digital video signal interface module as claimed in claim 4, wherein the shielded DDC data line (42) or DDC clock line (43) has a thickness of 28 AWG or more. 6. The digital video signal interface module according to any one of claims 3 to 5, wherein the power lines (40), ground lines (41), and HPD lines (44) have a thickness of 24 AWG or more. A laser driver 30 and a laser diode 38 for receiving the digital video signals R, G, B, and Clock output from the computer 1 and converting them into respective laser signals; A photodiode (39) for receiving the respective laser signals and restoring the electrical signal, and a PD amplifier (32) for amplifying and transmitting the signals of the photodiodes (39) to the LCD monitor (2); A plurality of optical fibers (37) installed between each of the laser diodes (38) and each of the photodiodes (39) to transmit the laser signal; A first power line 73 and a first ground line 74 for supplying power from the computer 1 to the laser driver 30; And a second power supply line (75) and a second ground line (76) for supplying power from the monitor (2) to the PD amplifier (32). 8. The digital video signal interface module as claimed in claim 7, wherein the second power line (75) is connected through a NC (No Connect) pin between the PD amplifier 32 and the monitor 2. . 8. The long-distance transmission is possible according to any one of claims 1, 2 and 7, wherein the optical fiber 37 is a 4-channel DVI (Digital Visual Interface) standard or a 5-channel LVDS () standard. Digital Video Signal Interface Module.