KR20090092118A - Apparatus of transmitting digital-image - Google Patents

Abstract

A digital-image transmission apparatus for transmitting the digital video data of HDMI or a DVI form is provided to limit the transmission range between the display device and the host machine by relaying EDID(Extended Display Identification Data) of a display device. A transmitter(31) is connected to a host device. A receiver(32) is connected to the display device. A transmission cable is connected between the transmission unit and the receiving unit. The transmission unit receives the communications speed lower than the communications speed of the host device of EDID of the display device. According to the transmission unit is 'the communications speed of the host device, EDID is transmitted with the host device.

Description

Apparatus of transmitting digital-image

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital-video transmission apparatus for transmitting digital video data, and more particularly, to digital-video transmission for transmitting digital video data in a high definition multimedia interface (HDMI) or digital visual interface (DVI) format. Relates to a device.

Referring to FIG. 1, the basic HDMI format digital video system includes a host device 11, a display device 12, and an electric cable. Herein, the electric cable is connected between the input / output terminals T _H1 to T _H14 of the host device 11 and the input / output terminals T _D1 to T _D14 of the display device 12.

The host device 11 includes an HDMI transmitter 111 and a graphics controller 112. The display device 12 includes a serial EEPROM (Electrically Erasable and Programmable Read Only Memory) 122 and an HDMI receiver 121.

The HDMI transmitter 111 in the host device 11 converts the audio data S _AUD , the clock signal S _CS , and the digital image data S _VID into Transition Minimized Differential Signaling (TMDS) signals according to the HDMI format. And output to the display device 12.

More specifically, the audio data S _AUD and the digital image data S _VID are processed by the HDMI transmitter 111 so that the red signals S _{R +} and S _{R −} of the two channels and the green of the two channels are processed. The signals S _{G +} and S _{G −} are output as blue signals S _{R +} and S _{R −} of two channels. The clock signal S _CS is processed by the HDMI transmitter 111 and output as the clock signals CLK + and CLK− of two channels.

The serial EEPROM 122 in the display device 12 stores the Extended Display Identification Data (EDID) of the display device 12 and stores the graphics in the host device 11 according to the Inter-Integrated Circuit (I ² C) communication protocol. The EDID is provided to the controller 112.

In the I ² C communication as described above, the graphic controller 112 transmits and receives a data signal SDA together with the serial EEPROM 122 while transmitting the clock signal SCL to the serial EEPROM 122. The graphic controller 112 provides a power supply potential (+ 5V) and a ground potential (GND) to the serial EEPROM 122 for the operation of the serial EEPROM 122. The display device 12 applies the HPD (Hot Plug Detect) signal voltage HPD to the graphic controller 112, and thus the graphic controller 112 detects that the display device 12 is connected to the display device 12. Unused spare terminals T _H14 , T _D14 are called NC (No Connection) terminals.

The graphic controller 112 in the host device 11 controls the operation of the HDMI transmitter 111 according to the EDID.

The HDMI receiver 121 in the display device 12 restores TMDS signals of the HDMI format from the host device 11 to audio data S _AUD , a clock signal S _CS , and digital image data S _VID . .

2 shows a digital imaging system in a general DVI (Digital Visual Interface) format. In FIG. 2, the same reference numerals as used in FIG. 1 indicate objects of the same function. Only differences of the system of FIG. 2 relative to the system of FIG. 1 are described below. Referring to FIG. 2, the basic DVI format digital imaging system includes a host device 21, a display device 22, and an electric cable. Herein, the electric cable is connected between the input / output terminals T _H1 to T _H14 of the host device 21 and the input / output terminals T _D1 to T _D14 of the display device 22.

The host device 21 includes a TMDS transmitter 211 and a graphic controller 212. The display device 22 includes a serial EEPROM 222 and a TMDS receiver 221.

The TMDS transmitter 211 in the host device 11 converts the clock signal S _CS and the digital image data S _VID into Transition Minimized Differential Signaling (TMDS) signals according to the DVI format, and outputs them to the display device 22. do.

The serial EEPROM 222 in the display device 22 stores the Extended Display Identification Data (EDID) of the display device 22 and stores the graphics in the host device 21 according to the Inter-Integrated Circuit (I ² C) communication protocol. The EDID is provided to the control unit 212.

The graphic controller 212 in the host device 21 controls the operation of the TMDS transmitter 211 according to the EDID.

The TMDS receiver 221 in the display device 22 restores the TMDS signals of the DVI format from the host device 21 to the clock signal S _CS and the digital image data S _VID .

1 or 2, the longest distance between the host devices 11 and 21 and the display devices 12 and 22 is limited to about 10 meters (m). If the distance between the host device 11, 21 and the display device 12, 22 is a long distance, a digital-video transmission device such as an optical cable module or an electric cable module is required. Representative electrical cable modules are called repeaters.

However, even in the case of the digital-video transmission device as described above, the transmission distance is considerably limited. The basic reason is that the host device 11, 21 according to the I ² C (Inter-Integrated Circuit) communication protocol in order to obtain the EDID (Extended Display Identification Data) from the display device (12, 22) To communicate with (12,22). In other words, as is well known, perfect synchronization is required to communicate according to the I ² C (Inter-Integrated Circuit) communication protocol, so that even if a digital-video transmission device is adopted to extend the transmission distance, the transmission distance is quite large. Restricted

SUMMARY OF THE INVENTION An object of the present invention is to provide a digital-video transmission apparatus in which the transmission distance between the host apparatus and the display apparatus is not restricted by effectively relaying the extended display identification data (EDID) of the display apparatus to the host apparatus. .

The digital-video transmission device of the present invention includes a transmitter connected to a host device, a receiver connected to a display device, and a transmission cable connected between the transmitter and the receiver. The transmitter, after receiving the EDID (Extended Display Identification Data) of the display device at a communication speed lower than the communication speed of the host device, and transmits the EDID to the host device according to the communication speed of the host device.

According to the digital-video transmission device of the present invention, since the transmitter receives and relays the EDID (Extended Display Identification Data) of the display device in advance at a communication speed (frequency) lower than the communication speed (frequency) of the host device, Even if the transmission distance between the host device and the display device increases, the synchronization required by the I ² C (Inter-Integrated Circuit) communication protocol may be satisfied. For example, since the I ² C communication speed (frequency) in the conventional host device 20 KHz to 100 KHz received a limit to the transmission distance, the digital to the present invention - I ² C communication speed (the frequency of transmission of the video transmitting apparatus As) decreases to 200 Hz, the transmission distance between the host device and the display device, that is, the length of the transmission cable can be significantly extended. For reference, although the I ² C communication speed (frequency) of the transmitter of the digital-video transmission device of the present invention is lowered to 200 Hz, the time required for receiving the EDID was less than 1 second. That is, the transmission distance between the host device and the display device may not be limited without causing inconvenience to the user.

1 is a diagram illustrating a basic digital-imaging system of a high definition multimedia interface (HDMI) format.

2 is a diagram illustrating a basic digital visual interface (DVI) digital-video transmission system.

3 is a view showing an optical cable module as a digital-video transmission device interposed between the host device and the display device of FIG. 1 or 2 according to the first embodiment of the present invention.

4 is a flow chart showing the operation algorithm of the micro-controller of FIG.

5 is a diagram illustrating an electric cable module as a digital-video transmission device interposed between the host device and the display device of FIG. 1 or 2 according to the second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

11,21 ... host device, 111 ... HDMI transmitter,

112,212 ... graphic controls, 12,22 ... display devices,

121 ... HDMI receiver, 122,222,313,513 ... serial EEPROM,

211 ... TMDS transmitter, 221 ... TMDS receiver,

31,51 ... transmitter, 32,52 ... receiver,

311 light emitting driver, 321 light receiving amplifier,

312,512 ... micro-controller, 511 ... TMDS amplifier,

521 ...... TMDS limiting amplifier, 522 ... I ² C buffer.

Hereinafter, one embodiment of the present invention will be described in detail.

3 shows an optical cable module as a digital-image transmission device interposed between the host device 11 or 21 and the display device 12 or 22 of FIG. 1 or 2 according to the first embodiment of the present invention. In FIG. 3, the same reference numerals as used in FIG. 1 or 2 indicate the objects of the same function. The basic digital imaging system of FIG. 1 or FIG. 2 described above is equally applied to the first embodiment of the present invention, and thus description thereof is omitted.

1 to 3, the digital-image transmission apparatus of the first embodiment of the present invention is a fiber optic line (T)_H15-T_D15 To T_H21-T_D21), Electric cables (T_H22-T_D22 To T_H24-T_D24), A transmitting unit 31, and a receiving unit 32 is an optical cable module. Reference sign L in FIG. 3_H1 To L_H6 And L_D1 Silver light emitting diodes, and P_D1 To P_D6 And P_H1 Indicates light receiving diodes.

The transmitter 31 includes a light emitting driver 311, light emitting diodes L _H1 to L _H6 , a light receiving diode P _H1 , a micro-controller 312, and a serial EEPROM (Electrically Erasable and Programmable Read Only Memory) 313. It includes.

The light emission driver 311 and the light emitting diodes L _H1 to L _H4 receive the digital image data (S _{R +} to CLK − in FIG. 1 or 2) from the host device 11 or 21 to the optical signals S _R. To CLK) to convert optical fibers (T _H15 -T _D15) To T _H18 -T _D18 ).

In addition, the micro-controller 312, the light emitting diodes L _H5 and L _H6 , the light receiving diode P _H1 , and the serial EEPROM 313 may be configured as clock signals for I ² C communication from the host device 11 or 21. SCL) and data SDA by converting the optical signals SCL and SDA _R into optical fiber lines T _H19 -T _D19 And T _H20 -T _D20 , and converts the I ² C communication data SDA _L from the optical fiber lines T _H21 -T _D21 into electrical signals and provides them to the host device 11 or 21.

Here, the micro-controller 312 may be connected to the display device 12, 22 at a communication speed (frequency), for example, 200 Hz, which is lower than the communication speed of the host device 11 or 21 (typically 20 KHz to 100 KHz). After receiving the Extended Display Identification Data (EDID) and storing it in the serial EEPROM 313, the EDID stored in the EEPROM 313 according to the communication speed (frequency) of the host device 11 or 21 is stored in the host device 11 or To 21).

Of course, the micro-controller 312 communicates with the display device 12 or 22 according to the I ² C (Inter-Integrated Circuit) communication protocol, and the EDID of the display device 12 or 22 is extended. The data is stored in the EEPROM 313.

Next, the micro-controller 312 communicates with the host device 11 or 21 in accordance with an Inter-Integrated Circuit (I ² C) communication protocol and transmits the EDID stored in the EEPROM 313 to the host device 11 or. To 21).

Therefore, since the transmitter 31 receives and relays the EDID (Extended Display Identification Data) of the display apparatus 12 or 22 in advance at a communication speed (frequency) lower than the communication speed (frequency) of the host device 11 or 21, Even if the transmission distance between the host device 11 or 21 and the display device 12 or 22 increases, the synchronization required by the Inter-Integrated Circuit (I ² C) communication protocol may be satisfied. For example, although the I ² C communication speed of the conventional host device 11 or 21 is 20 KHz to 100 KHz, the transmission distance is limited, but the I ² C of the transmitter 31 of the digital-video transmission device of the present embodiment is limited. As the communication speed drops to 200 Hz, the transmission distance, i.e. the transmission cable (T _H15 -T _D15 To T _H24 -T _D24 ) may be significantly extended. For reference, although the I ² C communication speed of the transmitter 31 of the digital-video transmission device of the present embodiment is lowered to 200 Hz, the time required for receiving the EDID was less than 1 second. That is, the transmission distance between the host device 11 or 21 and the display device 12 or 22 may not be limited without causing inconvenience to the user.

On the other hand, the receiver 32 is an optical cable (T _H15 -T _D15). To T _H20 -T _D20 optical signals S _R To SDA _R ) is converted into the digital image data S _{R +} to CLK-and the I ² C communication clock signal SCL and data SDA by the light receiving amplifier 321 to display the display device 12 or 22. ) And converts the I ² C communication data SDA from the display device 12 or 22 into an optical signal SDA _L and outputs it to the optical cable T _H21 -T _D21 .

4 shows an operation algorithm of the micro-controller 312 of FIG. The operation algorithm of the micro-controller 312 of FIG. 3 will be described with reference to FIGS. 3 and 4 as follows.

First, the micro-controller 312 is a host device as a logical '0' state in which the Hot Plug Detect (HPD) signal, which is a contact confirmation signal of the display device 12 or 22 to be input to the host device 11 or 21, is in an inactive state. Output to 11 or 21 (step S41). Accordingly, the micro-controller 312 determines that the display device 12 or 22 is not connected and does not transmit digital image data (S _{R +} to CLK − in FIG. 1 or 2).

Next, when the Hot Plug Detect (HPD) signal, which is the contact confirmation signal from the display device 12 or 22, is in a logic '1' state in which it is activated (step S42), the state of being connected to the display device 12 or 22 is established. Therefore, the micro-controller 312 is connected with the display device 12 or 22 at a communication speed lower than the communication speed of the host device 11 or 21 (typically 20 KHz to 100 KHz), for example, 200 Hz. While performing communication, Extended Display Identification Data (EDID) of the display device 12 or 22 is stored in the EEPROM 313 (step S43).

When the EDID is all stored in the EEPROM 313, the micro-controller 312 may activate a logic '1' in which the contact confirmation signal HPD of the display device 12 or 22 to be input to the host device 11 or 21 is activated. It outputs to the host apparatus 11 or 21 as a state (step S44).

Accordingly, the host device 11 or 21 is considered to be connected with the display device 12 or 22 and operates to obtain an EDID. Correspondingly, the micro-controller 312 transmits the EDID stored in the EEPROM 313 to the host device 11 or 21 according to the communication speed (frequency) of the host device 11 or 21 (step S45). .

5 shows an electrical cable module as a digital-video transmission device interposed between the host device 11 or 21 and the display device 12 or 22 of FIG. 1 or 2 according to a second embodiment of the invention. In Fig. 5, the same reference numerals as those in Fig. 1 or 2 indicate the objects of the same function. The basic digital imaging system of FIG. 1 or FIG. 2 described above is equally applied to the first embodiment of the present invention, and thus description thereof is omitted.

1, 2, and 5, the digital-video transmission apparatus of the second embodiment of the present invention includes an electric cable (T _{H15 +} -T _{D15 +} to T _H24 -T _D24 ), a transmitter 51, and a receiver ( 52) including electric cable module.

The transmitter 51 includes a transition minimized differential signaling (TMDS) amplifier 511, a micro-controller 512, and a serial electrically erasable and programmable read only memory 513.

The TMDS amplifying unit 511 amplifies the digital image data (S _{R +} to CLK− in FIG. 1 or 2) from the host device 11 or 21 to generate electric wires T _H15 -T _D15. To T _H18 -T _D18 ).

In addition, the micro-controller 512 and the serial EEPROM 513 transmit the I ² C communication clock signal SCL and data SDA from the host device 11 or 21 to the electric wires T _H19 -T _D19. And T _H20 -T _D20 , and provide I ² C communication data SDA from the electric line T _H20 -T _D20 to the host device 11 or 21.

Here, the micro-controller 512 is a communication speed (frequency) lower than the communication speed of the host device 11 or 21 (typically 20 KHz to 100 KHz), for example 200 Hz of the display device 12,22. After receiving the EDID (Extended Display Identification Data) and storing it in the serial EEPROM 513, the EDID stored in the EEPROM 513 is stored according to the communication speed (frequency) of the host device 11 or 21. To 21).

Of course, the micro-controller 512 communicates with the display device 12 or 22 in accordance with the I ² C (Inter-Integrated Circuit) communication protocol, while the ED- (Extended Display Identification Data) of the display device 12 or 22 is received. The data is stored in the EEPROM 513.

Next, the micro-controller 312 communicates with the host device 11 or 21 in accordance with an Inter-Integrated Circuit (I ² C) communication protocol and transmits the EDID stored in the EEPROM 513 to the host device 11 or. To 21).

Therefore, since the transmission unit 51 receives and relays the EDID (Extended Display Identification Data) of the display device 12 or 22 in advance at a communication speed (frequency) lower than the communication speed (frequency) of the host device 11 or 21, Even if the transmission distance between the host device 11 or 21 and the display device 12 or 22 increases, the synchronization required by the Inter-Integrated Circuit (I ² C) communication protocol may be satisfied. For example, since the I ² C communication speed of the conventional host device 11 or 21 is 20 KHz to 100 KHz, the transmission distance is limited, but the I ² C of the transmitter 51 of the digital-video transmission device of the present embodiment is limited. As the communication speed drops to 200 Hz, the transmission distance, i.e. the transmission cable (T _H15 -T _D15 To T _H24 -T _D24 ) may be significantly extended. For reference, although the I ² C communication speed of the transmitter 51 of the digital-video transmission device of the present embodiment was lowered to 200 Hz, the time required for receiving the EDID was less than 1 second. That is, the transmission distance between the host device 11 or 21 and the display device 12 or 22 may not be limited without causing inconvenience to the user.

Meanwhile, the receiver 52 includes a TMDS limited amplifier 521 and an I ² C buffer 522.

TMDS limited amplification unit 721 is the electric lines (T _H15 -T _D15) To T _H18 -T _D18 ) and amplify the digital image data (S _{R +} to CLK-in FIG. 1 or 2) to the display device 12 or 22.

I ² C buffer 522, the electric lines (T _H19 -T _D19) And buffers the clock signal SCL and data SDA for I ² C communication from T _H20 -T _D20 and provides the buffer to the display device 12 or 22, and for I ² C communication from the display device 12 or 22. The data SDA is buffered and output to the electric cables T _H20 -T _D20 .

The operation algorithm of the micro-controller 512 of this embodiment is as described with reference to FIG.

As described above, according to the digital-video transmission device according to the present invention, the transmitter receives in advance the Extended Display Identification Data (EDID) of the display device at a communication speed (frequency) lower than the communication speed (frequency) of the host device. Because of the relay, even if the transmission distance between the host device and the display device increases, the synchronization required by the I ² C (Inter-Integrated Circuit) communication protocol can be satisfied. For example, since the I ² C communication speed (frequency) in the conventional host device 20 KHz to 100 KHz received a limit to the transmission distance, digital according to the invention - I ² C communication speed (the frequency of transmission of the video transmitting apparatus As) decreases to 200 Hz, the transmission distance between the host device and the display device, that is, the length of the transmission cable can be significantly extended. For reference, although the I ² C communication speed (frequency) of the transmitter of the digital-video transmission device according to the present invention is lowered to 200 Hz, the time required for receiving the EDID was less than 1 second. That is, the transmission distance between the host device and the display device may not be limited without causing inconvenience to the user.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (7)

A digital-video transmission apparatus including a transmitter connected to a host device, a receiver connected to a display device, and a transmission cable connected between the transmitter and the receiver, The transmitting unit, And receiving the extended display identification data (EDID) of the display device at a communication speed lower than that of the host device, and then transmitting the EDID to the host device according to the communication speed of the host device. A digital-video transmission apparatus including a transmitter connected to a host device, a receiver connected to a display device, and a transmission cable connected between the transmitter and the receiver, The transmitting unit, Memory; And After receiving and storing the Extended Display Identification Data (EDID) of the display device at a communication rate lower than that of the host device, the EDID stored in the memory is stored according to the communication speed of the host device. Digital-video transmission device including a micro-controller for transmitting to the host device. The method of claim 2, And said memory is a serial electrically erasable and programmable read only memory (EEPROM). The method of claim 2, wherein in the transmitting unit, And a micro-controller storing the extended display identification data (EDID) of the display device in the memory while communicating with the display device according to an I ² C (Inter-Integrated Circuit) communication protocol. The method of claim 4, wherein in the transmitting unit, And the micro-controller transmits the EDID stored in the memory to the host device while communicating with the host device according to an I ² C (Inter-Integrated Circuit) communication protocol. The method of claim 5, wherein the micro-controller, After outputting the contact confirmation signal of the display device to be input to the host device to the host device in an inactive state, When the touch confirmation signal from the display device is in an activated state, the Extended Display Identification Data (EDID) of the display device is stored in the memory while communicating with the display device at a communication rate lower than that of the host device. Digital video transmission device. The method of claim 6, wherein the micro-controller, Once all of the EDID is stored in the memory, After outputting the contact confirmation signal of the display device to be input to the host device in the active state to the host device, And transmitting the EDID stored in the memory to the host device according to the communication speed of the host device.