JP2010286529A - Liquid crystal display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal display device capable of forming an empty space enabling a reproducing unit or the like to mount in an upper end part of a rear surface of this liquid crystal display device (LCD) by turning the direction of installation of the LCD upside down and displaying by inverting the liquid crystal display device in the vertical direction without adding a new printed wiring board. <P>SOLUTION: In this liquid crystal display device, signal lines CL, RL, and SL are formed in each of COF gd1, gd2, ..., gdm and are connected with a controller 4. The signal line CL is a line for transmitting a clock signal CPV for gate. The signal line RL is a line for connecting the controller 4 with a gate driver GDm directly to transmit a start pulse signal STV to the gate driver GDm directly. The signal line SL is a line for transmitting the start pulse signal input into the gate driver GDm in the direction of a gate driver GD1 from the gate driver GDm. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a liquid crystal display device such as a liquid crystal television.

  In recent years, liquid crystal display devices such as liquid crystal televisions are widely used. Hereinafter, the substrate arrangement of the liquid crystal television will be described.

  FIG. 1 is a substrate layout diagram in the back side of a conventional liquid crystal television. On the back surface of the LCD (liquid crystal display) module, a digital board A, a power board B, an inverter board C, and printed boards XR and XL are arranged.

  The power supply board B converts a commercial AC power supply voltage into a DC power supply voltage, generates various power supply voltages based on the DC power supply voltage, and supplies each power supply voltage to each circuit such as the digital board A and the inverter board C. Supply through. Here, the digital board A is connected to the power supply board B via the cable 32. The printed boards XR and XL are connected to each other via a cable 43, and the printed board XL is connected to the digital board A via a cable 42. Further, the inverter board C is connected to the power supply board B via the cable 31. The power supply voltage generated by the power supply board B is input to the printed board XL via the cable 32, the digital board A, and the cable 42. Further, this power supply voltage is also input from the printed circuit board XL to the printed circuit board XR via the cable 43. This power supply voltage is supplied from the printed circuit boards XR and XL to the COF (chip on film) group X, and from the rightmost COF of the COF group X to the COF group Y via the wiring formed in the liquid crystal cell. Is done.

  The digital board A extracts the TV broadcast signal of the selected channel from the TV broadcast signal received via the antenna by the tuner 10. Further, the digital substrate A separates the video signal and the audio signal from the television broadcast signal by the video signal processing circuit. The digital board A D / A converts the separated digital audio signal into an analog audio signal and outputs the audio from the speaker. Further, the digital board A generates image data for one screen of the LCD based on the separated video signal in the video signal processing circuit, and generates a panel drive signal based on the image data. The digital board A outputs the generated panel drive signal to the printed board XL via the cable 42. This panel drive signal is also input from the printed circuit board XL to the printed circuit board XR via the cable 43.

  The printed circuit boards XR and XL are arranged at the upper back portion of the LCD. The printed boards XR and XL are connected to a COF group X equipped with a plurality of source driver ICs for driving a plurality of source lines formed in the vertical direction of the liquid crystal panel. The COF at the right end of the COF group X is connected to a COF group Y equipped with a plurality of gate driver ICs for driving a plurality of gate lines formed in the horizontal direction of the liquid crystal panel. The COF group X and the COF group Y drive each pixel of the LCD configured by the pixel arrangement based on the panel drive signal, and display an image based on the image data on the LCD screen.

The above is the description regarding the substrate arrangement of the conventional liquid crystal display device.
Note that Patent Document 1 proposes a liquid crystal display device capable of left-right reversal display.

JP-A-6-160803

  In the above conventional liquid crystal display device, there is an industry demand for attaching a playback device or the like for reading data from a medium such as a DVD to the upper back end of the LCD.

  However, printed circuit boards XR, XL and COF group X are present at the upper back of the LCD in the conventional liquid crystal display device as shown in FIG. The printed circuit boards XR, XL, and COF group X cannot be moved to another location because the source driver IC group needs to drive a plurality of source lines. Therefore, in the conventional liquid crystal display device, the presence of the printed boards XR and XL and the COF group X becomes an obstacle, and a reproducing apparatus or the like cannot be attached to the rear upper end portion of the LCD due to restrictions on the board arrangement.

  The present invention is intended to solve such a conventional problem, and the LCD installation direction is turned upside down to form a free space in the upper rear surface of the LCD so that a playback device or the like can be attached. It is an object of the present invention to provide a liquid crystal display device capable of displaying upside down without adding a substrate.

  The liquid crystal display device of the present invention has the following configuration in order to solve the above problems.

(1) a liquid crystal panel including a plurality of gate lines, a plurality of source lines, and a plurality of pixels surrounded by the two lines;
A plurality of gate driver ICs for driving a plurality of gate lines of the liquid crystal panel;
A plurality of source driver ICs for driving a plurality of source lines of the liquid crystal panel;
The gate driver IC is instructed to sequentially drive all the gate lines line by line to turn on the transistor elements for one line, and the image data for one line is transmitted to each pixel through the turned on transistor elements. A timing controller that instructs the source driver IC to write
The timing controller is mounted on a printed circuit board disposed at the lower end on the back side of the liquid crystal panel,
The plurality of source driver ICs are mounted on a first flexible printed circuit board disposed at a lower end on the back side of the liquid crystal panel,
In the liquid crystal display device, the plurality of gate driver ICs are mounted on a second flexible printed circuit board,
The second flexible printed circuit board includes a first signal line for connecting the plurality of gate driver ICs in a cascade, a termination gate driver IC at the termination position of the cascade connection among all the gate driver ICs, and the timing controller. And a second signal line directly connecting the two,
The timing controller outputs a start pulse signal indicating a start timing of one frame for turning on a leading gate line to the termination gate driver IC via the second signal line.

In this configuration, it is assumed that the LCD module (hereinafter referred to as LCD) is installed upside down. When the installation direction of the LCD is turned upside down, the substrate arrangement on the back surface of the LCD is such that the first flexible printed circuit board and the printed circuit board are disposed on the lower end of the back surface of the LCD. In this board arrangement, an empty space is formed at the upper end of the back surface of the LCD, so that a playback device or the like for reproducing video / audio data recorded on the medium can be attached to this empty space.
Further, in this substrate arrangement, the start pulse signal is first input to the termination gate driver IC, not the start gate driver IC that is initially input when the installation direction is normal. Therefore, one frame of video is also displayed in an inverted state on the liquid crystal panel screen. The propagation of both signals is achieved by forming the first signal line and the second signal line on the second flexible printed circuit board without adding a new printed circuit board. Therefore, with this wiring pattern, the image of one frame can be displayed upside down without adding a new printed circuit board.
As described above, it is possible to form a vacant space in the rear upper end of the LCD by turning the LCD installation direction upside down, and display it upside down without adding a new printed circuit board. For this reason, it is not necessary to procure a material dedicated to a new printed board or to add a dedicated manufacturing process for adding a new printed board, so that the manufacturing cost can be reduced.

(2) The second flexible printed circuit board includes a gate line for turning on the transistor elements from the start gate driver IC at the start position of the cascade connection to the end gate driver IC among all the gate driver ICs. A third signal line for propagating a shift signal indicating the timing of shifting the signal is formed.

  In this configuration, the shift signal propagates through each gate driver IC from the start gate driver IC to the end gate driver IC.

(3) The first signal line is a line for propagating the start pulse signal input to the termination gate driver IC from the termination gate driver IC toward the start gate driver IC.

  In this configuration, the start pulse signal and the shift signal propagate in directions opposite to each other with respect to the connection direction of each gate driver IC.

  According to the present invention, the installation direction of the LCD is turned upside down so that a free space in which a playback device or the like can be attached is formed at the upper end of the back surface of the LCD, and displayed upside down without adding a new printed circuit board. be able to.

Substrate layout on the back of the LCD of a conventional liquid crystal television The block diagram which shows the main structures of the liquid crystal television which is embodiment of this invention Substrate layout diagram on the LCD back surface of the liquid crystal television according to the embodiment of the present invention The figure which shows the structure of the gate driver group of the liquid crystal television which is embodiment of this invention The figure which shows the waveform of the main signal input into the gate driver group or the source driver group from the controller of the liquid crystal television which is embodiment of this invention

  Hereinafter, a liquid crystal television which is an embodiment of the present invention will be described.

  FIG. 2 is a block diagram showing a main configuration of a liquid crystal television which is an embodiment of the present invention. The liquid crystal television 1 includes a tuner 10, a video signal processing circuit 12, a liquid crystal display (LCD) 26, an audio processing circuit 16, a speaker 18, a power supply circuit 20, a rectifier circuit 22, an inverter circuit 24, Is provided.

  The tuner 10 extracts a television broadcast signal (video / audio signal) of a selected channel from a television broadcast signal received via the antenna 10 a and outputs the extracted signal to the video signal processing circuit 12. The TV broadcast signal to be received may be analog broadcast and digital broadcast. When an analog television broadcast signal is received, it is A / D converted and digitized by a video signal processing circuit 12 described later.

  The video signal processing circuit 12 is a one-chip IC that performs digital processing. The video signal processing circuit 12 includes an A / D converter, a video decoder (V / D), a scaler, and a timing controller (Tcont) 4. The video signal processing circuit 12 has a composite terminal to which an analog composite signal is input and an HDMI (registered trademark) terminal 12a to which a digital video / audio signal can be input / output.

  The V / D separates the video signal and the audio signal from the digital video / audio signal input from the tuner 10 or the HDMI (registered trademark) terminal 12a, outputs the separated audio signal to the audio processing circuit 16, and The R, G, and B primary color signals are demodulated from the separated video signal. V / D is also used for RGB video signals, color adjustment such as color density adjustment, contrast adjustment, TINT adjustment, brightness adjustment, skin color correction, black and white expansion adjustment, delay adjustment, gamma correction, sharpness adjustment, and noise removal. , And the like, and output to the scaler. The scaler converts a continuous interlaced video signal into a progressive video signal so that the input digital video signal matches the number of screen pixels (aspect ratio, m: n) of the liquid crystal panel 5. Then, the scaling process is performed, image data for one screen to be displayed on the liquid crystal panel 5 is generated, and the generated image data is output to Tcont4. Tcont4 generates a panel drive signal (control signal) based on the input image data and outputs the panel drive signal to the driver circuit 14.

  The driver circuit 14 includes a plurality of source driver ICs that drive the source lines of the liquid crystal panel 5 that constitute the LCD 26, and a plurality of gate driver ICs that drive the gate lines of the liquid crystal panel 5. The driver circuit 14 drives each pixel of the liquid crystal panel 5 configured by the pixel arrangement based on the panel drive signal, and displays an image based on the image data on the screen of the liquid crystal panel 5.

  When a digital audio signal is input, the audio processing circuit 16 D / A converts the digital audio signal into an analog audio signal. Further, the audio processing circuit 16 amplifies the analog audio signal with a built-in amplifier, and then outputs it to the speaker 18 for audio output.

  The rectifier circuit 22 receives an AC power supply voltage from a commercial power supply via the AC cable 22a, converts the AC power supply voltage into a DC power supply voltage, and supplies the DC power supply voltage to the inverter circuit 24 and the power supply circuit 20. The power supply circuit 20 generates various voltages based on the DC power supply voltage supplied from the rectifier circuit 22 and supplies the generated voltages to each circuit except the inverter circuit 24.

  The inverter circuit 24 converts the DC power supply voltage supplied from the rectifier circuit 22 into a high-frequency AC voltage, supplies an AC voltage as a drive signal to the backlight of the LCD 26 via an inverter harness (not shown), Light up.

  3A is a substrate layout diagram on the back surface of the LCD, and FIG. 3B is a substrate layout diagram on the back surface of the LCD when the installation direction of the LCD is turned upside down. Here, the LCD 26 is an LCD module, and includes a liquid crystal panel 5, a backlight as a light source, a reflecting plate that reflects the light, and a rear chassis 6 that covers the reflecting plate.

  The back surface (rear chassis 6) of the LCD 26 shown in FIGS. 3A and 3B is covered with a rear cabinet that constitutes a part of the casing of the liquid crystal television 1. A digital board A, a power board B, an inverter board C, and printed boards XR and XL are attached to the rear chassis 6 of the LCD 26 with the rear cabinet removed. Hereinafter, the positional relationship of each substrate and the circuit mounted on each substrate will be described with reference to FIG.

  The power supply board B mounts the rectifier circuit 22 and the power supply circuit 20 and is disposed at the center of the back surface of the LCD 26. The power supply board B converts a commercial AC power supply voltage into a DC power supply voltage, generates various power supply voltages based on the DC power supply voltage, and supplies each power supply voltage to each circuit such as the digital board A and the inverter board C. Supply through. Here, the digital board A is connected to the power supply board B via the cable 32. The printed boards XR and XL are connected to each other via a cable 43, and the printed board XL is connected to the digital board A via a cable 42. Further, the inverter board C is connected to the power supply board B via the cable 31. The power supply voltage generated by the power supply board B is input to the printed board XL via the cable 32, the digital board A, and the cable 42. Further, this power supply voltage is also input from the printed circuit board XL to the printed circuit board XR via the cable 43. This power supply voltage is supplied from the printed circuit boards XR and XL to the COF (chip on film) group X, and from the rightmost COF of the COF group X to the COF group Y via the wiring formed in the liquid crystal cell. Is done.

  The inverter board C is mounted with the inverter circuit 24 and is arranged to be long and vertically oriented on the left side of the back surface of the LCD 26.

  The digital board A is arranged on the upper right side on the back surface of the LCD 26. On the digital board A, a video signal processing circuit 12 is mounted, and an HDMI terminal 12a, a composite terminal, and a tuner 10 are arranged. The digital board A uses the tuner 10 to extract a television broadcast signal (video / audio signal) of a selected channel from a television broadcast signal received via the antenna 10a. Further, the digital board A uses the video signal processing circuit 12 to separate the video signal and the audio signal from the video / audio signal input from the tuner 10 or the HDMI terminal 12a. The digital board A D / A converts the separated digital audio signal into an analog audio signal and outputs the audio from the speaker 18. Further, the digital board A generates image data for one screen of the liquid crystal panel 5 based on the separated video signal, and generates a panel drive signal based on the image data. The digital board A outputs the generated panel drive signal to the printed board XL via the cable 42. This panel drive signal is also input from the printed circuit board XL to the printed circuit board XR via the cable 43.

  The printed circuit boards XR and XL are arranged at the upper rear end portion of the LCD 26. The printed boards XR and XL are connected to a COF group X equipped with a plurality of source driver ICs for driving a plurality of source lines formed in the vertical direction of the liquid crystal panel 5. The COF at the right end of the COF group X is connected to a COF group Y equipped with a plurality of gate driver ICs for driving a plurality of gate lines formed in the horizontal direction of the liquid crystal panel 5. That is, the COF group X and the COF group Y have the driver circuit 14 mounted thereon. The COF group X and the COF group Y drive each pixel of the liquid crystal panel 5 configured by the pixel arrangement based on the panel drive signal, and display a video based on the image data on the screen of the liquid crystal panel 5.

  The above is the description regarding the substrate arrangement of the liquid crystal television 1 according to the embodiment of the present invention.

  Here, when the installation direction of the LCD 26 is turned upside down, the substrate arrangement on the back surface of the LCD 26 is in the state shown in FIG. In the substrate arrangement shown in FIG. 3B, an empty space S is formed at the upper end of the back surface of the LCD 26. Therefore, in the liquid crystal television 1, the optical disk drive 110 for reproducing the video / audio data recorded on the DVD 100 can be attached to the empty space S. Further, in FIG. 3B, since the printed boards XR and XL are arranged at the lower end portion, the insertion port 91 into which the DVD 100 can be set can be provided on the upper plate 90 of the casing of the liquid crystal television 1. The user can set the DVD 100 from the insertion slot 91. In this embodiment, the optical disk drive 110 is connected to the HDMI terminal 12 a via the HDMI cable 111, and the video / audio data read from the DVD 100 is input to the video signal processing circuit 12 of the digital board A via the HDMI cable 111. To do. Thereby, the video based on the video / audio data is displayed on the liquid crystal panel 5.

  However, when the installation direction of the LCD 26 is turned upside down, the image displayed on the liquid crystal panel 5 is also turned upside down. Therefore, this embodiment is configured as follows.

  FIG. 4 shows the configuration of the COF group Y of the liquid crystal television 1 of the present embodiment. The liquid crystal television 1 includes a COF group Y on which a gate driver IC is mounted, a timing controller 4 that supplies signals necessary for liquid crystal driving to the gate driver IC and the source driver IC, and a gate driver IC and a source driver IC. And a liquid crystal panel 5 driven by.

  Each of the gate drivers GD1, GD2,..., GDm is a multi-output LSI chip that drives a gate line (not shown) of the liquid crystal panel (display element) 5. Each of the gate drivers GD1, GD2,..., GDm is a copper foil wiring laid out at a fine interval on an insulating film called a tape carrier in order to connect each input / output terminal of the LSI chip and electrodes of other components. Are mounted on COF (chip-on-film) gd1, gd2,..., Gdm made of sealing resin for fixing and moisture-proofing the LSI chip.

  The gate drivers GD1, GD2,..., GDm are input / output of various signals such as the start pulse signal STV and the gate clock signal CPV supplied from the controller 4 while mounted on the COFgd1, gd2,. Cascade connected in a cascade direction to the terminals. The outer lead terminal on the input side of each COF used for cascade connection is connected to the outer lead terminal on the input side of the adjacent COF. The outer lead terminal on the output side of each COF is connected to the liquid crystal panel 5 as a lead line to the gate line of the gate pulse (drive signal) output from each of the gate drivers GD1, GD2,. .

  The liquid crystal panel 5 includes pixels that have a liquid crystal layer and are arranged in a matrix, and TFTs (Thin Film Transistors) that drive pixels of three colors RGB. The gate electrode of the TFT is connected with p gate lines arranged in the horizontal direction on the liquid crystal panel 5, and the source electrode is connected with a plurality of source lines arranged in the vertical direction (see FIG. 5 described later). .

Signal lines SL, CL, RL and power supply lines VDD, VCC, GND are formed in each of COFgd1, gd2,..., Gdm. The signal lines SL, CL, RL and the power supply lines VDD, VCC, GND are connected to a controller 4 including a liquid crystal drive power supply circuit. The signal line CL is a line for propagating a gate clock signal CPV (clock pulse vertical). The signal line RL is a line for directly propagating a start pulse signal STV (start pulse vertical) to the gate driver GDm when the LCD 26 is installed upside down, and directly connects the controller 4 and the gate driver GDm. The signal line SL is a line for propagating the start pulse signal STV input to the gate driver GDm from the gate driver GDm to the gate driver GD1 when the LCD 26 is installed upside down. On the other hand, as shown in FIG. 3A, the start pulse signal STV when installed in a normal direction propagates from the gate driver GD1 to the gate driver GDm.
The signal line SL corresponds to the “first signal line” of the present invention. The signal line RL corresponds to the “second signal line” of the present invention. The signal line CL corresponds to the “third signal line” of the present invention. The clock signal CPV corresponds to the “shift signal” of the present invention. The digital board A corresponds to the “printed board” of the present invention. The COF group X corresponds to the “first flexible printed circuit board” of the present invention. The COF group Y corresponds to the “second flexible printed circuit board” of the present invention. The gate driver GD1 corresponds to the “start gate driver IC” of the present invention. The gate driver GDm corresponds to the “termination gate driver IC” of the present invention.

  FIG. 5 is a diagram showing waveforms of main signals input from the controller 4 to the gate driver IC group or each source driver IC group. In the figure, one selection period is enlarged to show CLK and DATA. One frame is usually 60 to 70 Hz.

The control signals supplied from the controller 4 to the gate drivers GD1, GD2,..., GDm include a gate clock signal CPV (clock pulse vertical) and a start pulse signal STV (start pulse vertical). The clock signal CPV for the gate is a synchronization signal for shifting the gate line to be driven one line at a time in synchronization with the rising of the signal, and the TFT for one horizontal line in which the gate is turned on is synchronized with the rising of the signal. This corresponds to shifting in the vertical direction line by line. The gate drivers G1, G2,..., Gm turn on the TFTs for one line when the level of the clock signal CPV changes from the Low level to the Hi level. The start pulse signal STV is a synchronization signal that specifies the timing for turning on the leading gate line, and indicates the start timing of one frame.
Control signals supplied from the controller 4 to the source driver IC group include a dot clock signal CLK and a latch pulse LP. The dot clock signal CLK is a synchronization signal for outputting the display data DATA to the liquid crystal panel 5. Each source driver IC outputs display data DATA to the liquid crystal panel 5 in synchronization with the dot clock signal CLK. The latch pulse LP is a signal indicating the timing at which the display data DATA of each line is output to the liquid crystal panel 5. Each source driver IC writes image data DATA for one line to each pixel via the turned-on TFT in synchronization with the rising edge of the latch pulse LP.

  When displaying data on the screen of the liquid crystal panel 5, the gate lines are sequentially driven one by one by the gate drivers GD1, GD2,. Then, data for one horizontal line is written simultaneously from the source driver to each pixel.

  Returning to FIG. 4, the clock signal CPV for the gate and the power supply voltage are propagated from the gate driver GD1 to the gate driver GDm. On the other hand, the start pulse signal STV is propagated from the gate driver GDm to the gate driver GD1 when the LCD 26 is installed upside down.

  Thus, in the liquid crystal television 1 of the present embodiment, the start pulse signal STV and the gate clock signal CPV are opposite to each other in the cascade connection direction of the gate drivers GD1, GD2,. Propagating. As a result, the image of one frame is also displayed in a vertically inverted state on the screen of the liquid crystal panel 5. Further, the propagation of both signals is achieved by forming signal lines CL, RL, and SL in the respective COFgd1, gd2,..., Gdm without adding a new printed circuit board. Therefore, in the liquid crystal television 1 of the present embodiment, one frame of video can be displayed upside down without adding a new printed circuit board.

  As described above, in the liquid crystal television 1 of this embodiment, the installation direction of the LCD 26 is turned upside down to form the empty space S in which the playback device or the like can be attached at the upper end of the back surface, and without adding a new printed circuit board. It can be displayed upside down. For this reason, it is not necessary to procure a material dedicated to a new printed board or to add a dedicated manufacturing process for adding a new printed board, so that the manufacturing cost can be reduced.

1 ... Liquid crystal television 4 ... Timing controller 5 ... Liquid crystal panel 6 ... LCD
DESCRIPTION OF SYMBOLS 10 ... Tuner 10a ... Antenna 12 ... Video signal processing circuit 12a ... HDMI terminal 14 ... Driver circuit 16 ... Audio processing circuit 18 ... Speaker 20 ... Power supply circuit 22 ... Rectification circuit 22a ... AC cable 24 ... Inverter circuit 26 ... LCD
31 ... Cable 32 ... Cable 41 ... Cable 42 ... Cable 43 ... Cable 90 ... Casing upper plate 91 ... Insertion slot 100 ... DVD
DESCRIPTION OF SYMBOLS 110 ... Optical disk drive 111 ... HDMI cable A ... Digital board B ... Power supply board C ... Inverter board XR, XL ... Printed board X, Y ... COF group GD1, ..., GDm ... Gate driver gd1, ..., gdm ... COF

Claims (3)

A liquid crystal panel including a plurality of gate lines, a plurality of source lines, and a plurality of pixels surrounded by the two lines;
A plurality of gate driver ICs for driving a plurality of gate lines of the liquid crystal panel;
A plurality of source driver ICs for driving a plurality of source lines of the liquid crystal panel;
The gate driver IC is instructed to sequentially drive all the gate lines line by line to turn on the transistor elements for one line, and the image data for one line is transmitted to each pixel through the turned on transistor elements. A timing controller that instructs the source driver IC to write
The timing controller is mounted on a printed circuit board disposed at the lower end on the back side of the liquid crystal panel,
The plurality of source driver ICs are mounted on a first flexible printed circuit board disposed at a lower end on the back side of the liquid crystal panel,
In the liquid crystal display device, the plurality of gate driver ICs are mounted on a second flexible printed circuit board,
The second flexible printed circuit board includes a first signal line for connecting the plurality of gate driver ICs in a cascade, a termination gate driver IC at the termination position of the cascade connection among all the gate driver ICs, and the timing controller. And a second signal line directly connecting the two,
The liquid crystal display device, wherein the timing controller outputs a start pulse signal indicating a start timing of one frame for turning on a leading gate line to the terminal gate driver IC via the second signal line.   In the second flexible printed circuit board, a gate line for turning on the transistor element is shifted from the start gate driver IC at the start position of the cascade connection to the end gate driver IC among all the gate driver ICs. The liquid crystal display device according to claim 1, wherein a third signal line for propagating a shift signal indicating timing is formed.   3. The first signal line is a line that propagates the start pulse signal input to the termination gate driver IC from the termination gate driver IC toward the start gate driver IC. The liquid crystal display device described.

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