This application claims the benefit of the filing date of Taiwan Application Ser. No. 093137036, filed on Dec. 1, 2004, the content of which is incorporated herein by reference.
1. Field of the Invention
The invention relates to a TFT-LCD capable of repairing discontinuous lines and a high-impedance detecting unit.
2. Description of the Related Art
LCDs (Liquid Crystal Displays) are a mainstream of portable displays due to small size and light weight. In addition, the great cost-down of the LCD has made the LCD become a medium/small scale display, which has the maximum potential in the market. Among the LCDs, the TFT-LCD (Thin Film Transistor Liquid Crystal Display) is the most popular product.
In a typical TFT-LCD, a common electrode substrate and an active matrix substrate are disposed and opposite to each other, and a liquid crystal material is interposed between the two substrates. As shown in
Owing to the trend of the high resolution LCD, the traces of the data lines 12 and the scan lines 13 are made as possibly thin so that longer and more traces can be accommodated. Thus, the traces may be discontinuous (termination lines) due to the processing technology and other factors. When some traces are discontinuous, the display pixels controlled through the discontinuous traces cannot work normally. A few bad display pixels still can be accepted in the LCD specification, but too many display pixels that cannot work normally make the LCD become a bad product, and a lot of bad products are scrapped accordingly. In view of this, various technologies for repairing traces are disclosed. The frequently used trace repairing technology will be described in the following.
In this drawing, the scan lines are not shown in order to simplify the drawing, and only the discontinuous data lines have to be repaired in an example. An external test unit (not shown) is provided to test whether the data lines 12 are discontinuous lines. When the discontinuous data line 28 is detected, the discontinuous data line 28 is repaired using the repairing OP amplifier 24 which is chosen because of a smaller RC loading and the nearer distance, and the repairing traces 26, 27. The repairing trace 26 is disposed on an upper peripheral portion of a matrix display area 11, and the disposed repairing trace 27 surrounds the matrix display area. When the discontinuous data line 28 is detected, a near repairing OP amplifier 24 can be connected to the repairing traces 26, 27 to repair the discontinuous data line 28. The data line driving unit 16 first connects the output connection point c of the discontinuous data line 28 to the input terminal repairing trace 26, and the input terminal of the repairing OP amplifier 24 connects to the connection point a of the input terminal repairing trace 26 so as to receive the data signal provided from the data line driving unit 16. Next, the connection point e of the output terminal repairing trace 27 is connected to the data line 28″. Thus, the signal on the discontinuous data line 28 of the data line driving unit 16 may be outputted from the repairing OP amplifier 24 to the display pixel corresponding to the data line portion 28″. In brief, because the discontinuous data line 28 is broken into two parts, the discontinuous data line 28 only can receive the data signal outputted by the data line driving unit 16 on the data line 28′, while the data line 28″ cannot receive the desired data signal until the repairing circuit is used. The object of the invention may be achieved according to the above-mentioned transfer path.
In the drawing, only one discontinuous data line 28 is shown. However, there may be several discontinuous data lines, and the number of the discontinuous data lines that can be repaired is restricted by the number of the repairing traces and the repairing OP amplifiers. Although the scan lines are not illustrated in the drawing, the discontinuous scan lines may be repaired in the same manner. In practice, the repairing OP amplifiers 24, 24′ are disposed in the data line driving units 16, 16′, and the positions thereof in the drawing are arranged in order to simplify the description. In addition, the formation of the connection points a, b, c, d and e may be performed using the laser fuse.
The output terminals of the OP amplifiers are connected to the same output terminal repairing trace 27 at the beginning of manufacturing the panel. The following issues have to be considered.
1. If the discontinuous line is formed at some lateral side, the signal of the discontinuous line is coupled to the input terminal of the OP amplifier near the lateral side using the laser fusing technology, and the OP amplifier generates the repair signal. Thus, the distance from the output terminal of the OP amplifier to the discontinuous line may be shortened, the loading seen from the output terminal may be effectively reduced, and the possibility of repair failure may be decreased.
2. Because the laser fuse needs addition process steps and the problem of yield still exists, the output terminals of the OP amplifiers are connected to the same output terminal repairing trace at the beginning of manufacturing the panel in order to eliminate the cost for the addition process steps and avoid the problem of the reduced yield.
3. If one set of repairing traces is only coupled to one OP amplifier, the more repairing traces, and the far the distance from the visible region of the glass to the glass edge.
Although the above-mentioned repairing technology can really repair the discontinuous data line 28 and thus reduce the number of bad products, the prior art still has some drawbacks. The input terminal f of the OP amplifier 24′ is floating because the discontinuous data line 28 does not have to be repaired, so an uncertain output occurs at the output terminal d, and the uncertain output together with the OP amplifier 24 form the output competition. So, the signal on the output terminal repairing trace may be unstable or incorrect, such that the color deviation exists between the display pixels, which receive the output signals of the repairing OP amplifiers.
It is therefore an object of the invention to provide a TFT-LCD capable of repairing discontinuous lines without color deviation.
Another object of the invention is to provide a high-impedance detecting unit applicable to a TFT-LCD capable of repairing discontinuous lines, so that the high-impedance detecting unit can detect a state of an input terminal of a repairing OP amplifier and control an operation of the repairing OP amplifier.
To achieve the above-identified objects, the invention provides a TFT-LCD (Liquid Crystal Display) capable of repairing discontinuous lines. The LCD has a plurality of data line driving units for driving a plurality of data lines, a plurality of scan line driving units for driving a plurality of scan lines, and a plurality of repairing circuits for repairing discontinuous data lines among the data lines. Each of the repairing circuits includes at least one input terminal repairing trace, a plurality of OP amplifiers, a high-impedance detecting module and at least one output terminal repairing trace. The input terminal repairing trace is connected to the discontinuous data lines of the plurality of data line driving units when the discontinuous data lines are needed to be repaired. Each of the OP amplifiers has an input terminal, an output terminal and a control terminal. The input terminal of one of the OP amplifiers is connected to the input terminal repairing trace when the discontinuous lines are needed to be repaired. The high-impedance detecting module detects whether the input terminals of the OP amplifiers are floating, outputs a control signal to control the output functions of the OP amplifiers, disables the corresponding control signal when the input terminal of the OP amplifier is at a floating state, and enables the corresponding control signal when a voltage is detected at the input terminal of the OP amplifier. The output terminal repairing trace is connected to the output terminal of each of the OP amplifiers. The OP amplifier further receives the control signal of the high-impedance detecting module. An output of the OP amplifier is set to be a high-impedance state when the control signal is disabled. The OP amplifier outputs a signal according to a signal from the input terminal when the control signal is enabled.
The feature and operational principle of the invention will be described with reference to the accompanying drawings, wherein the same or similar components are denoted by the same or similar symbols.
In order to repair the discontinuous scan line (or termination scan line), the TFT-LCD further includes at least one repairing circuit, wherein only one repairing circuit is shown in the embodiment. The repairing circuit includes at least one input terminal repairing trace 26, at least one output terminal repairing trace 27, a plurality of repairing OP amplifiers 34, 34′, and a high-impedance detecting module 35. The number of the repairing OP amplifiers is determined according to the number of data line driving units, wherein two repairing OP amplifiers are illustrated in this embodiment. The output terminals of the repairing OP amplifiers 34, 34′ are connected to the output terminal repairing trace 27. The high-impedance detecting module 35 detects the state of the input terminal of each of the repairing OP amplifiers 34, 34′, and generates a control signal to control the output state thereof. Although the high-impedance detecting module 35 and the repairing OP amplifiers 34, 34′ are positioned in the outside of the data line driving units 16, 16′, it is preferred that they are disposed in the data line driving units 16, 16′. In this embodiment, the high-impedance detecting module 35 includes two high-impedance detecting units 350, 350′. As shown in
When it is detected that a discontinuous line exists among data lines, the processing method is the same as the prior art and detail descriptions thereof will be omitted. However, because the input terminal f of the repairing OP amplifier 34′ in the typical repair method is at a floating state, noises may occur. Thus, the output terminal d of the repairing OP amplifier 34′ may output an uncertain voltage, and the uncertain voltage will interfere with the voltage of the output terminal b of the repairing OP amplifier 34, such that the data signal transferred to data line 28″ may be incorrect or unstable, thereby causing the image color distortion. Hence, the invention utilizes the high-impedance detecting module 35 to detect whether the repairing OP amplifier has received a signal, and to turn off the output terminal of the repairing OP amplifier when no signal is received (or in the floating state) to avoid influencing the outputs of other repairing OP amplifiers.
As shown in
As shown in
Because the comparison signal Vout may cause an error of judgment owing to noises, the comparison signal Vout is acquired by way of repeated test, and the logic processing unit 352 is utilized to generate the OP control signal CS according to the number of times about the comparison signal Vout at the high logic level. The logic processing unit 352 receives the comparison signal Vout, utilizes a counter 353 to count the number of times about the comparison signal Vout at high logic level during the testing period, and utilizes a second comparator 354 to compare the counting value with a threshold value. When the counting value is bigger than the threshold value, the logic processing unit 352 enables the OP control signal CS to enable the corresponding repairing OP amplifier. Inversely, when the counting value is smaller than the threshold value yet after the test ends, the logic processing unit 352 disables the OP control signal CS to disable the output of the corresponding repairing OP amplifier.
The working level of each signal in the high-impedance detecting module 35 may be high or low, the switch control signals SCS1, SCS2 to be provided to the first and second switches S1, S2 may be provided by an internal or external signal generator. The capacitance of the capacitor C1 and the resistance of the resistor R1 may be configured to fit the impedance at the input terminal of the corresponding repairing OP amplifier. On the basis of smooth and correct detection operation of the high-impedance, the design for the ON and OFF periods of switches is free and flexible.
The multiplexer 61 receives the signals RS1 to RSn at the input terminals of the plurality of repairing OP amplifiers, selects a signal as the test signal according to a selection signal, and outputs the test signal to the high-impedance detecting unit 350. The high-impedance detecting unit 350 checks the state of the test signal, and outputs a state signal to the plurality of latch units 63. The latch units 63 sample and hold the corresponding test result according to different latch control signal 1 to latch control signal n, and output the latched signals to the corresponding repairing OP amplifiers. That is, when the multiplexer 61 selects the first repairing OP amplifier to detect, the first latch unit 63 is controlled to sample and hold the output signal of the high-impedance detecting unit 350.
While certain exemplary embodiments have been described and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not restrictive on the broad invention, and that this invention not be limited to the specific construction and arrangement shown and described, since various other modifications may occur to those ordinarily skilled in the art. For instance, the OP amplifiers may be replaced by a component having a control terminal, an input terminal and an output terminal, wherein the output at the output terminal does not affect the input at the input terminal. The high-impedance detecting units may be disposed inside or outside the data or scan line driving unit, and the numbers of the OP amplifiers, the input terminals and the output terminal repairing traces do not have to be the same. In addition, the invention can be applied in the TFT-LCD, a display, which has a plurality of scan lines and drive lines to constitute many light-emitting pixels and is formed using semiconductor manufacturing processes, or electrical devices.
Number | Date | Country | Kind |
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93137036 A | Dec 2004 | TW | national |
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