1. Field of the Invention
The present invention relates to a liquid crystal panel drive circuit and a liquid crystal display apparatus.
2. Description of the Related Art
In a liquid crystal display panel, pixels including transistors are arranged in rows and columns, with gate bus lines extending in the horizontal direction being connected to the gates of the pixel transistors, and data bus lines extending in the vertical direction being connected to the pixel capacitors. When data is to be displayed on the liquid crystal display panel, gate drivers drive the gate bus lines one after another to make transistors conductive on a successive line, and the data drivers write the data of one horizontal line to the pixels through the turned-on transistors.
When the gates are driven, the farther away from the gate drivers, the more distorted the gate signal will be because of the resistance and capacitance of the gate bus lines. The signal distortion brings about timing differences between the positions nearer to the gate drivers and the positions farther away from the gate drivers. In detail, the timing at which the gates open is increasingly delayed at the positions further away from the gate drivers compared with the positions nearer to the gate drivers. The timing at which the data drivers output signals for driving the liquid crystal thus needs to be determined by taking into account the gate signal distortion.
Where the timing at which the gates open is delayed at positions far away from the gate drivers due to the gate signal distortion, the data supposed to be written at this pixel position may fail to be written, and the data of next timing (i.e., the data of the next line) may be written at this pixel position. In order to avoid this, the data write timing of the data drivers needs to be controlled such as to match the gate timing at the positions far away from the gate drivers. Such setting, however, ends up reducing the data write timing at the positions nearer to the gate drivers.
As liquid crystal display panels are manufactured with an increasingly fine resolution, the horizontal cycle shortens, resulting in the difficulties in securing a sufficient data write time. Also, as the liquid crystal display panels are manufactured with an increasingly large panel size, the gate bus lines are elongated, thereby making the effect of gate signal distortion increasingly conspicuous. The finer and larger the liquid crystal display panels, therefore, the more difficult it is to secure a sufficient data write time.
Accordingly, there is a need for a liquid crystal display apparatus and drive circuit that can secure a sufficient data write time.
The timing at which the data drivers write data needs to be accurately controlled. This is especially so when the liquid crystal display panels become increasingly finer and larger. Conventionally, the data write time is determined by applying the data tested for a particular liquid crystal display panel to other types of liquid crystal display panels, or is determined by applying the empirical knowledge accumulated over the years to various types of liquid crystal display panels. This may result in a certain type of a liquid crystal display panel suffering a write failure.
Accordingly, there is a need for a liquid crystal display apparatus that can determine the data write time reliably and accurately regardless of the types of liquid crystal display panels and the delay characteristics of gate bus lines.
In order to enlarge the display size under the limitation of a given physical size of a liquid crystal display apparatus, the frame portion surrounding the display portion needs to be reduced in size. In order to achieve this, it is preferable to provide signal lines coupled to the drivers within the liquid crystal display panel (i.e., on the TFT board) rather than on the circuit boards that are conventionally provided in the frame portion. In such a configuration, the drivers are connected in a cascade connection.
Accordingly, there is a need for a configuration having signal lines provided inside the liquid crystal display panel and drivers connected in a cascade connection wherein the data drivers operate at the timing that is properly controlled regardless of differences in the signal propagation lengths and the presence of signal distortion.
It is a general object of the present invention to provide a liquid crystal display apparatus and associated driver that substantially obviate one or more of the problems caused by the limitations and disadvantages of the related art.
Features and advantages of the present invention will be set forth in the description which follows, and in part will become apparent from the description and the accompanying drawings, or may be learned by practice of the invention according to the teachings provided in the description. Objects as well as other features and advantages of the present invention will be realized and attained by a liquid crystal display apparatus and associated driver particularly pointed out in the specification in such full, clear, concise, and exact terms as to enable a person having ordinary skill in the art to practice the invention.
To achieve these and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, the invention provides a circuit for driving a liquid crystal display panel, the circuit including a plurality of output circuits that are coupled to respective data bus lines of the liquid crystal display panel, and output liquid crystal drive signals to the respective data bus lines with respective delays that progressively increase from a first one of the data bus lines to a last one of the data bus lines.
In the circuit described above, the timing at which data drivers output the liquid crystal drive signals is adjusted according to the distances from gate drivers to the respective data bus lines. A constant data write timing is thus achieved regardless of the distances from the gate drivers.
According to another aspect of the present invention, a liquid crystal display apparatus includes a liquid crystal display panel which includes a plurality of data bus lines and a plurality of gate bus lines, a gate driver which drives the plurality of gate bus lines by a gate pulse, a detection circuit which detects a delay of the gate pulse propagating on the gate bus lines and a data driver which delays timing of data pulses for driving the data bus lines in response to the delay detected by the detection circuit.
In the liquid crystal display apparatus as described above, the delay of an actual gate pulse is detected, and the data pulses are delayed according to the detected delay. This makes it possible to set a data write timing reliably and accurately regardless of the types of liquid crystal display panels and/or the delay characteristics of gate bus lines.
According to another aspect of the present invention, a circuit for driving a liquid crystal display panel, which is to be coupled to and supply display data to data bus lines of the liquid crystal display panel, includes input nodes which receive the display data and a clock signal, first output nodes which output the display data to the data bus lines, a synchronizing circuit which synchronizes the display data with the clock signal, and a second output node which supplies the display data synchronized with the clock signal by the synchronizing circuit to a circuit for driving the liquid crystal display panel provided at a next stage.
In the circuit described above, the display data is output to the next stage in synchronization with the clock signal used inside the data driver. This makes it possible to drive data drivers at proper timings regardless of delays and signal distortions that vary depending on the lengths of wires in the panel.
Other objects and further features of the present invention will be apparent from the following detailed description when read in conjunction with the accompanying drawings.
In the following, embodiments of the present invention will be described with reference to the accompanying drawings.
A liquid crystal display apparatus of
In the present invention, the timing at which the data drivers 12 supply liquid crystal drive voltages is adjusted according to the distances from the gate drivers 11 to the respective data bus lines 14, thereby securing a constant data write time irrespective of the distances from the gate drivers 11.
A letter designation (a) in
As shown in FIGS. 3-(a) and (b), the period during which the gate is open is delayed by a time delay T at the position B compared with the timing at the position A. In the present invention, the timing at which the data drivers 12 supply the liquid crystal drive voltages is adjusted as shown in FIGS. 3-(c) and (d), such that the timing of the liquid crystal drive voltage at the position B (FIG. 3-(d)) is delayed by the delay T relative to the timing of the liquid crystal drive voltage at the position A (FIG. 3-(c)). This makes it possible to secure the constant data write timing regardless of the distances from the gate drivers 11.
The data driver 12 of
The output circuit 21-1 that corresponds to the data bus line 14 closest to the gate drivers 11 does not have an associated buffer 22, and the output circuit 21-2 that corresponds to the data bus line 14 second closest to the gate drivers 11 has one associated buffer 22. Further, the output circuit 21-3 corresponding to the data bus line 14 third closest to the gate drivers 11 has two associated buffers 22. By the same token, the output circuit 21-X corresponding to the data bus line 14 X-th closest to the gate drivers 11 has X-1 associated buffers 22.
With this provision, the timing at which the data drivers 12 output the liquid crystal drive voltages is adjusted according to the distances from the gate drivers 11 to the respective data bus lines 14. A constant data write timing is thus achieved regardless of the distances from the gate drivers 11.
In
Letter designations (a) through (d) in
In a liquid crystal display apparatus, generally, a plurality of data drivers 12 are provided for the liquid crystal display panel 10 as shown in
In the configuration of the data driver 12 shown in
In the data driver 12 of
When the selection signal is HIGH, the control signal supplied through the series of buffers 51 connected to the two-input AND circuit 41 is fed to a corresponding output circuit. When the selection signal is LOW, the control signal supplied through the series of buffers 51 connected to the two-input AND circuit 42 is fed to a corresponding output circuit. The number of buffers 51 connected to the two-input AND circuit 42 is double the number of buffers 51 connected to the two-input AND circuit 41, thereby providing twice as long a delay time. Setting of HIGH/LOW of the selection signal thus controls the delays of the liquid crystal drive voltages (i.e., the outputs OUT1 through OUTX) output from the data driver 12.
In the data driver 12 of
When the selection signal is HIGH, the control signal supplied through the series of buffers 71 connected to the two-input AND circuit 61 is fed to a corresponding output circuit. When the selection signal is LOW, the control signal supplied through the series of buffers 71 connected to the two-input AND circuit 62 is fed to a corresponding output circuit. Only one buffer 71 is situated on the signal path coupled to the two-input AND circuit 61, and two buffers 71 are situated on the signal path coupled to the two-input AND circuit 62. With this provision, the selection of the two-input AND circuit 62 will provide twice as long a delay time. In this manner, setting of HIGH/LOW of the selection signal controls the delays of the liquid crystal drive voltages (i.e., the outputs OUT1 through OUTX) output from the data driver 12.
A liquid crystal display apparatus 100 of
The timing controller 111 includes a control signal generation circuit 121, a detection circuit 122, an LP generation circuit 123, and a drive-signal generation circuit 124. The control signal generation circuit 121 generates various control signals including the control signals and timing signals for driving the data driver 112 and the gate driver 113. The detection circuit 122 detects delays of the gate pulses on the gate bus lines of the liquid crystal display panel 114. The detected delays of the gate pulses are reported to the LP generation circuit 123. The LP generation circuit 123 generates a latch pulse LP that triggers the transfer of display data to output-purpose D/A converters inside the data driver 112. The drive-signal generation circuit 124 supplies the display data to the data driver 112 at proper timing, so that the data driver 112 writes the display data in the liquid crystal display panel 114.
The detection circuit 122 receives the gate pulses from the gate bus lines 126 of the liquid crystal display panel 114, i.e., receives one gate pulse from the position A nearest to the gate driver 113 and another gate pulse from the position B farthest away from the gate driver 113. The detection circuit 122 generates a pulse signal indicative of a time difference of the two pulses, i.e., the delay of the gate pulse, and supplies the generated pulse signal to the LP generation circuit 123. The LP generation circuit 123 generates the latch pulse LP that determines the output timing of analog data signals supplied from the data driver 112 to the liquid crystal display panel 114. The timing of this latch pulse LP is delayed by a length of the pulse signal supplied from the detection circuit 122. This makes it possible to delay the timing of the data pulses that are write data signals output from the data driver 112 according to the delay of gate pulses.
The detection circuit 122 includes comparators 131 and 132, a voltage converter 133, and a JK flip-flop 134. The comparators 131 and 132 receive the respective analog pulse signals from the position A and position B of the gate bus line 126, and convert them to digital signals. The converted digital signals are further converted by the voltage converter 133 into voltage signals that are suitable for the JK flip-flop 134. The JK flip-flop 134 is set at the rising edge of a pulse of the position A, and is reset at the rising edge of a pulse of the position B. Accordingly, the JK flip-flop 134 outputs a pulse signal that has a pulse width equal to the time difference between the position-A pulse and the position-B pulse, i.e., a pulse width equal to the delay along the gate bus line.
The negative logic output of the JK flip-flop 134 that remains at LOW for duration equal to the delay along the gate bus line is coupled to the enable input ENAB of the LP generation circuit 123. The clock input CLK of the LP generation circuit 123 receives a clock signal from the control signal generation circuit 121. Further, the reset input RE of the LP generation circuit 123 receives a pulse signal (reference pulse) from the control signal generation circuit 121 that indicates the start of each horizontal period. The clear input CLR is normally set to LOW.
The LP generation circuit 123 is a counter circuit implemented as an ASIC or the like, and is conventionally used in liquid crystal display apparatuses. The LP generation circuit 123 counts the number of pulses of the clock signal that is supplied to the clock input CLK, and outputs the latch pulse LP at the predetermined count. When the reset input RE is asserted, the count is reset. In the present invention, the enable input ENAB of this circuit is utilized for the purpose of delaying the timing of the latch pulse LP that is output from the circuit. During the LOW state of the enable input ENAB, the clock signal supplied to the clock input CLK is not counted. Accordingly, the provision of a LOW pulse to the enable input ENAB stops the counting operation for the duration equal to the LOW period of this pulse signal, thereby delaying the output timing of the latch pulse LP by a delay corresponding to the pulse width.
A letter designation (a) in
A letter designation (d) shows a gate pulse waveform observed at the position A of
In the present invention, the detection circuit 122 detects the time difference between the rising edge of the gate pulse observed at the position A (FIG. 15-(d)) and the rising edge of the gate pulse observed at the position B (FIG. 15-(e)), and outputs a delay pulse indicative of this time difference as shown in (f). The LP generation circuit 123 delays the generation timing of the latch pulse LP by the pulse width of this delay pulse, thereby generating the timing-corrected latch pulse LP as shown in (g). At the timing indicated by this latch pulse LP, the data driver 112 outputs write data signals as shown in (h). The data signal shown in (h) has the timing that is corrected according to the present invention.
The timing of the write data illustrated in FIG. 15-(h) is delayed by the pulse width of the delay pulse relative to the timing of the write data subjected to no timing correction as shown in (c). As a result, even though the gate pulse has a waveform as shown in (d) at the position A and a distorted waveform as shown in (e) at the position B, correct write data can be written properly at both the position A and the position B. Namely, proper data writing is achieved at all the positions from the position A to the position B.
In this manner, the function of setting a data write time according to the present invention detects the delay of an actual gate pulse, and delays the data pulses according to the detected delay. This makes it possible to set a data write timing reliably and accurately regardless of the types of liquid crystal display panels and/or the delay characteristics of gate bus lines.
In the following, another aspect of the present invention will be described.
There is a demand for an increase in the display volume and display size whereas there is also a demand for compact computer monitors. In a liquid crystal display apparatus, a TFT board and a common board facing each other are stuck together, with liquid crystal placed therebetween. The liquid crystal allows the passage of light that corresponds in amount to the voltage differences between the TFT board electrodes and the common board electrodes, thereby achieving the presentation of gray scale levels by use of different voltages. In order to apply voltage differences and to have the pixels hold the respective voltages, the TFT board has source-side driver ICs (i.e., data drivers) and gate-side driver ICs (i.e., gate drivers) electrically connected thereto. The frame portion of a liquid crystal display apparatus needs to accommodate electrical connections for the source-side drivers and the gate-side drivers, and these driver ICs need a printed-circuit board, a flexible circuit board, or the like for the purpose of supplying control signals.
The related-art liquid crystal display apparatus of
In order to enlarge the display size within the limited physical size of the monitor apparatus, the frame portion surrounding the display portion needs to be reduced in size. To this end, the input signal lines 229 coupled to the drivers (driver ICs) may be provided directly on the TFT board rather than on the circuit boards that are provided in the frame portion as shown in
The liquid crystal display apparatus of
As a countermeasure, a design may be made such as to reduce the wire resistance inside the panel, or the timing of signals may be adjusted by taking into account the delay. As the display panel increases in size and resolution, however, the time difference between the point closer to the signal origin and the point farther away from the signal origin widens, thereby making it difficult to take proper measures.
In the following, a data driver that obviates the above-described problem of wire delays will be described.
The data driver of
The shift register unit 241 asserts a plurality of output signal lines one after another in synchronization with the data clock signal ICLK supplied from a host device such as a personal computer, a control device, or the like, thereby supplying data latch signals to the data register unit 242. The data register unit 242 stores the RGB display data in its internal register circuits in response to the data latch signals as the RGB display data are successively supplied. In this manner, the data register unit 242 stores therein the display data that corresponds to its associated portion of the entire display line (i.e., a gate bus line). The display data stored in the data register unit 242 is latched by the latch unit 243 in synchronization with the latch pulse LP.
The display data stored in the latch unit 243 is supplied to the D/A converter unit 245 through the level shift unit 244. The D/A converter unit 245 includes D/A conversion circuits corresponding to respective data lines, and these D/A conversion circuits convert the display data from digital to analog, thereby outputting analog gray-scale signals. The D/A converter unit 245 receives a set of reference potentials. Each D/A conversion circuit divides potentials of the set of reference potentials to generate a potential corresponding to the associated gray scale, followed by outputting an analog gray-scale signal having a potential corresponding to the supplied digital display data.
The output unit 246 includes output buffers provided for the respective data lines, and each output buffer receives a corresponding analog gray-scale signal from the D/A converter unit 245. Each output buffer supplies the received analog gray-scale signal to the TFT board as a data bus line drive signal for driving a corresponding data bus line.
In the data driver of the present invention, the display data RGB fed to the data register unit 242 are supplied to the next stage as display data OR, OG, and OB in synchronization with an output clock signal OCLK that is supplied from the shift register unit 241 to the next stage. Further, the cascade signal that is supplied to the next stage is output from the shift register unit 241 in synchronization with the output clock OCLK. This cascade signal indicates the start of data that is relevant to the recipient data driver.
The data register unit 242 of
The data register unit 242 of
In the above description, the output clock signal OCLK output from the shift register unit 241 may be the same signal as the input clock signal ICLK that is supplied to the shift register unit 241. Where there are intervening buffers or the like in the shift register unit 241, however, the output clock signal OCLK ends up having a different timing than the input clock signal ICLK. In such a case, the cascade signal output from the shift register unit 241 should be synchronized with the output clock signal OCLK.
The configuration of
In
In this manner, the data driver according to the present invention outputs the display data signals and the cascade signal to the next stage in synchronization with the clock signal used inside the data driver. This makes it possible to drive the data drivers at proper timings regardless of delays and signal distortions that vary depending on the lengths of wires in the panel. The provision of wires inside a large-scale panel can thus be properly made.
Further, the present invention is not limited to these embodiments, but various variations and modifications may be made without departing from the scope of the present invention.
The present application is based on Japanese priority application No. 2001-360961 filed on Nov. 27, 2001, with the Japanese Patent Office, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | Kind |
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2001-360961 | Nov 2001 | JP | national |
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62-269995 | Nov 1987 | JP |
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Number | Date | Country | |
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20030098833 A1 | May 2003 | US |