A liquid crystal driver includes a voltage generator for generating gray scale voltages on the basis of reference voltages, and an output device for selecting one gray scale voltage from the generated gray scale voltages in accordance with display data, for applying inversion/non-inversion control to the selected gray scale voltage with respect to an inversion reference voltage on the basis of the selected gray scale voltage, an AC switching signal and the inversion reference voltage, and for outputting different liquid crystal supply voltages for one and the same display data to a liquid crystal panel.
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0. 28. A display device, which inverts polarity of voltage at pixels every row or dot, comprising:
a display panel having a plurality of pixels arranged corresponding to crossing points of a plurality of data lines and a plurality of scan lines; and
a driver being arranged on a single side of the display panel for outputting gray scale voltages corresponding to display data consisting of a plurality bits to the pixels via the data lines;
wherein the driver includes:
output terminals provided corresponding to the data lines;
amplifiers provided corresponding to the output terminals for outputting the gray scale voltage corresponding to the display data; and
a selector for switching a connection between the amplifier and the output terminal;
wherein the adjacent two amplifiers are shared by the adjacent two output terminals; and
wherein the selector switches the connections between the adjacent two amplifiers and the adjacent two output terminals with each other.
0. 17. A display device comprising:
a display panel having a plurality of pixels arranged corresponding to crossing points of a plurality of data lines and a plurality of scan lines; and
a driver being arranged on a single side of the display panel and connected with the data lines for outputting gray scale voltages corresponding to display data consisting of a plurality bits to the pixels via the data lines;
wherein the driver outputs the gray scale voltages having polarity different from each other to adjacent two data lines;
wherein the driver includes:
a first amplifier for outputting the gray scale voltage having a positive polarity corresponding to the display data to one of the adjacent two data lines;
a second amplifier for outputting the gray scale voltage having a negative polarity corresponding to the display data to an other of the adjacent two data lines; and
a selector for switching an output destination of the positive polarity gray scale voltage output from the first amplifier between the one of the adjacent two data lines and the other of the adjacent two data lines while switching an output destination of the negative polarity gray scale voltage output from the second amplifier between the other of the adjacent two data lines and the one of the adjacent two data lines;
wherein the adjacent two pixels on the display panel connected to the adjacent two data lines having polarity different from each other.
0. 23. A display device comprising:
a display panel having a plurality of pixels;
a driver being arranged on a single side of the display panel;
wherein the driver has output terminals provided for data lines connected to pixels and outputs gray scale voltages corresponding to display data for each pixel consisting of a plurality of bits to the pixel from the output terminal via the data line, and a polarity of the gray scale voltage output from the output terminal at an odd-numbered position is different from a polarity of the gray scale voltage output from the output terminal at an even-numbered position,
wherein the driver includes:
a first amplifier for outputting a positive polarity gray scale voltage corresponding to the display data to the odd-numbered position output terminal;
a second amplifier for outputting a negative polarity gray scale voltage corresponding to the display data to the even-numbered position output terminal; and
a selector for switching an output destination of the positive polarity gray scale voltage output from the first amplifier between the odd-numbered position output terminal and the even-numbered position output terminals while switching an output destination of the negative polarity gray scale voltage output from the second amplifier between the even-numbered position output terminal and the odd number position output terminal;
wherein the polarity of the voltage of the pixel connected with the odd-numbered position output terminal via the data line is different from the polarity of the voltage of the pixel connected with the even-numbered position output terminal via the data line.
0. 1. A liquid crystal driver comprising:
a plurality of output terminals for outputting display voltages to be applied to a liquid crystal display device;
an input terminal for receiving display data corresponding to said plurality of output terminals; and
output means for converting said input display data into said output display voltages;
wherein said output means selects a display voltage level corresponding to one input display data and simultaneously generates two different display voltages from the selected display voltage level so that either one of said two different display voltages can be selected as an output display voltage for each of said output terminals.
0. 2. A liquid crystal driver according to
0. 3. A liquid crystal driver according to
0. 4. A liquid crystal driver according to
0. 5. A liquid crystal driver according to
0. 6. A liquid crystal driver according to
0. 7. A liquid crystal driver according to
0. 8. A liquid crystal driver according to
0. 9. A liquid crystal driver according to
0. 10. A liquid crystal driver according to
0. 11. A liquid crystal display device comprising:
a liquid crystal panel including pixel portions which are arranged at positions of intersections of a plurality of data lines and a plurality of scanning lines in the form of a matrix;
a scanning driver for successively supplying voltages to said plurality of scanning lines; and
a liquid crystal driver as defined in
0. 12. A liquid crystal display device according to
0. 13. A liquid crystal driver according to
0. 14. A liquid crystal driver according to
0. 15. A liquid crystal driver according to
0. 16. A method of applying display voltages to a liquid crystal display device, the method comprising the steps of:
receiving display data corresponding to output terminals which output display voltages;
generating gray scale display voltage levels on the basis of reference voltages;
selecting one of the gray scale display voltage levels for each output terminal in accordance with said display data, the selected gray scale display voltage level being a first display voltage for the output terminal;
supplying an AC switching signal and an inversion reference voltage, said AC switching signal having a polarity which is periodically inverted;
inverting said selected gray scale voltage level with respect to said inversion reference voltage to generate an inverted selected gray scale display voltage level, the inverted selected gray scale display voltage level being a second display voltage for the output terminal, the second display voltage being different from the first display voltage, the first display voltage and the second display voltage being available simultaneously;
selecting one of the first display voltage and the second display voltage in accordance with the AC switching signal as an output display voltage for the output terminal; and
outputting the output display voltage from the output terminal.
0. 18. The display device according to
0. 19. The display device according to
0. 20. The display device according to
a first latch for holding the input display data;
a second latch for collectively holding the display data in the first latch according to a timing signal; and
a selection circuit for selecting one of a plurality of gray scale voltages as the gray scale voltage corresponding to the display data in the second latch.
0. 21. The display device according to
0. 22. The display device according to
0. 24. The display device according to
0. 25. The display device according to
0. 26. The display device according to
a first latch for holding the input display data;
a second latch for collectively holding the display data in the first latch according to a timing signal; and
a selection circuit for selecting one of a plurality of gray scale voltages as the gray scale voltage corresponding to the display data in the second latch.
0. 27. The display device according to
0. 29. The display device according to
a first latch for holding the input display data;
a second latch for collectively holding the display data in the first latch according to a timing signal; and
a selection circuit for selecting one of a plurality of gray scale voltages as the gray scale voltage corresponding to the display data in the second latch;
wherein the amplifier is input with the gray scale voltage from the selection circuit.
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Notice: More than one reissue application has been filed for the reissue of U.S. Pat. No. 5,774,106. This reissue applications are application Ser. Nos. 09/324,168, now U.S. Pat. No. RE39,366; 11/406,488; 11/980,700 (the present application); and 11/980,691; all of which are reissues of U.S. Pat. No. 5,774,106.
This application is related to application Ser. No. 08/135,357 filed on Oct. 19, 1993, entitled “Liquid Crystal Display Driving Method/Driving Circuit Capable of Being Driven with Equal Voltages” which is assigned to the same assignee as the present application. The contents of application Ser. No. 08/135,537 are incorporated herein by reference. This application is a continuation reissue application of continuation reissue U.S. application Ser. No. 11/406,488, filed Apr. 19, 2006, which is a continuation reissue application of U.S. reissue application Ser. No. 09/324,168, filed Jun. 2, 1999, now U.S. Pat. No. RE39,366 issued Oct. 31, 2006, which is a reissue application of U.S. Pat. No. 5,774,106, issued Jun. 30, 1998, the subject matter of which is incorporated by reference herein. This application is related to continuation reissue U.S. application Ser. No. 11/980,691, filed Oct. 31, 2007, which is a continuation reissue of continuation reissue U.S. application Ser. No. 11/406,488, filed Apr. 19, 2006.
1. Field of the Invention
The present invention relates to a liquid crystal driver and a liquid crystal display device using the same and, particularly, relates to an active matrix type liquid crystal driver and a liquid crystal display device using the same.
2. Description of the Related Art
A conventional liquid crystal driver using a data driver LSI HD66310 described in Hitachi LCD driver LSI databook (Published by Hitachi Ltd., March 1994, pp. 1166-1185) will be explained below.
In
In
Alternate-column inversion drive of the liquid crystal panel has an advantage in that display quality is improved with compared with the case of no use of alternate-column inversion drive, because voltages applied to liquid crystal cells are inverted on alternate columns so that the current flowing in the common electrode at the time of liquid crystal drive becomes smaller. As for the conventional data driver arrangement, therefore, data drivers are arranged in the upper and lower portions of the liquid crystal panel. On the other hand, the liquid crystal display device is on strong demands not only for high quality display but also for small size and light weight. Arrangement of one data driver in a single side makes it easy to reduce size and weight. The arrangement of one data driver in a single side of the liquid crystal panel, however, has a problem that display quality deteriorates compared with the case of alternate-column inversion drive of the liquid crystal panel.
An object of the present invention is to provide a liquid crystal driver for performing alternate-column inversion drive in which liquid crystal cells are driven so as to be inverted on alternate columns in order to obtain high image quality while one data driver is arranged in a single side of a liquid crystal panel in order to reduce the size and weight of a liquid crystal display, that is, in order to reduce a liquid crystal panel driving circuit for the purpose of high-density mounting, and to provide a liquid crystal display device using the liquid crystal driver.
To achieve the foregoing object, according to an aspect of the present invention, a voltage generating means for generating a plurality of gray scale voltages on the basis of reference voltages and an output means for selecting one gray scale voltage from the generated gray scale voltages correspondingly to display data and for outputting different-polarity liquid crystal supply voltages for one and the same display data in the liquid crystal panel on the basis of the selected gray scale voltage, an AC switching signal and an inversion AC switching signal are provided in a liquid crystal driver.
According to another aspect of the present invention, a level-shift circuit for shifting the level of a digital input signal is provided in a scanning driver so that the level of the digital input signal is shifted by the level-shift circuit to a signal level allowed operate in the inside of the scanning driver.
Alternate-column inversion drive can be achieved by one data driver as long as the aforementioned voltage generating means and the aforementioned output means are used.
Accordingly, the circuit scale of an electric source circuit for generating reference voltages can be reduced.
In addition, because the level-shift circuit provided in the input side of the scanning driver can shift the level of the digital input signal to a signal level allowed to operate in the inside of the scanning driver, the circuit scale of the liquid crystal display can be reduced without necessity of use of any external level-shift circuit.
The reference numeral 116 designates an EOR circuit for performing control as to whether the AC switching signal 106 is to be inverted or not to be inverted on the basis of the selection signal 107; 117, an AC switching signal outputted from the EOR circuit 116; 118, a level shifter circuit for converting the level of the control signal 108 into a signal level for a high rate withstand voltage process; 120, a signal outputted from the level shifter circuit 118 by shifting the level of the AC switching signal 106; 121, a signal outputted from the level shifter circuit 118 by shifting the level of the AC switching signal 117; and 122, a signal outputted from the level shifter circuit 118 by shifting the level of the control signal 108. The reference numeral 123 designates a latch address control circuit; 124, a group of latch signals generated by the latch address control circuit 123; 125, a latch circuit for latching the display data 112 successively; 126, display data latched by the latch circuit 125; 127, a latch circuit for latching the display data 126 simultaneously in synchronism with the display timing signal 113; and 128, display data latched by the latch circuit 127.
The reference numeral 129 designates a gray scale voltage generating circuit for generating 64 levels of gray scale voltages from 9 levels of reference voltages 115 and outputting one level of gray scale voltages corresponding to display data; 130, the gray scale voltages generated by the gray scale voltage generating circuit 129; and 131, an output circuit for outputting voltages obtained by inverting or non-inverting the gray scale voltages 130 on the basis of the inversion reference voltage 119 correspondingly to the AC switching signals 120 and 121. Output currents of the output circuit 131 are controlled by the control signal 122. The reference numeral 132 designates liquid crystal driving voltages. The reference numeral 133 designates a scanning circuit; 134, gate driving signals successively selected by the scanning circuit 133; and 135, a liquid crystal panel of 640 dots×480 lines.
In
Each of the latch circuits 125 has 240 outputs (6 bits per one output) so that display data corresponding to one horizontal line can be latched successively in the data drivers 109-1 to 109-8. The display data 126 thus latched by the latch circuits 125 correspondingly to one horizontal line are further latched simultaneously by the latch circuits 127 on the basis of the display timing signal 113 synchronized with the gate selection signal 134 outputted from the scanning circuit 133. Each of the latch circuits 127 has 240 outputs (6 bits per one output) so that display data corresponding to one horizontal line can be latched simultaneously in the data drivers 109-1 to 109-8. The display data 128 thus latched by the latch circuits 127 are transferred to the gray scale voltage generating circuits 129. The electric source circuit 103 generates 9-level reference signals 104 for generating gray scale voltages and an inversion reference voltage 105 for AC switching. Each of the buffer circuits 114 buffers the reference voltages 104 and the inversion reference voltage 105 supplied from the power supply circuit 103 and supplies these voltages as reference voltage 115 and inversion reference voltage 119 to the gray scale voltage generating circuits 129 and the output circuit.
The gray scale voltage generating circuit 129 generates 64 levels of gray scale voltages from the reference voltages 115, selects one level of gray scale voltages corresponding to display data for each output and sends the selected voltage level to the output circuit 131. The AC switching signal 106 is a signal for designating the timing of AC switching. The selection signal 107 is a signal for selecting whether the timing of AC switching is to be changed or not to be changed for every output. The AC switching signal 117 is a signal obtained by inverting or non-inverting the AC switching signal 106 correspondingly to the selection signal 107. The control signal 108 is a signal for performing driving control of the output circuit 131. The input signal levels of the display data 101, control signal group 102, reference voltage 104, inversion reference voltage 105, AC switching signal 106, selection signal 107 and control signal 108 are all in a range of from 0 V to 5 V. On the other hand, the level of the liquid crystal driving voltage requires about 15 V for the purpose of AC drive.
Accordingly, it is necessary to use a high rate withstand voltage process (rate voltage: 15 V) as the output circuit for outputting liquid crystal driving voltages. Therefore, the level shifter 118 shifts the levels of the AC switching signals 106 and 117 and of the control signal 108 to high rate withstand voltage levels to supply these signals to the output circuit 131. The output circuit 131 inverts or non-inverts the gray scale voltages 130 on the basis of the inversion reference voltage 105 correspondingly to the AC switching signals 120 and 121 to buffer-output inverted/non-inverted voltages as liquid crystal driving voltages 132. The scanning circuit 133 generates a gate selection signal 134 for selecting horizontal lines one by one on the liquid crystal panel 135. Thus, the liquid crystal panel 135 is driven by a liquid crystal driving voltage 132 supplied in synchronism with the gate selection signal 134 so that display can be performed by liquid crystal driving voltages corresponding to display data, which are among the 64 levels of gray scale voltages of positive polarity or negative polarity.
Display data 101 are latched successively by three pixels by the latch circuit 125 on the basis of the latch signal 124 generated by the latch address control circuit 123. Specifically, the display data 112 are latched by three pixels (18 bits) successively by the latch circuit 125 so that display data 112 are latched by 6-bit latch circuits 901-1, 901-2 and 901-3 corresponding to the first group of three pixels, latched by 6-bit latch circuits 901-4, 901-5 and 901-6 corresponding to the second group of three pixels and finally latched by 6-bit latch circuits 901-238, 901-239 and 901-240 corresponding to the last group of three pixels.
Thus, the eight data drivers latch the display data successively, so that latching of display data corresponding to one line is completed. The display data 126 thus latched by the latch circuit 125 correspondingly to one line are further latched by the latch circuit 127 simultaneously on the basis of the display timing signal 113. The reference voltages 104 are 9-level voltages, which are buffered by the buffer circuit 114 and outputted as reference voltages 115. Then, the gray scale voltage generating circuit 903 generates 64 levels of gray scale voltages from the 9 levels of reference voltages 115.
Referring now to
Referring back to
Further, the AC switching signal 106 and the selection signal 107 are supplied to the EOR circuit 116, in which the AC switching signal 106 is outputted without inversion when the level of the selection signal 107 is “Low” whereas the AC switching signal 106 is outputted with inversion when the level of the selection signal 107 is “High”. That is, the AC switching signal 117 is the same as the AC switching signal 106 when the level of the selection signal 107 is “Low” whereas the AC switching signal 117 is a signal obtained by inverting the AC switching signal 106 when the level of the selection signal 107 is “High”. The control signal 108 is a signal for designating control of driving currents of the output circuits 906-1 to 906-240. The respective levels of the AC switching signals 106 and 117 and of the control signal 108 are shifted by the level shifter circuit 118 in order to adjust the voltage to the signal level of the output circuit 131 allowed to operate in a liquid crystal driving voltage level range (of from 5 V to −10 V), so that these signals are outputted as AC switching signals 120 and 121 and a control signal 122, respectively.
In the output circuit 131, each of the output circuits 906-1 to 906-240 corresponding to the respective outputs receives a positive-polarity gray scale voltage 130, an inversion reference voltage 119, AC switching signals 120 and 121 and a control signal 122 and inverts or non-inverts the gray scale voltage 130 on the basis of the inversion reference voltage 119 correspondingly to the AC switching signal to thereby drive the liquid crystal panel. Referring now to
Either gray scale voltage 130 or inversion voltage 1102 selected by the selection circuit 1103 correspondingly to the AC switching signal 120 is outputted as an output voltage 1104 and buffered by the output buffer circuit 1105 to drive the liquid crystal panel 135. Referring to
The output buffer circuit 1105 is a voltage follower circuit which makes the differential amplification circuit 1201 receive the output voltage 1104 and makes the current amplification circuits 1202 and 1203 amplify the current to drive the liquid crystal panel 135. The control signal 122 is a signal for controlling the current amplification circuit 1203. The current amplification circuit 1203 is enabled to operate by turning the level of the control signal 122 to “High” level so that the current amplification circuit 1203 can cooperate with the current amplification circuit 1202 to output a large current, whereas the current amplification circuit 1203 is disabled from operating by turning the level of the control signal 122 to a “Low” level so that the current amplification circuit 1202 alone can output a small current. In this manner, electric power consumed by the current amplification circuits can be saved because current amplification can be performed by using the two current amplification circuits 1202 and 1203 when a large output current is required and because the current amplification circuit 1203 can be disabled from operating so that the current amplification circuit 1202 alone is used for current amplification when such a large output current is not required.
Further, circuit portions surrounded by the broken line in the data driver in
In the liquid crystal display using data drivers of this embodiment as described above, alternate-column inversion drive can be performed so that high quality image display can be made even in the case where the data drivers are arranged in one side of the liquid crystal panel as shown in FIG. 15. Further, alternate-column inversion drive can be performed by AC switching for each line as shown in
Although this embodiment has shown the case where 240-output data drivers are used as the data drivers, it is to be understood that the present invention may be applied also to the case where 192- or 160-output data drivers are used as the data drivers and that 192- or 160-output data drivers can be provided easily by rearranging the latch address control circuits and the latch circuits correspondingly to the number of outputs. Although the description of this embodiment has been made upon the case where the rate voltage of the low rate withstand voltage process and the rate voltage of the high rate withstand voltage process are 5 V and 15 V, respectively, the same effect as in this embodiment can be obtained in the case where the rate voltage of the low rate withstand voltage process and the rate voltage of the high rate withstand voltage process are, for example, in a range of from 5 V to 3 V and in a range of 30 V to 10 V, respectively.
The scanning driver in this embodiment will be described below.
As shown in
In this embodiment, a level-shift circuit is provided in the input side of the scanning driver so that the circuit scale of the peripheral circuits can be reduced.
The threshold voltage of the inverter circuit 2004 is set to the center of the input signal level, and the amplitude level thereof is VCC-VSS. The amplitude level of the inverter circuit 2005 is VCC-VSS. In this level-shift circuit 2001, inversion/non-inversion level-shifted signals can be outputted without necessity of the reference voltage as shown in the level-shift circuit 1901.
Further, as shown in
As described above, in this embodiment, because a buffer circuit for buffering 9-level liquid crystal reference voltages 104 is arranged in the input side of each data driver, the driving current is small so that the circuit scale of the electric source circuit 103 can be reduced.
A second embodiment of the present invention in which data drivers for performing 64-level gray scale display on the basis of 9-level reference voltages are used will be described below. The gray scale voltage generating circuit in this embodiment is different from that in the first embodiment, but the other circuits in this embodiment are similar to those in the first embodiment.
In
The display data 101 are latched by three pixels successively by the latch circuit 125 on the basis of the latch signal 124 generated by the latch address control circuit 123. Specifically, the display data 101 are latched by three pixels (18 bits) by the latch circuit 125 successively in a manner so that display data 112 are latched by 6-bit latch circuits 901-1, 901-2 and 901-3 corresponding to the first group of three pixels, next latched by 6-bit latch circuits 901-4, 901-5 and 901-6 corresponding to the second group of three pixels and finally latched by 6-bit latch circuits 901-238, 901-239 and 901-240 corresponding to the last group of three pixels.
Thus, the eight data drivers latch the display data successively, so that latching of display data corresponding one line is completed. The display data 126 thus successively latched by the latch circuit 125 correspondingly to one line are latched simultaneously by the latch circuit 127 on the basis of the display timing signal 113. The reference voltages 104 which are 9-level reference voltages are buffered by the buffer circuit 114 and then outputted as reference voltages 115. On the other hand, the inversion reference voltage 105 is buffered by the buffer circuit 114 and then outputted as an inversion reference voltage 119.
The reference voltages 115 are supplied to the gray scale voltage generating circuits 2101-1 to 2101-240 corresponding to respective outputs. The gray scale voltage generating circuits 2101-1 to 2101-240 generate gray scale voltages 130 corresponding to display data from the display data 128 and the reference voltages 115 corresponding to the respective outputs.
The 6-bit display data 128 which express 64 gray scales are decoded by the decoder 2201 so that the upper three bits of the display data 128 and the lower three bits thereof are independent from each other. The decoded signal 2202 of the upper three bits on 8 lines is supplied to the selection circuits 2204 and 2205, and the decoded signal of the lower three bits on 8 lines is supplied to the selection circuit 2210. The selection circuit 2204 selects one level from 8 levels of from V8 to V1 among the 9-level reference voltages 115 (V8 to V0) correspondingly to the decoded signal 2202. The selection circuit 2205 selects one level from 8 levels of from V7 to V0 among the 9-level reference voltages 115 (V8 to V0) correspondingly to the decoded signal 2202. Assume now that combinations of the two voltages which are selected by the selection circuits 2204 and 2205, respectively, are V8-V7, V7-V6, V6-V5, V5-V4, V4-V3, V-3-V2, V2-V1, and V1-V0.
The voltage dividing circuit 2208 divides the potential difference between the two selected voltages 2206 and 2207 into eight to generate 8 levels of gray scale voltages in between the two selected voltages. The selection circuit 2210 selects one level from the 8 levels of gray scale voltages 2209 generated by the voltage dividing circuit correspondingly to the decoded signal 2203 to output the selected level as a gray scale voltage 130. In this manner, 64 levels of gray scale voltages can be generated by using eight combinations of the selected voltages 2206 and 2207 and division of potential difference in each combination into eight. That is, 64 levels of gray scale voltages in a range of from 0 V to 5 V are generated from the reference voltages 104 having voltage levels of from 0 V to 5 V, so that a gray scale voltage 130 corresponding to the display data is selected from the 64 levels of gray scale voltages correspondingly to each output.
The inversion voltage 2304 which is a voltage obtained by inverting the positive-polarity gray scale voltage 130 corresponds to a negative-polarity liquid crystal driving voltage. Either positive voltage 2303 or inversion voltage 2304 is selected by the selection circuit 2305 correspondingly to the AC switching signal 120 and outputted as an output voltage 132 to drive the liquid crystal panel 135.
A third embodiment of the present invention will be described below. This embodiment is different from the first embodiment in the circuit for inverting the reference voltage.
The data drivers are required because the number of outputs from each of the data drivers 2407-1 to 2407-10 is 192 and because the resolution of the liquid crystal panel 2425 is 640×RGB×480 pixels. The display data 2401 which are 18-bit display data (3 pixels×6 bits for gray scales) are transferred successively, so that latch signals 2413 synchronized with the display data 2401 are generated by the latch address control circuits 2412 on the basis of the control signal group 2409 to thereby latch the display data 2410 in the latch circuits 2414 successively. Each of the latch circuits 2414 has latch circuits for latching 192 pixels (6 bits per one pixel) so that display data corresponding to one horizontal line can be latched successively in the data drivers 2407-1 to 2407-10. The display data 2415 thus latched by the latch circuits 2414 correspondingly to one horizontal line are further latched simultaneously by the latch circuits 2416 on the basis of the display timing signal 2411 synchronized with the gate selection signal 2424 outputted from the scanning circuit 2423. The display data 2417 thus latched are supplied to the liquid crystal driving circuit 2421. The voltage generating circuit 2418 generates AC reference voltages 2419 and 2420 different in AC switching timing from each other on the basis of the reference voltages 2405 and 2406 generated by the power supply circuit 2404 and the AC switching signal 2403 so as to be supplied to the liquid crystal driving circuit 2421. In the liquid crystal driving circuit 2421, liquid crystal driving voltages 2422 corresponding to the display data 2417 are generated on the basis of the AC reference voltages 2419 and 2420 to thereby drive the liquid crystal panel 2425.
In
The AC reference voltages 2419 and 2420 are supplied to the liquid crystal driving circuits 2501-1 to 2501-192 alternately for the 192 outputs. Each of the liquid crystal driving circuits 2501-1 to 2501-192 generates and outputs 64 levels of liquid crystal driving voltages on the basis of the display data of 6 bits per one output and 9 levels of AC reference voltages 2419 or 2420. The 64 levels of liquid crystal driving voltages can be outputted by selecting 2 levels from the 9 levels of AC reference voltages with use of upper 3 bits of the 6-bit display data and then selecting one level from 8 levels of voltages obtained by dividing the selected two levels of voltages into 8 equal parts with use of lower 3 bits of the display data. In this manner, the data driver can generate a liquid crystal driving voltage in which AC switching timing varies correspondingly to each output, so that alternate-column inversion drive of the liquid crystal panel 2425 can be performed.
Although this embodiment has shown the case where each of the liquid crystal driving circuits has a structure in which AC reference voltages different in AC switching timing are switched over once per one output, the present invention can be applied to the case where AC reference voltages are switched over once per two outputs or once per a plurality of outputs.
Reference voltages 2405 of 9 levels VLEV0 to VLEV9 from the electric source circuit 2404 are buffered by the amplification buffer circuits 2601-0 to 2601-8 and supplied to the differential amplification circuits 2602-0 to 2602-8 and the selection circuits 2603-0 to 2603-8 and 2604-0 to 2604-8, respectively. In the differential amplification circuits 2602-0 to 2602-8, the reference voltages (VLEV0 to VLEV8) 2405 are inverted and outputted on the basis of the reference voltage (VCEN) 2406. The selection circuits 2603-0 to 2603-8 and 2604-0 to 2604-8 receive the outputs of the amplification buffer circuits 2601-0 to 2601-8 and the outputs of the differential amplification circuits 2602-0 to 2602-8, respectively, and select these outputs on the basis of the AC switching signal 2403. Because inverted AC switching signals are inputted to the selection circuits 2604-0 to 2604-8, the polarity of voltages selected by the selection circuits 2603-0 to 2603-8 and the polarity of voltages selected by the selection circuits 2604-0 to 2604-8 are reversed to each other.
This timing is shown in FIG. 27. When the level of the AC switching signal (M) 2403 is high, AC reference voltages (V1RV0 to V1RV8) 2419 selected by the selection circuits 2603-0 to 2603-8 are outputted as values VLEV01NV-VLEV81NV, respectively, and AC reference voltages (V2RV0 to V2RV8) 2420 selected by the selection circuits 2604-0 to 2604-8 are outputted as values VLEV0-VLEV8, respectively. When the level of the AC switching signal (M) 2403 is contrariwise low, AC reference voltages (V1RV0 to V1RV8) 2419 selected by the selection circuits 2603-0 to 2603-8 are outputted as values VLEV0-VLEV8, respectively, and AC reference voltages (V2RV0 to V2RV8) 2420 selected by the selection circuits 2604-0 to 2604-8 are outputted as values VLEV01NV-VLEV81NV, respectively. In this manner, AC reference voltages 2419 and 2420 different in AC switching timing from each other are generated.
A fourth embodiment of the present invention will be described below. This embodiment is similar to the third embodiment except that voltage generating circuits used in this embodiment are assembled so as to be different from those in the third embodiment so that this embodiment can be adapted to common electrode AC drive of the liquid crystal panel.
In
The data drivers are required because the number of outputs from each of the data drivers 2802-1 to 2802-10 is 192 and because the resolution of the liquid crystal panel 2425 is 640×RGB×480 pixels. The display data 2401 which are 18-bit display data (3 pixels×6 bits for gray scales) are transferred successively, so that latch signals 2413 synchronized with the display data 2401 are generated by the latch address control circuits 2412 on the basis of the control signal group 2409 to thereby latch the display data 2410 in the latch circuits 2414 successively. Each of the latch circuits 2414 has latch circuits for latching 192 pixels (6 bits per one pixel) so that display data corresponding to one horizontal line can be latched successively in the data drivers 2802-1 to 2802-10. The display data 2415 thus latched by the latch circuits 2414 correspondingly to one horizontal line are further latched simultaneously by the latch circuits 2416 on the basis of the timing signal 2411 synchronized with the gate selection signal 2424 outputted from the scanning circuit 2423. The display data 2417 thus latched are supplied to the liquid crystal driving circuits 2421. The voltage generating circuits 2803 generate AC reference voltages 2419 and 2420 on the basis of the reference voltages 2405 and 2406 generated by the electric source circuit 2404, the AC switching signal 2403 and the control signal 2801 so as to be supplied to the liquid crystal driving circuits 2421. In the liquid crystal driving circuits 2421, liquid crystal driving voltages 2422 corresponding to the display data 2417 are generated on the basis of the AC reference voltages 2419 and 2420 to thereby drive the liquid crystal panel 2425.
Reference voltages 2405 of 9 levels VLEV0 to VLEV8 from the electric source circuit 2404 are buffered by the amplification buffer circuits 2601-0 to 2601-8 and supplied to the differential amplification circuits 2602-0 to 2602-8 and the selection circuits 2603-0 to 2603-8 and 2604-0 to 2604-8, respectively. In the differential amplification circuits 2602-0 to 2602-8, the voltages (VLEV0 to VLEV8) are inverted with respect to the reference voltage (VCEN) 2406.
When the level of the control signal (SVCOM) 2801 is low, as shown in
A fifth embodiment of the present invention will be described below. This embodiment is similar to the third embodiment except that voltage generating circuits used in this embodiment are different from those in the third embodiment.
In
Reference voltages 2405 of 9 levels VLEV0 to VLEV8 from the electric source circuit 2404 are buffered by the amplification buffer circuits 3101-0 to 3101-8 and supplied to the level-shift circuits 3102-0 to 3102-8 and the selection circuits 3103-0 to 3103-8 and 3104-0 to 3104-8, respectively. In the level-shift circuits 3102-0 to 3102-8, the levels of the reference voltages (VLEV0 to VLEV8) 2405 are shifted correspondingly to the voltage level of the reference voltage (VSH) 2406.
When the level of the AC switching signal (M) 2403 is contrariwise low, AC reference voltages (V1LS0 to V1LS8) 2419 selected by the selection circuits 3103-0 to 3103-8 are outputted as values VLEV0 to VLEV8, respectively, and AC reference voltages (V2LS0 to V2LS8) 2420 selected by the selection circuits 3104-0 to 3104-8 are outputted as values VLEV8SFT to VLEV0SFT, respectively. In this manner, AC reference voltages 2419 and 2420 different in AC switching timing from each other are generated.
Next, the operation of the liquid crystal driving circuit 2421 is the same as in the third embodiment. In the configuration as described above, the data drivers can generate liquid crystal driving voltages different in AC switching timing correspondingly to each output, so that alternate-column inversion drive of the liquid crystal panel 2425 can be achieved.
A sixth embodiment of the present invention will be described below.
The reference numeral 3318 designates a voltage generating circuit for generating AC reference voltages which are used for AC driving the liquid crystal on the basis of the reference voltages 3305 and 3306; and 3319 and 3320, positive-polarity and negative-polarity reference voltages generated by the voltage generating circuit. The reference numeral 3321 designates a liquid crystal driving circuit for generating liquid crystal driving voltages corresponding to the data bus 3317 for display data and AC switching signal on the basis of the reference voltages 3319 and 3320; and 3322, liquid crystal driving voltages generated by the liquid crystal driving circuit 3321. The reference numeral 3323 designates a scanning circuit; 3324, gate driving signals successively selected by the scanning circuit 3323; and 3325, a liquid crystal panel.
Ten data drivers are required because the number of outputs from each of the data drivers 3307-1 to 3307-10 is 192 and because the resolution of the liquid crystal panel 2425 is 640×RGB×480 pixels. The display data 3301 which are 18-bit data (3 pixels×6 bits for gray scales), and the AC switching signal 3303 composed of 3 bits per 3 pixels, are transferred successively, so that latch signals 3313 synchronized with the display data 3301 and the AC switching signal 3303 are generated by the latch address control circuits 3312 on the basis of the control signal group 3309 to thereby latch the data from the data bus 3310 into the latch circuits 3314 successively. Each of the latch circuits 3314 has latch circuits for latching 192 pixels (6 bits for display data and 1 bit for AC switching signal per one pixel) so that display data and AC switching signal corresponding to one horizontal line can be latched successively in the data drivers 3307-1 to 3307-10.
The display data and AC switching signal latched by the latch circuits 3314 correspondingly to one horizontal line are latched simultaneously through the data bus 3315 by the latch circuits 3316 on the basis of the timing signal 3311 synchronized with the gate selection signal 3324 of the scanning circuit 3323. The data bus 3317 thus latched is supplied to the liquid crystal driving circuits 3321. The voltage generating circuits 3318 generate different AC reference voltages 3319 and 3320 corresponding to two levels of AC switching on the basis of the reference voltages 3305 and 3306 generated by the electric source circuit 3304 and supply the AC reference voltages 3319 and 3320 to the liquid crystal driving circuits 3321, respectively. The liquid crystal driving circuits 3321 generate liquid crystal driving voltages 3322 corresponding to the display data 3317 on the basis of the AC reference voltages 3319 and 3320 to thereby drive the liquid crystal panel 3325.
The AC reference voltages 3319 and 3320 are supplied to the liquid crystal driving circuits 3401-1 to 3401-192 for 192 outputs, respectively. Each of the liquid crystal driving circuits 3401-1 to 3401-192 generates 64 levels of liquid crystal driving voltages on the basis of the data bus 3317 containing 6-bit display data and AC switching signal per one output and the 9 levels of AC reference voltages 3319 or 3320. The 64 levels of liquid crystal driving voltages can be outputted by selecting either AC reference voltage 3319 or AC reference voltage 3320 as an AC switching signal, selecting 2 levels from the 9 levels of AC reference voltages with use of upper 3 bits of the 6-bit display data and then selecting one level from 8 levels of voltages obtained by dividing the selected two levels of voltages into 8 equal parts with use of lower 3 bits of the display data.
In the configuration as described above, the data drivers can generate liquid crystal driving voltages different in AC switching timing for respective outputs, so that alternate-column inversion drive of the liquid crystal panel 3325 can be achieved. Further, the AC switching timing can be changed easily once per two outputs, once per a plurality of outputs, once per one line, or the like, by changing the setting of the AC switching signal transferred in synchronism with display data.
Further, as a seventh embodiment of the present invention, there is shown an embodiment of the output circuit for attaining saving of consumed electric power and reduction of chip size in the first and second embodiments. This embodiment is different from the first and second embodiments only in the output circuit.
In the first and second embodiments, a combination of a normal amplification circuit and an inversion amplification circuit is required for each output. On the contrary, in this embodiment, a combination of a normal amplification circuit and an inversion amplification circuit is used so as to be common to two outputs, so that the chip size can be reduced. In
Further, as shown in
Futami, Toshio, Mano, Hiroyuki, Takita, Isao, Ikeda, Makiko, Furuhashi, Tsutomu, Nitta, Hiroyuki, Tsunekawa, Satoru
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