The present application claims priority from Japanese patent application JP 2003-186652 filed on Jun. 30, 2003, the contents of which are hereby incorporated by reference into this application.
The present application relates to a liquid crystal drive device for driving a liquid crystal display device and more particularly, to a liquid crystal drive device capable of achieving reduction in power consumption.
A liquid crystal display device comprises a liquid crystal display panel, and a liquid crystal drive device supplying various signals and voltages for effecting display on the liquid crystal display panel. The liquid crystal display device currently in the mainstream of a display device for various types of electronic equipment is the so-called active-matrix type having active elements in a pixel circuit. Since thin-film transistors are generally used as the active elements, and the active elements are described as the thin-film transistors in the present specification.
This type of liquid crystal display device comprises a liquid crystal display panel having a plurality of source electrode interconnects extending in a first direction (for example, a longitudinal direction) on an inner face of an insulating substrate and juxtaposed in a second direction (for example, a transverse direction) intersecting the first direction, a plurality of gate electrode interconnects extending in the second direction and juxtaposed in the first direction, a thin-film transistor disposed at respective crossover points of the source electrode interconnects and the gate electrode interconnects, constituting a pixel respectively, a plurality of common electrode interconnects for applying a common electrode voltage (hereinafter referred to merely as “common voltage” as well) to common electrodes disposed through the intermediary of a liquid crystal layer, respectively, and an external terminal coupled in common to the common electrode interconnects, and a liquid crystal drive circuit supplying various signals and voltages for effecting display on the liquid crystal display panel. In this connection, the liquid crystal display device is not limited to one wherein the plurality of common electrode interconnects are coupled in common to the external terminal (also referred to as a common electrode terminal, or merely as a common electrode), outside a pixel region (display region) of the liquid crystal display panel but some liquid crystal display panel has common electrodes serving as a flat electrode in common to all pixels.
In display operation of the liquid crystal display device, the thin-film transistor of the pixel selected by a select voltage applied to one of the gate electrode interconnects is turned on, and an alignment direction of the liquid crystal layer interposed between a pixel electrode and the common electrode, coupled to the thin-film transistor, is caused to change, thereby controlling a quantity of transmitted light or reflected light. The common voltage applied to the common electrode at this point in time is generated by use of a voltage boosted by a boost circuit. The above and other objects and novel features of the invention will more fully appear from the following detailed description when the same is read in conjunction with the accompanying drawings. Specific examples of a conventional liquid crystal display device and a conventional liquid crystal drive device for driving the same, respectively, are described later in contrast with the present invention under the item “DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS”.
Particularly with a portable terminal using a cell as a power source, lower power consumption thereof has since become an important factor. For example, a common voltage (hereinafter referred to also as “VCOM”) applied to an external terminal (referred to also as a common electrode CT) coupled in common to a plurality of common electrode interconnects undergoes a change (charging/discharging) between a certain reference voltage (for example, a low potential “VCOML”) and another reference voltage (for example, a high potential “VCOMH”) generated by a boost circuit. Consequently, power consumption in the course of common electrodes being charged or discharged is large, thereby creating one of factors hindering implementation of reduction in power consumption of a liquid crystal display device as a whole.
It is therefore an object of the invention to implement reduction in power of common electrode voltages applied to the common electrode interconnects, respectively, by a liquid crystal drive device, to thereby achieve reduction in power consumption of the liquid crystal display device as a whole.
A summary of a representative embodiment of the invention, disclosed herein, will be briefly described as follows.
To achieve the above-described object, the invention provides a liquid crystal drive device for driving one sheet of liquid crystal panel, the liquid crystal drive device comprising a power source circuit having a first terminal to which a first reference voltage VCC (power source voltage for a logic system) is supplied, a second terminal to which a second reference voltage GND (ground potential) is supplied, a third terminal to which a third reference voltage (power source voltage VCI for an analog system) is supplied, and a fourth terminal (VCOM output terminal) coupled to an external terminal of the liquid crystal display panel, wherein a first voltage generation circuit for generating a first voltage (VCOMH) higher than the first reference voltage; and a second voltage generation circuit for generating a second voltage (VCOML) lower than the second reference voltage are coupled to the first terminal and the second terminal, respectively.
With the liquid crystal drive device according to the invention, control is preferably effected such that a voltage (a common voltage VCOM) supplied to the fourth terminal is changed from the second voltage (VCOML) to the third reference voltage (VCI) and subsequently, changed form the third reference voltage (VCI) to the first voltage (VCOMH)
The liquid crystal drive device according to the invention may comprise a first voltage generation circuit (first boost circuit) for generating the first voltage (VCOMH) higher than the third reference voltage VCI), and a second voltage generation circuit (second boost circuit) for generating the second voltage (VCOML) lower than the second reference voltage (GND), provided at the first terminal and second terminal, respectively, controlling such that a voltage supplied to the fourth terminal may be changed from the first voltage (VCOMH) to the second reference voltage (GND) and subsequently, changed form the second reference voltage (GND) to the second voltage (VCOML).
Further, the invention provides in its second aspect a liquid crystal drive device for driving two sheets of liquid crystal panel, that is, a first liquid crystal panel and a second liquid crystal panel, having a power source circuit comprising a first terminal to which a first reference voltage VCC is supplied, a second terminal to which a second reference voltage (GND) is supplied, and a third terminal to which a third reference voltage (VCI) is supplied. The liquid crystal drive device further comprises a voltage generation circuit coupled to the first terminal and second terminal, for generating the first voltage (VCOMH) higher than the first reference voltage (VCC) and the second voltage (VCOML) lower than the second reference voltage (GND), a first common voltage generation circuit coupled in common to a plurality of pixels of the first liquid crystal display panel, for generating a first common voltage (VCOM1), a second common voltage generation circuit coupled in common to the plurality of pixels of the second liquid crystal display panel, for generating a second common voltage (VCOM2), a fourth terminal for outputting the first common voltage (VCOM1), and a fifth terminal for outputting the second common voltage (VCOM2).
Further, when the first common voltage generation circuit or the second common voltage generation circuit generates the first common voltage (VCOM1) or the second common voltage (VCOM2), supplied to the fourth terminal or the fifth terminal, the first common voltage generation circuit or the second common voltage generation circuit controls such that the first common voltage (VCOM1) or the second common voltage (VCOM2) is changed form the second voltage (VCOML) to the third reference voltage (VCI), and subsequently, changed from the third reference voltage (VCI) to the first voltage (VCOMH).
Still further, the liquid crystal drive device according to the invention may comprise a common voltage generation circuit coupled to the external terminal, for generating common voltages, and when a potential on the external terminal makes a transition from a first potential of the first voltage (VCOMH) to a second potential of the second voltage (VCOML) different from the first potential, the common voltage generation circuit may form a voltage waveform having an inflection point at a third potential point between the first potential and the second potential.
It is to be pointed out that the invention is obviously not limited to the above configurations and configurations described hereinafter with reference to the embodiments of the invention, and that various changes and modifications may be made in the invention without departing from the spirit and scope thereof.
Embodiments of the invention are described in detail hereinafter with reference to the accompanying drawings for the embodiments.
The liquid crystal drive device CRL receives display signals to be displayed on the liquid crystal display panel, various clocks, and timing signals such as vertical, horizontal, and synchronizing signals, and so forth, from external signal sources, respectively. In
Further, the liquid crystal drive device CRL has a fourth terminal VCOM (VCOM output terminal) coupled to the liquid crystal display panel PNL. As a result of miniaturization in the process of fabricating a semiconductor integrated circuit, elements have since decreased in size, resulting in lower voltage resistance of elements for the logic system, so that the first reference voltage VCC is generally lower than the third reference voltage VCI. There is a case where the third reference voltage VCI is stabilized with precision higher than that for the first reference voltage VCC because the third reference voltage VCI is for generating a voltage for driving the liquid crystal display panel PNL although the invention is not particularly limited thereto. Accordingly, the first reference voltage VCC may be generated by lowering voltage from the third reference voltage VCI. That can reduce the number of terminals to thereby implement reduction in cost. For brevity, the terminals are denoted by respective signal names or voltage names thereof herein.
The liquid crystal drive device CRL comprises a source driver SDR, a gate driver GDR, a common electrode driver VCDR, a driver control circuit DRCR incorporating a timing controller TCON, and a LCD power source circuit PWU.
The control signals (the display signals, various clocks, and timing signals such as vertical, horizontal, and synchronizing signals, and so forth) received from the external signal sources, respectively, are processed by the driver control circuit DRCR, a source control signal SCi containing the display data is supplied to the source driver SDR, and a gate control signal GCi for generating the scanning signal is supplied to the gate driver GDR, whereupon the source signal Si and the gate signal (scanning signal) Gi are applied to a source electrode interconnect and a gate electrode interconnect of the liquid crystal display panel PNL, respectively.
Meanwhile, the LCD power source circuit PWU generates a first common voltage VCOM1 and a second common voltage VCOM2 from the first reference voltage VCC, second reference voltage GND, and third reference voltage VCI, on the basis of a power source circuit control signal and a VCOM control signal, received from the driver control circuit DRCR, sending out the first common voltage VCOM1 and second common voltage VCOM2 to the common electrode driver VCDR. The common electrode driver VCDR is controlled by a common electrode control signal (the VCOM control signal) delivered from the timing controller TCON, thereby applying a common voltage to a common electrode interconnect (common interconnect) of the liquid crystal display panel PNL.
The liquid crystal drive device CRL in
Furthermore, with the liquid crystal drive device CRL in
Based on the reference voltage delivered from the reference voltage generation circuit VRG, and voltages boosted by the boost circuit MVR, the source voltage generation circuit SVG, the gate voltage generation circuit GVG, and the common electrode voltage generation circuit VCVG give source voltages VS0 to Vsn, gate voltages VGH, VGL, VCOM voltages VCOMH, VCOML to the source driver SDR, the gate driver GDR, and the VCOM driver VCDR, respectively. Based on the source voltages VS0 to Vsn as received and the source control signal Sci from the driver control circuit DRCR, the source driver SDR sends out the display data Si to the source electrode interconnects. Based on the gate voltages VGH, VGL as received and the gate control signal Gci, the gate driver GDR sends out the scanning signal Gi to the gate electrode interconnects. Then, based on the VCOM voltages VCOMH, VCOML and the VCOM control signal, the VCOM driver VCDR sends out the common voltage VCOM that is a common electrode potential (common potential) to the common electrode interconnects.
The LCD panel has a thin-film transistor TFT constituting a pixel at respective crossover points of the source electrode interconnects S1, S2, . . . Sm, and the gate electrode interconnects G1, G2, . . . Gm, and the respective gate electrode interconnects are coupled to respective gate electrodes of the thin-film transistors TFTs while the respective source electrode interconnects are coupled to respective source electrodes (or drain electrodes) of the thin-film transistors TFTs. The respective drain electrodes (or source electrodes) of the thin-film transistors TFTs are coupled to respective pixel electrodes serving as electrodes on one side of respective liquid crystal cells. Electrodes on the other side of the respective liquid crystal cells, that is, the common electrodes are coupled to the common electrode interconnects coupled to the common electrode CT serving as the external terminal. In
A liquid crystal drive device CRL shown in
The operation of the liquid crystal drive device according to the invention is described in detail hereinafter in contrast with the conventional technology.
In
In the operation mode, the output VCOM is charged to the level of the first voltage VCOMH upon transition of the signal M form the L-level to the H-level.
Upon transition of the signal M form the H-level to the L-level, the output VCOM is charged to the level of the second voltage VCOML. The same operation is thereafter repeated.
Thus, with the conventional VCOM driver, the output VCOM undergoes charging operations (charging operation/discharging operation) between the first voltage VCOMH and the second voltage VCOML, so that power consumption at this point in time is large. Accordingly, there is a limitation to an extent of reduction in power consumption of a liquid crystal display device as a whole.
A signal GON is a gate-on (display enable) signal, the signal M is the VCOM AC-conversion signal, and VCOMG is a level select signal of the second voltage VCOML at a time when VCOM is converted into AC. An oscillation operation between VCOM=the first voltage VCOMH and the ground potential GND is executed at VCOMG=0 while an oscillation operation between VCOM=the first voltage VCOMH and the second voltage VCOML is executed at VCOMG=1. A signal EQ is a timing signal (control signal) for pre-charging the output VCOM with the third reference voltage VCI or the ground potential GND. The signals GON, M, EQ, and VCOMG, respectively, are delivered from the timing controller TCON. Further, a signal QE is a control signal for effecting the operation of the present invention by presetting it at a H-level, and is not directly associated with operation timing. Accordingly, in case that the signal QE is at a L-level, it is obvious that the operation can be effected according to the conventional operation.
The operation in
At a timing of the signal M making a L-level to H-level transition, the control signal EQ makes a L-level to H-level transition. At this point in time, the switch control signal CL of the switch SW2 for the output VCOM makes a H-level to L-level transition. That is, with the switch control signal CL at the L-level, the switch SW2 becomes nonconducting, so that the output VCOM is cut off from VCOML as the output of the VCOM voltage generation circuit VCVG, and is in high impedance state. Thereafter, the switch control signal CC of the switch SW4 is caused to makes a L-level to H-level transition at a timing delayed from the transition of the control signal EQ form the L-level to the H-level. Such delay is intended to prevent the rising edge and falling edge of the switch control signal CC from overlapping with the rising edge and falling edge of the control signal EQ, respectively, as shown in
With this arrangement, it is possible to prevent current from the third reference voltage VCI from flowing into VCOML, due to concurrent drop of respective impedances at the switches SW2, and SW4, thereby enabling power consumption to be suppressed. Because lines (VCOMH, VCOML, GND, VCI, in
With the elapse of a predetermined time controlled by the timing controller TCON (refer to
At a timing of the signal M making a H-level to L-level transition, the control signal EQ makes a L-level to H-level transition as in the previously-described case. At this point in time, the switch control signal CH of the switch SW1 for the output VCOM makes a H-level to L-level transition. That is, with the switch control signal CH at the L-level, the switch SW1 becomes nonconducting, so that the output VCOM is cut off from VCOMH of the VCOM voltage generation circuit VCVG, and is in high impedance state.
Thereafter, the switch control signal CG of the switch SW3 is caused to make a L-level to H-level transition at a timing delayed from the transition of the control signal EQ form the L-level to the H-level. Such delay is intended to suppress an increase in power consumption, due to concurrently drop of respective impedances at the switches SW1, and SW3. When the switch control signal CG is at the H-level, the output VCOM is coupled to the ground potential GND, so that the output VCOM is charged toward the ground potential GND (actually discharging operation).
With the elapse of a predetermined time controlled by the timing controller TCON, the control signal EQ makes a H-level to L-level transition. At this point in time, the switch control signal CG makes a H-level to L-level transition, thereby cutting off the output VCOM from the ground potential GND. At a timing delayed from the H-level to L-level transition of the switch control signal CG, the switch control signal CL of the switch SW2 makes a L-level to H-level transition. Such delay is intended to suppress an increase in power consumption, due to concurrent drop of respective impedances at the switches SW2 and SW1. That is, when the switch control signal CL of the switch SW2 is at the H-level, the switch SW2 becomes conducting, so that the output VCOM is coupled to VCOML of the VCOM voltage generation circuit VCVG, and is charged to the level of VCOML. Thereafter, the same operation is repeated.
In
In
Now, an advantageous effect of the liquid crystal drive device according to the invention is described in contrast with that for the conventional liquid crystal drive device.
From the viewpoint of power supply to the VCOM voltage generation circuit VCVG, the operation waveform in
Meanwhile, a discharging current Idis at a time of discharging is Cp (VCOMH−VCOML)/Δt, representing the sum of a discharging current Idis1 at voltage difference between VCOMH and the ground potential GND and a discharging current Idis2 at voltage difference between the ground potential GND and VCOML, and in this case, converted power is VCI×(Idis1+Idis2) because a current due to one-hold boosting of the current Ici supplied from the third reference voltage VCI becomes the discharging current Ichis.
Meanwhile, at a time of discharging from the first voltage VCOMH to the second voltage VCOML, a discharging current from the first voltage VCOMH to the ground potential GND, Idis1=Cp (VCOMH−GND)/Δt, and if converted in terms of power consumed at the third reference voltage VCI, power consumption becomes zero because the discharging current is drawn to the ground potential GND. Then, at a time of discharging from the ground potential GND to the second voltage VCOML, a discharging current Idis2=Cp (GND−VCOML)/Δt, being a current due to one-hold boosting of the current Ici supplied from the third reference voltage VCI, so that consumed power in that case as converted is VCI×Idis2.
As is evident from comparison of
Now, a visually-expressed difference between the operation waveform of VCOM operation according to the present invention and that in the case of the conventional technology, as described in the foregoing, is described hereinafter through comparison.
In contrast, the VCOM operation waveform shown in
The liquid crystal drive device according to the invention, CRL (denoted by “LC controller” in the figure), comprises latch circuits LAT1, LAT2, for fetching data, a display RAM GRAM, various drivers for supplying a liquid crystal display panel PNL (denoted by “LC panel” in the figure) with display data, scanning signals, and so forth, and a LCD power source circuit PWU (denoted by “LC power source circuit” in the figure). Miniaturization as well as higher function is required of the cellular phone, however, miniaturization makes it difficult to use a large cell, and it is quite difficult to reduce power consumption of the cellular phone due to higher function required thereof. Accordingly, it is essential to reduced power consumption of a liquid crystal drive device. Under the circumstance, by use of the liquid crystal drive device according to the invention, reduction in power consumption can be easily implemented.
There are generally available a line reversal system for reversing the common electrode voltage VCOM for every gate line, and a frame reversal system for reversing the common electrode voltage VCOM for every frame cycle. With the line reversal system, image quality is excellent but power consumption is large, and conversely, with the frame reversal system, power consumption is small although image quality is not so good. As described hereinbefore, since the present invention has an advantageous effect of reducing power consumption of the VCOM driver, the present invention is particularly effective if applied to the case of the line reversal system among control systems of the common electrode voltage VCOM, and particularly lower power consumption can be achieved by applying the present invention to the VCOM driver during line reversal drive.
When the common electrode voltage VCOM makes a transition from the second voltage VCOML to the first voltage VCOMH, the transition may proceed from VCOML to the ground potential GND and subsequently, to the third reference voltage VCI before finally proceeding to the first voltage VCOMH although not shown in the figures. At a time of the transition from the second voltage VCOML to the ground potential GND, a current flows in from the ground potential GND, so that power consumed is zero as seen from the point of the liquid crystal drive device CRL. Accordingly, current consumed, in the transition from the second voltage VCOML to the third reference voltage VCI, becomes Cp×VCI/Δt, as seen from the point of the liquid crystal drive device CRL, and the current consumed is smaller as compared with the case of
For switch control at this pointing in time, it is preferable to provide a switch control circuit for controlling the switches SW2, SW3, SW4, and SW1, respectively, in operation in
Further, the operation waveform of the VCOM operation, at that time, has the inflection point corresponding to the third reference voltage VCI, and the inflection point corresponding to the ground potential GND, in the charging process form the second voltage VCOML to the first voltage VCOMH.
Furthermore, electronic equipment to which the liquid crystal drive device according to the invention is applied is not limited to the cellular phone shown in
Thus, with the present invention, it is possible to implement reduction in power of the common electrode voltages applied from the power source of the liquid crystal drive device to the common electrode interconnects of a liquid crystal display panel, respectively. Hence, the invention can provide the liquid crystal drive device for use in a liquid crystal display panel, capable of attaining lower power consumption of the liquid crystal display panel as a whole.
Number | Date | Country | Kind |
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2003-186652 | Jun 2003 | JP | national |
Number | Date | Country | |
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Parent | 10830072 | Apr 2004 | US |
Child | 11892619 | Aug 2007 | US |