The present application claims a priority of the Chinese patent application No. 201310272216.9 filed on Jul. 1, 2013, which is incorporated herein by reference in its entirety.
The present invention relates to the field of display technology, in particular to a gamma voltage generating circuit, controlling method thereof, and a liquid crystal display.
Gamma voltage generating circuit functions as to, in accordance with a gamma curve required by a thin film transistor liquid crystal display (TFT-LCD), set gamma voltages as voltages for gray scale display of the TFT-LCD. Each gamma voltage generates all the gray scale voltages under the effect of a digital-to-analog converter of a source driver.
Currently, for the LCD, the gamma voltage generating circuit is usually provided in a source driver IC, and generates the desired respective gamma voltage by adopting voltage dividing resistors . Eight (V1, V2, . . . , V7, V8) or fourteen (V1, V2, . . . , V13,V14) voltage nodes are extracted and those voltages are applied to an external output as shown in
A relatively large amount of resistors are required to achieve such a gamma voltage generating circuit. For instance, a 6-bit source driver IC needs 129 resistors, and an 8-bit source driver IC needs 257 resistors. These resistors will occupy large space of the source driver IC. In addition, the number of the gamma voltages needs to be increases so as to improve the gray scale display properties of the LCD. Correspondingly, it needs more resistors to constitute the existing gamma voltage generating circuit so as to generate the desired number of gamma voltages. As a result, it is adverse to the integration of the source driver IC, as well as the reduction of the process complexity and the cost.
An object of the present invention is to provide a gamma voltage generating circuit, its controlling method, and a liquid crystal display, so as to reduce the number of resistors in the gamma voltage generating circuit in the prior art, thereby to facilitate the integration of a source driver IC and reduce the process complexity of the source driver IC.
In one aspect, an embodiment of the present invention provides a gamma voltage generating circuit, comprising: an output end, a first reference voltage input end, a second reference voltage input end, a pre-stage voltage-dividing circuit having a first pre-stage output end and a second pre-stage output end, and a post-stage voltage-dividing circuit having a first post-stage input end, a second post-stage input end and a post-stage output end.
The first reference voltage input end and the second reference voltage input end are coupled to the pre-stage voltage-dividing circuit respectively, the pre-stage voltage-dividing circuit is coupled to the post-stage voltage-dividing circuit, and the post-stage voltage-dividing circuit is coupled to the output end of the gamma voltage generating circuit.
The first pre-stage output end of the pre-stage voltage-dividing circuit is coupled to the first post-stage input end, and the second pre-stage output end of the pre-stage voltage-dividing circuit is coupled to the second post-stage input end, so as to divide reference voltages input from the first reference voltage input end and the second reference voltage input end, respectively, thereby to generate a primary gamma voltage.
The post-stage output end of the post-stage voltage-dividing circuit is coupled to the output end of the gamma voltage generating circuit, so as to divide the primary gamma voltage, thereby to generate a secondary gamma voltage.
In another aspect, an embodiment of the present invention provides a method for controlling the above-mentioned gamma voltage generating circuit, comprising: determining a desired gamma voltage by a source driver; dividing reference voltages input from a first reference voltage input end and a second reference voltage input end, respectively, so as to generate a primary gamma voltage by a pre-stage voltage-dividing circuit; dividing the primary gamma voltage by a post-stage voltage-dividing circuit, so as to generate a secondary gamma voltage; and outputting the desired gamma voltage through an output end of the gamma voltage generating circuit.
In yet another aspect, an embodiment of the present invention provides a liquid crystal display comprising the above-mentioned gamma voltage generating circuit.
According to embodiments of the present invention, the pre-stage voltage-dividing circuit is multiplexed by the post-stage voltage-dividing circuit, so it is able to generate more gamma voltages using less elements, thereby to facilitate the integration of the source driver IC and reduce the process complexity of the source driver IC.
The present invention will be described hereinafter in conjunction with the drawings. It should be appreciated that, the following embodiments are merely used to illustrate and explain the present invention, but shall not be used to limit the present invention.
The technical solutions provided by embodiments of the present invention are described in detail as follows.
As shown in
The first reference voltage input end A0 and the second reference voltage input end A15 are coupled to the pre-stage voltage-dividing circuit 10, respectively, the pre-stage voltage-dividing circuit 10 is coupled to the post-stage voltage-dividing circuit 20, and the post-stage voltage-dividing circuit 20 is coupled to the output end H1 of the gamma voltage generating circuit.
The pre-stage voltage-dividing circuit 10 has a first pre-stage output end D1 and a second pre-stage output end D2.
The post-stage voltage-dividing circuit 20 has a first post-stage input end E1, a second post-stage input end E17 and a post-stage output end G1.
The first pre-stage output end D1 of the pre-stage voltage-dividing circuit 10 is coupled to the first post-stage input end E1, and the second pre-stage output end D2 of the pre-stage voltage-dividing circuit 10 is coupled to the second post-stage input end E17, so as to divide reference voltages from the first reference voltage input end A0 and the second reference voltage input end A15, thereby to generate a primary gamma voltage.
The primary gamma voltage is generated by the pre-stage voltage-dividing circuit 10. As a first step of generating the gamma voltage, the pre-stage voltage-dividing circuit 10 divides a first reference voltage and a second reference voltage into a predetermined number of primary voltages.
The voltage from the first reference voltage input end A0 may be a positive supply voltage AVDD, and the voltage from the second reference voltage input end A15 may be 0, i.e., the second reference voltage input end A15 is grounded. As shown in
The post-stage output end G1 of the post-stage voltage-dividing circuit 20 is coupled to the output end H1 of the gamma voltage generating circuit, so as to divide the primary gamma voltage, thereby to generate a secondary gamma voltage.
The secondary gamma voltage is a final gamma voltage obtained by performing the second voltage dividing, through the post-stage voltage-dividing circuit 20, on each of the predetermined number of the primary voltages.
The pre-stage voltage-dividing circuit 10 comprises N+1 pre-stage resistors (i.e., the 0th pre-stage resistor R0 to the Nth pre-stage resistor RN), a first switch group (i.e., N pre-stage switches including the 1st pre-stage switch S1 to the Nth switch SN), and 2 pre-stage operational amplifiers (i.e., the 1st pre-stage operational amplifier OPf1 and the 2nd pre-stage operational amplifier OPf2).
The N+1 pre-stage resistors are sequentially coupled in series (e.g., the pre-stage resistors R0, R1, R2, R3, . . . , R14 are sequentially coupled in series as shown in
One end of the nth pre-stag switch Sn is coupled to a common node between the (n−1)th pre-stage resistor and the nth pre-stage resistor Rn−1 (e.g., as shown in
In order to select the desired gamma voltage using the switch-on and switch-off states of the pre-stage switches, when n is an odd number, the other end of the nth pre-stage switch Sn is coupled to an in-phase input end of the 1st pre-stage operational amplifier OPf1 (e.g., when n=3, the other end of the switch S3 is coupled to the in-phase input end of the 1st pre-stage operational amplifier OPf1), and when n is an even number, the other end of the nth pre-stage switch Sn is coupled to an in-phase input end of the 2nd pre-stage operational amplifier OPf2 (e.g., when n=10, the other end of the switch S10 is coupled to the in-phase input end of the 2nd pre-stage operational amplifier OPf2).
An reverse-phase input end and an output end (i.e., an output end C1) of the 1st pre-stage operational amplifier OPf1 are both coupled to the first pre-stage output end (e.g., a first pre-stage output end D1 in
The post-stage voltage-dividing circuit 20 comprises M post-stage resistors (i.e., the 1st post-stage resistor r1 to the Mth post-stage resistor rM), a second switch group (i.e., M+1 post-stage switches including the 1st post-stage switch s1 to the (M+1)th post-stage switch SM+1), and R post-stage operational amplifiers (i.e., the 1st post-stage operational amplifier to the Rth post-stage operational amplifier), wherein R is a positive integer not less than 1. In the circuit as shown in
The M post-stage resistors are sequentially coupled in series (e.g., the post-stage resistors r1, r2, r3, . . . , r16 are sequentially coupled in series as shown in
One end of the 1st post-stage switch S1 is coupled to the first post-stage input end (e.g., E1 in
One end of the mth post-stage switch sm is coupled to a common node between the (m−1)th post-stage resistor rm−1 and the mth post-stage resistor rm (e.g., one end of the switch S3 is coupled to a common node E3 between the post-stage resistor r2 and the post-stage resistor r3), and the other end of the mth post-stage switch sm is coupled to an in-phase input end of any one of the R post-stage operational amplifiers (e.g., the other end of the switch S3 is coupled to the in-phase input end F1 of the post-stage operational amplifier OPr). m is a positive integer not less than 1 and not greater than M+1, and M is a positive integer greater than 1.
In order to reduce the number of the post-stage operational amplifiers and facilitate the integration of the source driver, the number (R) of the post-stage operational amplifiers in the post-stage voltage-dividing circuit is 1. At this time, the other ends of all the post-stage switches in the post-stage voltage dividing circuit are coupled to the in-phase input end of the post-stage operational amplifier OPr, as shown in
Among the R post-stage operational amplifiers, the reverse-phase input end and the output end of each post-stage operational amplifier (e.g., the output end G1 of the post-stage operational amplifier OPr) are both coupled to the post-stage output end (e.g., the post-stage output end H1 in
In the gamma voltage generating circuit (which has the circuit diagram as shown in
It is to be noted that, in
The gamma voltage generating circuit in
A first intermediate-stage input end of the intermediate-stage voltage-dividing circuit 30 (e.g., Em1) is coupled to a first output end of an previous-stage voltage-dividing circuit (e.g., D1), a second intermediate-stage input end (e.g., Em(k+1)) is coupled to a second output end of the previous-stage voltage-dividing circuit (e.g., D2), a first intermediate-stage output end (e.g., Dm1 as shown in
The post-stage voltage-dividing circuit 20 is specifically used to divide the voltage from the previous-stage voltage-dividing circuit, thereby to generate the secondary gamma voltage.
The previous-stage voltage-dividing circuit and the next-stage voltage-dividing circuit will be described hereinafter.
On the basis of the circuit as shown in
On the basis of the circuit as shown in
When merely one intermediate-stage voltage-dividing circuit 30 is included, its first intermediate-stage input end is coupled to the first pre-stage output end, its second intermediate-stage input end is coupled to the second pre-stage output end, its first intermediate-stage output end is coupled to the first post-stage input end, and its second intermediate-stage output end is coupled to the second post-stage input end.
As shown in
The K intermediate-stage resistors are sequentially coupled in series. One end of the 1st intermediate-stage resistor Rm1, which is not coupled to the 2nd intermediate-stage resistor Rm2, is coupled to the first intermediate-stage input end, and one end of the Kth intermediate-stage resistor RmK, which is not coupled to the (K−1)th intermediate-stage resistor Rm(K−1), is coupled to the second intermediate-stage input end.
One end of the 1st intermediate-stage switch is coupled to the first intermediate-stage input end, and the other end of the 1st intermediate-stage switch is coupled to an in-phase input of the 1st or 2nd intermediate-stage operational amplifier. One end of the (K+1)th intermediate-stage switch is coupled to the second intermediate-stage input end, and the other end of the (K+1)th intermediate-stage switch is coupled to an in-phase input end of the 1st or 2nd intermediate-stage operational amplifier. One end of the kth intermediate-stage switch is coupled to a common node between the (k−1)th intermediate-stage resistor and the kth intermediate-stage resistor, and the other end of the kth intermediate-stage switch is coupled to an in-phase input end of the 1st or 2nd intermediate-stage operational amplifier. k is a positive integer greater than 1 and not greater than K+1, and K is a positive integer greater than 1.
A reverse-phase input end and an output end of the 1st intermediate-stage operational amplifier OPm1 are both coupled to the first intermediate-stage output end, and a reverse-phase input end and an output end of the 2nd intermediate-stage operational amplifier OPm2 are both coupled to the second intermediate-stage output end.
In order to select the desired gamma voltage using the switch-on and switch-off state of the pre-stage switch, one end of the 1st intermediate-stage switch Sm1 is coupled to the first intermediate-stage input end, and the other end thereof is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1. One end of the (K+1)th intermediate-stage switch Sm(K+1) is coupled to the second intermediate-stage input end. When K+1 is an odd number, the other end of the (K+1)th intermediate-stage switch Sm(K+1) is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1, and when K+1 is an even number, the other end of the (K+1)th intermediate-stage switch Sm(K+1) is coupled to an in-phase input end of the 2nd intermediate-stage operational amplifier OPm2.
One end of the kth intermediate-stage switch Smk is coupled to a common node between the (k−1)th intermediate-stage resistor Rm(k−1) and the kth intermediate-stage resistor Rmk. When k is an odd number, the other end of the kth intermediate-stage switch Smk is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1, and when k is an even number, the other end thereof is coupled to an in-phase input end of the 2nd intermediate-stage operational amplifier OPm2. k is a positive integer not less than 1 and not greater than K+1,and K is a positive integer greater than 1.
The gamma voltage generating circuit as shown in
In order to minimize the number of resistors, the number of the pre-stage and the number of the post-stage resistors need to be kept in balance as possible. For example, in the case of a 6-bit source driver IC, N is 8 and M is 16, and in the case of a 8-bit source driver IC, N is 16 and M is 16 too.
Alternatively, in the case of a 8-bit source driver IC, there is one intermediate-stage voltage-dividing circuit, N is 8, K is 8, and M is 4.
The first pre-stage output end D1 of the pre-stage voltage-dividing circuit 100 is coupled to the first post-stage input end E1, and the second pre-stage output end D2 thereof is coupled to the second post-stage input end E2, so as to divide reference voltages AVDD from the reference voltage input ends, thereby to generate a primary gamma voltage.
The post-stage output ends (Q1, Q2) of the post-stage voltage-dividing circuit 200 are coupled to the output end H1 of the gamma voltage generating circuit, so as to divide the primary gamma voltage, thereby to generate a secondary gamma voltage.
The pre-stage voltage-dividing circuit 100 comprises N+1 pre-stage resistors (i.e., the 0th pre-stage resistor R0 to the Nth pre-stage resistor RN), N pre-stage switches (i.e., the 1st pre-stage switch S1 to the Nth switch SN), and 2 pres-stage operational amplifiers (i.e., the 1st pre-stage operational amplifier OPf1 and the 2nd pre-stage operational amplifier OPf2).
The N+1 pre-stage resistors are sequentially coupled in series. One end of the 0th pre-stage resistor R0, which is not coupled to the 1st pre-stage resistor R1 is coupled to the reference voltage input end, and one end of the Nth resistor RN, which is not coupled to the (N−1)th resistor RN−1, is coupled to the ground (GND).
One end of the nth pre-stage switch Sn is coupled to a common node between the (n−1)th pre-stage resistor Rn−1 and the nth pre-stage resistor Rn. When n is an odd number, the other end of the nth pre-stage switch Sn is coupled to an in-phase input end of the 1st pre-stage operational amplifier OPf1, and when n is an even number, the other end of the nth pre-stage switch Sn is coupled to an in-phase input end of the 2nd pre-stage operational amplifier OPf2. n is a positive integer not less than 1 and not greater than (N+1), and N is a positive integer greater than 1.
A reverse-phase input end and an output end of the 1st pre-stage operational amplifier OPf1 are both coupled to the first pre-stage output end, and a reverse-phase input end and an output end of the 2nd pre-stage operational amplifier OPf2 are both coupled to the second pres-stage output end.
The post-stage voltage-dividing circuit 200 comprises M post-stage resistors (i.e., the 1st post-stage resistor r1 to the Mth post-stage resistor rM), M+1 post-stage switches (i.e., the 1st post-stage switch s1 to the (M+1)th post-stage switch SM+1), and 2 post-stage operational amplifiers (i.e., the 1st post-stage operational amplifier OPr1 and the 2nd post-stage operational amplifier OPr2).
The M post-stage resistors are sequentially coupled in series. One end of the 1st post-stage resistor r1, which is not coupled to the 2nd post-stage resistor r2, is coupled to the first post-stage input end, and one end of the Mth post-stage resistor rM, which is not coupled to the (M−1)th post-stage resistor rM−1, is coupled to the second post-stage input end.
One end of the 1st post-stage switch s1 is coupled to the first post-stage input end, and the other end thereof is coupled to an in-phase input end of the 1st post-stage operational amplifier OPr1. One end of the (M+1)th post-stage switch SM+1 is coupled to the second post-stage input end. When M+1 is an odd number, the other end of the (M+1)th post-stage switch SM+1 is coupled to an in-phase input end of the 1st post-stage operational amplifier OPr1, and when M+1 is an even number, the other end of the (M+1)th post-stage switch SM+1 is coupled to an in-phase input end of the 2nd post-stage operational amplifier OPr2.
One end of the mth post-stage switch sm is coupled to a common node between the (m−1)th post-stage resistor rm−1 and the mth post-stage resistor rm. When m is an odd number, the other end of the mth post-stage switch sm is coupled to an in-phase input end of the 1st post-stage operational amplifier OPr1, and when m is an even number, the other end thereof is coupled to an in-phase input end of the 2nd post-stage operational amplifier OPr2. m is a positive integer not less than 1 and not greater than M+1, and M is a positive integer greater than 1.
A reverse-phase input end and an output end of the 1st post-stage operational amplifier OPr1 are both coupled to the post-stage output end, and a reverse-phase input end and an output end of the 2nd post-stage operational amplifier OPr2 are both coupled to the post-stage output end. The post-stage output end is coupled to the output end of the gamma voltage generating circuit.
In the gamma voltage generating circuit as shown in
The gamma voltage generating circuit in
A first intermediate-stage input end of the intermediate-stage voltage-dividing circuit is coupled to a first output end of a previous-stage voltage-dividing circuit, a second intermediate-stage input end is coupled to a second output end of the previous-stage voltage-dividing circuit, a first intermediate-stage output end is coupled to a first input end of a next-stage voltage-dividing circuit, and a second intermediate-stage output end is coupled to a second input end of the next-stage voltage-dividing circuit.
On the basis of the circuit as shown in
On the basis of the circuit as shown in
When merely one intermediate-stage voltage-dividing circuit 300 is included, the first intermediate-stage input end of the intermediate-stage voltage-dividing circuit 300 is coupled to the first pre-stage output end, the second intermediate-stage input end of the intermediate-stage voltage-dividing circuit 300 is coupled to the second pre-stage output end, the first intermediate-stage output end of the intermediate-stage voltage-dividing circuit 300 is coupled to the first post-stage input end, and the second intermediate-stage output end of the intermediate-stage voltage-dividing circuit 300 is coupled to the second post-stage input end.
The intermediate-stage voltage-dividing circuit 300 comprises K intermediate-stage resistors (i.e., the 1st intermediate-stage resistor Rm1 to the Kth intermediate-stage resistor RmK), K+1 intermediate-stage switches (i.e., the 1st intermediate-stage switch Sm1 to the (K+1)th intermediate-stage switch Sm(K+1)), and 2 intermediate-stage operational amplifiers (i.e., the 1st intermediate-stage operational amplifier OPm1 and the 2nd intermediate-stage operational amplifier OPm2).
The K intermediate-stage resistors are sequentially coupled in series. One end of the 1st intermediate-stage resistor Rm1, which is not coupled to the 2nd intermediate-stage resistor Rm2, is coupled to the first intermediate-stage input end, and one end of the Kth intermediate-stage resistor RmK, which is not coupled to the (K−1)th intermediate-stage resistor Rm(K−1), is coupled to the second intermediate-stage input end.
One end of the 1st intermediate-stage switch Sm1 is coupled to the first intermediate-stage input end, and the other end thereof is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1. One end of the (K+1)th intermediate-stage switch Sm(K+1) is coupled to the second intermediate-stage input end. When K+1 is an odd number, the other end of the (K+1)th intermediate-stage switch Sm(K+1) is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1, and when K+1 is an even number, the other end thereof is coupled to an in-phase input end of the 2nd intermediate-stage operation amplifier OPm2.
One end of the kth intermediate-stage switch Smk is coupled to a common node between the (k−1)th intermediate-stage resistor Rm(k−1) and the kth intermediate-stage resistor Rmk. When k is an odd number, the other end of the kth intermediate-stage switch Smk is coupled to an in-phase input end of the 1st intermediate-stage operational amplifier OPm1, and when k is an even number, the other end of the kth intermediate-stage switch Smk is coupled to an in-phase input end of the 2nd intermediate-stage operational amplifier OPm2. k is a positive integer not less than 1 and not greater than K+1, and K is a positive integer greater than 1.
A reverse-phase input end and an output end of the 1st intermediate-stage operational amplifier OPm1 are both coupled to the first intermediate-stage output end, and a reverse-phase input end and an output end of the 2nd intermediate-stage operational amplifier OP are both coupled to the second intermediate-stage output end.
The gamma voltage generating circuit as shown in
In the case of a 6-bit source driver IC, N is 8 and M is 16, and in the case of a 8-bit source driver IC, N is 16 and M is 16 too.
In the case of a 8-bit source driver IC, there is one intermediate-stage voltage-dividing circuit, N is 8, K is 8, and M is 4.
In this embodiment, a method is provided for controlling the gamma voltage generating circuit according to the first or second embodiment. The gamma voltage generating circuit has the structure shown in
Further, the secondary gamma voltage is just the gamma voltage desired for the source driver, the pre-stage voltage-dividing circuit comprises a first switch group, and the post-stage voltage-dividing circuit comprises a second switch group.
The source driver determines the desired gamma voltage, determines the switch group corresponding to the desired gamma voltage in accordance with the correspondence between the switch group and the gamma voltage, and switches off the corresponding switch group.
The correspondence between the switch group and the gamma voltage may be stored in a gamma lookup table in
It should be appreciated that, the switch group may comprises a first switch group, a second switch group, a first intermediate switch group, and additional switches to be added when it is required to add a certain stage of the voltage-dividing circuit. The correspondence between the switch group and the gamma voltage refers to the correspondence between a single, or a plurality of, switches in each stage of the voltage-dividing circuit in the gamma voltage generating circuit (e.g., the pre-stage voltage-dividing circuit) and the gamma voltage.
During the actual implementation, the switch group may be determined in accordance with the actually required gamma voltage and the gamma voltage generating circuit, so as to output the actually required gamma voltage when the determined switch group is in a switch-off state (while the other switch groups is in a switch-on state).
While V[n] represents the voltage at each stage, the correspondence between the switch group and the gamma voltage is listed hereinafter by taking the gamma voltage generating circuit in
V[1]: (=V1) S1 and s1 OFF;
V[2]: (=V2) S2 and s17 ON;
V[3]: S2, S3 and s16 OFF;
V[4]: S2, S3 and s15 OFF;
V[5]: S2, S3 and s14 OFF;
V[6]: S2, S3 and s13 OFF;
V[7]: S2, S3 and s12 OFF;
V[8]: S2, S3 and s11 OFF;
V[9]: S2, S3 and s10 OFF;
V[10]: S2, S3 and s9 OFF;
V[11]: S2, S3 and s8 OFF;
V[12]: S2, S3 and s7 OFF;
V[13]: S2, S3 and s6 OFF;
V[14]: S2, S3 and s5 OFF;
V[15]: S2, S3 and s4 OFF;
V[16]: S2, S3 and s3 OFF;
V[17]: S2, S3 and s2 OFF;
V[18]: (=V3) S3 and s1 OFF;
V[19]: S3, S4 and s2 OFF;
V[20]: S3, S4 and s3 OFF;
V[21]: S3, S4 and s4 OFF;
V[22]: S3, S4 and s5 OFF;
V[23]: S3, S4 and s6 OFF;
V[24]: S3, S4 and s7 OFF;
V[25]: S3, S4 and s8 OFF;
V[26]: S3, S4 and s9 OFF;
V[27]: S3, S4 and s10 OFF;
V[28]: S3, S4 and s11 OFF;
V[29]: S3, S4 and s12 OFF;
V[30]: S3, S4 and s13 OFF;
V[31]: S3, S4 and s14 OFF;
V[32]: S3, S4 and s15 OFF;
V[33]: S3, S4 and s16 OFF;
V[34]: (=V4) S4 and s17 OFF;
V[35]: S4, S5 and s16 OFF;
V[36]: S4, S5 and s15 OFF;
V[37]: S4, S5 and s14 OFF;
V[38]: S4, S5 and s13 OFF;
V[39]: S4, S5 and s12 OFF;
V[40]: S4, S5 and s11 OFF;
V[41]: S4, S5 and s10 OFF;
V[42]: S4, S5 and s9 OFF;
V[43]: S4, S5 and s8 OFF;
V[44]: S4, S5 and s7 OFF;
V[45]: S4, S5 and s6 OFF;
V[46]: S4, S5 and s5 OFF;
V[47]: S4, S5 and s4 OFF;
V[48]: S4, S5 and s3 OFF;
V[49]: S4, S5 and s2 OFF;
V[50]: (=V5) S5 and s1 OFF . . .
An embodiment of the present invention further provides a liquid crystal display comprising the gamma voltage generating circuit mentioned in the first, second or third embodiments. Apart from the gamma voltage generating circuit, the other parts of the liquid crystal display have the structures similar to an existing liquid crystal display, which will not be repeated herein.
It should be appreciated that, embodiments of the present invention may be provided as a method, a system or a computer program product, so the present invention may be implemented in the form of full hardware embodiments, full software embodiments, or combinations thereof. In addition, the present invention may be in the form of a computer program product implemented on one or more computer-readable storage mediums (including but not limited to disk memory, CD-ROM and optical memory) including computer-readable program codes.
The present invention is described with reference to the flow charts and/or block diagrams showing the method, device (system) and computer program product according to the embodiments of the present invention. It should be appreciated that each process and/or block, or combinations thereof, in the flow charts and/or block diagrams may be implemented via computer program. These computer program may be applied to a general-purpose computer, a special-purpose computer, an embedded processor or any other processor of programmable data processing equipment, so as to form a machine, thereby to obtain the device capable of implementing the functions specified in one or more processes in the flow charts and/or one or more blocks in the block diagrams in accordance with the computer program executed by the computer or the processor of the other programmable data processing equipment.
These computer program may also be stored in a computer-readable memory capable of guiding the computer or the other programmable data processing equipment to work in a special manner, so as to form a product including a command device capable of implementing the functions specified in one or more processes in the flow charts and/or one or more blocks in the block diagrams.
These computer program may also be loaded onto a computer or the other programmable data processing equipment, so as to perform a series of operations thereon and generate the processing implemented by the computer, thereby to provide the steps capable of implementing the functions specified one or more processes in the flow charts and/or one or more blocks in the block diagrams in accordance with the instructions.
Although the preferred embodiments are described above, a person skilled in the art may make modifications and alterations to these embodiments in accordance with the basic concept of the present invention. So, the attached claims are intended to include the preferred embodiments and all of the modifications and alterations that fall within the scope of the present invention.
Number | Date | Country | Kind |
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201310272216.9 | Jul 2013 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2013/084999 | 10/10/2013 | WO | 00 |