This application claims the benefit of Korean Patent Application No. 10-2007-0103171, filed on Oct. 12, 2007, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
The present invention relates to a method and apparatus for generating a gradation voltage, and more particularly, to a method and apparatus for generating a gradation voltage which implements gamma inversion as an X-axis symmetric type.
In general, an image sensor or a display panel has its intrinsic gamma properties that need to be considered in a display system including the image sensor or the display panel, and described with reference to
The display system illustrated in
The decoder DEC receives input of a plurality of gradation voltages V<0> to V<255> generated in the gradation voltage generator 130. The decoder DEC further outputs, from among the gradation voltages V<0> to V<255>, a gradation voltage corresponding to display data DATA as a display data voltage V_data that is then applied to the LCD panel 150 through the buffer BUF. The brightness of the LCD panel 150 (referred to as B_panel) corresponds to the display data voltage V_data.
For example, it will be considered that a gamma curve of the LCD panel 150 illustrated
For the linear brightness output illustrated in
To prevent the deterioration of a liquid crystal in the driving of the LCD panel 150, an inversion driving method is used during which the display data voltage V_data is applied so that an alignment direction of the liquid crystal changes per predetermined period. The inversion driving method can be classified as one of a frame inversion type, a line inversion type, a column inversion type, and a dot inversion type, depending on the set up of a pixel group that is being simultaneously inverted. Furthermore, the inversion driving method can be classified as a Y-axial symmetric type and an X-axis symmetric type, depending on whether the display data DATA or the gradation voltages V<0> to V<255> are being inverted.
The gradation voltage generator 130 included in the display system needs to generate the gradation voltages <0> to V<255> while considering the aforementioned gamma properties and inversion driving.
The present invention provides a method and apparatus for generating gradation voltages which implements gamma inversion as an X-axis symmetric type.
According to an aspect of the present invention, there is provided an apparatus for generating a gradation voltage, comprising a maximum/minimum selection unit configured to output a voltage corresponding to a maximum selection signal as a maximum reference voltage and a voltage corresponding to a minimum selection signal as a minimum reference voltage, from a distribution of voltages ranging from a first source voltage to a second source voltage; a first selector configured to output the maximum reference voltage or the minimum reference voltage as a 1st gradation voltage, in response to an inversion control signal; a second selector configured to output the minimum reference voltage or the maximum reference voltage as an Nth gradation voltage, in response to the inversion control signal, where N is a natural number; and a gamma control unit configured to select, from among a plurality of voltages in a voltage distribution between the 1st gradation voltage and the Nth gradation voltage, voltages corresponding to a 1st gamma selection signal to an Mth gamma selection signal, respectively, as a 1st gamma voltage to an Mth gamma voltage, where M is a natural number, and generate a 2nd gradation voltage to an (N−1)th gradation voltage from the 1st gamma voltage to the Mth gamma voltage.
The maximum/minimum selection unit can comprise a source division unit configured to generate a plurality of voltages from a voltage distribution ranging from the first source voltage to the second source voltage; a maximum selector configured to output the voltage corresponding to the maximum selection signal as the maximum reference voltage, from among voltages ranging from the first source voltage to a middle voltage of the voltage distribution; and a minimum selector configured to output the voltage corresponding to the minimum selection signal as the minimum reference voltage, from among voltages ranging from the middle voltage to the first source voltage.
The apparatus can further comprise a maximum adjustment register configured to output the maximum selection signal to the maximum selector through a first level shifter; and a minimum adjustment register configured to output the minimum selection signal to the minimum selector through a second level shifter.
The apparatus can further comprise an X-axis symmetry register configured to outputting the inversion control signal to the first selector and the second selector through a level shifter.
When a logic level of the inversion control signal is at a first level, the first selector can output the maximum reference voltage as the 1st gradation voltage, and the second selector can output the minimum reference voltage as the Nth gradation voltage.
When a logic level of the inversion control signal is at a second level, the first selector can output the minimum reference voltage as the 1st gradation voltage, and the second selector can output the maximum reference voltage as the Nth gradation voltage.
The gamma control unit can comprise: a 1st gradation buffer configured to buffer and output the 1st gradation voltage output from the first selector; and a Nth gradation buffer configured to buffer and output the Nth gradation voltage output from the second selector.
The gamma control unit can comprise a gamma division unit configured to generate the plurality of voltages through the voltage distribution between the 1st gradation voltage and the Nth gradation voltage; and 1st to Mth gamma selectors configured to output, from the plurality of voltages, voltages corresponding to the 1st to Mth gamma selection signals as 1st to Mth gamma voltages, respectively.
The apparatus can further comprise a gamma adjustment register configured to output each of the 1st gamma selection signal to the Mth gamma selection signal, respectively, to the 1st gamma selector to the Mth gamma selector, through respective level shifters.
The gamma control unit can further comprise: 1st to Mth gamma buffers configured to buffer and output the 1st to Mth gamma voltages output from the 1st to Mth gamma selectors, respectively.
The gamma control unit may further comprise a gradation division unit configured to generate the 2nd gradation voltage to the (N−1)th gradation voltage through a voltage distribution between the 1st gamma voltage to the Mth gamma voltage.
In the apparatus: an mth gamma buffer can output an mth gamma voltage as an nth gradation voltage; an (m+1)th gamma buffer can output an (m+1)th gamma voltage as an (n+p)th gradation voltage; and an (m+2)th gamma buffer can output an (m+2)th gamma voltage as an (n+p+q)th gradation voltage, where m, n, p, and q are natural numbers, and m=1 to M and n=1 to N.
The gradation division unit can be configured to generate an (n+1)th gradation voltage to an (n+p−1)th gradation voltage through a voltage distribution between the nth gradation voltage and the (n+p)th gradation voltage, and to generate an (n+p+1)th gradation voltage to an (n+p+q−1)th gradation voltage through a voltage distribution between the (n+p)th gradation voltage and the (n+p+q)th gradation voltage.
The
gamma voltage being output from the
gamma selector to the
gamma buffer may not be used as the gradation voltage.
The gamma control unit can further comprise an inflection point adjustment switch configured to adjust a connection point between an mth gamma buffer and the gradation division unit, in response to an inflection point adjustment signal, where m is a natural number that equals 1 to M.
The apparatus may further comprise an inflection point adjustment register configured to output the inflection point adjustment signal to the inflection point adjustment switch through a level shifter.
According to another aspect of the present invention, there is provided a method of generating a gradation voltage, comprising selecting a maximum reference voltage and a minimum reference voltage, from a distribution of voltages ranging from a first source voltage to a second source voltage; selecting the maximum reference voltage as a 1st gradation voltage and the minimum reference voltage as an Nth gradation voltage, or selecting the minimum reference voltage as the 1st gradation voltage and the maximum reference voltage as the Nth gradation voltage, in response to an inversion control signal, where N is a natural number; selecting a 1st gamma voltage to an Mth gamma voltage, in a voltage distribution between the 1st gradation voltage and the Nth gradation voltage, where M is a natural number; and generating a 2nd gradation voltage to an (N−1)th gradation voltage by a voltage distribution between the 1st gradation voltage, the 1st gamma voltage to the Mth gamma voltage, and the Nth gradation voltage.
When a logic level of the inversion control signal is at a first level, the maximum reference voltage can be selected as the 1st gradation voltage and the minimum reference voltage is selected as the Nth gradation voltage.
When a logic level of the inversion control signal is at a second level, the minimum reference voltage can be selected as the 1st gradation voltage and the maximum reference voltage is selected as the Nth gradation voltage.
When an mth gamma voltage is output as an nth gradation voltage and an (m+i)th gamma voltage is output as an (n+p)th gradation voltage and an (m+2)th gamma voltage is output as an (n+p+q)th gradation voltage, an (n+i)th gradation voltage to an (n+p−1)th gradation voltage can be generated through a voltage distribution between the nth gradation voltage and the (n+p)th gradation voltage, and an (n+p+i)th gradation voltage to an (n+p+q−1)th gradation voltage can be generated through a voltage distribution between the (n+p)th gradation voltage and the (n+p+q)th gradation voltage, where m, n, p, and q are natural numbers and m=1 to M and n=1 to N.
The various features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments in accordance therewith, with reference to the attached drawings, in which:
Hereinafter, aspects of the present invention will be described by explaining illustrative embodiments in accordance therewith, with reference to the attached drawings. While describing these embodiments, detailed descriptions of well-known items, functions, or configurations are typically omitted for conciseness.
Before the present invention will be explained,
In
For example, when a display data sequence is DATA<0>, DATA<0>, DATA<0>, DATA<0>, DATA<0> and the display data sequence is inverted in the second part P2 only, the display data sequence becomes DATA<0>, DATA<255>, DATA<0>, DATA<255>, DATA<0>. When the display data sequence of DATA<0>, DATA<255>, DATA<0>, DATA<255>, DATA<0>, instead of the display data sequence of DATA<0>, DATA<0>, DATA<0>, DATA<0>, DATA<0>, is input to the decoder DEC of
In
For example, when the display data sequence of DATA<0>, DATA<0>, DATA<0>, DATA<0>, DATA<0> is input to the decoder DEC of
As illustrated in
In
In
A plurality of selectors A, B, C, D, E, F, G, H and I, controlled by a gamma adjustment register GAMMA AR, each select any one of a plurality of voltages generated by the voltage distribution between nodes N4, N5, N6 and N7. The gamma adjustment register GAMMA AR controls the selection operation of the selectors A, B, C, D, E, F, G, H and I, to determine a gamma curve.
A buffer A2 outputs a voltage being output from the selector A as a 2nd gradation voltage V<1>. A buffer A3 outputs a voltage being output from the selector B as a 12th gradation voltage V<1>. As illustrated in
For example, when the gradation voltage generator of
When the gradient adjustment register GRADIENT AR adjusts the selection operation of the first gradient selector GD1 and second gradient selector GD2 to reset the gradient of the gamma curve, the voltage levels of the 2nd gradation voltage V<1> through the 255th gradation voltage V<254> are all changed. Considering this aspect, it is difficult for the gradation voltage generator of
In
In
Since one skilled in the art, given the benefit of the above description, understands the operation of selectors B through K, the operation of buffers A3 through A12 and the generation of a 10th gradation voltage V<9> to a 255th gradation voltage V<254> will not be described in detail herein.
In
In
The biggest difference between the gradation voltage generators of
The apparatus for generating the gradation voltage of
The maximum/minimum selection unit, which comprises the source division unit DIV_source, the maximum selector MS1 and the minimum selector MS2, outputs a voltage corresponding to a maximum selection signal S_max as a maximum reference voltage V_max and outputs, among the voltages from a first source voltage V_vdd to a second source voltage V_vgs, a voltage corresponding to a minimum selection signal S_min as a minimum reference voltage V_min. Specifically, the source division unit DIV_source generates a plurality of voltages by voltage distribution between a first source voltage V_vdd and a second source voltage V_vgs. The maximum selector MS1 outputs, among the voltages from the first source voltage V_vdd to a middle voltage V_mid, a voltage corresponding to the maximum selection signal S-max as the maximum reference voltage V_max. The minimum selector MS2 outputs, among the voltages from the middle voltage V_mid to the second source voltage V_vgs, the voltage corresponding to the minimum selection signal S_min as the minimum reference voltage V_min.
The maximum adjustment register MAX AR outputs the maximum selection signal S_max to the maximum selector MS1 through the level shifter LS, to control the selection operation of the maximum selector MS1. The minimum adjustment register MIN AR outputs the minimum selection signal S_min to the minimum selector MS2 through a level shifter LS, to control the selection operation of the minimum selector MS2.
The first selector SEL1 outputs the maximum reference voltage V_max or the minimum reference voltage V_min as a 1st gradation voltage V<0>, in response to an inversion control signal S_inv. The second selector SEL2 outputs the minimum reference voltage V_min or the maximum reference voltage V_max as a 256th gradation voltage V<255>, in response to the inversion control signal S_inv. The X-axis symmetry register X-axis SYMMETRY REG outputs the inversion control signal S_inv to the first selector SEL1 and the second selector SEL2 through the level shifter LS, to control the selection operation of the first and second selectors SEL1 and SEL2.
An operation section of the apparatus for generating the gradation voltage as illustrated in
The gamma control unit, which comprises the gradation buffers A1 and A13, the gamma division unit DIV_gamma, the gamma selectors GM1 to GM11, the gamma buffers A2 to A12, and the gradation division unit DIV_gradation, selects, from among the voltages generated by the voltage distribution between the 1st gradation voltage V<0> and the 256th gradation voltage V<255>, voltages each corresponding to a 1st gamma selection signal GS1 to an 11th gamma selection signal GS11, as a 1st gamma voltage GV1 to an 11th gamma voltage GV11 and generates a 2nd gradation voltage V<1> to a 255th gradation voltage V<254> from the 1st gamma voltage GV1 to the 11th gamma voltage GV11.
The gradation buffer A1 buffers the 1st gradation voltage V<0> being output from the first selector SEL1. The gradation buffer A13 buffers the 256th gradation voltage V<255> being output from the second selector SEL2. The gamma division unit DIV_gamma generates a plurality of voltages by the voltage distribution between the 1st gradation voltage V<0> and the 256th gradation voltage V<255>.
The gamma selector GM1 outputs a voltage, among a plurality of the voltages being input from the gamma division unit DIV_gamma, corresponding to a 1st gamma selection signal GS1, as a 1st gamma voltage GV1. The gamma buffer A2 buffers the 1st gamma voltage GV1 being output from the gamma selector GM1 to output the 1st gamma voltage GV1 as a 2nd gradation voltage V<1>. The gamma selector GM2 outputs a voltage corresponding to a 2nd gamma selection signal GS2, from among a plurality of the voltages being input from the gamma division unit DIV_gamma, as a 2nd gamma voltage GV2. The gamma buffer A3 buffers the 2nd gamma voltage GV2 being output from the 2nd gamma selector GM2 to output the 2nd gamma voltage GV2 as a 6th gradation voltage V<5>.
One skilled in the art, having the benefit of this disclosure, would understand the operations of gamma selector GM3 to the gamma selector GM11, with reference to the operation of the gamma selector GM1 and the gamma selector GM2, as described above. Furthermore, one skilled in the art, having the benefit of this disclosure, would understand the operation of the gamma buffer A4 to the gamma buffer A12, with reference to the operation of the gamma buffer A2 and the gamma buffer A3. For example, when m, n, p and q are natural numbers, an mth gamma buffer outputs an mth gamma voltage, which is output from an Mth gamma selector, as an nth gradation voltage, an (m+1)th gamma buffer outputs an (m+1)th gamma voltage, which is output from an (m+1)th gamma selector, as an (n+p)th gradation voltage, and an (m+2)th gamma buffer outputs an (m+2)th gamma voltage, which is output from an (m+2)th gamma selector, as an (n+p+q)th gradation voltage. Values of p and q may vary according in different embodiments.
The gradation division unit DIV_gradation generates the 2nd gradation voltage V<1> to the 255th gradation voltage V<254> by the voltage distribution between the 1st gamma voltage GV1 to the 11th gamma voltage GV11. Specifically, the gradation division unit DIV_gradation generates an (n+1)th gradation voltage to an (n+p−1)th gradation voltage by the voltage distribution between the nth gradation voltage and the (n+p)th gradation voltage and generates an (n+p+1)th gradation voltage to an (n+p+q−1)th gradation voltage by the voltage distribution between the (n+p)th gradation voltage and the (n+p+q)th gradation voltage. For example, in
In
The gamma adjustment register GAMMA AR outputs the 1st gamma selection signal GS1 to the 11th gamma selection signal GS11 respectively to the gamma selector GM1 to the gamma selector GM11, through respective level shifters LS. That is, the gamma adjustment register GAMMA AR controls the selection operation of the gamma selector GM1 to the gamma selector GM11, so as to determine a gamma curve.
The apparatus for generating the gradation voltage of
However, in
If the symmetric reference voltage Vcenter is used as the 128th gradation voltage V<127>, each of the 1st gradation voltage to the 128th gradation voltage and each of the 256th gradation voltage to the 129th gradation voltage do not satisfy the accurate X-axis symmetric interrelationship therebetween, as illustrated in the gamma curve of the graph in
The apparatus for generating the gradation voltage as illustrated in
The apparatus for generating the gradation voltage as illustrated in
As described above, each display panel has its intrinsic gamma properties. When the inflection point of the gamma curve for a display panel is adjusted by using the inflection point adjustment switches SW1, SW2, SW3, and SW4 and the inflection point adjustment register INFP AR, each display panel is provided with the gamma curve that is proper for the display panel.
The apparatus for generating the gradation voltage according to aspects of the present invention is described above. However, aspects of the present invention can be understood as a method of generating a gradation voltage for X-axis symmetric gamma inversion. That is, in an embodiment of the method of generating the gradation voltage according to aspects of the present invention, the following operation is performed:
From among a plurality of voltages generated by voltage distribution between a first source voltage V_vdd and a second source voltage V_vgs, a maximum reference voltage V_max and a minimum reference voltage V_min are selected.
Subsequently, in response to an inversion control signal S_inv, the maximum reference voltage V_max is selected as a 1st gradation voltage V<0> and the minimum reference voltage V_min is selected as an Nth gradation voltage V<N−1> or the minimum reference voltage V_min is selected as the 1st gradation voltage V<0> and the maximum reference voltage V_max is selected the Nth gradation voltage V<N−1>. Specifically, when a logic level of the inversion control signal S_inv is at a first level, the maximum reference voltage V_max is selected as the 1st gradation voltage V<0> and the minimum reference voltage V_min is selected as the Nth gradation voltage V<N−1>. When the logic level of the inversion control signal S_inv is at a second level, the minimum reference voltage V_min is selected as the 1st gradation voltage V<0> and the maximum reference voltage V_max is selected as the Nth gradation voltage V<N−1>.
Subsequently, from among a plurality of voltages generated by the voltage distribution between the 1st gradation voltage V<0> and the Nth gradation voltage V<N−1>, a 1st gamma voltage GV1 to an Mth gamma voltage GVM are selected, where N and M are natural numbers.
A 2nd gradation voltage V<1> to an (N−1)th gradation voltage V<N−2> are then generated using the voltage distribution between the 1st gradation voltage V<0>, the 1st gamma voltage GV1 to the Mth gamma voltage GVM, and the Nth gradation voltage V<N−1>. For example, when an Mth gamma voltage (wherein m is 1 to M) is output as an nth gradation voltage (wherein n is 1 to N), an (m+1)th gamma voltage is output as an (n+p)th gradation voltage and an (m+2)th gamma voltage is output as an (n+p+q)th gradation voltage, and an (n+1)th gradation voltage to an (n+p−1)th gradation voltage are generated by the voltage distribution between the nth gradation voltage and the (n+p)th gradation voltage. Furthermore, an (n+p+1)th gradation voltage to an (n+p+q−1)th gradation voltage are generated by the voltage distribution between the (n+p)th gradation voltage and the (n+p+q)th gradation voltage.
In
In the present invention, since middle level between the first gradation and the N gradation is accurately used as the reference X-axis, the apparatus for generating the gradation voltage can accurately support the X-axis symmetric gamma inversion. Furthermore, the apparatus for generating the gradation voltage according to aspects of the present invention can provide a gamma curve suitable for each display panel by properly adjusting the inflection point of the gamma curve.
While the foregoing has described what are considered to be the best mode and/or other preferred embodiments, it is understood that various modifications can be made therein and that the invention or inventions can be implemented in various forms and embodiments, and that they may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim that which is literally described and all equivalents thereto, including all modifications and variations that fall within the scope of each claim.
Number | Date | Country | Kind |
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10-2007-0103171 | Oct 2007 | KR | national |