JP4744970B2 - Display device drive circuit and display device - Google Patents

Description

  The present invention relates to a driving circuit for a display device.

A driver circuit of a display device (liquid crystal display device or the like) generally includes a γ correction circuit for correcting optical characteristics. This γ correction circuit has a conversion table for converting input (gradation) data (Video data) to display data. In this conversion table, for example, 64 bits ( ²⁶ types) of 6-bit input data are input. Each is associated with any of 8-bit 256 (= 2 ⁸ ) types of display data.

  By the way, in a display device such as a liquid crystal display device, from the viewpoint of reliability (durability), AC driving for applying both positive and negative voltages to the display panel is performed. However, the γ characteristic of the display panel differs depending on whether the input data is positive or negative. For example, the video data-output voltage curve of the normally white liquid crystal (see FIG. 6) is a curve that is roughly inverted between the positive polarity (solid line) and the negative polarity (dashed line) (the center value of the output voltage is the axis). ), But it is not a completely inverted curve. For this reason, it is necessary to prepare two types of conversion tables, one for positive polarity and one for negative polarity.

For example, as shown in FIG. 7, when the bit width of the input data is 6 bits and the display data after γ correction requires an 8 bit data width, the conversion table includes either positive polarity or negative polarity. On the other hand, a storage circuit of 2 ⁶ (= 64) entries × 8 bits, that is, 512 bits is required. In the prior art shown in FIG. 7, this conversion table is prepared for each of positive and negative, and a total of 512 bits × 2 = 1024 bits of storage circuit is provided.
Japanese Patent Laid-Open No. 7-1754478 (release date: May 15, 1995) JP 2003-280615 (release date: November 5, 2003)

  This conversion table is constituted by a storage circuit such as a RAM, a ROM, or a flash memory. However, if two types of conversion tables for positive polarity and negative polarity are provided as described above, the circuit scale increases. Such an increase in circuit scale has been a big problem especially for portable display devices that are required to be miniaturized.

  The present invention has been made in view of the above problems, and an object thereof is to reduce the size of a γ correction circuit mounted on a drive circuit (driver) of a display device.

  In order to solve the above problems, the γ correction circuit according to the present invention is a γ correction circuit that generates two γ correction data for the input data of each gradation. A γ conversion table for generating the γ correction data, an adjustment table for generating the adjustment data from the input data, and an operation for generating the second γ correction data based on the first γ correction data and the adjustment data And a circuit.

  According to the above configuration, one γ conversion table and one adjustment table are used when generating two types of γ correction data (for example, for positive polarity and negative polarity) for input data of each gradation. Here, for example, by setting the bit width of the adjustment data output from the adjustment table to be smaller than the bit width of the first γ correction data, two γ conversion tables (full The total circuit area of the table (for example, the storage circuit) can be reduced as compared with the conventional configuration in which the entry is provided. As a result, the γ correction circuit can be reduced.

  As described above, in the γ correction circuit, the number of bits of the adjustment data is preferably smaller than the number of bits of the first γ correction data.

  The drive circuit of the display device of the present invention generates first display data corresponding to the first polarity and second display data corresponding to the second polarity for the input data of each gradation, and uses these to generate the display device. A drive circuit for a display device driven by alternating current, a γ conversion table for generating first γ correction data obtained by γ correction from input data, an adjustment table for generating adjustment data from input data, and the first And an arithmetic circuit for generating second γ correction data based on the first γ correction data and the adjustment data, the first γ correction data as the first display data, and the second γ correction data as the first display data. It is characterized by being used as two display data.

  In the above configuration, two display data (for example, for positive polarity and negative polarity) are generated for input data of each gradation, with one γ conversion table and one adjustment table. Therefore, for example, if the bit width of the adjustment data output from the adjustment table is made smaller than the bit width of the first display data, two γ conversion tables (full entries) are associated with each γ correction data. Compared with the case of providing, the total circuit area of the table (for example, the memory circuit) can be reduced. As a result, the drive circuit of the display device can be reduced.

  As described above, in the driving circuit of the display device, the number of bits of the adjustment data is preferably smaller than the number of bits of the first display data.

  In the driving circuit of the display device of the present invention, the output potentials corresponding to the first and second display data are respectively the first and second output potentials, and the adjustment data is the first output potential and It is preferable to adopt a configuration corresponding to the difference between the potential difference between the reference potentials and the potential difference between the second output potential and the reference potential. According to the above configuration, the bit width of the adjustment data can be reduced when the positive and negative output voltages for the same gradation are similar.

  In the driving circuit of the display device of the present invention, it is preferable that a sign bit for identifying whether or not to input to the adjustment table is added to the input data. According to the above configuration, if the sign bit corresponds to the first polarity, the adjustment table is not input, and if the sign bit corresponds to the first polarity, the adjustment table. The data processing efficiency can be improved.

In the driving circuit of the display device of the present invention, it is possible to correspond to the γ characteristics of a plurality of first to n-th liquid crystal panels (n is an integer of 2 or more), and the first and second display data are stored for each γ characteristic. In order to generate the γ conversion table and one adjustment table as the first γ characteristic, the first adjustment table for the first polarity and the second adjustment for the second polarity are used for each γ characteristic after the second γ characteristic. For the first γ characteristic, the first γ correction data obtained based on the input data and the γ conversion table is used as the first display data, and the adjustment data is based on the input data and the adjustment table. And the second γ correction data obtained based on the adjustment data and the first γ correction data is used as the second display data. The γ characteristics after the second γ characteristic are The adjustment data is generated based on the first adjustment table provided for the γ characteristic, and the first display data is generated based on the adjustment data and the first γ correction data related to the first γ characteristic. And generating adjustment data based on the input data to the corresponding γ characteristic and the second adjustment table provided for the γ characteristic, and the second data related to the adjustment data and the first γ characteristic. It is characterized in that a configuration for generating a second display data on the basis of the γ correction data.

  In the drive circuit of the display device of the present invention, the input data exists for each color from the first color to the nth (n is an integer of 2 or more), and the first and second display data are generated for each color. Therefore, the γ conversion table and one adjustment table for the first color are used, and the first adjustment table for the first polarity and the second adjustment table for the second polarity are used for each color after the second color. For the first color, the first display data is first gamma correction data obtained based on the first color input data and the gamma conversion table, and the first color input data and adjustment The adjustment data is generated based on the table, and the second γ correction data obtained based on the adjustment data and the first γ correction data is used as the second display data. Input color Adjustment data is generated based on the data and the first adjustment table provided for the color, and the first display data is generated based on the adjustment data and the first γ correction data relating to the first color. And generating adjustment data based on the input data for the corresponding color and the second adjustment table provided for the color, and the adjustment data and the second γ correction data for the first color. It can also be set as the structure which produces | generates 2nd display data based on.

  In the display device drive circuit according to the present invention, the display unit of the display device is divided into first to nth (n is an integer of 2 or more) regions, and the first and second display data are stored for each region. In order to generate the gamma conversion table and one adjustment table for the first region, the first adjustment table for the first polarity and the second adjustment table for the second polarity are used for each region after the second region. A table is provided, and for the first area, the first display data is first γ correction data obtained based on the input data to the first area and the γ conversion table, and the input data to the first area The adjustment data is generated based on the adjustment table and the second γ correction data obtained based on the adjustment data and the first γ correction data is used as the second display data. In the area Therefore, the adjustment data is generated based on the input data to the area and the first adjustment table provided for the area, and the adjustment data and the first γ correction data for the first area are generated. The first display data is generated based on the input data to the corresponding area and the second adjustment table provided for the area, and the adjustment data and the first area are generated. The second display data may be generated based on the second γ correction data according to the above.

  In addition, a display device according to the present invention includes a drive circuit for the display device.

  As described above, the γ correction circuit according to the present invention generates two γ correction data (for example, positive polarity and negative polarity) for each gradation input data, One adjustment table is used. Therefore, the total circuit area of the table (for example, the storage circuit) can be reduced as compared with the conventional configuration in which two γ conversion tables (full entries) are provided corresponding to each γ correction data. As a result, the γ correction circuit can be reduced.

  In this embodiment, as an example, a γ correction circuit in which the bit width of input data is 6 bits and the bit width of output data after γ conversion is 8 bits will be described. In this embodiment, the case of mounting on a liquid crystal display device is described, but the present invention is not limited to this. This γ correction circuit can be applied to any display device that performs AC driving and performs γ correction and has a similar positive polarity and negative polarity characteristics during AC driving.

  First, when the liquid crystal display device is AC driven, the positive and negative γ curves have a shape similar to the center level axis. Therefore, the γ correction circuit of the present invention can be applied. FIG. 1 is a block diagram showing the configuration of the γ correction circuit according to the present embodiment. Here, negative γ correction data (output curve) is obtained based on positive γ correction data (output curve). Of course, the positive γ correction data (output curve) may be obtained based on the negative γ correction data (output curve).

  As shown in the figure, the γ correction circuit 3 of the present embodiment includes a γ conversion table 8 (for positive polarity), an arithmetic circuit 11, and an adjustment table 9 (for negative polarity). The arithmetic circuit 11 includes an inverter circuit 10. As described above, the γ correction circuit 3 includes the two types of storage circuits (γ conversion table 8 and adjustment table 9) and the arithmetic circuit 11, and uses positive γ correction data (positive display data). The calculation circuit 11 inverts this value and the adjustment data in the adjustment table 9 is calculated by the calculation circuit 11 to obtain γ correction data for negative polarity (negative display data). The configuration of the adjustment data is as shown in FIG. 5, and any one bit is treated as a code bit and the rest is treated as a correction value (here, 3 bits).

  Below, the production | generation method of each display data of positive polarity and negative polarity is shown.

  The γ conversion table 8 is a storage circuit, and holds output data b (8 bits) that realizes a positive γ curve shown in FIG. 6 with respect to input data a (6 bits). When the display polarity is positive, the input data a (6 bits) is used as an address value to access the γ conversion table 8, and the output b is used as it is as positive display data (8 bits).

  When the display data g for negative polarity is generated, the γ conversion table 8 and the adjustment table 9 (for negative polarity) are used. First, using the input data a (6 bits) as an address value, the γ conversion table 8 and the adjustment table 9 are accessed to obtain the respective output data d (4 bits, adjustment data) and output data e (8 bits).

If the sign bit of the input data corresponds to plus, it is input only to the γ conversion table 8 and not input to the adjustment table 9. On the other hand, if the sign bit corresponds to minus, it is input to the γ conversion table 8 and the adjustment table 9. This sign bit can improve data processing efficiency. Further, in the present embodiment, one entry of the adjustment table 9 is treated as 4 bits (total ²⁶ × 4 bits = 256 bits), the most significant bit is treated as a sign bit, and the remaining 3 bits are used for data adjustment. In this case, adjustment in 15 steps from -7 to +7 is possible. If the output potential (analog data output from the DAC) corresponding to the display data for positive polarity and negative polarity is the first and second output potentials, respectively, the adjustment data d is the first output. It is a value corresponding to the difference between the potential difference between the potential and the reference potential and the potential difference between the second output potential and the reference potential.

  Returning to FIG. 1, the output data e (8 bits) obtained from the γ conversion table 8 becomes inverted data f in the arithmetic circuit 11. The inversion data f and the lower 3 bits of the output data d of the adjustment table 9 are calculated by the arithmetic circuit 11 according to the sign bit of the output data d, and the output data g (8 bits) is displayed as display data for negative polarity. And The display data for the positive polarity and the negative polarity is converted into an output voltage (analog data) by the DAC and output to the liquid crystal panel. Thus, according to the present embodiment, the desired positive and negative γ curves can be realized without having positive and negative display γ conversion tables as in the prior art. .

In the present embodiment, a 4-bit adjustment table 9 (storage circuit) is provided as the negative polarity table. The storage circuit scale required for this adjustment table is ²⁶ entries × 4 bits = 256 bits. Since a normal γ conversion table ( ²⁶ entries × 8 bits = 512 bits) is used for the positive polarity, the γ correction circuit 3 of the present embodiment has a memory circuit of 512 bits + 256 bits = 768 bits. As a result, the same result can be obtained with a circuit scale of 3/4 compared to the conventional configuration including the γ conversion table (512 bits + 512 bits = 1024 bits) for both positive and negative.

  Here, the negative display data is obtained based on the positive γ correction data. Conversely, the γ conversion table 8 (memory circuit) is used as the negative γ conversion table and the output data (γ correction) is obtained. Data) and adjustment data may be calculated by an arithmetic circuit to generate display data for positive polarity. Further, if the bit width of the adjustment table is adjusted according to the characteristics of the liquid crystal, the circuit can be further reduced or the adjustment width can be expanded.

  Furthermore, the γ correction circuit according to the present invention is very effective when it is necessary to support a plurality of γ curves (γ characteristics) in order to support a plurality of liquid crystal panels. For example, when supporting the first and second γ curves, conventionally, two positive and negative γ conversion tables are required for each of the first and second γ curves, for a total of four γ conversions. A table was needed. However, if this embodiment is applied, one of the positive polarity tables is a γ conversion table having all entries, the other positive polarity table is an adjustment table, and each negative polarity table is an adjustment table. For example, an increase in the circuit area of the γ correction circuit can be suppressed as much as possible. Furthermore, in addition to the above configuration, by adding adjustment tables for positive and negative polarities, it becomes possible to support three γ curves. As described above, according to the present embodiment, a single γ conversion table (full entry) is provided, and after that, by simply increasing the adjustment table, a plurality of liquid crystal display elements having different optical characteristics can be handled. Cost reduction can be achieved.

  FIG. 2 shows a specific example of the configuration. As shown in the figure, in order to be able to cope with the first to third γ characteristics (three liquid crystal panels) and to generate display data for positive polarity and negative polarity for each γ characteristic, the first γ characteristics A γ conversion table 45 and an adjustment table 46 are provided for use, and a first adjustment table 48 for the first polarity and a second adjustment table 49 for the second polarity are provided for the second γ characteristic, and a third γ For the characteristics, a first adjustment table 50 for the first polarity and a second adjustment table 51 for the second polarity are provided. Further, an arithmetic circuit 52 is provided.

  Here, for the first γ characteristic, the first γ correction data d1 obtained based on the input data and the γ conversion table 45 is used as display data for positive polarity, and the adjustment data based on the input data and the adjustment table 46. d2 is generated, and the second γ correction data d3 obtained by the arithmetic circuit 52 based on the adjustment data d2 and the first γ correction data d1 is used as display data for negative polarity.

  For the second γ characteristic, the adjustment data d4 is generated based on the input data and the adjustment table 48 provided for the second γ characteristic, and the first γ correction relating to the adjustment data d4 and the first γ characteristic is generated. Display data for positive polarity is generated by the arithmetic circuit 52 based on the data d1, and adjustment data d5 is generated based on the input data and the second adjustment table 49 provided for the second γ characteristic. Based on the data d5 and the second γ correction data d3 related to the first γ characteristic, the arithmetic circuit 52 generates display data for negative polarity.

  Further, for the third γ characteristic, the adjustment data d6 is generated based on the input data and the adjustment table 50 provided for the third γ characteristic, and the first γ correction related to the adjustment data d6 and the first γ characteristic is generated. Display data for positive polarity is generated by the arithmetic circuit 52 based on the data d1, and adjustment data d7 is generated based on the input data and the second adjustment table 51 provided for the second γ characteristic. Based on the data d7 and the second γ correction data d3 related to the first γ characteristic, the arithmetic circuit 52 generates display data for negative polarity.

  In addition to the case where a plurality of liquid crystal panels are supported, the present configuration may be applied to one liquid crystal panel. In the case of a large liquid crystal panel, the γ curve (γ characteristic) changes as the viewing angle changes. Therefore, it is possible to optimize the display by dividing the scanning line into blocks and applying the configuration of the γ correction circuit.

  FIG. 3 shows a specific example of the configuration. As shown in the figure, the display unit of the display device is divided into first to third blocks (for example, a central block and left and right blocks), and generates display data for positive polarity and negative polarity for each block. Therefore, a γ conversion table 55 and an adjustment table 56 are provided for the first block, and a first adjustment table 58 for the first polarity and a second adjustment table 59 for the second polarity are provided for the second block. For the third block, a first adjustment table 60 for the first polarity and a second adjustment table 61 for the second polarity are provided, and an arithmetic circuit 62 is further provided.

  Here, for the first block, the first γ correction data d1 obtained based on the input data and the γ conversion table 55 is used as display data for positive polarity, and the adjustment data based on the input data and the adjustment table 56. d2 is generated, and the second γ correction data d3 obtained by the arithmetic circuit 62 based on the adjustment data d2 and the first γ correction data d1 is used as display data for negative polarity.

  For the second block, the adjustment data d4 is generated based on the input data and the adjustment table 58 provided for the second block, and the first γ correction related to the adjustment data d4 and the first block is generated. The display circuit for positive polarity is generated by the arithmetic circuit 62 based on the data d1, and the adjustment data d5 is generated based on the input data and the second adjustment table 59 provided for the second block. Based on the data d5 and the second γ correction data d3 related to the first block, the arithmetic circuit 62 generates display data for negative polarity.

  Further, for the third block, the adjustment data d6 is generated based on the input data and the adjustment table 60 provided for the third block, and the first γ correction related to the adjustment data d6 and the first block is generated. Display data for positive polarity is generated by the arithmetic circuit 62 based on the data d1, and adjustment data d7 is generated based on the input data and the second adjustment table 61 provided for the second block. Based on the data d7 and the second γ correction data d3 related to the first block, the arithmetic circuit 62 generates display data for negative polarity.

  Further, the configuration of the γ correction circuit can be applied to R, G, and B input data. In other words, a γ conversion table and an adjustment table corresponding to each color may be provided, or a γ conversion table corresponding to R display data may be provided, and the other G and B may correspond to the adjustment table.

  FIG. 4 shows a specific example of the configuration. As shown in the figure, when input data exists for each of three colors of R (red), G (green), and B (blue), display data for positive polarity and negative polarity is generated for each color. Therefore, a γ conversion table 65 and an adjustment table 66 are provided for R, and a first adjustment table 68 for the first polarity and a second adjustment table 69 for the second polarity are provided for G. For B, a first adjustment table 70 for the first polarity and a second adjustment table 71 for the second polarity are provided, and an arithmetic circuit 72 is further provided.

  Here, for R, the first γ correction data d1 obtained based on the input data of R and the γ conversion table 65 is set as R display data for positive polarity, and for adjustment based on the input data and the adjustment table 66. Data d2 is generated, and second gamma correction data d3 obtained by the arithmetic circuit 72 based on the adjustment data d2 and the first gamma correction data d1 is used as R display data for negative polarity.

  For G, adjustment data d4 is generated based on the input data of G and the adjustment table 68 provided for G, and based on the first γ correction data d1 related to the adjustment data d4 and R. The G display data for positive polarity is generated by the arithmetic circuit 72, and the adjustment data d5 is generated based on the input data and the second adjustment table 69 provided for G. The adjustment data d5 and R Based on the second γ correction data d3 related to the above, the arithmetic circuit 72 generates G display data for negative polarity.

  Further, for B, adjustment data d6 is generated based on the input data of B and the adjustment table 70 provided for B, and based on the first γ correction data d1 related to the adjustment data d6 and R. The arithmetic circuit 72 generates B display data for positive polarity, and generates adjustment data d7 based on the input data and the second adjustment table 71 provided for G. The adjustment data d7 and R Based on the second γ correction data d3 related to the above, the arithmetic circuit 72 generates B display data for negative polarity.

  As described above, according to the present embodiment, the circuit scale can be reduced because there is no table entry for the positive electrode and the negative electrode. Further, when it is necessary to support a plurality of γ curves, if there is one table having all entry data, the remainder can be calculated using an adjustment table, and the circuit configuration can be simplified. Further, since the total number of bits in each table (γ conversion table / adjustment table) is small, power consumption can be reduced. Furthermore, since the values of all the positive and negative entries can be set by a combination of the full entry table (γ conversion table) and the adjustment table, the set values are not limited and the degree of freedom is high.

  The present invention is not limited to the above-described embodiment, and various modifications are possible within the scope shown in the claims, and the embodiment can be obtained by appropriately combining technical means disclosed in the embodiment. Is also included in the technical scope of the present invention.

  The γ correction circuit according to the present invention (and a drive circuit for a display device equipped with the γ correction circuit) can be widely applied to display devices for mobile devices, display devices such as TVs and monitors.

It is a block diagram which shows the structure of the drive circuit of the display apparatus which concerns on the basic form of this invention . It is a block diagram which shows the structure of the drive circuit of the display apparatus which concerns on embodiment of this invention . It is a block diagram which shows the structure of the drive circuit of the display apparatus which concerns on a reference form. It is a block diagram which shows the structure of the drive circuit of the display apparatus which concerns on another reference form. It is a schematic diagram which shows the structure of the data for adjustment. It is a graph which shows the input data (Video data) -output voltage characteristic in a liquid crystal display device. It is a block diagram which shows the structure of the drive circuit of the conventional display apparatus.

1 Driver Circuit 3 γ Correction Circuit 15 55 66 γ Conversion Table 52 62 72 Arithmetic Circuit 46 48 to 51 Adjustment Table 56 58 to 61 Adjustment Table 66 68 to 71 Adjustment Table

Claims (5)

This is a drive circuit for a display device that generates first display data corresponding to the first polarity and second display data corresponding to the second polarity for input data of each gradation and uses them to drive the display device AC. And
A γ conversion table for generating first γ correction data obtained by performing γ correction on the input data;
An adjustment table for generating adjustment data from input data;
An arithmetic circuit that generates second γ correction data based on the first γ correction data and the adjustment data,
In order to be able to cope with the γ characteristics of a plurality of first to nth (n is an integer of 2 or more) liquid crystal panels and to generate the first and second display data for each γ characteristic, γ conversion is used as the first γ characteristic. A first adjustment table for the first polarity and a second adjustment table for the second polarity are provided for the table and one adjustment table for each γ characteristic after the second γ characteristic,
For the first γ characteristic, the first γ correction data obtained based on the input data and the γ conversion table is used as the first display data, and adjustment data is generated based on the input data and the adjustment table. The second γ correction data obtained based on the data and the first γ correction data is used as the second display data.
For each γ characteristic after the second γ characteristic, adjustment data is generated based on the input data and the first adjustment table provided for the γ characteristic, and the adjustment data and the first γ characteristic are related to the first γ characteristic. The first display data is generated based on the γ correction data of 1, and the adjustment data is generated based on the input data to the corresponding γ characteristic and the second adjustment table provided for the γ characteristic. A drive circuit for a display device, characterized in that second display data is generated based on the adjustment data and the second γ correction data relating to the first γ characteristic .   The display device driving circuit according to claim 1, wherein the number of bits of the adjustment data is smaller than the number of bits of the first display data.   The display potentials corresponding to the first and second display data are respectively referred to as first and second display potentials, and the adjustment data includes the potential difference between the first display potential and the reference potential, and the second display potential. The display device drive circuit according to claim 1, wherein the drive circuit corresponds to a difference between a potential and a potential difference between the reference potential and the potential difference.   The display device drive circuit according to claim 1, wherein a sign bit for identifying whether to input to the adjustment table is added to the input data. Display apparatus comprising the driving circuit of a display device according to any one of claims 1-4.

Images