KR20180059158A - Device and Method For Processing Compensation Data And Organic Light Emitting Diode Display Device Using The Same - Google Patents

Abstract

The present invention relates to a device to process compensation data and a method thereof, and an organic light emitting diode (OLED) display device using the same. In a data compression unit of a conventional compensation data processing device, when compression is performed by using a quantization method, an identical quantization parameter is used for all bitstreams and a compression rate may be different for each bitstream, thus causing a problem that all target bit sizes required by a system are not satisfied. To solve such problem, a plurality of bitstreams are generated by using different quantization parameters based on identical compensation data and a bitstream satisfying a target bit size is selected from the plurality of bitstreams, thereby being able to compress the compensation data by using the optimal quantization parameter.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compensation data processing apparatus and method, and an organic light emitting diode display device using the compensation data processing apparatus and method.

The present invention relates to an apparatus and method for compensating data and an organic light emitting diode display using the same.

[0004] 2. Description of the Related Art [0005] As the information society develops, the demand for display devices for displaying images has increased in various forms. Among them, the organic light emitting diode display device has advantages of high response speed, high luminous efficiency, high luminance and wide viewing angle by using a self-luminous element which emits light by itself. In such an organic light emitting diode display device, a current driving method for controlling the amount of current and controlling the luminance of the organic light emitting diode is generally used.

<3> However, the current flowing in the organic light emitting diode (EL) will receive a significant impact on the threshold voltage of the driving thin film transistor. The threshold voltage of such a driving thin film transistor varies depending on the application of a continuous gate bias stress for a long time, which causes a characteristic deviation between the pixels PX, which in turn deteriorates the display quality of an image .

In order to solve such a display quality degradation problem, compensation data for compensating the threshold voltage of the driving thin film transistor is used. However, as the number of pixels of the display panel increases, the size of the compensation data also increases, and a large-capacity memory capable of storing the data needs to be provided, thereby increasing manufacturing costs. To solve this problem, a technique of compressing and storing compensation data is used.

<5> Figure 1 is a block diagram showing parts of the data compression of the compensation data processing apparatus according to an exemplary conventional example. FIG. 2 and FIG. 3 are views for explaining the operation of the data compression unit of FIG.

Bitstream satisfying; (TCR Target Compression Ratio) ( <6> to classify the data compression unit data attribute (data context) of the compensation data of the conventional compensation data processing device, and removing a properties section insensitive to the loss of the target compression ratio bit stream.

<7> 1, a data compression unit predictor 10, the encoder 15, the property extractor 18, and the controller 19 of the compensation data processing apparatus.

The predictor 10 calculates a prediction value of the input compensation data and outputs prediction errors between the calculated prediction value and the compensation data. The encoder 15 outputs a preliminary bit stream through an encoding process for compressing the received prediction error. The property extractor 18 classifies the data context of the compensation data and transmits it to the controller 19. The controller 19 truncates data portions having loss-insensitive characteristics until the spare bitstream reaches a target bit size based on the data characteristics. Accordingly, the data compression unit can adjust the size of the bitstream.

<9> In detail, 2, the controller 19 compares the target bit size to the spare bit stream (preliminary bit stream). If the spare bitstream is larger than the target bit size, the controller 19 first analyzes the data context to reduce the overflow bits.

<10> Then, the controller 19 has the same characteristic data; to form a group having a (cx context data of the drawing sheet) (e.g., cx1, cx2, cx3), to calculate the size of each group of. For example, the spare bitstream of FIG. 2 includes a first group comprising three unit bits having a first characteristic (cx1), a second group comprising eight unit bits having a second characteristic (cx2) , And a third characteristic (cx3).

<11> Then, the controller 19 selects a group to be removed (truncation) to meet the target bit-size of the first to third groups. For example, since there are three unit bits overflowed in FIG. 2, the controller 19 can remove the first group having the first characteristic (cx1). A codeword for use in restoring the subsequent data can be inserted in the removed place.

If <12> 3, the graph of Figure 3 shows the frequency characteristic of the compensation data. The compensation data includes a loss-insensitive low-frequency region (A) and a loss-sensitive high-frequency region (B). That is, when a loss occurs in the high-frequency region (B), the display quality of the image output to the display device may be lowered. Therefore, the controller 19 first removes the group having the characteristic corresponding to the low-frequency region A.

<13> However, if also fails to achieve the target bit size to remove all of the groups that correspond to the low frequency region (A), because the controller 19 must also remove the group that corresponds to the high frequency region (B), the compensation data There is a disadvantage that a loss occurs and the display quality of an image is lowered.

<14> is, the method of quantizing and encoding the compensated data can be used to solve this problem. However, in this case, there is a problem that it is difficult to uniformly apply the same quantization parameter to all bitstreams because the compression ratios are different for each bitstream.

The present invention provides a compensation data processing apparatus and method capable of processing compensation data without degrading the display quality by efficiently compressing and storing the compensation data of the organic light emitting diode display device, and an organic light emitting diode display device using the same The purpose is to provide.

In addition, the present invention compresses and stores compensation data of an organic light emitting diode display device using optimized quantization parameters, thereby reducing the capacity of a memory used in a display device, And an organic light emitting diode display device using the same.

It is to be understood that the objects of the present invention are not limited to the above-mentioned objects and other objects and advantages of the present invention which are not mentioned can be understood by the following description, Will be. Also, the objects and advantages of the invention will be readily appreciated that this can be realized by the means as claimed and combinations thereof.

<18> on by analyzing the data compression unit data characteristic of the compensation data of the conventional compensation data processing apparatus, in preference to the compensation data of the sensitive high-frequency region at a loss to remove the compensation data of the insensitive low frequency region to the loss, the target bit size Thereby forming an appropriate bitstream. However, there is a problem in that if the compression is not sufficiently performed by this method, the display quality of the image is lowered.

In addition, when compression is performed using a quantization method, if the same quantization parameter is used for all bitstreams, the compression rate may be different for each bitstream, and thus the target bit size required by the system can not be satisfied .

To <20> to solve the problem, the compensation data processing device according to the present invention is based on the same compensation data with each other to generate a plurality of bit stream using different quantization parameters, and the target bit size from among a plurality of bitstreams By selecting the bitstream to be satisfied, the compensation data can be compressed without loss using the optimal quantization parameter.

<21> In addition, the reward data compression unit compensation data from the data processing apparatus 1, the prediction error for a first data compression unit, and the compensation for the quantization using the quantization parameter, and outputs a first bitstream by encoding them And a second data compression unit for quantizing the second prediction error of the data using the second quantization parameter different from the first quantization parameter and outputting the second bitstream obtained by encoding the second prediction error.

According to another aspect of the present invention, there is provided an OLED display device including a display panel, a data driver for generating compensation data, and a compensation data processor for compressing and storing the compensation data, A first data compression unit for generating a first bitstream for the compensation data using a first quantization parameter and a second bitstream for the compensation data using a second quantization parameter different from the first quantization parameter A control unit for comparing a size of the first and second bit streams with a previously stored target bit size and selecting a bit stream closest to the target bit size; And a frame memory.

According to another aspect of the present invention, there is provided a compensation data processing method comprising the steps of: quantizing a first prediction error of compensation data using a first quantization parameter, outputting a first bitstream obtained by encoding the first prediction error, Quantizes the first bitstream and the second bitstream using a second quantization parameter different from the first quantization parameter, outputs a second bitstream obtained by encoding the second bitstream, compares a size of the first bitstream and the second bitstream with a previously stored target bit size And selecting a bitstream closest to the target bit size from among the first bitstream and the second bitstream.

<24> through this end, the invention of a plurality of bit streams each compressed to a different quantization parameter, by selecting a bit-stream to meet the target bit-size, it is possible to optimize the size of the compensation data.

According to the present invention, it is possible to improve the compression efficiency by selecting a bit stream satisfying the target bit size from a plurality of bit streams compressed based on different quantization parameters for the same compensation data. In addition, the size of the compensation data can be optimized by the above method, and the compensation data can be processed without reducing the display quality.

<26> Further, the present invention can reduce the capacity of a frame memory for storing the compensation data in accordance with the improvement in the compression ratio, it is possible to reduce the cost of having a large memory, the frame memory to reduce the power consumption also used in have.

<27> Figure 1 is a block diagram showing parts of the data compression of the compensation data processing apparatus according to an exemplary conventional example.
<28> 2 and 3 are views for explaining the operation of the data compression section 1.
<29> Figure 4 is an equivalent circuit diagram for a pixel of a general organic light emitting diode display device.
<30> Figure 5 is a diagram showing an OLED display according to an embodiment of the present invention.
<31> Figure 6 is a block diagram for explaining the compensation data processor of Fig.
<32> Figure 7 is a block diagram for explaining a data compression in FIG.
<33> Figure 8 is a block diagram for explaining the first and second data compressing unit included in the data compressor of FIG.
<34> Figure 9 is a block diagram illustrating the components included in the first and second data compression unit of Fig.
<35> Figure 10 is a block diagram for explaining the operation of the compensation data processor of Fig.
<36> Figure 11 is a block diagram for explaining the data compression units included in the compression unit of the compensation data processor according to another embodiment of the present invention.
<37> Figure 12 is a block diagram for explaining the operation of the compensation data processor of Fig.
<38> Figure 13 is a flowchart for explaining the compensation data processing method in accordance with some embodiments of the invention.

The above and other objects, features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. . In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to denote the same or similar elements.

<40> or less, will be described in detail with reference to the drawings compensation data processing apparatus and method, and an organic light emitting diode display using the same according to an embodiment of the present invention.

<41> Figure 4 is an equivalent circuit diagram for a pixel of a general organic light emitting diode display device.

If <42> Referring to Figure 4, a pixel (P) comprises a switching transistor (Tsw), a driving transistor (Tdr), organic light emitting diodes (EL) and a capacitor (Cst).

<43> In detail, the switching transistor (Tsw), and applies the data voltage to the first node (N1) in response to the scan signal. The driving transistor Tdr receives the driving voltage VDD and applies a current to the organic light emitting diode EL according to the driving voltage VDD and the voltage applied to the first node N1. The capacitor Cst maintains the voltage applied to the first node N1 for one frame.

<44> will be described a method of driving the organic light emitting diode display device including such a pixel (P).

<45> First, when the scan signal to the gate line (GL) is a switching transistor (Tsw) is turned on (Turn-On), At this time, the data voltage applied to the data line (DL) is a switching transistor (Tsw) And is charged into the capacitor Cst.

<46> If the next scanning signal to the gate line (GL) is no longer applied, the driving transistor (Tdr) by the data voltage charged in the capacitor (Cst) is driven. At this time, a current corresponding to the data voltage flows to the organic light emitting diode EL, thereby displaying an image.

<47> where the current flowing through the organic light emitting diode (EL) is subjected to great impact on the threshold voltage of the driving transistor (Tdr). The threshold voltage of the driving transistor Tdr is varied by application of a constant gate bias stress for a long time. Such a result causes a characteristic deviation between the pixels P, which results in lowering the display quality of the image.

In order to solve such a display quality degradation problem, a current flowing through the driving transistor Tdr of each pixel P is sinked to sense the characteristics of the driving transistor Tdr. Then, the compensated data is calculated by using the sensed characteristic in an external compensation algorithm. Then, the calculated compensation data is reflected on data inputted from the outside and supplied to each pixel P.

<49> On the other hand, such a compensation data that is stored in the memory before it is reflected on the data inputted from the outside is supplied with the data.

In this case, since the compensation data has a size of 10 bits per one pixel (P), when the organic light emitting diode display device of UHD (Ultra High-Definition) resolution is used as a reference, 3840 X 2160 X 3 X And has a size of 10 bits.

<51> Accordingly, a large amount of this memory to store the compensation data of the same size should be provided to the organic light emitting diode display device. However, with such a large-capacity memory, manufacturing costs increase. In general, the compensation data is compressed and stored in a memory, and then restored and supplied to each pixel P, thereby reducing the cost of a large-capacity memory.

<52> Figure 5 is a diagram showing an OLED display according to the embodiment of the present invention.

<53> 5, the OLED display according to the embodiment of the present invention includes a display panel 100, a gate driver 110, data driver 120, the compensation data processing unit 140 and timing controller (150).

<54> In detail, the display panel 100 includes a plurality of which is arranged at each intersection of the plurality of gate lines (GL) and data lines (DL) and a respective gate line (GL) and data lines (DL) cross each other And pixels P. 3, the plurality of pixels P include a switching transistor Tsw, a driving transistor Tsw, an organic light emitting diode EL, and a capacitor Cst.

The gate driver 110 sequentially supplies a scan signal Scan to each gate line GL. The gate driver 110 sequentially outputs an output of a shift register and a shift register that sequentially shifts and outputs a gate start pulse supplied from the timing controller 150 according to a gate shift clock, ), A level shifter for converting into a swing width suitable for driving the thin film transistor, and an output buffer.

The data driver 120 supplies a data voltage Vdata to the plurality of data lines DL and senses a sink current flowing through the data line DL to generate compensation data corresponding to the sink current do. In order to generate such compensation data (data), the data driver 120 may include a data compensation circuit (not shown) to which an external compensation algorithm is applied.

The compensation data processing unit 140 quantizes and encodes the compensation data generated by the data driver 120 and stores the compensated data in the memory 140. The compensation data processing unit 140 dequantizes and decodes the compensation data to store the compensated data into the timing controller 150 Supply. The compensation data processing unit 140 may be incorporated in the organic light emitting diode display device separately from the timing control unit 150.

The timing controller 150 reflects the compensated data 'data' restored to externally input image data RGB and aligns the compensated data 'data' according to the size and resolution of the display panel 100, .

The timing controller 150 generates a plurality of gate control signals GCS and a plurality of data control signals DCS using externally input sync signals and supplies them to the gate driver 110 and the data driver 120. [ (120).

<60> where the compensation data processing unit 140 is the predicted value of the compensation data (data) of the threshold voltage (prediction value), a prediction error (prediction Errors) of an organic light emitting display device according to an embodiment of the present invention . Then, the compensation data processing unit 140 performs encoding using different quantization parameters. The components and operation of the compensation data processing unit 140 will be described later in detail.

<61> In this case, the value of the compensation data (data) is most converging one, in some pixels might contain specific value if the processing of all bit streams with the same quantization parameter, be compression rate is different for each bit stream within a certain range, . As a result, a loss occurs in the compensation data (data), so that the value of the data before and after compression may vary.

<62> Thus, in the embodiment of the present invention, converts the same compensation data (data) of a plurality of bit stream using different quantization paramiteoeul, selects the optimal bit stream that meets the target bit size from among a plurality of bitstreams . Thus, optimum efficiency can be obtained in the compression step, and the capacity of the memory required to store the compensation data (data) can be reduced.

<63> In the following will be described for the specific component of the compensation data processing unit 140.

<64> Figure 6 is a block diagram for explaining the compensation data processor of Fig.

If <65> Referring to Figure 6, the compensation data processing unit 140 of the invention includes a data compressor 210, a control unit 220, frame memory 230, a data decompression unit 240.

The data compression unit 210 receives compensation data (data) from the data driver 120. The data compression unit 210 generates a plurality of bit stream sets obtained by compressing the received compensation data by quantizing and encoding based on a plurality of quantization parameters.

The control unit 220 receives a plurality of bit stream sets from the data compression unit 210. The control unit 220 selects a bit stream that is closest to the target bit size among a plurality of bit stream sets.

The frame memory 230 stores a bit stream selected by the controller 220.

The data decompression unit 240 decompresses the bit stream read from the frame memory 230 through a dequantization and decoding process to generate compensation data (data?). The data decompression unit 240 performs inverse quantization using the quantization parameters used in the bitstream selected by the data compression unit 210. [ The data decompression unit 240 generates the compensation data (data?) By advancing the processes of the data compression unit 210 in the reverse order.

The decompressed compensation data (data?) Is transmitted to the timing controller 150. Since the timing controller 150 has been described above, a duplicate description will be omitted.

<71> Figure 7 is a block diagram for explaining a data compression in FIG.

If <72> Referring to Figure 7, the data compression unit 210 of the present invention includes a plurality of data compression units (210_1 - 210_9). For example, the data compression unit 210 may include nine data compression units 210_1 to 210_9. However, the present invention is not limited thereto, and the number of data compression units 210_1 to 210_9 can be arbitrarily adjusted. Hereinafter, it is assumed that the data compression unit 210 includes nine data compression units 210_1 to 210_9 for convenience of explanation.

<73> and each data compression unit 210 comprises substantially the same components and method of operation as each other. Further, the plurality of data compression units 210_1 to 210_9 receive the same input data (for example, compensation data (data)). However, each of the data compression units 210_1 to 210_9 generates respective bit streams using different quantization parameters. For example, nine data compression units 210_1 to 210_9 output nine different bit streams (bit streams 1 to 9) based on the same compensation data (data).

A plurality of output bit streams (bit streams 1 to 9) are transmitted to the controller 220. The controller 220 selects a bit stream (bit stream_f) that satisfies the target bit size among the plurality of bit streams (bits stream 1 to 9). That is, the controller 220 selects a bitstream whose size is closest to the target bit size. The selected bit stream (bit stream_f) may be stored in the frame memory 230.

<75> Figure 8 is a block diagram for explaining the first and second data compressing unit included in the data compressor of FIG. FIG. 9 is a block diagram for explaining components included in the first and second data compression units of FIG. 8; FIG.

<76> 8 and 9, the first data compression unit (210_1) has a first predictor (12) (predictor), the first prediction error controller (14) (prediction error controller), a first encoder (16 (encoder). The first prediction error controller 14 includes a first quantizer 14a and a first reconstructor 14b.

<77> a first predictor 12 calculates a prediction for the current pixel value based on the compensation data (data) prediction value (prediction value). The predicted value can be calculated as the result of the operation of the adjacent pixels. The first predictor 12 calculates the current pixel value? Forecast value? To calculate the first prediction errors.

<78> In addition, the time to restore the compensation data (data?) In the subsequent data decompression unit 240? To recover the original signal through the prediction value + prediction error?.

<79> a first quantizer (14a) is, in the first quantized prediction error based on the first quantization parameter calculates a first quantization error (quantized error). Quantization refers to the process of converting an analog level signal to a digital level.

<80> a first reconstructed exchanger (14b), a first feed back (feedback) of the first reconstructed data (reconstructed data) generated based on the quantization errors in the first predictor (12). Then, the first predictor 12 predicts the next pixel value using the compensation data (data) and the first received reconstructed data, and calculates the next first prediction error based on the predicted next pixel value.

<81> a first encoder (16) produces a first bit stream (bit stream 1) and, encoding the first quantization error received from the first reconstructed group (14b). The encoding is a process of converting a quantized value into a digital value expressed by only '0' and '1'. The generated first bit stream (bit stream 1) is transmitted to the controller 220.

<82> The second data compression unit (210_2) comprises a second predictor (22), the second prediction error controller 24, the second encoder (26). The second prediction error controller 24 includes a second quantizer 24a and a second reconstructor 24b. The second data compression unit 210_2 includes substantially the same components as the first data compression unit 210_1 and operates in substantially the same manner.

<83> In other words, the second predictor 22 calculates a prediction pixel value of the current predicted value based on the compensation data (data), and? The current pixel value? The second prediction error is calculated using the predicted value?. At this time, the second predictor 22 may calculate the next predicted value based on the second reconstructed data fed back from the second reconstructor 24b.

<84> However, the second quantizing unit (24a) generates the second quantization error by quantizing the second prediction error based on the first quantization parameter and a second, different quantization parameter unlike the first quantizer (14a) . Therefore, the first quantization error of the second quantization error may be different from each other.

<85> Then, the second reconstruction group (24b), the second feedback for the second reconstruction data generated based on the quantization error to the second predictor (22), the second encoder 26, a second reconstruction group And generates a second bit stream (bit stream 2) by encoding the second quantization error received from the first quantization error decoder 24b. At this time, the second bit stream 2 may be different from the first bit stream 1.

<86> the third to ninth data compression units (210_3 - 210_9) of Fig. 7 and although not shown clearly all of the plurality of data compression unit to in Figure 8, omitted from the drawings is substantially in a first data compression unit (210_1), and They may include the same structure and operate in the same manner. Accordingly, the third to ninth data compression units 210_3 to 210_9 may generate the third to ninth bit streams 3 to 9, respectively, and may transmit them to the control unit 220.

<87> Figure 10 is a block diagram for explaining the operation of the compensation data processor of Fig.

If <88> Referring to Figure 10, controller 220 may calculate the size of each of the received first to ninth bit stream (bit stream 1 ~ 9). The control unit 220 selects a bit stream satisfying a pre-stored target bit size based on the sizes of the calculated bit streams 1 to 9. That is, the controller 220 can select a bit stream whose bitstream size is closest to the target bit size. The selected bitstream (bitstream_f) can satisfy the compression rate required by the system.

<89> As a result, the data compression unit 210 of the present invention can be compressed to a bit stream through a series of processes of the predicted value calculation, quantization and encoding. In this process, the data compression unit 210 may generate a bitstream using an optimal quantization parameter that satisfies a target bit size of the system.

<90> In other words, the data compression unit 210 of the present invention may provide a bit-stream to meet the target bit size required by the system through the process. Accordingly, it is possible to overcome the problem that bitstreams of different sizes are formed due to different compression ratios for each input compensation data, and the bitstream compression efficiency can be improved. In addition, the size of the compensation data stored in the frame memory 230 can be optimized, and a large amount of compensation data can be processed without reducing the display quality of the image.

<91> Figure 11 is a block diagram for explaining the data compression units included in the compression unit of the compensation data processor according to another embodiment of the present invention. 12 is a block diagram for explaining the operation of the compensation data processing unit of FIG. For the sake of convenience of description, the same elements as those of the above-described embodiment will be described below with the exception of duplicate descriptions.

<92> 7 and 11, any of the compression unit of the plurality includes (210) the data compression units (210_1 - 210_9) according to another embodiment of the present invention one does not include the predictive error controller .

<93> In the following, a ninth will be described in the data compression unit (210_9) does not contain a prediction error controller on the assumption. The remaining data compression units (for example, the first to eighth data compression units 210_1 to 210_8) include the same structures as those described with reference to Figs. 8 and 9 and the data compression unit, and can operate in the same manner .

<94> a ninth data compression unit (210_9) may include only a ninth predictor 32 and the ninth encoder 36. The ninth data compression unit 210_9 does not include the quantizers and the reconstructors included in the prediction error controller, and thus does not perform the feedback operation of the quantization and reconstruction data.

<95> a ninth predictor 32 calculates a prediction pixel value of the current predicted value based on the compensation data (data), and? The current pixel value? Forecast value? To calculate the prediction error.

<96> Next, a ninth encoder (36) produces a ninth bit stream (bit stream 9) encodes the prediction error received from the ninth predictor 32. Accordingly, since the size of the ninth bit stream 9 is not quantized, it may be larger than the sizes of the first to eighth bit streams 1 to 8.

<97> a ninth data ninth bit stream generated by the compression unit (210_9) (bit stream 9) is transmitted to the controller 220.

If <98> 12, the control unit 220 may calculate the size of each of the received first to ninth bit stream (bit stream 1 ~ 9). The control unit 220 controls the quantization of the quantized bitstreams (e.g., the first through eighth bitstreams 1 through 8) and the non-quantized bitstreams (e.g., the ninth bitstream 9) Can be considered. The controller 220 selects a bitstream satisfying a pre-stored target bit size based on the sizes of the calculated bitstreams.

The controller 220 can select a bitstream whose bitstream size is closest to the target bit size. The selected bitstream (bitstream_f) can satisfy the compression rate required by the system. Accordingly, the data compression unit 210 can generate a bitstream using an optimal quantization parameter that satisfies a target bit size of the system.

<100> Figure 13 is a flowchart for explaining the compensation data processing method in accordance with some embodiments of the invention.

When <101> Referring to Figure 13, the compensation data processing method in accordance with some embodiments of the present invention, first, creating a plurality of bit streams to each other based on different quantization parameters for the same compensation data (data) (S110).

<102> For example, the first to produce a coded using the quantization parameter first bit stream (stream1 bit), generate a second bit stream compressed using the quantization parameters (bit stream2). A specific method of generating a bitstream using the quantization parameter has been described with reference to FIGS. 8 and 9, and therefore will not be described here.

<103> In this case, any one of a plurality of bit streams may be in a bit stream generated without using a quantization parameter.

<104> Next, calculate the size of the generated multi-bit stream and comparing it to the stored group and the target bit size (S120).

<105> then selects a bit stream that satisfies the pre-stored target bit size of the plurality of bit streams (S130). For example, a bitstream whose size is closest to the target bit size can be selected.

<106> and then stores the selected bitstream to a frame memory (230) (S140). The selected bitstream can satisfy the compression rate required by the system.

<107> As a result, the compensation data process of the present invention method, it is possible to use the optimal quantization parameter satisfying a target bit size of the system generates a bit stream of the size required by the system.

<108> Thereby, the compression rate is different for the compensation data to be input, and can overcome the problem that the bit stream of different sizes to form, it is possible to improve the compression efficiency of the bit stream. Further, the size of the compensation data stored in the frame memory can be optimized, and there is an advantage that a large amount of compensation data can be processed without reducing the display quality of the image.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And are not limited by the accompanying drawings.

100: display panel 110: gate driver
120: Data driver 140: Compensation data processor
150: timing control unit 210: data compression unit
220: control unit 230: frame memory
240: Data decompression unit

Claims (16)

A first data compression unit for quantizing first prediction errors of the compensation data using a first quantization parameter and outputting a first bit stream obtained by encoding the first prediction errors, A second data compression unit for quantizing the second prediction error of the second quantization parameter using a second quantization parameter different from the first quantization parameter and outputting a second bitstream obtained by encoding the second prediction error; And
And a controller for comparing a size of the first and second bit streams with a previously stored target bit size to select a bit stream closest to the target bit size,
Compensation data processing unit.
The method according to claim 1,
The first data compression unit
A first predictor for outputting a first prediction error for a prediction value of the compensation data;
A first quantizer for quantizing the first prediction error based on the first quantization parameter and outputting a first quantization error;
A first reconstructor for feedbacking reconstructed data generated based on the first quantization error to the first predictor; And
And a first encoder for encoding the first quantization error to generate the first bitstream
Compensation data processing unit.
3. The method of claim 2,
The first predictor
Calculates the predicted value based on the first reconstructed data and the compensation data fed back, compares the predicted value with the compensation data, and calculates the first prediction error
Compensation data processing unit.
3. The method of claim 2,
The second data compression unit
A second predictor for outputting a second prediction error for a predicted value of the compensation data;
A second quantizer for quantizing the second prediction error based on the second quantization parameter and outputting a second quantization error;
A second reconstructor for feeding back the second reconstructed data generated based on the second quantization error to the second predictor; And
And a second encoder for encoding the second quantization error to generate the second bitstream
Compensation data processing unit.
The method according to claim 1,
A third predictor for outputting a third prediction error for a predicted value of the compensation data; And
And a third encoder for encoding the third prediction error and outputting a third bit stream,
Compensation data processing unit.
6. The method of claim 5,
The control unit
Compares the size of the third bitstream with the target bit size, and selects a bitstream closest to the target bit size among the first to third bitstreams
Compensation data processing unit.
6. The method of claim 5,
A frame memory for storing the bit stream selected by the controller; And
And a data decompression unit for decoding the pre-compression compensation data based on the bit stream
Compensation data processing unit.
A display panel in which data lines and gate lines cross each other;
A data driver for converting input image data to a data voltage, outputting the data to the data lines, and generating compensation data for the data voltage;
A gate driver sequentially outputting a gate pulse synchronized with the data voltage to the gate lines; And
And a compensation data processor for compressing and storing the compensation data,
Wherein the compensation data processor comprises:
A first data compression unit for generating a first bit stream for the compensation data using a first quantization parameter;
A second data compression unit for generating a second bitstream for the compensation data using a second quantization parameter different from the first quantization parameter;
A controller for comparing a size of the first and second bit streams with a previously stored target bit size and selecting a bit stream closest to the target bit size; And
And a frame memory for storing the selected bit stream
Organic light emitting diode display.
9. The method of claim 8,
The first data compression unit;
A first predictor for outputting a first prediction error for a predicted value of the compensation data;
A first quantizer for quantizing the first prediction error based on the first quantization parameter and outputting a first quantization error;
A first reconstructor for feeding back the first reconstructed data generated based on the first quantization error to the first predictor; And
And a first encoder for encoding the first quantization error to generate the first bitstream
Organic light emitting diode display.
10. The method of claim 9,
The first predictor
Calculates the predicted value based on the first reconstructed data and the compensation data fed back, compares the predicted value with the compensation data, and calculates the first prediction error
Organic light emitting diode display.
9. The method of claim 8,
Wherein the compensation data processor comprises: a third predictor for outputting a third prediction error for a prediction value of the compensation data; And
And a third encoder for encoding the third prediction error and outputting a third bitstream,
The control unit selects a bitstream that is closest to the previously stored target bit size among the first to third bitstreams
Organic light emitting diode display.
Quantizing the first prediction error of the compensation data using the first quantization parameter, and outputting a first bitstream obtained by encoding the first prediction error;
Quantizing the second prediction error of the compensation data using a second quantization parameter different from the first quantization parameter, and outputting a second bitstream obtained by encoding the second prediction error;
Comparing a size of the first bitstream and the second bitstream with a previously stored target bit size; And
Selecting a bitstream closest to the target bit size from among the first bitstream and the second bitstream
A method for processing compensation data.
13. The method of claim 12,
The step of outputting the first bitstream
Outputting a first prediction error for a predicted value of the compensation data;
Quantizing the first prediction error based on the first quantization parameter and outputting a first quantization error;
Feedbacking the reconstructed data generated based on the first quantization error to outputting the first prediction error; And
And generating the first bitstream by encoding the first quantization error
A method for processing compensation data.
14. The method of claim 13,
The step of outputting the first prediction error for the predicted value of the compensation data
Calculating the predicted value based on the first reconstructed data and the compensation data fed back,
And calculating the first prediction error by comparing the predicted value with the compensation data
A method for processing compensation data.
14. The method of claim 13,
The step of outputting the second bitstream
Outputting a second prediction error for a predicted value of the compensation data;
Quantizing the second prediction error based on the second quantization parameter and outputting a second quantization error;
Feedbacking the second reconstruction data generated based on the second quantization error to the step of outputting the second prediction error; And
And generating the second bitstream by encoding the second quantization error
A method for processing compensation data.
13. The method of claim 12,
Outputting a third prediction error for a predicted value of the compensation data, encoding the third prediction error, and outputting a third bitstream; And
And comparing the size of the third bitstream with the target bit size,
Wherein the step of selecting a bitstream closest to the target bit size comprises selecting a bitstream closest to a previously stored target bit size among the first through third bitstreams
A method for processing compensation data.

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