KR20130107559A - Display system and driving method thereof - Google Patents

Abstract

PURPOSE: A display system and a driving method thereof improve a slew rate of an output signal of a source driving circuit by generating gamma voltages for R, G, and B image data, respectively. CONSTITUTION: Multiple gamma voltage generators (310) generate gamma voltages for R image data, G image data, and B image data, respectively. Multiple source voltage generators (320) generate source voltages corresponding to data values of image data by receiving the gamma voltages. A switching unit (330) outputs the source voltages to a display panel to match the source voltages with the R image data, the G image data, and the B image data outputted through odd lines and even lines of the display panel.

Description

Display system and its driving method {DISPLAY SYSTEM AND DRIVING METHOD THEREOF}

The present invention relates to the field of displays, and more particularly to a display system and a method of driving the same.

In general, a thin film transistor (hereinafter referred to as TFT) liquid crystal display (hereinafter referred to as "LCD") or an organic light emitting diode (hereinafter referred to as "OLED") display The device is driven by a source drive circuit and a gate drive circuit. The TFT-LCD or OLED display outputs image data in units of lines according to the operation of the source driving circuit and the gate driving circuit.

 In order to output image data to a TFT-LCD or OLED display device, an output signal (eg, a source voltage) of a source driving circuit must be raised to a target level within a unit line output time. However, as the display devices become larger in area, the number of lines in the panel increases, thereby reducing the unit line output time. Therefore, it is an important problem to improve the slew rate of the output signal of the source driving circuit.

SUMMARY OF THE INVENTION An object of the present invention is to provide a display system having an improved slew rate of an output signal and a driving method thereof.

According to an embodiment of the present invention, a display system includes a plurality of gamma voltage generators that generate gamma voltages for R image data, G image data, and B image data, and receives the gamma voltage to receive data values of the image data. A plurality of source voltage generators respectively generating a source voltage corresponding to the display panel; a display panel receiving the source voltage and outputting the R image data, the G image data, and the B image data; And a switching unit configured to output the source voltage to the display panel so as to match the R image data, G image data, and B image data output through a line and an even line.

In a method of driving a display driving circuit according to an embodiment of the present invention, a gamma voltage generation step of generating gamma voltages for R image data, G image data, and B image data, respectively, and using the gamma voltage, the R image data Generating a source voltage corresponding to data values of the G image data and the B image data, and the R image data output through an odd line and an even line of the display panel; And outputting the source voltage to the display panel so as to match G image data and B image data.

According to embodiments of the present invention, it is possible to improve the slew rate of the output signal of the display system. In addition, it is possible to provide a display system applicable to both a MUX type and a NO-MUX type display panel.

1 is a block diagram illustrating a display device according to an exemplary embodiment of the present invention.
2 shows a display system according to an embodiment of the present invention.
3 illustrates a display system including a MUX type display panel according to an embodiment of the present invention in more detail.
4 is a timing diagram illustrating signals of a display system including a mux type display panel according to an exemplary embodiment of the present invention.
5 and 6 show a display system including a mux type display panel according to another embodiment of the present invention.
7 illustrates a display system including a no-mux type display panel according to an embodiment of the present invention.
8 is a timing diagram for explaining signals of a display system including a no-mux type display panel according to an exemplary embodiment of the present invention.
9 shows a display system including a no-mux type display panel according to another embodiment of the present invention.
10 illustrates a display system including an RGB stripe display panel according to an embodiment of the present invention.
11 is a flowchart illustrating a method of driving a display system according to an exemplary embodiment of the present invention.

It is to be understood that the specific structural or functional descriptions of embodiments of the present invention disclosed herein are only for the purpose of illustrating embodiments of the inventive concept, But may be embodied in many different forms and is not limited to the embodiments set forth herein.

Embodiments in accordance with the concepts of the present invention are capable of various modifications and may take various forms, so that the embodiments are illustrated in the drawings and described in detail herein. It should be understood, however, that it is not intended to limit the embodiments according to the concepts of the present invention to the particular forms disclosed, but includes all modifications, equivalents, or alternatives falling within the spirit and scope of the invention.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are intended to distinguish one element from another, for example, without departing from the scope of the invention in accordance with the concepts of the present invention, the first element may be termed the second element, The second component may also be referred to as a first component.

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may be present in between. Should be. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between. Other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, the terms "comprises" or "having", etc. are intended to specify the presence of stated features, integers, steps, operations, elements, parts or combinations thereof, , Steps, operations, components, parts, or combinations thereof, as a matter of principle.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

One embodiment of the present invention relates to a display system and a driving method thereof. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. do. Throughout the specification, R means Red, B is Blue, G means Green. Although a display system including an OLED panel is described herein as an example, embodiments of the present invention are applicable to a display system including various display panels such as an LCD panel.

1 schematically illustrates a display device according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a display device 1000 according to an exemplary embodiment of the present invention may include a DC / DC converter 100, a controller 200, a source driving circuit 300, a gate driving circuit 400, and an OLED panel ( 500). The OLED panel 500 may have a pentile structure, for example. That is, the OLED panel 500 may be composed of odd lines in which pixels are arranged in the order of R, G1, B, and G2, and even lines arranged in the order of B, G2, R, and G1. G1 and G2 image data may refer to G image data. Meanwhile, the OLED panel 500 may have, for example, an RGB stripe structure. Hereinafter, the case where the OLED panel 500 has a pentile structure will be described first.

The DC / DC converter 100 converts a DC voltage supplied from a power source (not shown) into a high voltage that is efficient for driving the OLED panel 500. The DC / DC converter 100 may generate a high voltage signal by adjusting the duty ratio of the pulse width modulated signal PWM, for example. The DC / DC converter 100 supplies the converted high voltage to the controller 200 and the source driving circuit 300.

The controller 200 generates a plurality of control signals for controlling the source driving circuit 300 and the gate driving circuit 400. In detail, the controller 200 supplies a source control signal SDC to the source driving circuit 300. The source driving circuit 300 may operate in response to the source control signal SDC input from the controller 200. In addition, the controller 200 supplies a gate control signal GDC to the gate driving circuit 400. The gate driving circuit 400 may operate in response to the gate control signal GDC.

The controller 200 supplies the odd switch control signal ODD_EN and the even switch control signal EVEN_EN to the source driving circuit 300. In addition, the controller 200 supplies the first source output control signal CLA and the second source output control signal CLB to the source driving circuit 300. The first source output control signal CLA and the second source output control signal CLB will be described later.

The controller 200 transmits the image data to the source driving circuit 300. Although not shown, the controller 200 receives image data from an external device (eg, a graphic controller). The image data may include, for example, R image data, G image data, and B image data. The G image data may include G1 and G2 image data. The image data may have a digital data value of k bits (k is a natural number).

The source driving circuit 300 receives the R image data, the B image data, and the G image data from the controller 200. The source driving circuit 300 generates gamma voltages for R, G, and B image data, respectively. The source driving circuit 300 generates the source voltage corresponding to the data value of the image data for each image data by using the R, G, and B image data and the gamma voltage corresponding thereto. The generated source voltages will be fed to the OLED panel 500 respectively.

In other words, the source driving circuit 300 of the display apparatus 1000 according to an exemplary embodiment may generate a gamma voltage for each of R, G, and B image data, thereby eliminating or shortening the gamma voltage setting change time. The gamma voltage setting change time may mean a time required to generate a new gamma voltage according to the change of the image data. As a result, the elimination or shortening of the gamma voltage setting change time may lead to an improvement in the slew rate of the output signal (eg, the source voltage) of the source driving circuit 300.

On the other hand, the source driving circuit 300 controls the output of the source voltage so that the generated source voltage matches the image data output through the odd line and even line of the OLED panel 500. This may be performed based on the odd switch control signal ODD_EN and the even switch control signal EVEN_EN supplied from the controller 200.

The gate driving circuit 400 sequentially supplies a pulse signal to a gate line (not shown) in response to the gate control signal GDC.

The OLED panel 500 outputs image data in response to operations of the source driving circuit 300 and the gate driving circuit 400. In detail, the OLED panel 500 is connected to the source driving circuit 300 through a plurality of channels. Here, the channel may mean a voltage supply passage connecting the source driving circuit 300 and the OLED panel 500. That is, the OLED panel 500 may sequentially output an output signal (eg, a source voltage) supplied from the source driving circuit 300 through an odd line and an even line.

The OLED panel 500 may be a MUX type or a NO-MUX type. The MUX type may refer to a panel in which a plurality of channels are time-divided and driven within a unit line output time. Here, the unit line output time may mean a time required for outputting image data through one line of the OLED panel 500. The no-mux type may refer to a panel in which each channel is independently driven within a unit line output time.

As described above, the source driving circuit 300 of the display device according to the exemplary embodiment generates gamma voltages for R, G, and B image data, respectively. Therefore, the slew rate of the output signal (eg, source voltage) of the source driving circuit 300 can be improved. In particular, when the source driving circuit 300 of the display device according to the exemplary embodiment drives the mux type OLED panel 500, the slew rate of the output signal (eg, source voltage) may be further improved.

2 schematically illustrates a display system according to an embodiment of the present invention. The source driving circuit 300 is connected to the OLED panel 500 through a plurality of channels (first to nth channels).

2, a display system according to an exemplary embodiment of the present invention includes a plurality of gamma voltage generators 310, a plurality of source voltage generators 320, a switching unit 330, and an OLED panel 500. do.

The plurality of gamma voltage generators 310 generates gamma voltages for each of R, G1, B, and G2 image data. The number of the gamma voltage generators 310 may vary depending on the number of pixels of the OLED panel 500, etc. The case where three gamma voltage generators 310 are three is described as an example to avoid repetition of the description. The plurality of gamma voltage generators 310 may include, for example, a first gamma voltage generator 311, a second gamma voltage generator 312, and a third gamma voltage generator 313. The first gamma voltage generator 311 generates a first gamma voltage with respect to the R image data. The second gamma voltage generator 312 generates a second gamma voltage for the G1 image data. The third gamma voltage generator 313 generates a third gamma voltage for the B image data. In addition, the second gamma voltage generator 312 generates a fourth gamma voltage for the G2 image data. The second gamma voltage and the fourth gamma voltage may be the same. That is, the plurality of gamma voltage generators 310 may generate a gamma voltage for each of the R, G1, B, and G2 image data to eliminate or shorten the gamma voltage setting change time.

The plurality of source voltage generators 320 receives the gamma voltages generated from the plurality of gamma voltage generators 310. The plurality of source voltage generators 320 respectively generate source voltages for input R, G1, B, and G2 image data. The number of the plurality of source voltage generators 320 may also vary according to the number of pixels. The case of four source voltage generators 320 is described as an example to avoid repetition of the description. The plurality of source voltage generators 320 may include, for example, a first source voltage generator 321, a second source voltage generator 322, a third source voltage generator 323, and a fourth source voltage generator. 324 may be included. The first source voltage generator 321 receives the first gamma voltage and generates a first source voltage corresponding to the data value of the R image data. The second source voltage generator 322 receives the second gamma voltage to generate a second source voltage corresponding to the data value of the G1 image data. The third source voltage generator 323 receives the third gamma voltage and generates a third source voltage corresponding to the data value of the B image data. The fourth source voltage generator 324 receives the fourth gamma voltage and generates a fourth source voltage corresponding to the data value of the G2 image data.

The switching unit 330 transfers the first to fourth source voltages received from the plurality of source voltage generators 320 to the OLED panel 500. The switching unit 330 is controlled by the odd switching control signal OEE_EN and the even switch control signal EVEN_EN supplied from the controller 200. In detail, the switching unit 330 may apply the first to fourth source voltages such that the first to fourth source voltages match the image data output through the odd and even lines of the OLED panel 500. To pass). For example, when image data is output to an odd line of the OLED panel 500, the switching unit 330 may convert the first source voltage to the first channel, the second source voltage to the second channel, and the third source voltage. Are transferred to the third channel and fourth source voltage to the fourth channel, respectively. When image data is output to an even line of the OLED panel 500, the switching unit 330 may convert the first source voltage to the third channel, the second source voltage to the fourth channel, and the third source voltage to the first channel. The fourth source voltage is controlled to transfer to the second channel, respectively.

FIG. 3 illustrates in more detail a display system including a MUX type display panel according to an embodiment of the present invention. Since the plurality of gamma voltage generators 310 may be the same as described with reference to FIG. 2, redundant description thereof will be omitted.

Referring to FIG. 3, each of the source voltage generators 321, 322, 323, and 324 described in FIG. 2 includes a decoder and an amplifier, respectively. In detail, the first source voltage generator 321 includes a first decoder 321a and a first amplifier 321b. The first decoder 321a generates a first intermediate voltage corresponding to the data value of the R image data. The first amplifier 321b generates a first source voltage by buffering or amplifying the first intermediate voltage. The second source voltage generator 322 includes a second decoder 322a and a second amplifier 322b. The third source voltage generator 323 includes a third decoder 323a and a third amplifier 323b. The fourth source voltage generator 323 includes a fourth decoder 324a and a fourth amplifier 324b. Operations of the second decoder 322a, the third decoder 323a, and the fourth decoder 324a may be the same as the first decoder 321a. Operations of the second amplifier 322b, the third amplifier 323b, and the fourth amplifier 324b may be the same as the first amplifier 321b. Thus, the second amplifier 322b generates a second source voltage. The third amplifier 323b generates a third source voltage. The fourth amplifier 324b generates a fourth source voltage.

The switching unit 330 includes a plurality of odd switches SW_ODD and a plurality of even switches SW_EVEN. The number of the plurality of odd switches SW_ODD and the plurality of even switches SW_EVEN may vary depending on the number of channels of the OLED panel 500, and four cases are described as an example to avoid repetition of the description. The plurality of odd switches SW_ODD are opened and closed according to the control of the odd switching control signal ODD_EN. In detail, when the plurality of odd switches SW_ODD are closed, image data may be output to the odd line of the OLED panel 500. The plurality of odd switches SW_ODD may be opened when image data is output to an even line of the OLED panel 500. The plurality of even switches SW_EVEN are opened and closed according to the control of the even switching control signal EVEN_EN. When the plurality of even switches SW_EVEN are closed, image data may be output to an even line of the OLED panel 500. The plurality of even switches SW_EVEN may be opened when image data is output to an odd line of the OLED panel 500. That is, the plurality of odd switches SW_ODD and the plurality of even switches SW_EVEN are controlled to be opened and closed opposite to each other.

On the other hand, the source driving circuit 300 according to an embodiment of the present invention may further include a source output selection switch (SW_CLA, SW_CLB). In particular, when the OLED panel 500 is a mux type, the source driving circuit 300 may further include source output selection switches SW_CLA and SW_CLB. The source output selection switches SW_CLA and SW_CLB may be sequentially opened and closed by time division of the unit line output time. This will be described later in detail with reference to FIG. 4.

4 is a timing diagram illustrating signals of a display system including a mux type display panel according to an exemplary embodiment of the present invention.

3 and 4, the voltage S1 of node A is shown. When the first source output control signal CLA becomes logic 'low' at time t2, the source output selection switch SW_CLA is closed. However, this is merely exemplary and may be configured such that the source output selection switch SW_CLA is closed when the first source output control signal CLA becomes logic 'high'. When the source output selection switch SW_CLA is closed, the first source voltage is supplied to the OLED panel 500 through the first channel. Therefore, the voltage S1 level of the node A will rise at time t2. At the same time, the third source voltage is supplied to the OLED panel 500 through the third channel. Thus, the voltage level at node C will rise.

Thereafter, when the source output selection switch SW_CLA is opened, the voltage S1 level of the node A will drop. Meanwhile, in order to prevent generation of a short current, the second source output control signal CLB may have a logic 'at a predetermined time interval with a time point t3 at which the first source output control signal CLA is converted to logic' high '. Is converted to 'low'. When the second source output control signal CLB becomes logic 'low', the source output selection switch SW_CLB is closed. However, this is merely exemplary and may be configured such that the source output selection switch SW_CLB is closed when the second source output control signal CLB becomes logic 'high'. When the source output select switch SW_CLB is closed, the second source voltage is supplied to the OLED panel 500 through the second channel. Therefore, the voltage level of the node B will increase at a time point that passes by a predetermined time interval from the time t3. At the same time, the fourth source voltage is supplied to the OLED panel 500 through the fourth channel. Thus, the voltage level at node D will rise.

On the other hand, when the odd switching control signal ODD_EN becomes logic 'low' at time t2, the plurality of odd switches SW_ODD are closed. However, this is merely exemplary and may be configured such that the plurality of odd switches SW_ODD are closed when the odd switching control signal ODD_EN becomes logic 'high'. When the odd switching control signal ODD_EN becomes logic 'low', image data is output to an odd line of the OLED panel 500.

When the even switching control signal EVEN_EN becomes logic 'low' at time t5, the plurality of even switches SW_EVEN are closed. However, this is merely exemplary and may be configured such that the plurality of even switches SW_EVEN are closed when the even switching control signal EVEN_EN becomes a logic 'high'. When the even switching control signal EVEN_EN becomes logic 'low', image data is output to an even line of the OLED panel 500.

That is, the odd switching control signal ODD_EN maintains the plurality of odd switches SW_ODD in the closed state within the unit line output time. The even switching control signal EVEN_EN maintains the plurality of even switches SW_EVEN in the closed state within the unit line output time. Therefore, the image data may be output through the odd line or even line of the OLED panel 500 within the unit line output time.

5 and 6 show a display system including a mux type display panel according to another embodiment of the present invention. Description of the same configuration is omitted to avoid duplication. In this embodiment, it is assumed that image data is input in units of odd lines and even lines.

First, referring to FIG. 5, the source driving circuit 600 according to the present embodiment includes a plurality of gamma voltage generators 610, a plurality of source voltage generators 620, a switching unit 630, and a first mux. 640, a second mux 660, a plurality of odd switches SW_ODD, and a plurality of even switches SW_EVEN.

The plurality of gamma voltage generators 610 includes gamma voltage generators 611 and 612 for generating gamma voltages for R, G1, B, and G2 image data, respectively.

R and G1 image data are input to the first mux 640. The first mux 640 selects and outputs one of R and G1 image data based on the SEL1 signal. The SEL1 signal is input from the controller 200 to the first mux 640. For example, when the first mux 640 selects and outputs R image data, the gamma voltage generator 611 may output a gamma voltage with respect to the R image data. When the first mux 640 selects and outputs G1 image data, the gamma voltage generator 611 may output a gamma voltage with respect to the G1 image data.

In addition, the B and G2 image data are input to the second mux 660. The second mux 660 selects and outputs one of the B and G2 image data based on the SEL2 signal. The SEL2 signal is input from the controller 200 to the second mux 660. For example, when the second mux 660 selects and outputs B image data, the gamma voltage generator 612 may output a gamma voltage for the B image data. When the second mux 660 selects and outputs G2 image data, the gamma voltage generator 612 may output a gamma voltage for the G2 image data.

The image data output through the first mux 640 and the gamma voltage output from the gamma voltage generator 611 are input to the source voltage generator 621. The image data output through the second mux 660 and the gamma voltage output from the gamma voltage generator 612 are input to the source voltage generator 622. The source voltage generators 621 and 622 will generate a source voltage, respectively.

Source voltages generated from the source voltage generators 621 and 622 are transferred to the OLED panel 500 through the switching unit 630. Specifically, when the odd switch SW_ODD of the switching unit 630 is closed and the even switch SW_EVEN is opened, image data is output through the odd line of the OLED panel 500. On the contrary, when the odd switch SW_ODD of the switching unit 630 is opened and the even switch SW_EVEN is closed, image data is output through the even line of the OLED panel 500. In addition, as described with reference to FIG. 4, while the odd switch SW_ODD is closed, the source output selection switch SW_CLA and the source output selection switch SW_CLB are alternately closed. Therefore, R, G1, B, and G2 image data are output through one line (or odd line or even line) during the unit line output time.

Referring to FIG. 6, the source driving circuit 700 according to the present exemplary embodiment may include a plurality of gamma voltage generators 710, a plurality of source voltage generators 720, a first mux 730, and a second mux 750. ).

The gamma voltage generator 710 includes a gamma voltage generator 711 and a gamma voltage generator 712 that generate gamma voltages for R, G1, B, and G2 image data, respectively.

First, the case where the odd line image data (eg, R, G1, B, and G2 image data) is input to the first mux 730 and the second mux 750 will be described. R and G1 image data are input to the first mux 730. The first mux 730 selects and outputs one of R and G1 image data based on the SEL1 signal. The SEL1 signal is input from the controller 200 to the first mux 730. For example, when the first mux 730 selects and outputs R image data, the gamma voltage generator 711 may output a gamma voltage with respect to the R image data. When the first mux 730 selects and outputs G1 image data, the gamma voltage generator 711 may output a gamma voltage with respect to the G1 image data.

The B and G2 image data are input to the second mux 750. The second mux 750 selects and outputs one of the B and G2 image data based on the SEL2 signal. The SEL2 signal is input from the controller 200 to the second mux 750. For example, when the second mux 750 selects and outputs B image data, the gamma voltage generator 712 may output a gamma voltage for the B image data. When the second mux 750 selects and outputs G2 image data, the gamma voltage generator 712 may output a gamma voltage with respect to the G2 image data.

A case where even line image data (eg, B, G2, R, and G1 image data) is input to the first mux 730 and the second mux 750 will be described. The B and G2 image data are input to the first mux 730. In this case, when the first mux 730 selects and outputs B image data, the gamma voltage generator 711 may output a gamma voltage for the B image data. When the first mux 730 selects and outputs G2 image data, the gamma voltage generator 711 may output a gamma voltage for the G2 image data.

R and G1 image data are input to the second mux 750. In this case, when the second mux 750 selects and outputs the R image data, the gamma voltage generator 712 may select and output the gamma voltage with respect to the R image data. When the second mux 750 selects and outputs G1 image data, the gamma voltage generator 712 may output a gamma voltage with respect to the G1 image data.

The image data output through the first mux 730 and the gamma voltage output from the gamma voltage generator 711 are input to the source voltage generator 721. The image data output through the second mux 750 and the gamma voltage output through the gamma voltage generator 712 are input to the source voltage generator 722. The source voltage generators 721 and 722 will generate a source voltage, respectively.

Source voltages generated from the source voltage generators 721 and 722 are supplied to the OLED panel 500. The difference from the embodiment described with reference to FIG. 5 is that the generated source voltages are supplied to the OLED panel 500 without switching. In the case of the odd line, R and G1 image data are input to the first mux 730, and the B and G2 image data are input to the second mux 750, and in the case of the even line, B and G2 are input to the first mux 730. This is because R and G1 video data are input to the video data as the second mux 750. The generated source voltages will be supplied to the OLED panel 500 according to the switching operation of the source output selection switches SW_CLA and SW_CLB. Therefore, R, G1, B, and G2 image data are output through one line (or odd line or even line) during the unit line output time.

7 illustrates a display system including a no-mux type display panel according to an embodiment of the present invention. Description of the same configuration is omitted to avoid duplication.

Referring to FIG. 7, the source driving circuit 800 according to the present exemplary embodiment includes a plurality of gamma voltage generators 810, a plurality of source voltage generators 820, and a switching unit 830. Operations of the plurality of gamma voltage generators 810, the plurality of source voltage generators 820, and the switching unit 830 may be the same as those described with reference to FIG. 3. The difference from the embodiment described in FIG. 3 is that the source driving circuit 800 according to the present embodiment does not include the source output selection switches SW_CLA and SW_CLB. Meanwhile, the source driving circuit 800 according to the present exemplary embodiment may include the source output selection switches SW_CLA and SW_CLB, but it may be understood that the source output selection switches SW_CLA and SW_CLB are controlled in a closed state. That is, the source driving circuit 300 described in FIG. 3 is applicable to both mux type OLED panels or no-mux type OLED panels.

8 is a timing diagram for explaining signals of a display system including a no-mux type display panel according to an exemplary embodiment of the present invention.

Referring to FIGS. 7 and 8, the voltage S1 of node A is shown. When the odd switching control signal ODD_EN becomes logic 'low' at time t2, the plurality of odd switches SW_ODD are closed. However, this is merely exemplary and may be configured such that the plurality of odd switches SW_ODD are closed when the odd switching control signal ODD_EN becomes logic 'high'.

When the odd switching control signal ODD_EN becomes logic 'low', the first source voltage is supplied to the OLED panel 500 through the first channel. Therefore, the voltage S1 level of the node A will rise at time t2. At the same time or sequentially, the second source voltage, the third source voltage and the fourth source voltage are supplied to the OLED panel 500 through the second channel, the third channel and the fourth channel, respectively. Thus, the voltage levels of nodes B, C and D will rise, respectively. That is, when the odd switching control signal ODD_EN becomes logic 'low', image data is output to the odd line of the OLED panel 500. At the time t4, the panel scan signal CLK becomes logic 'low'.

When the odd switching control signal ODD_EN becomes logic 'high' at time t5, the plurality of odd switches SW_ODD are opened. However, this is merely exemplary and may be configured such that the plurality of odd switches SW_ODD are closed when the odd switching control signal ODD_EN becomes logic 'low'.

In addition, when the even switching control signal EVEN_EN becomes logic 'low' at time t5, the plurality of even switches SW_EVEN are closed. When the even switching control signal EVEN_EN becomes logic 'low', the first source voltage will be supplied to the OLED panel 500 through the third channel. Therefore, the voltage S3 level of the node C will rise at time t2. At the same time or sequentially, the second source voltage, the third source voltage and the fourth source voltage will be supplied to the OLED panel 500 through the fourth channel, the first channel and the second channel, respectively. Thus, the voltage levels at nodes D, A, and B, respectively, will rise. That is, when the even switching control signal EVEN_EN becomes logic 'low', image data will be output to the even line of the OLED panel 500.

The odd switching control signal ODD_EN maintains the plurality of odd switches SW_ODD in the closed state within the unit line output time. The even switching control signal EVEN_EN maintains the plurality of even switches SW_EVEN in the closed state within the unit line output time. Therefore, image data may be output through the odd line and / or even line of the OLED panel 500 within the unit line output time.

9 illustrates a display system including a no-mux type display panel according to another exemplary embodiment of the present invention.

Referring to FIG. 9, the source driving circuit 900 according to the present exemplary embodiment includes a plurality of gamma voltage generators 910, a plurality of source voltage generators 920, and a switching unit 930. Operations of the plurality of gamma voltage generators 910 and the plurality of source voltage generators 920 may be the same as described with reference to FIG. 3.

The difference from the embodiment described with reference to FIG. 7 is that the R, G1, B, and G2 image data are input to the plurality of source voltage generators 920 in units of odd lines and even lines. In detail, in the case of the odd line image data, the R image data is input to the first decoder 921a. The G1 image data is input to the second decoder 922a. The B video data is input to the third decoder 923a. The G2 image data is input to the fourth decoder 924a.

In the case of even line image data, the R image data is input to the first decoder 921a. The G2 image data is input to the second decoder 922a. The B video data is input to the third decoder 923a. The G1 image data is input to the fourth decoder 924a.

Therefore, the switching unit 930 controls the output of the source voltage so that the source voltage output through the first channel and the third channel matches the image data output through the odd and even lines of the OLED panel 500. Here, the first channel refers to a source line for supplying the source voltage generated from the first amplifier 921b to the OLED panel 500. The third channel refers to a source line for supplying the source voltage generated from the third amplifier 923b to the OLED panel 500. As a result, the configuration of the switching unit 930 may be further simplified in this embodiment as compared with the embodiment described with reference to FIG. 7.

10 illustrates a display system including an RGB stripe display panel according to an embodiment of the present invention. That is, the embodiment shown in FIG. 10 describes the case where the OLED panel 2000 has an RGB stripe structure. The source driving circuit 3000 is connected to the OLED panel 2000 through a plurality of channels (first to nth channels).

Referring to FIG. 10, a display system according to an exemplary embodiment of the present invention includes a plurality of gamma voltage generators 3100, a plurality of source voltage generators 3200, a switching unit 3300, and an OLED panel 2000. do.

The plurality of gamma voltage generators 3100 generates gamma voltages for each of R, G, and B image data. The number of the gamma voltage generator 3100 may vary depending on the number of pixels of the OLED panel 2000, and the like, and the case of three gamma voltage generators 3100 is described as an example to avoid repetition of the description. The plurality of gamma voltage generators 3100 may include, for example, a first gamma voltage generator 3110, a second gamma voltage generator 3120, and a third gamma voltage generator 3130. The first gamma voltage generator 3110 generates a first gamma voltage with respect to the R image data. The second gamma voltage generator 3120 generates a second gamma voltage for G image data. The third gamma voltage generator 3130 generates a third gamma voltage for the B image data. That is, the plurality of gamma voltage generators 310 may generate a gamma voltage for each of R, G, and B image data to eliminate or shorten the gamma voltage setting change time.

The plurality of source voltage generators 3200 receives the gamma voltages generated from the plurality of gamma voltage generators 3100. The plurality of source voltage generators 3200 generate source voltages for input R, G, and B image data, respectively. The number of the plurality of source voltage generators 3200 may also vary depending on the number of pixels, and the like is described as an example in which three source voltage generators 3200 are three to avoid repetition of the description. The plurality of source voltage generators 3200 may include, for example, a first source voltage generator 3210, a second source voltage generator 3220, and a third source voltage generator 3230. The first source voltage generator 3210 receives the first gamma voltage and generates a first source voltage corresponding to the data value of the R image data. The second source voltage generator 3220 may receive the second gamma voltage and generate a second source voltage corresponding to the data value of the G image data. The third source voltage generator 3230 receives the third gamma voltage to generate a third source voltage corresponding to the data value of the B image data.

In detail, the source voltage generators 3210, 3220, and 3230 each include a decoder and an amplifier. In detail, the first source voltage generator 3210 includes a first decoder 3210a and a first amplifier 3210b. The first decoder 3210a generates a first intermediate voltage corresponding to the data value of the R image data. The first amplifier 3210b generates a first source voltage by buffering or amplifying the first intermediate voltage. The second source voltage generator 3220 includes a second decoder 3220a and a second amplifier 3220b. The third source voltage generator 3230 includes a third decoder 3230a and a third amplifier 323b. Operations of the second decoder 3220a and the third decoder 3230a may be the same as the first decoder 321a. Operations of the second amplifier 3220b and the third amplifier 3230b may be the same as the first amplifier 3210b. Thus, the second amplifier 3220b generates a second source voltage for the G image data. The third amplifier 3230b generates a third source voltage for the B image data.

The switching unit 3300 transfers the first to third source voltages received from the plurality of source voltage generators 3200 to the OLED panel 2000. The switching unit 3300 is controlled by the odd switching control signal ODD_EN and the even switch control signal EVEN_EN supplied from the controller 200. In detail, the switching unit 3300 may display the first to third source voltages such that the first to third source voltages match the image data output through the odd and even lines of the OLED panel 2000. To pass). For example, when image data is output to an odd line of the OLED panel 2000, the switching unit 3300 may convert the first source voltage to the first channel, the second source voltage to the second channel, and the third source voltage. Are controlled to deliver to the third channel, respectively.

In detail, the switching unit 3300 includes a plurality of odd switches SW_ODD and a plurality of even switches SW_EVEN. The number of the plurality of odd switches SW_ODD and the plurality of even switches SW_EVEN may vary depending on the number of channels of the OLED panel 2000. The plurality of odd switches SW_ODD are opened and closed according to the control of the odd switching control signal ODD_EN. When the plurality of odd switches SW_ODD are closed, image data will be output to an odd line of the OLED panel 2000. The plurality of even switches SW_EVEN are opened and closed according to the control of the even switching control signal EVEN_EN. When the plurality of even switches SW_EVEN are closed, image data may be output to an even line of the OLED panel 500. That is, the plurality of odd switches SW_ODD and the plurality of even switches SW_EVEN are controlled to be opened and closed opposite to each other. In the present embodiment, since the OLED panel 2000 has an RGB stripe structure, for example, the plurality of even switches SW_EVEN may be opened and the plurality of odd switches SW_ODD may be kept closed.

As described above, the display system according to an embodiment of the present invention generates gamma voltages for R, G, and B image data, respectively. Accordingly, the slew rate of the output signal (eg, source voltage) of the source driving circuit 3000 can be improved.

11 is a flowchart illustrating a method of driving a display system according to an exemplary embodiment of the present invention.

Referring to FIG. 11, in the method of driving a display system according to an embodiment of the present invention, generating a gamma voltage for each of R, G, and B image data (S110), and using the gamma voltage, R, G, and B. Generating a source voltage corresponding to the data value of the image data (S120) and outputting the source voltage to the display panel such that the source voltage matches the R, G, and B image data output through the odd and even lines of the display panel; It includes a step (S130). The G image data may include G1 image data and G2 image data. That is, the case where the G image data includes the G1 and G2 image data may be a case where the OLED panel 500 has a pentile structure.

In operation S110, gamma voltage generation for each of the R, G, and B image data may be simultaneously performed. That is, the gamma voltage for the R image data, the gamma voltage for the G image data, and the gamma voltage for the B image data may be simultaneously generated.

Therefore, the driving method of the display system according to an embodiment of the present invention can eliminate or shorten the gamma voltage setting change time, and as a result, improve the slew rate of the output signal (ex. Source voltage) of the source driving circuit. have.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

1000: display device 100: DC / DC converter
200: controller
300, 600, 700, 800, 900: source drive circuit
400: gate driving circuit
500, 2000: OLED panel
310, 610, 710, 810, and 910: a plurality of gamma voltage generators
320, 620, 720, 820, and 920: a plurality of source voltage generators
330, 630, 830, 930: switching unit

Claims (10)

A plurality of gamma voltage generators generating gamma voltages for the R image data, the G image data, and the B image data, respectively;
A plurality of source voltage generators receiving the gamma voltages and generating source voltages corresponding to data values of the image data;
A display panel receiving the source voltage and outputting the R image data, G image data, and B image data; And
And a switching unit configured to output the source voltage to the display panel such that the source voltage matches the R image data, G image data, and B image data output through the odd and even lines of the display panel. The method of claim 1,
The G image data includes G1 image data and G2 image data. 3. The method of claim 2,
The plurality of gamma voltage generators may include a first gamma voltage generator that generates a first gamma voltage for the R image data;
A second gamma voltage generator configured to generate a second gamma voltage with respect to the G1 image data; And
A third gamma voltage generator configured to generate a third gamma voltage for the B image data,
And the second gamma voltage generator generates a fourth gamma voltage for the G2 image data, wherein the second gamma voltage and the fourth gamma voltage are the same. The method of claim 3, wherein
The source voltage generator may include a first decoder configured to receive the first gamma voltage and generate a first intermediate voltage corresponding to a data value of the R image data;
A second decoder configured to receive the second gamma voltage and generate a second intermediate voltage corresponding to a data value of the G1 image data;
A third decoder configured to receive the third gamma voltage and generate a third intermediate voltage corresponding to a data value of the B image data; And
And a fourth decoder configured to receive the fourth gamma voltage and generate a fourth intermediate voltage corresponding to a data value of the G2 image data. 5. The method of claim 4,
The source voltage generator may include a first amplifier configured to receive the first intermediate voltage from the first decoder to generate a first source voltage;
A second amplifier receiving the second intermediate voltage from the second decoder to generate a second source voltage;
A third amplifier receiving the third intermediate voltage from the third decoder to generate a third source voltage; And
And a fourth amplifier receiving the fourth intermediate voltage from the fourth decoder to generate a fourth source voltage. The method of claim 1,
The switching unit includes: a plurality of odd switches for transferring the source voltage matched to the image data output to the odd line of the display panel to the display panel; And
And a plurality of even switches for transmitting the source voltage matching the image data output to the even line of the display panel to the display panel. In a method of driving a display system comprising a display panel:
A gamma voltage generating step of generating gamma voltages for the R image data, the G image data, and the B image data, respectively;
Generating a source voltage corresponding to data values of the R image data, G image data, and B image data by using the gamma voltage; And
A source voltage output step of outputting the source voltage to the display panel to match the R image data, G image data, and B image data output through an odd line and an even line of the display panel; Method of driving a display system. The method of claim 7, wherein
And the G image data includes G1 image data and G2 image data. The method of claim 8,
The gamma voltage generating step may include generating a first gamma voltage with respect to the R image data;
Generating a second gamma voltage for the G1 image data;
Generating a third gamma voltage for the B image data; And
Generating a fourth gamma voltage for the G2 image data,
And the second gamma voltage and the fourth gamma voltage are the same. The method of claim 9,
In the generating of the gamma voltage, the first gamma voltage, the second gamma voltage, the third gamma voltage and the fourth gamma voltage are simultaneously generated.

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