KR102615994B1 - Driving Unit And Display Device Including The Same - Google Patents

Abstract

The present invention relates to a driving unit and a display device including the same, including a plurality of driving integrated circuits that generate data voltages using a high potential power supply voltage and a plurality of gamma reference voltages, and a direct current to direct current converter that generates a high potential power supply voltage. , a gamma reference voltage supply unit that generates a plurality of gamma reference voltages, and a high potential power supply voltage supplied to the one located closest to the DC-DC converter among the plurality of driving integrated circuits is input as a first feedback voltage, and a plurality of driving integrated circuits is provided. Among the integrated circuits, the one located furthest from the DC-DC converter includes a feedback unit that receives the supplied high potential voltage as a second feedback voltage and compares the difference between the first and second feedback voltages with a reference voltage to generate a control voltage. In addition, the DC-DC converter provides a driving unit for a display device that adjusts the size of the high potential voltage according to the control voltage and outputs it, and prevents the high potential power supply voltage from becoming smaller than the gamma reference voltage to prevent abnormal operation of the driving integrated circuit. This is prevented and the display quality of the image is improved.

Description

Driving unit and display device including the same {Driving Unit And Display Device Including The Same}

The present invention relates to a driving unit for a display device, and particularly to a driving unit including a feedback unit and a display device including the same.

As the information society develops, the demand for display devices to display images is increasing in various forms, and in recent years, liquid crystal displays (LCDs), plasma display panels (PDPs), and organic light emitting devices have been developed. Various flat display devices such as diode displays (OLED: organic light emitting diode device) are being used.

Such a display device includes a display panel and a driver. The display panel displays an image using a plurality of pixels, and the driver generates a gate voltage and a data voltage for driving the plurality of pixels and supplies them to the display panel.

Specifically, the driver generates a data voltage using a high potential power voltage and a plurality of gamma reference voltages, which will be described with reference to the drawings.

1 is a diagram showing a conventional driving unit for a display device.

As shown in FIG. 1, the driving unit 30 for a conventional display device includes a plurality of first to fourth driving integrated circuits (DIC1 to DIC4) and a DC/DC converter (DC/DC converter). 40) and a gamma reference voltage supply unit 42.

The first to fourth driving integrated circuits (DIC1 to DIC4) generate data voltages using a high potential power supply voltage (VDD) and a plurality of gamma reference voltages (GMA), respectively, and supply them to a display panel (not shown).

The DC-DC converter 40 generates a high potential power supply voltage (VDD) and supplies it to the first to fourth driving integrated circuits (DIC1 to DIC4), respectively, and the gamma reference voltage supply unit 42 provides a plurality of gamma reference voltages (GMA). ) is generated and supplied to the first to fourth driving integrated circuits (DIC1 to DIC4), respectively.

Here, the high potential power supply voltage (VDD) is supplied from the DC to DC converter 40 through the first wiring 50, respectively, to the first to fourth driving integrated circuits (DIC1 to DIC4), and a plurality of gamma reference voltages (GMA). ) is supplied from the gamma reference voltage supply unit 42 through the second wiring 52 to the first to fourth driving integrated circuits DIC1 to DIC4, respectively.

The first and second wirings 50 and 52 can each be expressed as an equivalent resistance (Re) connected in series, and the fourth driving integrated circuit is located closest to the DC-DC converter 40 and the gamma reference voltage supply unit 42. The circuit (DIC4) supplies a high potential power supply voltage (VDD) and a plurality of gamma reference voltages (GMA) through the first and second wirings 50 and 52 having the smallest equivalent resistance value (for example, 0). The first and second wirings in which the first driving integrated circuit (DIC1) disposed furthest from the DC to DC converter 40 and the gamma reference voltage supply unit 42 has the largest equivalent resistance value (e.g., 3Re) A high potential power supply voltage (VDD) and multiple gamma reference voltages (GMA) are supplied through (50, 52).

A plurality of gamma reference voltages (GMA) are applied to a plurality of nodes of a resistor string used to generate a data voltage corresponding to image data, and serve to keep the voltage of the plurality of nodes stable. The high potential power supply voltage (VDD) applied to one end of the resistance string has a larger value than the gamma reference voltage (GMA) applied to multiple nodes of the resistance string.

While the current amount of the high potential power supply voltage (VDD) and the amount of current change according to the displayed image are relatively large, the current amount of many gamma reference voltages (GMA) is less than 1/10 of the current amount of the high potential power supply voltage (VDD). Therefore, since it is relatively small, the voltage drop (IR DROP) of the classic power supply voltage VDD via the first wiring 50 is relatively large, and a plurality of gamma reference voltage GMA through the second wiring 52 The voltage drop is relatively small.

Accordingly, in the first or second driving integrated circuits (DIC1, DIC2) located relatively far from the DC to DC converter 40, the high potential power supply voltage (VDD) may be smaller than a plurality of gamma reference voltages (GMA). do.

As such, when the high potential power supply voltage (VDD) supplied to one of the first to fourth driving integrated circuits (DIC1 to DIC4) is smaller than a plurality of gamma reference voltages (GMA), the corresponding driving integrated circuit may operate abnormally. This can be explained with reference to the drawings.

FIG. 2 is a diagram illustrating an anti-static circuit of a driving integrated circuit of a conventional display device drive unit, and will be described with reference to FIG. 1 .

As shown in FIG. 2, each of the first to fourth driving integrated circuits DIC1 to DIC4 of the conventional display device driver 30 includes an anti-static circuit 54. It serves to block static electricity input to the gamma reference voltage input terminal of each of the first to fourth driving integrated circuits (DIC1 to DIC4).

This anti-static circuit 54 includes first and second diodes D1 and D2 connected in series, the cathode of the first diode D1 is connected to the high potential power supply voltage VDD, and the first and second diodes D1 and D2 are connected in series. The node between the second diodes D1 and D2 is connected to the gamma reference voltage input terminal, and the anode of the second diode D2 is connected to the ground voltage.

When a plurality of gamma reference voltages (GMA) are input to each gamma reference voltage input terminal of the first to fourth driving integrated circuits (DIC1 to DIC4), a plurality of gamma reference voltages (GMA) that are smaller than the high potential voltage (VDD) and larger than the ground voltage are generated. Due to the GMA), the current does not flow through the first and second diodes D1 and D2, but the current flows along the first path F1, so that a plurality of gamma reference voltages GMA are normally applied to the resistance column.

When high-voltage static electricity is input to each gamma reference voltage input terminal of the first to fourth driving integrated circuits (DIC1 to DIC4), the second path (F2) is generated by high-voltage static electricity that is greater than the high potential voltage (VDD) and greater than the ground voltage. Accordingly, current flows to the first diode (D1) and high-voltage static electricity is blocked.

However, a high potential power supply voltage (VDD) smaller than a plurality of gamma reference voltages (GMA) due to a voltage drop in the first or second driving integrated circuits (DIC1, DIC2) located relatively far from the DC to DC converter 40. When supplied, current flows to the first diode (D1) along the second path (F2) by a plurality of gamma reference voltages (GMA) that are greater than the high potential voltage (VDD) and greater than the ground voltage, thereby generating a plurality of gamma reference voltages ( GMA) is blocked and the resistance heat is not applied.

Accordingly, there is a problem in that the first or second driving integrated circuits (DIC1 and DIC2) operate abnormally, generating abnormal data voltages and supplying them to the display panel, and as a result, the image displayed by the display panel has block dims. There is a problem that the display quality of the image deteriorates due to display defects such as dim).

The present invention is intended to solve the above-described problem, by controlling the high potential power voltage output from the DC to DC converter according to the high potential power voltage supplied to the driving integrated circuit located closest to and farthest from the DC converter, thereby generating high potential power. The purpose of the present invention is to provide a driver and a display device including the same, which prevent abnormal operation of the driver integrated circuit and improve image display quality by preventing the voltage from becoming less than the gamma reference voltage.

In addition, the present invention selectively controls the high potential power supply voltage output from the DC to DC converter according to the difference between the high potential power supply voltage supplied to the drive integrated circuit located furthest from the DC converter and the drive integrated circuit located closest to the DC converter. Another purpose is to provide a driving unit and a display device including the same, which prevent malfunction of the driving integrated circuit in high-load images and prevent image display defects.

In order to achieve the object as described above, the present invention includes a plurality of driving integrated circuits that generate data voltages using a high potential power supply voltage and a plurality of gamma reference voltages, and a direct current to direct current converter that generates the high potential power supply voltage. and a gamma reference voltage supply unit that generates the plurality of gamma reference voltages, and the high potential power supply voltage supplied to the one of the plurality of driving integrated circuits disposed closest to the DC-DC converter is input as a first feedback voltage, Among the plurality of driving integrated circuits, the high potential voltage supplied to the one located furthest from the DC-DC converter is input as a second feedback voltage, and the difference between the first and second feedback voltages is compared with a reference voltage to provide a control voltage. It includes a feedback unit that generates, and the direct current to direct current converter provides a driving unit for a display device that adjusts the magnitude of the high potential voltage according to the control voltage and outputs it.

And, the driving unit for the display device includes a first wiring that transmits the high-potential power voltage from the DC-DC converter to the plurality of driving integrated circuits, and a first wiring that transmits the high-potential power voltage from the gamma reference voltage supply unit to the plurality of driving integrated circuits. It may further include a second wire that transmits the gamma voltage.

In addition, the feedback unit outputs the first feedback voltage as the control voltage when the difference between the first and second feedback voltages is less than or equal to the reference voltage, and the difference between the first and second feedback voltages is It may include a comparator that outputs the second feedback voltage as the control voltage when it is greater than the reference voltage, and a variable power unit that supplies the reference voltage.

In addition, the DC-DC converter outputs the high-potential power voltage without changing its size when the control voltage is the first feedback voltage, and increases the size when the control voltage is the second feedback voltage to output the high-potential power supply. Voltage can be output.

Meanwhile, the present invention includes a display panel that displays an image using a data voltage, a plurality of driving integrated circuits that generate the data voltage using a high potential power supply voltage and a plurality of gamma reference voltages, and the high potential power supply voltage. A DC to DC converter that generates, a gamma reference voltage supply unit that generates the plurality of gamma reference voltages, and a first high potential power supply voltage supplied to the one of the plurality of driving integrated circuits located closest to the DC to DC converter. It receives input as a feedback voltage, and receives the high potential voltage supplied to the one located furthest from the DC-DC converter among the plurality of driving integrated circuits as a second feedback voltage, and uses the difference between the first and second feedback voltages as a reference. It includes a feedback unit that generates a control voltage by comparing it with the voltage, and the DC-DC converter provides a display device that adjusts the magnitude of the high potential voltage and outputs it according to the control voltage.

In addition, the plurality of driving integrated circuits each include a digital-to-analog converter that converts image data into the data voltage using the plurality of gamma reference voltages, and a plurality of resistance strings each receiving the plurality of gamma reference voltages. It can be included.

Additionally, the display device may further include a timing control unit that generates the image data, a gate control signal, and a data control signal.

And, the feedback unit outputs the first feedback voltage as the control voltage when the difference between the first and second feedback voltages is less than or equal to the reference voltage, and the difference between the first and second feedback voltages is the If it is greater than the reference voltage, the second feedback voltage can be output as the control voltage.

In addition, the DC-DC converter outputs the high potential power voltage without changing its size when the control voltage is the first feedback voltage, and increases the size when the control voltage is the second feedback voltage to output the high potential power supply. Voltage can be output.

The present invention controls the high-potential power voltage output from the DC-DC converter according to the high-potential power voltage supplied to the driving integrated circuit located closest to and farthest from the DC-DC converter, so that the high-potential power voltage becomes smaller than the gamma reference voltage. This has the effect of preventing abnormal operation of the driving integrated circuit and improving the display quality of the image.

In addition, the present invention selectively controls the high potential power supply voltage output from the DC to DC converter according to the difference between the high potential power supply voltage supplied to the drive integrated circuit located furthest from the DC converter and the drive integrated circuit located closest to the DC converter. By doing so, malfunction of the driving integrated circuit in high-load images is prevented and image display defects are prevented.

1 is a diagram showing a conventional driving unit for a display device.
Figure 2 is a diagram showing an anti-static circuit of a driving integrated circuit of a conventional display device drive unit.
Figure 3 is a diagram showing a display device according to an embodiment of the present invention.
Figure 4 is a diagram showing a driving unit of a display device according to an embodiment of the present invention.
Figure 5 is a diagram showing a DC-DC converter and a feedback unit of the driving unit according to an embodiment of the present invention.

Hereinafter, a driver and a display device including the same according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

FIG. 3 is a diagram illustrating a display device according to an embodiment of the present invention, and FIG. 4 is a diagram illustrating a driving unit of the display device according to an embodiment of the present invention.

As shown in FIGS. 3 and 4, the display device 110 according to an embodiment of the present invention includes a display panel 120 that displays an image, and a plurality of voltages for driving the display panel 120. The display device 110 may be an organic light emitting diode display device (OLED display device) or a liquid crystal display device (LCD device). .

Although not shown, the display panel 120 includes a plurality of gate wires and a plurality of data wires that cross each other to define a plurality of pixels, and each of the plurality of pixels may include a plurality of thin film transistors, and a plurality of gates. An image can be displayed using the data voltage supplied through multiple data wires depending on the gate voltage supplied through the wires.

When the display device 110 is an organic light emitting diode display device, each of the plurality of pixels of the display panel 120 may include a switching thin film transistor, a driving thin film transistor, a storage capacitor, and a light emitting diode, and the display device 110 may include a liquid crystal display device. In the case of a display device, each of the plurality of pixels of the display panel 120 may include a thin film transistor, a storage capacitor, and a liquid crystal capacitor.

The driver 130 includes first to eighth driving integrated circuits (DIC1 to DIC8), first and second printed circuit boards 134 and 136, and a power supply unit 132.

The first to eighth driving integrated circuits (DIC1 to DIC8) generate and display data voltages using image data, a plurality of data control signals, a high potential power supply voltage (VDD), and a plurality of gamma reference voltages (GMA), respectively. It is supplied to each of the plurality of pixels through the plurality of data wires and thin film transistors of the panel 120.

A plurality of gamma reference voltages (GMA) are applied to a plurality of nodes of a resistor string used to generate a data voltage corresponding to image data, and serve to keep the voltage of the plurality of nodes stable. The first to eighth driving integrated circuits (DIC1 to DIC8) each include a digital-to-analog converter (DAC) that converts image data into a data voltage using a plurality of gamma reference voltages (GMA), and It may include a plurality of resistance strings to which a plurality of gamma reference voltages are applied, and a high potential power supply voltage (VDD) may be applied to one end of the plurality of resistance strings.

In Figure 4, one of the plurality of gamma voltages (GMA) is shown to be supplied to each of the first to eighth driving integrated circuits (DIC1 to DIC8), but in reality, each of the plurality of gamma voltages (GMA) is supplied to the first to eighth driving integrated circuits (DIC1 to DIC8). It is supplied to each of the driving integrated circuits (DIC1 to DIC8).

In the embodiment of FIG. 3, the number of driving integrated circuits is 8 as an example, but in other embodiments, the number of driving integrated circuits may be more or less than 8.

Here, the first to eighth driving integrated circuits (DIC1 to DIC8) generate gate voltages using a plurality of gate control signals and a high potential power supply voltage (VDD), respectively, to connect the plurality of gate wirings of the display panel 120. It can be supplied to thin film transistors through.

Alternatively, a separate driving integrated circuit (not shown) may generate the gate voltage and supply it to the display panel 120.

The first printed circuit board 134 transmits the high potential power voltage (VDD) of the power supply unit 132 and a plurality of gamma reference voltages (GMA) to each of the first to fourth driving integrated circuits (DIC1 to DIC4), The second printed circuit board 136 transmits the high potential power voltage (VDD) of the power supply unit 132 and a plurality of gamma reference voltages (GMA) to each of the fifth to eighth driving integrated circuits (DIC5 to DIC8).

To this end, the first and second printed circuit boards 134 and 136 each have a first wiring 150 that transmits a high potential power supply voltage (VDD) and a second wiring (150) that transmits a plurality of gamma reference voltages (GMA). 152).

The first and second wirings 150 and 152 can each be expressed as an equivalent resistance (Re) connected in series, and the fourth driving integrated circuit is located closest to the DC-DC converter 140 and the gamma reference voltage supply unit 142. The circuit (DIC4) supplies a high potential power supply voltage (VDD) and a plurality of gamma reference voltages (GMA) through the first and second wirings 150 and 152 having the smallest equivalent resistance value (for example, 0). The first and second wirings in which the first driving integrated circuit (DIC1) disposed furthest from the DC to DC converter 140 and the gamma reference voltage supply unit 142 has the largest equivalent resistance value (e.g., 3Re) A high potential power supply voltage (VDD) and a number of gamma reference voltages (GMA) are supplied through (150, 152).

And, although not shown, the driver 130 uses a number of timing signals such as video signals and data enable signals, horizontal synchronization signals, vertical synchronization signals, and clocks transmitted from external systems such as graphics cards or TV systems. , It may further include a timing control unit that generates a gate control signal, a data control signal, and image data. The generated data control signal and image data are supplied to the first to eighth driving integrated circuits (DIC1 to DIC8) to generate a data voltage. is used for the generation of, and the generated gate control signal is supplied to the first to eighth driving integrated circuits (DIC1 to DIC8) or a separate driving integrated circuit and used to generate a gate voltage.

This timing control unit may be mounted on one of the power supply unit 132 and the first and second printed circuit boards 134 and 132.

The power supply unit 132 generates a high potential power voltage (VDD) and a plurality of gamma reference voltages (GMA) and supplies them to the first to eighth driving integrated circuits (DIC1 to DIC8). For this purpose, a direct current to direct current converter (DC /DC converter) 140, a gamma reference voltage supply unit 142, and a feedback unit 144.

Specifically, the DC-DC converter 140 generates a high potential power supply voltage (VDD) and supplies it to the first to eighth driving integrated circuits (DIC1 to DIC8) according to the control voltage (CON) of the feedback unit 144. The size of the high potential power supply voltage (VDD) is adjusted and output.

The gamma reference voltage supply unit 142 generates a plurality of gamma reference voltages (GMA) and supplies them to the first to eighth driving integrated circuits (DIC1 to DIC8). The high potential power voltage supplied from the DC to DC converter 140 (VDD) can also be used to generate multiple gamma reference voltages (GMA).

The feedback unit 144 detects the magnitude of the high potential power supply voltage (VDD) supplied from the DC to DC converter 140 to the fourth driving integrated circuit (DIC4) disposed closest to the first feedback voltage (FB1), The level of the high potential power supply voltage (VDD) supplied to the first driving integrated circuit (DIC1) located furthest from the DC to DC converter 140 is detected as a second feedback voltage (FB2), and the first and second feedback voltages are The difference between (FB1, FB2) is compared with the reference voltage (REF) to generate a control voltage (CON) and supply it to the DC to DC converter (140).

And, although not shown, the feedback unit 144 adjusts the magnitude of the high potential power supply voltage (VDD) supplied to the fifth driving integrated circuit (DIC5) located closest from the DC to DC converter 140 to the first feedback voltage ( FB1), and the magnitude of the high potential power supply voltage (VDD) supplied to the eighth driving integrated circuit (DIC8) located furthest from the DC-DC converter 140 is detected as the second feedback voltage (FB2), The difference between the first and second feedback voltages (FB1, FB2) is compared with the reference voltage (REF) to generate a control voltage (CON) and supply it to the DC to DC converter (140).

Alternatively, the driving unit 130 may include a separate power supply unit that supplies the high potential voltage (VDD) to the fifth to eighth driving integrated circuits (DIC5 to DIC8).

For example, when the difference between the first and second feedback voltages FB1 and FB2 is less than or equal to the reference voltage REF (|FB1-FB2|≤REF), the feedback unit 144 provides a relatively large first feedback. The voltage FB1 is output as a control voltage CON, and when the difference between the first and second feedback voltages FB1 and FB2 is greater than the reference voltage REF (|FB1-FB2|>REF), the feedback unit 144 ) can output a relatively small second feedback voltage (FB2) as a control voltage (CON).

And, when the control voltage (CON) is the first feedback voltage (FB1), the DC-DC converter 140 outputs the high potential power voltage (VDD) as is without adjusting the size, and the control voltage (CON) is the second feedback. In the case of the voltage FB2, the DC to DC converter 140 can output the high potential power voltage (VDD) by increasing its size.

Accordingly, when displaying a general image, that is, the voltage drop of the high potential power supply voltage (VDD) through the first wiring 150 is relatively small, so the difference between the first and second feedback voltages FB1 and FB2 is the reference voltage. When it is smaller than (REF), the power supply unit 132 supplies the high potential power voltage (VDD) whose size is not increased to the first to eighth driving integrated circuits (DIC1 to DIC8).

In addition, when displaying a specific image such as a high load image, that is, the voltage drop of the high potential power supply voltage (VDD) through the first wiring 150 is relatively large, so that the first and second feedback voltages FB1, When the difference between FB2) is greater than the reference voltage (REF), the power supply unit 132 supplies a high potential power voltage (VDD) of increased size to the first to eighth driving integrated circuits (DIC1 to DIC8), thereby It is possible to prevent the upper power supply voltage (VDD) from becoming smaller than multiple gamma reference voltages (GMA) (i.e., the high potential power supply voltage (VDD) from becoming smaller than the highest voltage among multiple gamma reference voltages (GMA)). As a result, abnormal operation of the first to eighth driving integrated circuits (DIC1 to DIC8) is prevented and image display defects such as block dims are prevented.

The specific configuration of this power supply unit 132 will be described with reference to the drawings.

FIG. 5 is a diagram illustrating a DC-DC converter and a feedback unit of a driving unit according to an embodiment of the present invention, which will be described with reference to FIGS. 3 and 4.

As shown in FIG. 5, the DC-DC converter 140 includes a diode (D), an inductor (L), a transistor (T), and a control unit 160, and the feedback unit 144 includes a comparator (162). ) and a variable power unit 164.

In the DC-DC converter 140, the anode of the diode (D) is connected to one end of the inductor (L) and the drain of the transistor (T), the control unit 160 is connected to the gate of the transistor (T), and the anode of the diode (T) is connected to the gate of the transistor (T). )'s source is connected to the ground voltage.

Although not shown, the other end of the inductor (L) may be connected to a separate power supply, and a capacitor may be connected between the ground voltage and the cathode of the diode (D), which is the output terminal of the DC-DC converter (140).

In this DC-DC converter 140, when the transistor (T) is turned on, current does not flow to the diode (D), energy is stored in the inductor (L), and the transistor (T) is turned on. When turned off, current flows through the diode (D) and the energy of the inductor (L) is stored in the capacitor.

Afterwards, when the transistor T is turned on again, the energy stored in the capacitor is output from the DC-DC converter 140 as a high-potential power supply voltage (VDD).

Here, the control unit 160 controls the gate voltage of the transistor (T) according to the control voltage (CON) transmitted from the feedback unit 144, and controls the high potential power supply voltage (VDD) according to the control of the gate voltage of the transistor (T). ) is adjusted in size.

For example, when the control voltage (CON) has a relatively large value, the size of the high potential power supply voltage (VDD) decreases, and when the control voltage (CON) has a relatively small value, the size of the high potential power supply voltage (VDD) decreases. The size may increase.

In the feedback unit 144, the comparator 162 receives the first and second feedback voltages (FB1, FB2) and the reference voltage (REF) and outputs a control voltage (CON), and the variable power unit 164 receives the reference voltage. (REF) is output.

The comparator 162 operates when the difference between the first and second feedback voltages FB1 and FB2 is less than or equal to the reference voltage REF (|FB1-FB2|≤REF), and the feedback unit 144 provides a relatively large 1The feedback voltage (FB1) is output as the control voltage (CON), and when the difference between the first and second feedback voltages (FB1, FB2) is greater than the reference voltage (REF) (|FB1-FB2|>REF), the feedback unit (144) can output a relatively small second feedback voltage (FB2) as a control voltage (CON).

The variable power unit 164 can output a reference voltage (REF) optimized for the specifications or driving environment of the display device by changing the size of the reference voltage (REF) output using elements such as resistors. For example, For example, the reference voltage (REF) can be determined by considering an additional margin in the difference between the high potential power supply voltage (VDD) and the set value of the highest voltage among multiple gamma voltages (GMA).

The operation of the DC-DC converter 140 and the feedback unit 144 will be described in detail.

For example, when the display device 110 displays a general image, that is, the voltage drop of the high potential power supply voltage (VDD) through the first wiring 150 is relatively small, so that the first to fourth driving integrated circuits DIC1 to DIC4) are about 16.0V, about 16.0V, about 16.0V, and about 16.0V, respectively, and a plurality of gamma voltages are supplied to the first to fourth driving integrated circuits (DIC1 to DIC4). When the highest voltage among the voltages (GMA) is about 15.8V, about 15.8V, about 15.8V, and about 15.8V, the comparator 162 of the feedback unit 144 is about 16.0V and about 16.0V, respectively. and second feedback voltages (FB1, FB2), and since the difference between the first and second feedback voltages (FB1, FB2), about 0V, is less than the reference voltage (REF), about 0.2V, the first feedback voltage ( FB1) outputs about 16.0V as the control voltage (CON), and the control unit 160 of the DC-DC converter 140 controls the transistor (T) according to the control voltage (CON) of about 16.0V to output about 16.0V. Outputs as high potential power supply voltage (VDD).

In addition, when the display device 110 displays a specific image such as a high load image, that is, the voltage drop of the high potential power supply voltage (VDD) through the first wiring 150 is relatively large, so that the first to The high potential power supply voltage (VDD) supplied to the four driving integrated circuits (DIC1 to DIC4) is about 15.7V, about 15.8V, about 15.9V, and about 16.0V, respectively, and the first to fourth driving integrated circuits (DIC1 to DIC4) When the highest voltages among the plurality of gamma voltages (GMA) supplied to are about 15.8V, about 15.8V, about 15.8V, and about 15.8V, the comparator 162 of the feedback unit 144 is about 16.0V and about 15.8V. 15.7V is input as the first and second feedback voltages (FB1, FB2), respectively, and the difference between the first and second feedback voltages (FB1, FB2), about 0.3V, is greater than the reference voltage (REF), about 0.2V. Thus, the second feedback voltage (FB2) of about 15.7V is output as the control voltage (CON), and the control unit 160 of the DC-DC converter 140 operates the transistor (T) according to the control voltage (CON) of about 15.7V. is controlled to output about 16.3V as a compensated high potential power supply voltage (VDD), and the compensated high potential power supply voltage (VDD) of about 16.3V is applied to the first to fourth driving integrated circuits (DIC1 to DIC4), respectively. It is supplied at 16.0V, approximately 16.1V, approximately 16.2V, and approximately 16.3V.

Therefore, not only the high potential power supply voltage (VDD) of about 16.3V supplied to the fourth driving integrated circuit (DIC4) located closest to the DC to DC converter 140, but also the first The high potential power supply voltage (VDD) of approximately 16.0V supplied to the driving integrated circuit (DIC1) also has a value greater than the highest voltage among multiple gamma voltages (GMA) of approximately 15.8V, and as a result, the high potential power supply voltage (VDD) ) is prevented from becoming smaller than the highest voltage among multiple gamma reference voltages (GMA).

As such, in the driving unit 130 and the display device 110 including the same according to an embodiment of the present invention, high potential power is supplied to the first driving integrated circuit (DIC1) located furthest from the DC to DC converter 140. The voltage (VDD) and the high potential power supply voltage (VDD) supplied to the fourth driving integrated circuit (DIC4) disposed closest to the current-to-current converter (140) are detected as first and second feedback voltages (REF), respectively, When the difference between the first and second feedback voltages (REF) is greater than the reference voltage (REF), the DC-DC converter 140 applies the increased size high potential power supply voltage (VDD) to the first to fourth driving integrated circuits ( By supplying it to DIC1 to DIC4), it is possible to prevent the high potential power supply voltage (VDD) from becoming lower than the highest voltage among the plurality of gamma reference voltages (GMA), and as a result, the first to fourth driving integrated circuits (DIC1 to DIC4) ) abnormal operation is prevented and video display defects such as block dims are prevented.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the technical spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

110: display device 120: display panel
130: driving unit 132: power supply unit
134, 136: first and second printed circuit boards 140: direct current to direct current converter
142: Gamma reference voltage supply unit 144: Feedback unit

Claims (11)

a plurality of driving integrated circuits that generate data voltages using a high-potential power supply voltage and a plurality of gamma reference voltages;
a direct current to direct current converter that generates the high potential power supply voltage;
a gamma reference voltage supply unit generating the plurality of gamma reference voltages;
Among the plurality of driving integrated circuits, one of the plurality of driving integrated circuits placed closest to the DC-DC converter receives the supplied high-potential power voltage as a first feedback voltage, and one of the plurality of driving integrated circuits arranged furthest from the DC-DC converter. A feedback unit that receives the supplied high potential power voltage as a second feedback voltage and compares the difference between the first and second feedback voltages with a reference voltage to generate a control voltage.
Including,
The DC-DC converter adjusts the size of the high potential power voltage according to the control voltage and outputs it,
The direct current to direct current converter is,
a diode that outputs the high potential power supply voltage;
an inductor connected to the diode;
a transistor connected between the diode and the inductor and a ground voltage;
A control unit that switches the transistor according to the control voltage
Including,
The plurality of driving integrated circuits include first to fourth driving integrated circuits,
The feedback unit receives the high potential power voltage supplied to the fourth driving integrated circuit located closest to the DC to DC converter through the first wiring having the smallest equivalent resistance value as the first feedback voltage, and receives the highest potential power voltage as the first feedback voltage. A driving unit for a display device that receives the high potential power voltage supplied to the first driving integrated circuit located furthest from the DC to DC converter through the first wiring having a large equivalent resistance value as the second feedback voltage.
According to claim 1,
a first wiring that transmits the high-potential power voltage from the DC-DC converter to the plurality of driving integrated circuits;
A second wiring that transmits the plurality of gamma voltages from the gamma reference voltage supply unit to the plurality of driving integrated circuits.
A driving unit for a display device further comprising:
According to claim 1,
The feedback unit,
When the difference between the first and second feedback voltages is less than or equal to the reference voltage, the first feedback voltage is output as the control voltage, and when the difference between the first and second feedback voltages is greater than the reference voltage, the first feedback voltage is output as the control voltage. a comparator that outputs a second feedback voltage as the control voltage;
Variable power supply unit that supplies the reference voltage
Including,
The variable power unit changes the size of the reference voltage using a resistor, and determines the reference voltage by considering an additional margin in the difference between the high potential power supply voltage and the set value of the highest voltage among the plurality of gamma voltages. Drive part for the device.
According to claim 3,
The direct current to direct current converter is,
When the control voltage is the first feedback voltage, output the high potential power voltage without changing its size,
A driver for a display device that outputs the high potential power voltage by increasing its size when the control voltage is the second feedback voltage.
a display panel that displays images using data voltage;
a plurality of driving integrated circuits that generate the data voltage using a high potential power supply voltage and a plurality of gamma reference voltages;
a direct current to direct current converter that generates the high potential power supply voltage;
a gamma reference voltage supply unit generating the plurality of gamma reference voltages;
Among the plurality of driving integrated circuits, one of the plurality of driving integrated circuits placed closest to the DC-DC converter receives the supplied high-potential power voltage as a first feedback voltage, and one of the plurality of driving integrated circuits arranged furthest from the DC-DC converter. A feedback unit that receives the supplied high potential power voltage as a second feedback voltage and compares the difference between the first and second feedback voltages with a reference voltage to generate a control voltage.
Including,
The DC-DC converter adjusts the size of the high potential power voltage according to the control voltage and outputs it,
The direct current to direct current converter is,
a diode that outputs the high potential power supply voltage;
an inductor connected to the diode and storing energy;
a transistor connected between the diode and the inductor and a ground voltage;
A control unit that switches the transistor according to the control voltage
Including,
The plurality of driving integrated circuits include first to fourth driving integrated circuits,
The feedback unit receives the high potential power voltage supplied to the fourth driving integrated circuit located closest to the DC to DC converter through the first wiring having the smallest equivalent resistance value as the first feedback voltage, and receives the highest potential power voltage as the first feedback voltage. A display device that receives the high-potential power voltage supplied to the first driving integrated circuit located furthest from the DC-DC converter through the first wiring having a large equivalent resistance value as the second feedback voltage.
According to claim 5,
A plurality of driving integrated circuits, each
a digital-to-analog converter that converts image data into the data voltage using the plurality of gamma reference voltages;
A plurality of resistance rows each receiving the plurality of gamma reference voltages
A display device including a.
According to claim 6,
A display device further comprising a timing control unit that generates the image data, a gate control signal, and a data control signal.
According to claim 5,
The feedback unit outputs the first feedback voltage as the control voltage when the difference between the first and second feedback voltages is less than or equal to the reference voltage, and the difference between the first and second feedback voltages is the reference voltage. A display device that outputs the second feedback voltage as the control voltage when it is greater than the control voltage.
According to claim 8,
The DC-DC converter outputs the high-potential power voltage without changing its size when the control voltage is the first feedback voltage, and increases the size to increase the size when the control voltage is the second feedback voltage. A display device that outputs. According to claim 1,
The high potential power voltage is output from the cathode of the diode, and the anode of the diode is connected to one end of the inductor and the drain of the transistor,
A driving unit for a display device wherein the gate of the transistor is connected to the control unit, and the source of the transistor is connected to the ground voltage.
According to claim 10,
A capacitor is connected between the cathode of the diode and the ground voltage,
The other end of the inductor is a driving unit for a display device connected to a power supply.

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