KR100944499B1 - Low power digital driving device for mobile application of amoled - Google Patents

Abstract

The present invention relates to a low-power digital driving device of an AMOLED, and more particularly, a power supply is selectively determined by comparing a value of image data supplied to each pixel with a previous value, and the value of the image data is different. When the precharge operation is required by external power supply, portable AMOLED can reduce power consumption of data driver by supplying power of module DC-DC converter provided outside data driver to each pixel for a short time. Relates to a low power digital driving device.

AMOLED. Data Driver, Digital Drive, Low Power

Description

LOW POWER DIGITAL DRIVING DEVICE FOR MOBILE APPLICATION OF AMOLED

The present invention relates to a low-power digital driving device of an AMOLED, and more particularly, a power supply is selectively determined by comparing a value of image data supplied to each pixel with a previous value, and the value of the image data is different. When the precharge operation is required by external power supply, portable AMOLED can reduce power consumption of data driver by supplying power of module DC-DC converter provided outside data driver to each pixel for a short time. Relates to a low power digital driving device.

Organic light emitting diodes (OLEDs), which have recently emerged as display devices, are a display device capable of high-speed response and high brightness using organic light emitting materials, and can be made thinner than LCD because no backlight is required. Such an organic light emitting display device generates an exciton by combining electrons injected from one electrode and holes injected from another electrode in a light emitting layer positioned between the two electrodes, and the excitons emit energy. It turns on the light.

As the voltage applied across the diode increases above the threshold voltage, the current flowing through the diode increases, and the amount of light output from the organic light emitting diode is proportional to the current.

The organic light emitting diode is classified into active type and passive type according to the driving method. The active organic light emitting diode (AMOLED: Active Matrix OLED) has a TFT element for controlling each pixel in each pixel, and a passive organic light emitting diode (PMOLED) : Passive Matrix OLED) is composed of a structure in which power is supplied to a pixel that is crossed by applying a voltage in both horizontal and vertical directions.

The passive organic light emitting diode (PMOLED) is useful for low-cost products of low resolution because of the short lifetime of the device and the increase of power consumption due to the high luminance required in the unit pixel, whereas the active organic light emitting diode (AMOLED) is used for the TFT element and the By using the memory function of the capacitor, the required luminance of the unit pixel is much lower, so it is applied to products requiring high resolution.

Recently, with the spread of portable display devices, portable devices having an active organic light emitting diode (AMOLED) as a display means have been proposed. As described above, a conventional portable device employing an active organic light emitting diode (AMOLED) as a display panel uses a voltage generated by an internal DC-DC converter included in a data driver, which is a digital driving device, to transfer a value of image data to a pixel. It is common to emit light.

Such a conventional digital driving device drives an output of 10-15V or more using only an internal DC-DC converter for driving a pixel to emit light of a pixel of the panel, and in this case, a pumping ratio of the internal DC-DC converter. ), A large power consumption is generated.

As shown in FIG. 2, a conventional digital driving apparatus includes an external module DC-DC converter 10 for supplying power to a panel, a scan driver 20 for sequentially scanning a panel and selecting pixels to emit light; And a data driver 30 for supplying the gradation current of the image data to be expressed to the selected pixel, and an internal DC-DC converter 50 provided in the data driver.

The module DC-DC converter 10 selects a pixel to emit light by supplying power to the gate of the second transistor provided in each pixel 40 through the scan driver 20, It is configured to supply power from one terminal of a transistor and a capacitor.

When the gray level value supplied from the data driver 30 according to the gray level of the image data is supplied to the other terminal of the second transistor, the power is supplied to the light emitting element to emit light, thereby to adjust the gray level of the image data. Will be represented.

However, in the conventional digital driver, the power supplied from the data driver 30 drives the pixel 40 depending on only the DC-DC converter 50 inside the data driver. In the DC-DC converter 50, there is a problem in that the power consumption of the driving device is greatly increased by a pumping ratio, which is a conversion ratio of the voltage generated when the voltage for precharging is changed.

As such, when the conventional digital driving device is used, the power consumption is greatly increased. In the large display device, the power consumption is not a big problem, but in the case of the portable display, the capacity of the battery is limited, so the need to reduce the power consumption is much greater. do. In addition, since the size of the driving device increases as power consumption increases, there is a problem that the size of the portable device is reversed.

Therefore, there is an urgent need for a method of dramatically reducing power consumption in applying a digital driving method in a portable display device.

The technical problem to be solved by the present invention is to compare the image data supplied to each pixel in the frame memory with the previous image data, and when the value of the image data is the same as a result of the comparison by the DC-DC converter inside the data driver If the power is continuously used and the value of the image data is different, write the power by DC-DC converter external to the data driver to the data line for a short time, and selectively switch the supply power according to the change of the image data. The present invention provides a low-power digital driver for a portable AMOLED device that can reduce the power consumption of a data driver by minimizing the change in the pumping ratio of a DC-DC converter.

A low-power digital driving device of a portable AMOLED for achieving the above technical problem includes an external DC-DC converter for supplying power to a panel, a scan driver for sequentially scanning the panel to select pixels to emit light, and an internal DC- provided in the driver. A digital driving device comprising a DC converter, a frame memory for storing image data, and a data driver including a latch unit for latching image data, wherein the data driver transfers the value of the image data latched by the latch unit to previous image data. A data comparator to compare with the value of; An inverter for inverting the output of the latch unit and supplying it to one terminal of a transistor forming each pixel; And one end connected to the data comparator, and the other terminal comprises a switch connected between the external DC-DC converter and the internal DC-DC converter to selectively supply power to the inverter. .

In addition, when the value of the image data latched as a result of the comparison in the data comparator is different from the value of the image data previously latched, the switch is connected to the external DC-DC converter to each pixel through the data line. It is characterized in that the power is configured to be supplied.

In addition, when the value of the latched image data is the same as the value of the previously latched image data as a result of the comparison in the data comparator, the switch is connected to the internal DC-DC converter to each pixel through the data line It is characterized in that the power is configured to be supplied.

The present invention compares the image data values supplied to each pixel and selects a power source to be supplied to the data line. The power is supplied for a long time, which significantly reduces the power consumption of the data driver, and according to the reduction of the power consumption, the DC-DC area of the data driving driver can be minimized, thereby greatly contributing to the miniaturization of a portable device.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a low-power digital driving device for an AMOLED mobile device according to an embodiment of the present invention includes an external DC-DC converter 100 for supplying power to a panel, and pixels to sequentially emit light by scanning the panel. In the digital driving device including a scan driver 200 to select and a data driver 300 to supply image data to be expressed in the selected pixel, the data driver 300 is an internal DC-DC converter 310 provided in the IC. ), A frame memory 320 storing image data, a latch unit 330 for latching image data of the frame memory, and a data comparator 340 for comparing the value of the latched image data with the value of previous image data. ), An inverter 350 for inverting the output of the latch unit and supplying it to one terminal of a transistor constituting each pixel, and a switch 360 for controlling power supply to the inverter according to a comparison result. It is configured.

At this time, each unit pixel (Pixel) 400 of the panel is connected to the external DC-DC converter 100 and the diode 410, which is a light emitting element, and one terminal in the same way as a conventional display panel (panel) such as an OLED panel A first transistor 420 that is supplied with power and is connected to the diode to supply a current to the light emitting device, a capacitor 430 connected between the gate of the first transistor and an external DC-DC converter, and One terminal is connected to the gate of the first transistor and a common node of the capacitor, and the other terminal is connected to the data driver through the data line 370, and the gate is connected to the scan driver through the scan line 210, according to the scan voltage. It is configured to include a second transistor 440 for switching.

The external DC-DC converter 100 sequentially supplies power to the gate of the second transistor 440 through a scan driver to select pixels 400 to emit light, and then to one end of the capacitor 430 of each pixel. And a DC-DC converter provided in a module external to the data driver to emit light by supplying power to one terminal of the first transistor 420 to supply current to the diode 410.

At this time, the external DC-DC converter 100 is configured such that one end is connected to the switch 360 provided in the data driver so that power supply to the data driver 300 is selectively performed by a switching action.

The scan driver 200 sequentially supplies the power supplied from the external DC-DC converter 100 to each pixel 400 according to a predetermined frequency through the scan line 210, and emits light by the image data. In order to select 400, the second transistor 440 is connected to the gate of the second transistor 440 included in each pixel.

The internal DC-DC converter 310 is a DC-DC converter provided in a data driver IC (DDI), and the second transistor includes a gray value corresponding to a value of image data to be expressed in each pixel. One end is connected to a switch 360 for switching the power supply to each inverter 350 provided in the data driver to selectively switch and supply to the other terminal of the 440.

The frame memory 320 temporarily stores image information of image data to be displayed, and the latch unit 330 is connected to one end of the frame memory to latch and transmit image data. The structure is the same as the frame memory and the latch unit included in the normal data driver.

The data comparator 340 is composed of a comparator for connecting one terminal to the latch unit 330 and comparing the value of the latched image data with the value of the image data previously latched, and the other terminal is an external or internal DC-. It is configured to be connected to a switch 360 for switching the power supply from the DC converter (100, 310) to the inverter (350).

In this case, when the value of the latched image data is different from that of the previously latched image data, the data comparator 340 transmits a new gray level value of the image data to the other terminal of the second transistor 440 included in each unit pixel. Configured to control switch 360 for delivery. Accordingly, the switch 360 is connected to an external DC-DC converter 100, which is an external power supply source of the data driver, is supplied power to the inverter 350, and a precharge operation in the capacitor 430 is performed. .

As such, after the power supplied to the external DC-DC converter 100 is written to the data line 370, the switch 360 is connected to the internal DC-DC converter 310 again. The time for which power is supplied from the external DC-DC converter 100 to the inverter 350 of the data driver is preferably maintained for a predetermined short time.

In addition, when the value of the latched image data is the same as the image data that was previously latched, the data comparator 340 supplies power to the inverter 350 from the internal DC-DC converter 310 and supplies the pixels to each pixel. The precharge operation using the external DC-DC conductor is not performed at the other terminal of the provided second transistor 440. Accordingly, only the power supplied from the internal DC-DC converter 310 is continuously used to output a voltage corresponding to the previous image data.

The inverter 350 receives the output of the latch unit 330 and supplies it to the other terminal of the second transistor 440 forming each pixel through the data line 370, and one terminal is supplied to the switch 360. The connected DC-DC converter is selectively controlled according to the comparison result in the data comparator 340.

The switch 360 has one end connected to the data comparator 340 so that the switch 360 switches according to the result of the data comparator, and the other terminal is connected to the data to selectively control the power supply to the inverter 350. It is configured to be connected between the external DC-DC converter 100 which is an external power source of the driver and the internal DC-DC converter 310 which is an internal power source.

Accordingly, the power supply by the external DC-DC converter 100 is switched to be made for a short time only when the value of the image data output from the latch unit 330 is different from the previous image data value, that is, During the switched time, the power of the external DC-DC converter 100 is applied to the data line 370 through the inverter 350 to reduce the pumping ratio of the internal DC-DC converter to reduce the pumping ratio. It is possible to minimize the power consumption of.

Next, the operation of the low power digital driving device of the portable AMOLED according to the present invention configured as described above will be described.

In the data driver 300 using the digital driving method, image data stored in a frame memory is written to a latch unit. The image data written to the latch unit 330 is transferred to the inverter 350 and recognized by the data comparator 340 connected to the latch unit and the common node of the inverter, and is previously stored in the data comparator. Comparison with.

If the result of the comparison is different from the previously written image data, the switch 360 is connected to the external DC-DC converter 100, and the power of the external DC-DC converter 100 is used as a new image data value. As the precharge operation of the capacitor 430 is performed, light is emitted from the light emitting device.

In addition, when the comparison result in the data comparator 340 is the same as the previously written image data, the switch 360 is connected to the internal DC-DC converter 310 and supplied from the external DC-DC converter. Instead of performing a precharge operation using a power source, the power of the internal DC-DC converter 310 is continuously used to output a voltage corresponding to the same image data.

Accordingly, power consumption can be minimized by reducing the pumping ratio in the internal DC-DC converter.

In addition, in the case of the scan driver 200, there is a difference according to a driving algorithm. However, since the scan lines are driven sequentially, the signal for charging the scan lines does not have the same value as before. Therefore, when applying the present invention to a scan driver, a separate data comparator is not required, but if the signal applied to the scan driver 200 has the same value as the previous value according to the type of algorithm applied to the scan driver, Of course, you can configure it by adding a data comparator.

That is, when the scan signal applied to the scan driver 200 is driven by an algorithm having the same scan signal value as the previous value, a second data comparator for comparing the scan signal with the previous scan signal, and the second data comparator; One end may be connected to the data comparator, and the other terminal may be configured to include a second switch connected between the external DC-DC converter and the internal DC-DC converter and selectively supplying power to the scan line 210.

In the above description, the technical idea of the present invention has been described with the accompanying drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

1 is a circuit diagram of a low power digital driving device of a portable AMOLED according to the present invention;

2 is a circuit diagram of a conventional digital drive device.

<Explanation of symbols for the main parts of the drawings>

100-External DC-DC Converter 200-Scan Driver

210-Scanline 300-Data Driver

310-Internal DC-DC Converters 320-Frame Memory

330-Latch 340-Data Comparator

350-Inverter 360-Switch

370-Data Line 400-Pixel

410-Diode 420-First Transistor

430-Capacitor 440-Second transistor

Claims (5)

Latches an external DC-DC converter that supplies power to the panel, a scan driver that sequentially scans the panel to select pixels to emit light, an internal DC-DC converter provided in the driver, a frame memory and image data storing image data In the digital driving device comprising a data driver provided with a latch unit, The data driver, A data comparator for comparing a value of image data latched by the latch unit with a value of previous image data; An inverter for inverting the output of the latch unit and supplying it to one terminal of a transistor forming each pixel; And One end is connected to the data comparator, the other terminal is a portable AMOLED comprising a switch connected to switch between the external DC-DC converter and the internal DC-DC converter and selectively supply power to the inverter Low power digital drive. The method of claim 1, The switch is connected to the external DC-DC converter when the value of the image data latched as a result of the comparison in the data comparator is different from the previously latched image data, so that power is supplied to each pixel through a data line. Low power digital driving device of the portable AMOLED, characterized in that. The method of claim 2, The switch is a low-power digital driving device of the portable AMOLED, characterized in that configured to be connected to the internal DC-DC converter after the power supply by the external DC-DC converter is supplied again. The method of claim 1, The switch is configured to be connected to the internal DC-DC converter so that power is supplied to each pixel through a data line when the value of the latched image data equals the value of the previously latched image data as a result of the comparison in the data comparator. Low power digital driving device of the portable AMOLED, characterized in that. The method of claim 1, When the scan signal to which the scan driver is applied is driven by an algorithm having the same scan signal value as the previous value, A second data comparator for comparing the scan signal with a previous scan signal; And One end is connected to the second data comparator, and the other terminal includes a second switch connected between the external DC-DC converter and the internal DC-DC converter and selectively supplying power to a scan line. Low power digital drive of portable AMOLED.

Images