This application claims the benefit of U.S. Provisional Patent Application No. 61/233,862 entitled Circuit for memory and use of the same in active matrix devices, inventor Keitaro Yamashita, filed Aug. 14, 2009, and incorporated herein by reference.
1. Field of Invention
The invention relates to a display apparatus and, in particular, to an organic light-emitting diode (OLED) display apparatus.
2. Related Art
Recently, the OLED with various advantages, such as high brightness, full color, wide viewing angle, self-emission, fast response speed, flexibility, simple manufacturing process, low cost, etc., is developed. Compared with the liquid crystal display technology, the OLED display apparatus is a better choice with considering the property requirements of flat display apparatuses.
The memory 15 stores pixel data which should be written into pixel circuit 10. The gate driver 16 control the pixel circuit 10 to receive image data from the source driver 17, and thus the source driver 17 writes the image data stored in the memory 15 into the pixel circuit 10.
Regarding to the resolution of QVGA, there are totally 320 pixels connected with the data line D, and the analog voltage corresponding to the image data is transmitted to the pixels in order through the data line D. Before next frame time, each pixel must maintain its brightness corresponding to the inputted analog voltage level. Since the brightness of each pixel is a function of the gate voltage of the p-type thin film transistor 12, the gate voltage of the p-type thin film transistor 12 should be remained for the period of a frame time (about 16.6 msec) by the capacitor 13.
However, the leakage current issue may occur in both the n-type thin-film transistor 11 and the p-type thin-film transistor 12, which will consume the electricity stored in the capacitor 13. Thus, the voltage level of the image data stored in the capacitor 13 may be changed. After a long period (e.g. longer than a frame time), the gate voltage of the p-type thin film transistor 12 is not guaranteed. This also leads to that the p-type thin-film transistor 12 can not be turned on or off according to the correct image data during a frame time unless new image data is provided. Nevertheless, the power consumption of the display apparatus is increased.
In view of the foregoing subject, an object of the present invention is to provide a display apparatus with lower power consumption.
To achieve the above-mentioned object, the present invention discloses a display apparatus including a plurality of pixels. Each of the pixels has a light emitting unit, a memory circuit, and a driving circuit. The memory circuit stores an image data. The driving circuit is electrically connected with the light emitting unit and the memory circuit, and drives the light emitting unit according to the image data.
As mentioned above, in the display apparatus of the present invention, each pixel has a memory circuit for storing the image data during a frame time. Accordingly, the image data can be remained in the memory circuit of the pixel without continuously receiving the image data from the data line. Therefore, the memory of the source driver is unnecessary to continuously store the pixel data and output it to the corresponding pixel, so that it is not needed to apply additional power to the source driver in this circumstance. Thus, the power consumption can be reduced. To be noted, the benefit of this driving method is maximized especially at the partial dimmed lit mode.
Moreover, the display apparatus of the present invention further includes a mode switching circuit for switching the control mode between a normal mode and a Memory-In-Pixel (MIP) mode. Accordingly, the display apparatus of the present invention can be driven based on the above-mentioned driving method with lower power consumption or the conventional driving method, so that the applications of the invention can be further broadened.
The invention will become more fully understood from the detailed description and accompanying drawings, which are given for illustration only, and thus are not limitative of the present invention, and wherein:
The present invention will be apparent from the following detailed description, which proceeds with reference to the accompanying drawings, wherein the same references relate to the same elements.
The memory circuit 22 can store an image data 221, and the driving circuit 23 is electrically connected with the light emitting unit 21 and the memory circuit 22 for driving the light emitting unit 21 according to the image data 221.
The pixels 20 are arranged in matrix, and every three pixels 20, for example, can construct a pixel unit. To be noted, the pixels 20 may also be arranged in a polygonal shape or other shape, and the pixel unit may be constructed by different numbers of pixels 20. The pixels 20 may be arranged, for example but not limited to, in stripe or in mosaic.
The light emitting unit 21 is, for example, an organic light-emitting diode (OLED). In this case, the display apparatus 2 is an OLED display apparatus. For instance, the OLED can be, for example but not limited to, a red light OLED, a green light OLED, a blue light OLED, a yellow light OLED or a white light OLED. Namely, the display apparatus includes an organic electroluminescence device.
The memory circuit 22 can be implemented with SRAM-like structures shown in
Please refer to
In this embodiment, each pixel 20 may further include a switch circuit 24 electrically connected with the memory circuit 22. In addition, the switch circuit 24 is further electrically connected with one of the scan lines S and one of the data lines D.
The display apparatus 2 may further include a plurality of scan lines S and a plurality of data lines D, which are electrically connected with the pixels 20, respectively. A gate driver 41 is configured to control the time sequence for writing data into the pixels 20 through the scan lines S, and a source driver 42 is configured to write image data 221 into the pixels 20 through the data lines D.
The switch circuit 24 controls the data writing of the memory circuit 22 periodically. For example, when the switch circuit 24 is turned on according to the control of the gate driver 41, the source driver 42 can write the image data 221 into the memory circuit 22 through the data line D.
The operation of pixel of this embodiment will be described hereinafter with reference
Accordingly, during a frame time, when a scan signal S1 is outputted through the scan line S to turn on the transistor 241 of the switch circuit 24, the image data 221 is transmitted to and stored in the memory circuit 22 through the data line D and the transistor 241. Consequently, the image data 221 stored in the memory circuit 22 can control the on-off state of the transistor 231 of the driving circuit 23 so as to control the current applied from power source Vdd to the light emitting unit 21. Accordingly, the brightness of the light emitting unit 21 can be controlled.
In the conventional OLED display apparatus as shown in
To be noted, the design of the memory circuit 22 may be various. As shown in
With reference to
On the contrary to
With reference to
In this embodiment, the memory circuit 22 is configured to store the image data, so that it is not necessary to apply additional power to the source driver for storing the image data into the pixels. Therefore, the power consumption of the display apparatus 2 can be further decreased.
However, the memory circuit 22 or 22a of
In this embodiment, the memory circuits 226˜229 can represent different bits, respectively. For example, the memory circuits 226 to 229 represent four bits from left to right. The transistors 231 can be designed to have different driving abilities. For example, the transistor 231 corresponding to the left bit may have more powerful driving ability, wherein the driving ability of the transistor 231 relates to the equivalent resistance of the transistor 231.
The memory circuit 32 stores an image data 321, and the driving circuit 33 is electrically connected with the light emitting unit 31 and the memory circuit 32 for driving the light emitting unit 31 according to the image data 321.
The arrangement and variation of the pixels 30 are similar to those of the pixels 20 of the previous embodiment, and the type and variation of the light emitting unit 31 are also similar to those of the light emitting unit 21 of the previous embodiment, so the detailed descriptions thereof will be omitted.
The data lines D are arranged perpendicular to the scan lines S, and the data lines D and the scan lines S are respectively connected with the pixels 30. The mode control lines C are arranged parallel to the scan lines S.
In this embodiment, the memory circuit 32 can be the memory circuit as described in the previous embodiment or other volatile or non-volatile memory circuit. Moreover, the memory circuit 32 is a discrete component for storing digital values. Alternatively, the memory circuit 32 can also be a capacitor that can store data in digital way, and the capacitor can present the stored data in digital mode or analog mode.
The mode switching circuit 35 is electrically connected with the memory circuit 32 and is controlled by the mode control line C for enabling the pixel 30 to operate in a MIP mode. The mode switching circuit 35 is further electrically connected with the memory circuit 32 and the driving circuit 33 for controlling the memory circuit 32 to presents the stored data in digital mode or analog mode, such that the driving circuit 33 drives the light emitting unit 31 according to the image data 321 of the memory circuit 32.
The detail and operation of the pixel 30 in this embodiment will be described hereinafter with reference
Referring to
The transistor 331 of the driving circuit 33 is a p-type thin film transistor. The source of the transistor 331 is connected to a power line (power source Vdd), which extends along the corresponding rows of pixels 30, and the gate of the transistor 331 is electrically connected to one end of the capacitor 322, the drain of the transistor 341, and the drain of the enabling switch 351. In this case, the other end of the capacitor 322 is connected to the power line (power source Vdd).
The transistor 341 is an n-type thin film transistor. The source of the transistor 341 is electrically connected with the corresponding data line D, and the gate of the transistor 341 is electrically connected with the scan line S, which extends along the corresponding rows of the pixels 30.
The enabling switch 351 is an n-type thin film transistor. The gate of the enabling switch 351 is electrically connected with the mode control line C, and the mode control line C extends along the corresponding rows of the pixels 30. The drain of the enabling switch 351 is electrically connected with the drain of the feedback switch 352.
The feedback switch 352 is an n-type thin film transistor. The source of the feedback switch 352 is electrically connected with a bias line L, which extends along the corresponding rows of the pixels 30. For example, the bias line L is a low voltage line.
If the enabling switch 351 is turned off, the image data 321 stored in the capacitor 322 is read by an analog method, so that the voltage level of the image data 321 can control the current flowing through the transistor 331. Otherwise, if the enabling switch 351 is turned on, the image data 321 stored in the capacitor 322 is read by a digital method, so that the MIP mode, which is a low power-consumption mode, can be performed.
With reference to
When the enabling switch 351 is turned off, the pixels 30 operate in a normal mode. The switch circuit 34 controls the memory circuit 32 to be written with the image data 321 periodically. Within a frame time, the scan line S outputs a scan signal S1 to turn on the transistor 341, so that the image data 321 can be inputted into the capacitor 322 through the data line D and the transistor 341. After the pixel 30 has been scanned by the scan line S, the transistor 341 is turned off and the voltage level of the capacitor 322 controls the current flowing through the transistor 331. The current flowing through the transistor 331 can drive the light emitting unit 31 to emit light to achieve the desired brightness.
Referring to
In the MIP mode, the image data 321 stored in the memory circuit 32 can be hold by an imbalance leakage current. For example, the imbalance leakage current occurs because leakage current of the switch circuit 34 is larger than that of the mode switching circuit 35. As shown in
The memory circuit 32 stores the image data hold by the imbalance leakage current, and it presents the stored data in digital mode. The driving circuit 33 drives the light emitting unit 31 according to the image data.
If the node N is in a high voltage level, the driving circuit 33 is turned off and the light emitting unit 31 does not emit light. Thus, the transistor of the feedback switch 352 is turned off, and the feedback path is disabled. The leakage current of the switch circuit 34 is larger than that of the enabling switch 351 and the feedback switch 352 to hold the image data. In this case, the node N is kept in the high voltage level so as to make the driving circuit 33 in a turn-off state. The light emitting unit 31 still does not emit light.
In order to remain the electric charges in the capacitor 322 without leaking through the transistor, the data line D can be kept in the high voltage level. Since the leakage current of the transistor 341 can be larger than that of the transistors of the enabling switch 351 and the feedback switch 352, consequently, the voltage of the node N may become the high voltage level or be kept in the high voltage level. This can disable the feedback path while the node N is in the high voltage level, so that the voltage can be maintained.
In addition, with reference to
In other words, the pixels 30 have two display modes: a first mode and a second mode.
The first mode is a normal mode. In this mode, the analog data are written into the capacitor 322 of the pixel 30 as usual, and the transistor 331 can control the current flowing through the light emitting unit according to the analog voltage level stored in the capacitor 322.
The second mode is a MIP mode. In this mode, the memory cell 32 of the pixel is isolated from the scan line, so that the data stored in the memory cell 32 can not be changed or rewritten. In the second mode, the gate driver does not output the scan signal to the pixel 30. The benefit of this driving method is maximized especially at the partial dimmed lit mode.
To sum up, in the display apparatus of the present invention, each pixel has a memory cell for storing the image data during a frame time. Accordingly, the image data can be remained in the memory cell of the pixel without continuously receiving the image data from the data line. Therefore, the memory of the source driver is unnecessary to continuously store the image data and output it to the corresponding pixel, so that it is not needed to apply additional power to the source driver in this circumstance. Thus, the power consumption can be reduced. To be noted, the benefit of this driving method is maximized especially at the partial dimmed lit mode.
Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternative embodiments, will be apparent to persons skilled in the art. It is, therefore, contemplated that the appended claims will cover all modifications that fall within the true scope of the invention.
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