1. Field of Invention
The present invention relates to a data-line driver circuit. More particularly, the present invention relates to a data-line circuit for a current-programmed electro-luminescence display device,
2. Description of Related Art
Electro-luminescence (EL) device is activated through a current drove method either in passive matrix scheme or active matrix scheme. Especially in the active scheme, the charge is held on a capacitor and applied to the pixels of EL device through a transistor driver circuit. A simplest and essential driver circuit of an active-matrix electro-luminescence display device is illustrated in
Nonetheless, the method of utilizing voltages to drive directly the driving TFT 104 as in the foregoing description would generate different light intensities by the same driving voltage due to every driving TFT having different characters. Therefore, a method of utilizing currents to drive the driving TFT 104 is generally used to adjust the threshold voltage and the mobility of the driving TFT 104.
However, there is a disadvantage of an electro-luminescence display device driven by currents. Data currents are generally provided by data lines, so the quantity of current sources must be equal to the quantity of data lines. In other words, many data lines and current sources are required to satisfy the demands for large size and high resolution in modern electro-luminescence display devices. Sony Corp. therefore has provided a current latch circuit to decrease the quantity of current sources, as illustrated in
In
The input data procedures of the current latch circuit in
The first circuit group 201 and the second circuit group 211 take turns receiving and then sending the data current. While data current is being written into one, the other is in charge of sending another data current to the pixel group. And after both of them have finished these procedures, they interchange their functions, thus repeatedly receiving and sending out the data currents.
This current latch circuit can substantially decrease the quantity of current sources, but each circuit groups and each shift register thereof must be controlled by external control signal (not shown) because this current latch circuit is based on two circuit groups interchanging. Disadvantages of the conventional system include too many external control signal lines and poor quality of the display device because two individual circuit groups interfere somewhat with the data currents.
The present invention provides a data-line driver circuit for a current-programmed electro-luminescence display device that satisfies the need to decrease the quantity of external control signal lines and the quantity of electronic elements in a current latch circuit.
The invention changes the two circuit groups of the current latch circuit from receiving and sending data currents in parallel connection to receiving and sending data currents in series connection. The data-line driver circuit receives data currents from an external signal source and drives the pixel group of an electro-luminescence display device. The data-line driver circuit includes a first circuit group, a second circuit group and a shift register. The shift register controls the first circuit group to receive the data currents and controls the second circuit group to duplicate the data currents and then send them to the pixel group.
In one preferred embodiment of the present inventions, the first circuit group is always in charge of receiving the data current Idata from the external signal source and writing the data current Idata to the second circuit group, and the second circuit group is always in charge of receiving the data current Idata from the first circuit group and writing the data current Idata to the pixel group. Under this circuit configuration, every circuit does not itself need to receive and write the data current to pixel group 330.
In conclusion, the invention changes the connection configuration and operating method of the conventional current latch circuit to decrease the quantities of external control signal lines and electronic elements. This means the space occupied thereby is also lessened. For display devices with limited space, such as notebooks whose size is fixed at A4 size, if its frame can be made smaller, the visible area of the display device is comparatively larger.
Furthermore, the invention avoids the problem of an unstable gray scale. The invention uses the same circuit to send signal current to the pixel group, and the characters of electronic elements in the circuit are thus stable. Variations in currents sent out therefrom are avoided because of different characteristics of different circuits even if the original signals are identical.
It is to be understood that both the foregoing general description and the following detailed description are by examples, and are intended to provide further explanation of the invention as claimed.
These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
The present invention provides a data-line driver circuit for a current-programmed electro-luminescence display device to improve the problems of too many external control signal lines and unstable gray scale of the conventional current latch circuit.
The shift register 322 controls the operation of a circuit group 301 and a circuit group 311, and has several periodic signal ports, from a first periodic signal port 326 to a second periodic signal port 327, and on to a Nth periodic signal port 328. The circuit 312 is coupled with the first periodic signal port 326, a circuit 314 is coupled with the second periodic signal port 327, and a circuit 316 is coupled with the Nth periodic signal port 328. The circuits 302, 304, and 306 all are coupled with an enable port 324 of the shift register 322. The circuits 302, 304, 306 form the circuit group 301, and the circuits 312, 314, 316 form the circuit group 311.
In
The shift register 322 operates the first periodic signal port 326, the second periodic signal port 327, and the enable port 324 with a same period; the three intervals 416, 426, and 436 are therefore identical. Moreover, there are time shifts between each of the other durations 412, 422, and 432, to avoid operating problems of data currents in the first periodic signal port 326, the second periodic signal port 327 and the enable port 324 due to their turn-on time point being too close. Subsequent durations 414, 424, and 434 are the same as well.
A data current Idata of
When the data current Idata is input into the current latch circuit from an external signal source, the shift register 322 turns on the duration 412 of the first periodic signal port 326, and the capacitor Cs1 of the circuit 312 starts to store the data 402 of the data current Idata. Then the shift register 322 turns on the duration 422 of the second periodic signal port 327, and the capacitor Cs1 of the circuit 314 starts to store the data 404 of the data current Idata.
After that, the shift register 322 turns on the duration 432 of the enable port 324, and a voltage stored in the Cs1 of the circuit 312 is converted to a data current Idata by a transistor M3 of the circuit 312. Then the data current Idata is converted to a voltage and stored in the Cs2 of the circuit 302 by a transistor M6 of the circuit 302. The circuits 304\314 and circuits 306\316 are also operated according to the foregoing method. Later, the scanning line (not illustrated in
During the duration 442, the shift register 322 turns on the duration 414 of the first periodic signal port 326, and the data 406 of the data current Idata is therefore stored in the capacitor Cs1 of the circuit 312. Then the shift register 322 turns on the duration 424 of the second periodic signal port 327, and the data 408 of the data current Idata is therefore stored in the capacitor Cs1 of the circuit 314. Finally, the shift register 322 turns on the duration 434 of the enable port 324; at this time, the voltages stored in the capacitors Cs1 of the circuits 312 and 314 are respectively duplicated to the capacitor Cs2 of the circuits 302 and 304.
Before the duration 434, a scanning line of the previous pixels in pixel group 330 must be closed; i.e. the duration 442 is ended at time T11, before the beginning time T13 of the duration 434. Otherwise, the data of the data current Idata stored in the circuits 312 and 314 are directly written into the pixel group 330 during the duration 434, and are not stored in the capacitor Cs2 of the circuits 312 and 314 separately.
Consequently, the circuit group 311 is always in charge of receiving the data current Idata from the external signal source and writing the data current Idata to the circuit group 301, and the circuit group 301 is always in charge of receiving the data current Idata from the circuit group 311 and writing the data current Idata to the pixel group 330. Under the circuit configuration in
There is an additional advantage of this current latch circuit in series connection. In the current latch circuit in parallel connection provided by Sony Corp., an enabling means responsible for enabling while a circuit group writes the pixel group must maintain a turned-on state. But the current latch circuit in series connection of the invention only needs a turn-on periodic signal. In other words, the enable function can be achieved by the shift register, and the shift register periodically switches the enable operations.
This preferred embodiment is also of the current sink-type, only reciting one unit of current latch circuit for interpreting. The shift register 522 only has one periodic signal port 526. But if there is more than one unit of current latch circuit, the shift register 522 can be expanded to take charge of more than one unit of current latch circuit.
When the data current Idata is input into the current latch circuit from an external signal source, the shift register 522 turns on the periodic signal port 526, and the capacitor Cs1 of the circuit 512 starts to store the data current Idata After that, the shift register 522 turns on the enable port 524, and a voltage stored in the Cs1 of the circuit 512 is transferred to the data current Idata by a transistor M3 of the circuit 512. Then the data current Idata is transferred to a voltage and stored in the Cs2 of the circuit 502 by a transistor M6 of the circuit 502. Later, the scanning line (not illustrated in
This preferred embodiment is of the current source-type, only reciting one unit of current latch circuit for interpreting. The shift register 622 therefore only has one periodic signal port 626. But if there is more than one unit of current latch circuit, the shift register 622 can be expanded to take charge of more than one unit of current latch circuit.
When the data current Idata is input into the current latch circuit from an external signal source, the shift register 622 turns on the periodic signal port 626, and the capacitor Cs1 of the circuit 612 starts to store the data current Idata. After that, the shift register 622 turns on the enable port 624, and a voltage stored in the Cs1 of the circuit 612 is transferred to the data current Idata by a transistor M3 of the circuit 612. Then the data current Idata is transferred to a voltage and stored in the Cs2 of the circuit 602 by a transistor M6 of the circuit 602. Later, the scanning line (not illustrated in
These three embodiments explain that the invention can use not only the current sink-type current latch circuit but also the current source-type current latch circuit. The features of the invention are as follows: the circuits coupled with the periodic signal port of the shift register are also coupled with the external signal source; the circuits coupled with the enable port of the shift register are also coupled with the pixel group; and these foregoing two circuits are coupled with each other in series connection.
Moreover, from the first embodiment and the second embodiment, it is evident that the configuration of electronic elements in the circuits is not limited by these embodiments recited foregoing.
Comparing the current latch circuit in series connection of the invention with the current latch circuit in parallel connection of Sony Corp, the invention has following advantages:
1. The quantity of shift registers is decreased. In
2. An additional switching to switch the current latch is unnecessary. In
3. Two additional external control signal lines to control the current latch are unnecessary. In
4. The quantity of transistors is decreased. Every unit of current latch circuit in
In conclusion, the invention changes the connection configuration and operating method of the conventional current latch circuit to decrease the quantities of external control signal lines and electronic elements. The electro-luminescence display device with this current latch circuit of the invention includes fewer external control signal lines and electronic elements, consequently reducing space occupied thereby. Generally, the external control signal lines and ICs are positioned inside the frame of the electro-luminescence display device.
If the quantity of the lines is great, the frame of the electro-luminescence display device is larger to contain these lines therein. For display devices with limited size, like notebooks whose size is fixed at A4, if its frame can make smaller, the visible area of the display device is comparatively larger. This improvement makes the display devices thinner, lighter and better than cathode ray tube display devices.
Furthermore, the invention avoids the problem of unstable gray scale. The invention uses the same circuit to send signal current to the pixel group, and the characters of electronic elements in the circuit are stable, thus avoiding variations in currents sent out therefrom due to different characteristics of different circuits even when the original signals are identical.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
Number | Date | Country | Kind |
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92108268 A | Apr 2003 | TW | national |
Number | Name | Date | Kind |
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20010033252 | Yamazaki et al. | Oct 2001 | A1 |
20020190944 | Morita | Dec 2002 | A1 |
20030210219 | Osame | Nov 2003 | A1 |
Number | Date | Country | |
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20040222748 A1 | Nov 2004 | US |