Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2000-03-29
2002-08-20
Niebling, John F. (Department: 2812)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C408S151000, C408S212000, C408S701000
Reexamination Certificate
active
06436815
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an electro-optical device, e.g. to an active liquid crystal electro-optical device, in particular, to a device provided with two complementary thin film insulated gate field effect transistors (hereinafter referred to as C/TFTs) having a structure of modified transfer gate MTG).
Also, the present invention relates to a method for driving an active electro-optical device, in particular, to a method for drifting an active electro-optical device with clear gradation level in a digital mode.
2. Description of the Prior Art
An active liquid crystal electro-optical device utilizing TFT is conventionally know. In this device, an amorphous or polycrystalline semiconductor is used for TFT, while either one of conductive type alone is used for each picture element thereof. Namely, an N-channel TFT(referred to as NTFT) is generally linked to the picture element in series.
Since the dielectric constant in a direction parallel to a molecular axis of the liquid crystal composition provided between substrates is different from that in a direction perpendicular thereto due to the material property thereof, arrangement of the composition can easily be made in both directions, horizontally or vertically, to the outside electric field. By utilizing the anisotropy of dielectric constant, the amount of transmitted light or of dispersion thereof is controlled in a liquid crystal electro-optical device, so as to perform ON/OFF display.
FIG. 8
shows an electro-optic property of nematic liquid crystal. When the applied voltage is small, which is indicated by Va or a point A, the amount of transmitted light is approximately 0% and at Vb or point B, it is approximately 20% , while at Vc or point C, it is approximately 70%, and at Vd or point D, it amounts to approximately 100%. Therefore, when the points A and D alone are used, two-graded display in black-and-white is possible, while, when the points B, C, or the points where electro-optical property (transmittance) rises in
FIG. 2
, are used, the display of intermediate gradation is possible.
As for the conventional electro-optical device utilizing TFTs, gradation display was performed by varying the voltage applied to a gate of the TFT or that applied between source and drain thereof, and controlling the voltage in an analogue mode.
Concerning the conventional method of gradation display in the electro-optical device utilizing TFt, and explanation will be made: an N-channel thin film transistor used for the conventional electro-optical device has the voltage-current characteristic as shown in
FIG. 3
, which shows the voltage-current characteristic of the N-channel thin film transistor utilizing amorphous silicon, and of the utilizing poly-silicon.
By controlling the voltage applied to a gate electrode of the thin film transistor having such characteristic in an analogue mode, drain current can be controlled and therefore strength of the electric field to be applied to the liquid crystal can be varied, whereby gradation display is possible.
In the case of an electro-optical device having picture elements of, for example, 640×400 dots, however, it is difficult to manufacture all 256,00 TFTs without variation in characteristics thereof. It is thought that is gradation levels are limit of the number of gradation levels of such electro-optical device having 640×400 picture elements in order to achieve productivity and yield required for practical process.
A gradation display may be performed by predetermining the value of gate voltage, while controlling only the turning of ON/OFF by gate voltage, and by variably controlling source or drain voltage. In this case, however, about 16 gradation levels are considered to be a limit, based on the fact that the characteristic are unstable. In an analogue mode of the gradation display control, clear display was difficult due to variation in characteristics of TFT.
Another method of gradation display using multiple frames is suggested. As shown in the outline indicated in
FIG. 11
, when a gradation display is to be performed using, for example 10 frames, by making two frames out of ten transparent, while the remainder of eight frames nontransparent, average 20% of transparency can be displayed at picture element A. A picture element B displays 70% of transparency on an average in the same manner, while a picture element C 50% of transparency on an average.
When such a display is carried out, however, since the number of frame is practically reduced thereby, flickering and display failure were generated. To solve the problem, the increasing of frame frequency, or the like, is suggested, whereas, the increase in power to be consumed in accordance with the increase in driving frequency, as well as the difficulty in the achievement of higher operation speed IC, indicated a limit of this method.
BRIEF SUMMARY OF THE INVENTION
An object of the present invention is to provide a method of compensating the variation in characteristics of TFT by inputting a reference signal repeated in a certain cycle and having signal level which varies during duration of the reference signal, from a controller side, in order to clarify the level of applied voltage, and by controlling the time of connecting the reference signal to the TFT by digital value, and thereby controlling the voltage to be applied to the TFT, namely, to offer an electro-optical device by using complementary thin film transistors (C/TFTs) having a structure of modified transfer gate (MTG) that performs digital gradation display.
The method is characterized in displaying gradation in an electro-optical device using a display drive method that has a display timing in relation to a time F for writing one picture plane and a time (t) for writing in one picture plane, without changing the time F, by applying a reference signal that has voltage variation in a cycle that is equal to the time (t) to one of the signal lines that are used for drive and selection of a picture element, as well as a selection signal at a certain timing within the time (t), to the other signal line, thereby determining the voltage to be applied to a liquid crystal, and thereby actually applying the voltage to the picture element.
In addition, the method is also characterized in high speed control without being limited by several tens of MHz that was a limit of data transfer speed for a conventional CMOS, since the timing is not dependent upon the transfer of the data, but is processed at a part for signal process. With a high speed clock being added to a driver IC itself that is put on the electro-optical device.
FIG. 1
shows a concrete drive waveform for driving the electro-optical device in accordance with the present invention. The electro-optical device has a circuit configuration equivalent to a circuit diagram having a 2×2 matrix form shown in FIG.
4
. Herein used is a half wave of a sine wave, as the reference signal waveform of varied voltage in a certain period of time as described supra. Sine waves
309
,
310
are applied to V
DD1
303
, V
DD2
304
that fall in a direction of a scanning line, while two-polarity (hereinafter referred to as bipolar) signals are applied to V
GG1
301
, V
GG2
302
that fall in a direction of information line. Digital control is carried out by a timing of applying the bipolar signals.
Namely, the amount of charge to be accumulated at the point A as well as electric potential at the point A are determined by changing the timing for selecting the signal of varied voltage in a certain period of time, as shown in
309
and
310
, and the size of the electric field to be applied to the picture element as well as to the liquid crystal is determined by defining a certain value for the electric potential
313
of a counter electrode.
The timing of applying the bipolar signal to gate signal lines such as V
GG1
, V
GG2
is not determined by the transfer speed of the information signal, but is regulated by the reference clock input to the driver IC that is direct
Hiroki Masaaki
Mase Akira
Yamazaki Shunpei
Nixon & Peabody LLP
Robinson Eric J.
Semiconductor Energy Laboratory Co,. Ltd.
Simkovic Viktor
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