Drive schemes for gray scale bistable cholesteric reflective displays
First Claim
1. A method of addressing a bistable cholesteric liquid crystal material having incremental reflectance properties disposed between opposed substrates, wherein one substrate has a first plurality of electrodes deposited thereon facing the other substrate which has a second plurality of electrodes deposited thereon, the intersections of the first and second plurality of electrodes forming a plurality of pixels, the method comprising the steps of:
- selecting first and second characteristic voltage values, wherein one of said characteristic voltage values drive the material to a minimum reflectance and the other of said characteristic voltage values drives the materials to a maximum reflectance;
energizing the first and second plurality of electrodes to drive all the liquid crystal material to one of the maximum and minimum reflectances; and
energizing the first and second plurality of electrodes to obtain a pixel voltage waveform so as to switch the liquid crystal material to a corresponding incremental reflectance somewhere between the reflectance obtained by application of said first and second characteristic voltage values, wherein application of a portion of said pixel voltage waveform to at least one of said plurality of electrodes is varied to vary said pixel voltage waveform between said first and second characteristic voltages to obtain a corresponding incremental reflectance of the liquid crystal material, wherein obtaining said pixel voltage waveform includes time modulating application of said portion of said pixel voltage waveform in the form of a single bi-level pulse having a first voltage level for a first variable period of time and a second voltage level, different than said first voltage level, for a second variable period of time, wherein the sum of said first and second variable periods of time are equal to a set time period.
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Abstract
A series of drive schemes are used to apply a single phase of at least one voltage pulse to drive a display with a bistable cholesteric liquid crystal material to a gray scale reflectance. Each drive scheme takes into consideration the initial texture of the cholesteric material and the range of voltages that may be applied between maximum and minimum reflectance of the material. Application of the single phase can be implemented by either time modulation or amplitude modulation.
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Citations
6 Claims
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1. A method of addressing a bistable cholesteric liquid crystal material having incremental reflectance properties disposed between opposed substrates, wherein one substrate has a first plurality of electrodes deposited thereon facing the other substrate which has a second plurality of electrodes deposited thereon, the intersections of the first and second plurality of electrodes forming a plurality of pixels, the method comprising the steps of:
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selecting first and second characteristic voltage values, wherein one of said characteristic voltage values drive the material to a minimum reflectance and the other of said characteristic voltage values drives the materials to a maximum reflectance;
energizing the first and second plurality of electrodes to drive all the liquid crystal material to one of the maximum and minimum reflectances; and
energizing the first and second plurality of electrodes to obtain a pixel voltage waveform so as to switch the liquid crystal material to a corresponding incremental reflectance somewhere between the reflectance obtained by application of said first and second characteristic voltage values, wherein application of a portion of said pixel voltage waveform to at least one of said plurality of electrodes is varied to vary said pixel voltage waveform between said first and second characteristic voltages to obtain a corresponding incremental reflectance of the liquid crystal material, wherein obtaining said pixel voltage waveform includes time modulating application of said portion of said pixel voltage waveform in the form of a single bi-level pulse having a first voltage level for a first variable period of time and a second voltage level, different than said first voltage level, for a second variable period of time, wherein the sum of said first and second variable periods of time are equal to a set time period. - View Dependent Claims (2, 3, 4, 5, 6)
applying an offset voltage to both the first and second plurality of electrodes.
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3. The method of addressing according to claim 2, wherein the steps of energizing the first and second plurality of electrodes include the step of:
applying a fresh voltage to drive the liquid crystal material to a planar texture, wherein application of said first characteristic voltage value maintains the planar texture, and wherein application of said second characteristic voltage value drives the liquid crystal material to focal conic texture.
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4. The method of addressing according to claim 2, wherein the steps of energizing the first and second plurality of electrodes include the step of:
applying a fresh voltage to drive the liquid crystal material to a focal conic texture, wherein application of said first characteristic voltage value maintains the focal conic texture, and wherein application of said second characteristic voltage value drives the liquid crystal material to a planar texture.
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5. The method of addressing according to claim 2, wherein the steps of energizing the first and second plurality of electrodes include the step of:
applying a fresh voltage to drive the liquid crystal material to a planar texture wherein application of said second characteristic voltage value maintains the planar texture, and wherein application of said first characteristic voltage value drives the liquid crystal material to focal conic texture.
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6. The method of addressing according to claim 1, further comprising:
repeating said time modulating application with an inverted form of said single bi-level pulse.
Specification