USRE37333EExpiredUtility

Ferroelectric liquid crystal display device having an A.C. holding voltage

44
Assignee: SEIKO INSTR INCPriority: Dec 9, 1983Filed: Sep 30, 1992Granted: Aug 21, 2001
Est. expiryDec 9, 2003(expired)· nominal 20-yr term from priority
G09G 3/3692G09G 3/3681G09G 3/2011G09G 2320/028G09G 2310/06G09G 2320/041G09G 3/3629G02F 1/13
44
PatentIndex Score
10
Cited by
7
References
116
Claims

Abstract

A liquid crystal display device utilizing a ferroelectric liquid crystal, e.g., a chiral smectic liquid crystal aligned to establish two bi-stable display states. The display device is driven in a time-sharing mode. The change of the bi-stable display states is effected by applying a selected voltage to the changed ferro-electric liquid crystal. Thereafter the display state is held by applying an A.C. pulse voltage.

Claims

exact text as granted — not AI-modified
What is claimed is:  
     
       1. A liquid crystal display device driven in a time-sharing mode, comprising: a pair of electrodes spaced apart from each other; a ferro-electric liquid crystal layer disposed between the pair of electrodes such that the layer loses a spiral molecular alignment thereof to establish two-bistable molecular alignments thereof; drive means connected between the pair of electrodes for applying an electric signal to the layer sufficient to change one of the two bi-stable molecular alignments to the other bi-stable molecular alignment and for applying an A.C. electric signal to the layer effective to hold the other bi-stable molecular alignment, the A.C. electric signal having an amplitude and a pulse width insufficient to change the bi-stable molecular alignments; and converting means for coverting the two bi-stable molecular alignments to corresponding optical ON and OFF display states, respectively. 
     
     
       2. A liquid crystal display device as claimed in claim  1 ; wherein the drive means includes means for electrically disconnecting the pair of electrodes after the application of the A.C. electric signal to the layer. 
     
     
       3. A liquid crystal display device as claimed in claim  1 ; wherein the drive means includes means for changing a driving frequency to compensate for changes in ambient temperature. 
     
     
       4. A liguid crystal display device as claimed in claim  1 ; wherein the drive means includes means for adjusting the electric signal effective to change the bi-stable molecular alignments to compensate for changes in ambient temperature. 
     
     
       5. A liquid crystal display device as claimed in claim  1 ; wherein the ferro-electric liquid crystal layer comprises a chiral smectic liquid crystal layer. 
     
     
       6. A liquid crystal display device as claimed in claim  1 ; wherein the drive means includes means for applying an A.C. electric signal having a high frequency sufficient to avoid the degradation of an optcial transparent intensity of the optical ON display state. 
     
     
       7. A liquid crystal display device as claimed in claim  1 ; including a liquid crystal panel having display and scanning electrodes in opposed relation to each other to define a matrix electrode structure; and wherein the drive means comprises an oscillating circuit for generating a clock signal, a driving voltage generating circuit for producing a driving voltage waveform, driving circuits for supplying a driving voltage according to the driving voltage waveform to the display electrodes and scanning electrodes, and a control circuit for controlling the driving voltage generating circuit and the driving circuits. 
     
     
       8. A liquid crystal display device as claimed in claim  7 ; wherein the control circuit has a first exclusive OR circuit for supplying a polarity changeover signal having a phase inverted with the changing ON or OFF to the other state to the driving voltage generating circuit and second exclusive OR circuit for supplying a data signal having a phase inverted with the changing ON or OFF to the other state to the driving circuit. 
     
     
       9. A liquid crystal display device as claimed in claim  8 ; wherein the drive means effects a first scanning operation for writing one of the optical ON and OFF display states and a second scanning operation for writing the other of the display states during one frame of operation. 
     
     
       10. A liquid crystal display device as claimed in claim  1 ; wherein the drive means includes means for applying an A.C. electric signal having no D.C. component. 
     
     
       11. A liquid crystal display device as claimed in claim  1 ; wherein the ferro-electric liquid crystal has a thickness sufficiently thin to lose the spiral molecular alignment of the layer. 
     
     
       12. A liquid crystal display device as claimed in claim  1 ; wherein the electric signal comprises an electric voltage signal and the A.C. electric signal comprises an A.C. electric voltage signal. 
     
     
       13. A liquid crystal display device driven in a time-sharing mode, comprising; a ferro-electric liquid crystal aligned to establish two bi-stable display states; and drive means for applying a selected voltage ±V ap  having a desired pulse amplitude and a pulse width to the liquid crystal to change one of the two bi-stable display states to the other bi-stable display state and for applying to the liquid crystal an A.C. pulse voltage having a pulse amplitude and a pulse width at least one of which is less than that of the selected voltage ±V ap  to thereby hold the other bi-stable display state. 
     
     
       14. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying a selected voltage ±V ap  containing a D.C. component. 
     
     
       15. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying a selected voltage ±V ap  containing no D.C. component. 
     
     
       16. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying a selected voltage having a polarity effective to change one of the two bi-stable display states to the other bi-stable display state during a first scanning operation and for applying another selected voltage having another polarity effective to change the other bi-stable display state to said one bi-stable display state during a second scanning operation. 
     
     
       17. A liquid crystal display device as claimed in claim  13 ; wherein the ferro-electric liquid crystal comprises ferro-electric liquid crystal molecules aligned to assume two bi-stable molecular alignment corresponding to the two bi-stable display states, respectively. 
     
     
       18. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for increasing the driving frequency after the drive means carries out a scanning operation for a given number of times. 
     
     
       19. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying to the liquid crystal a selected voltage having a modulated pulse width effective to develop an intermediate display state between the two bi-stable display states. 
     
     
       20. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying a selected voltage signal comprised of a first pulse effective to reset the display state of the liquid cystal to one of the two bi-stable states and a successive second pulse having a opposite polarity effective to change the reset display state to the other bi-stable state. 
     
     
       21. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for applying to the liquid crystal a selected voltage having a modulated duration effective to develop an intermediate display state between the two bi-stable display states. 
     
     
       22. A liquid crystal display device as claimed in claim  13 ; wherein the drive means includes means for effecting a first scanning operation for writing one of the two bi-stable display states and for effecting a second scanning operation for writing the other bi-stable display state during one frame of operation. 
     
     
       23. A smectic liquid crystal display device comprising in combination: a liquid crystal panel including a pair of opposed base plates, electrodes disposed on the respective inner surfaces of the opposed base plates, alignment membranes shaped on the respective inner surfaces of the opposed base plates, and a smectic liquid crystal compound inserted between the opposed base plates at an interval less than a spiral pitch of the liquid crystal compound so that the liquid crystal compound is aligned by the alignment membranes to establish two bi-stable optical states; means for applying a liquid crystal operating voltage of one polarity in a first half of an electrode selecting operation to the electrodes so as to select one of the two bi-stable optical states and for applying another liquid crystal operating voltage of another polarity in a second half of the electrode selecting operation to the electrode so as to select the other bi-stable optical state, and means for applying to the electrodes an alternating voltage which is less than the liquid crystal operating voltage in a non-electrode selecting operation so as to hold the selected bi-stable optical state. 
     
     
       24. A liquid crystal display device comprising: a pair of opposed electrodes; a ferro-electric liquid crystal disposed between the pair of electrodes so that the ferro-electric liquid crystal loses a spiral molecular alignment thereof to establish two bi-stable molecular alignments in which molecules of the ferro-electric liquid crystal are not aligned in parallel to the boundary surface of the liquid crystal; means connected to the electrodes for applying an electric signal to the liquid crystal in a time-sharing mode to select one of the two bi-stable molecular alignments; and a pair of polarizers for sandwiching the ferro-electric liquid crystal. 
     
     
       25. A ferro-electric liquid crystal electro-optical device comprising: a pair of opposed electrodes; a ferro-electric liquid crystal disposed between the opposed electrodes such that the electric liquid crystal loses a spiral molecular alignment thereof to establish two bi-stable molecular alignments; drive means for applying to the electrodes in a time-sharing mode a selected electric signal sufficient to change one of the bi-stable molecular alignments of the ferro-electric liquid crystal to the other bi-stable molecular alignment and for applying to the electrodes an A.C. electric signal having an amplitude and a pulse width insufficient to change one of the bi-stable molecular alignments of the ferro-electric liquid crystal to the other bi-stable molecular alignment, the A.C. electric signal being effective to hold the bi-stable molecular alignment; and a pair of polarizers for sandwiching the ferro-electric liquid crystal. 
     
     
       26. A device as claimed in claim  25 ; wherein the drive means includes means for applying a selected electric signal in the form of a voltage ±V ap  having a given pulse amplitude and a pulse width, and means for applying an A.C. electric signal in the form of an A.C. pulse voltage having a pulse amplitude and a pulse width at least one of which is less than that of the selected voltage ±V ap . 
     
     
       27. A device as claimed in claim  25 ; wherein the drive means includes means for applying an A.C. electric signal having a high frequency sufficient to avoid degradation of an optical transparent intensity of the ferro-electric liquid crystal. 
     
     
       28. A device as claimed in claim  25 ; wherein the drive means includes means for applying a selected electric signal containing a D.C. component. 
     
     
       29. A device as claimed in claim  25 ; wherein the drive means includes means for applying a selected electric signal containing no D.C. component. 
     
     
       30. A device as claimed in claim  25 ; wherein the drive means includes means for effecting a first scanning operation for selecting one of the two bi-stable molecular alignments and a second scanning operation for selecting the other bi-stable molecular alignment during one frame of operation. 
     
     
       31. A device as claimed in claim  25 ; wherein the drive means includes means for applying a selected electric signal comprised of a first pulse effective to reset the molecular alignment to one of the bi-stable molecular alignment and a successive second pulse having an opposite polarity effective to change the reset molecular alignment of the other bi-stable molecular alignment. 
     
     
       32. A device as claimed in claim  25 ; wherein the electric signal comprises an electric voltage signal and the A.C. electric signal comprises an A.C. electric voltage signal. 
     
     
       33. A liquid crystal optical device comprising: a liquid crystal layer comprised of ferro-electric liquid crystal molecules aligned to establish two optically distinctive bi-stable states in the liquid crystal layer; a pair of opposed electrode means sandwiching therebetween the liquid crystal layer; and drive means connected between the pair of electrode means for applying a selecting electric signal to the liquid crystal layer to select one of the two bi-stable states and for applying a holding AC electric signal to the liquid crystal layer to hold the selected bi-stable state. 
     
     
       34. A liquid crystal optical device as claimed in claim  33 ; wherein the liquid crystal layer has a thickness smaller than a pitch of a spiral alignment of the ferro-electric liquid crystal molecules so that the ferro-electric liquid crystal molecules lose their spiral alignment and re-align in two bi-stable alignments so as to establish the two optically distinctive bi-stable states of the liquid crystal layer. 
     
     
       35. A liquid crystal optical device as claimed in claim  33 ; wherein the pair of opposed electrode means comprise two sets of a plurality of electrodes intersecting with each other to define a plurality of optical elements at the intersections. 
     
     
       36. A liquid crystal optical device as claimed in claim  35 ; wherein the drive means includes time-sharing means connected between the two sets of electrodes to sequentially assign a time slot to each of the optical elements to drive the optical elements in a time-sharing mode. 
     
     
       37. A liquid crystal optical device as claimed in claim  36 ; wherein the time-sharing means includes means for applying a selecting signal to each optical element during the time slot assigned thereto and for applying a holding AC electric signal to each optical element during consecutive time slots assigned to the other optical elements. 
     
     
       38. A liquid crystal optical device as claimed in claim  37 ; wherein the means for applying the selecting and holding AC electric signals includes means for applying a selecting electric signal having an electric power sufficient to switch one of the two bi-stable states to the other bi-stable state and for applying a holding AC electric signal having an electric power insufficient to switch the bi-stable state so as to hold the bi-stable state. 
     
     
       39. A liquid crystal optical device as claimed in claim  33 ; wherein the device comprises a liquid crystal display device. 
     
     
       40. A liquid crystal optical device as claimed in claim  33 ; wherein the device comprises a liquid crystal shutter device. 
     
     
       41. A liquid crystal optical device as claimed in claim  33 ; wherein the selecting electric signal comprises a selecting electric voltage signal and the holding AC electric signal comprises a holding AC electric voltage signal. 
     
     
       42. A liquid crystal display device driven in a time- sharing mode, comprising:    
       
         a plurality of scanning electrodes and a plurality of display electrodes spaced apart from each other;  
       
         a ferro - electric liquid crystal layer disposed between the scanning electrodes and the display electrodes such that the layer loses a spiral molecular alignment thereof to establish two bi - stable molecular alignments;    
       
         drive means connected to the plurality of scanning electrodes for applying scanning electrode signals and sequentially applying selecting scanning electrode signals to each of the plurality of scanning electrodes and connected to the plurality of display electrodes for applying display electrode signals synchronized with the scanning electrode signals to the plurality of display electrodes; and  
       
         converting means for converting the two bi - stable molecular alignments to corresponding optical ON and OFF display states, respectively;    
         wherein selecting electrical signals produced by combining the selecting scanning electrode signals and the display electrode signals are applied to the layer between the scanning electrodes and the display electrodes in a selecting period of the scanning electrodes for sufficiently changing one of the two bi - stable molecular alignments to the other bi - stable molecular alignment and A.C. electric signals produced by combining the scanning electrode signals and the display electrode signals, the A.C. electric signals having an amplitude and a pulse width insufficient to change the bi - stable molecular alignments, and are applied to the layer between the scanning electrodes and the display electrodes in a non - selecting period of the scanning electrodes to hold the other bi - stable molecular alignment, such that the pulse width of each voltage polarity included in the A.C. electric signals does not exceed a time width of said each selecting period of the scanning electrodes.   
     
     
       43. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for electrically disconnecting the scanning electrodes and display electrodes after the application of the A.C. electric signal to the layer. 
     
     
       44. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for changing a driving frequency to compensate for changes in ambient temperature. 
     
     
       45. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for adjusting the selecting electrical signals effective to change the bi- stable molecular alignments to compensate for changes in ambient temperature.   
     
     
       46. A liquid crystal display device as claimed in claim  42 ; wherein the ferro- electric liquid crystal layer comprises a chiral smectic liquid crystal layer.   
     
     
       47. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for applying an A.C. electric signal having a high frequency sufficient to avoid the degradation of an optical transparent intensity of the optical ON display state. 
     
     
       48. A liquid crystal display device as claimed in claim  42 ; including a liquid crystal panel having display and scanning electrodes in opposed relation to each other to define a matrix electrode structure; and wherein the drive means comprises an oscillating circuit for generating a clock signal, a driving voltage generating circuit for producing a driving voltage waveform, driving circuits for supplying a driving voltage according to the driving voltage waveform to the display electrodes and scanning electrodes, and a control circuit for controlling the driving voltage generating circuit and the driving circuits. 
     
     
       49. A liquid crystal display device as claimed in claim  48 ; wherein the control circuit has a first exclusive OR circuit for supplying a polarity changeover signal having a phase inverted with the changing ON or OFF to the other state to the driving voltage generating circuit and a second exclusive OR circuit for supplying a data signal having a phase inverted with the changing ON or OFF to the other state to the driving circuit. 
     
     
       50. A liquid crystal display device as claimed in claim  49 ; wherein the drive means effects a first scanning operation for writing one of the optical ON and OFF display states and a second scanning operation for writing the other of the display states during one frame of operation. 
     
     
       51. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for applying an A.C. electric signal having no D.C. component. 
     
     
       52. A liquid crystal display device as claimed in claim  42 ; wherein the ferro- electric liquid crystal has a thickness sufficiently thin to lose the spiral molecular alignment of the layer.   
     
     
       53. A liquid crystal display device as claimed in claim  42 ; wherein the selecting electric signal comprises an electric voltage signal and the A.C. electric signal comprises an A.C. electric voltage signal. 
     
     
       54. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for applying A.C. electric signals having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       55. A liquid crystal display device as claimed in claim  42 ; wherein the drive means includes means for reducing the amplitude of the A.C. electric signals. 
     
     
       56. A liquid crystal display device as claimed in claim  42 ; wherein the A.C. electric signals each comprise a pair of bipolar pulses occurring within a time period not greater than the time width of said each selecting period of the scanning electrodes. 
     
     
       57. A liquid crystal display device driven in a time- sharing mode, comprising: a ferro - electric liquid crystal aligned to establish two bi - stable display states; and drive means for applying a selected voltage ±V   ap    having a desired pulse amplitude and a pulse width to the liquid crystal in a selected scanning period to change one of the two bi - stable display states to the other bi - stable display state and for applying to the liquid crystal an A.C. pulse voltage having a pulse amplitude and a pulse width at least one of which is less than that of the selected voltage ±V   ap    and wherein the pulse width included in the A.C. pulse voltage does not exceed a time width of the selected scanning period to thereby hold the other bi - stable display state.   
     
     
       58. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying a selected voltage ±V ap    containing a D.C. component.   
     
     
       59. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying a selected voltage ±V ap    containing no D.C. component.   
     
     
       60. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying a selected voltage having a polarity effective to change one of the two bi- stable display states to the other bi - stable display state during a first scanning operation and for applying another selected voltage having another polarity effective to change the other bi - stable display state to said one bi - stable display state during a second scanning operation.   
     
     
       61. A liquid crystal display device as claimed in claim  57 ; wherein the ferro- electric liquid crystal comprises ferro - electric liquid crystal molecules aligned to assume two bi - stable molecular alignments corresponding to the two bi - stable display states, respectively.   
     
     
       62. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for increasing the driving frequency after the drive means carries out a scanning operation for a given number of times. 
     
     
       63. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying to the liquid crystal a selected voltage having a modulated pulse width effective to develop an intermediate display state between the two bi- stable display states.   
     
     
       64. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying a selected voltage signal comprised of a first pulse effective to reset the display state of the liquid crystal to one of the two bi- stable states and a successive second pulse having an opposite polarity effective to change the reset display state to the other bi - stable display state.   
     
     
       65. A liquid crystal display device as claimed in claim  57 ; wherein the driving means includes means for applying to the liquid crystal a selected voltage having a modulated duration effective to develop an intermediate display state between the two bi- stable display states.   
     
     
       66. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for effecting a first scanning operation for writing one of the two bi- stable display states and for effecting a second scanning operation for writing the other bi - stable display state during one frame of operation.   
     
     
       67. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for applying A.C. electric signals having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       68. A liquid crystal display device as claimed in claim  57 ; wherein the drive means includes means for reducing the amplitude of the A.C. electric signals. 
     
     
       69. A liquid crystal display device as claimed in claim  57 ; wherein the A.C. pulses voltage comprises a pair of bipolar pulses occurring within a time period not greater than the time width of the selected scanning period. 
     
     
       70. A ferro- electric liquid crystal electro - optical device comprising: a pair of opposed electrodes; a ferro - electric liquid crystal disposed between the opposed electrodes such that the ferro - electric liquid crystal loses a spiral molecular alignment thereof to establish two bi - stable molecular alignments; drive means for applying to the electrodes in a time - sharing mode a selected electric signal sufficient to change one of the bi - stable molecular alignments of the ferro - electric liquid crystal to the other bi - stable molecular alignment and for applying to the electrodes an A.C. electric signal such that the pulse width of each voltage polarity included in the A.C. electric signal does not exceed a time period of the selected electric signal, the A.C. electric signal having an amplitude and a pulse width insufficient to change one of the bi - stable molecular alignments of the ferro - electric liquid crystal to the other bi - stable molecular alignment and being effective to hold the bi - stable molecular alignment; and a pair of polarizers for sandwiching the ferro - electric liquid crystal.   
     
     
       71. A device as claimed in claim  70 ; wherein the drive means includes means for applying a selected electric signal in the form of a voltage ±V ap    having a given pulse amplitude and a pulse width, and means for applying an A.C. electric signal in the form of an A.C. pulse voltage having a pulse amplitude and a pulse width at least one of which is less than that of the selected voltage ±V   ap . 
     
     
       72. A device as claimed in claim  70 ; wherein the drive means includes means for applying A.C. electric signals having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       73. A device as claimed in claim  70 ; wherein the drive means includes means for applying a selected electric signal containing a D.C. component. 
     
     
       74. A device as claimed in claim  70 ; wherein the drive means includes means for applying a selected electric signal containing no D.C. component. 
     
     
       75. A device as claimed in claim  70 ; wherein the drive means includes means for effecting a first scanning operation for selecting one of the two bi- stable molecular alignments and a second scanning operation for selecting the other bi - stable molecular alignment during one frame of operation.   
     
     
       76. A device as claimed in claim  70 ; wherein the drive means includes means for applying a selected electric signal comprised of a first pulse effective to reset the molecular alignment to one of the bi- stable molecular alignments and a successive second pulse having an opposite polarity effective to change the reset molecular alignment of the other bi - stable molecular alignment.   
     
     
       77. A device as claimed in claim  70 ; wherein the electric signal comprises an electric voltage signal and the A.C. electric signal comprises an A.C. electric voltage signal. 
     
     
       78. A device as claimed in claim  70 ; wherein the drive means includes means for reducing the amplitude of the A.C. electric signals. 
     
     
       79. A device as claimed in claim  70 ; wherein the A.C. electric signal comprises a pair of bipolar pulses occurring within a time period not greater than the time period of the selected electric signal. 
     
     
       80. A device as claimed in claim  70 ; wherein the pair of opposed electrodes comprises a display electrode and a scanning electrode, and wherein the selected electric signal comprises a selecting scanning electrode signal applied to the scanning electrode and a display electrode signal simultaneously applied to the display electrode and wherein the A.C. electric signal is produced by combining the scanning electrode signal and the display electrode signal. 
     
     
       81. A liquid crystal display device driven in a time- sharing mode, comprising:    
       
         a plurality of scanning electrodes and a plurality of display electrodes spaced apart from each other;  
       
         a ferro - electric liquid crystal layer disposed between the scanning electrodes and the display electrodes and having a thickness smaller than a pitch of a spiral alignment of the ferro - electric liquid crystal molecules so that the ferro - electric liquid crystal molecules lose their spiral alignment and re - align in two bi - stable alignments so as to establish two optically distinctive bi - stable states of the liquid crystal layer; and    
         drive means connected to the plurality of scanning electrodes for applying scanning electrode signals and sequentially applying selecting scanning electrode signals to each of the plurality of scanning electrodes and connected to the plurality of display electrodes for applying display electrode signals synchronized with the scanning electrode signals to the plurality of display electrodes to select one of the two bi - stable states and for applying a holding A.C. electric signal to the liquid crystal layer to hold a selected bi - stable state wherein the pulse width of each voltage polarity included in the A.C. electric signals does not exceed a time period of the selecting scanning electrode signals;    
         wherein a pulse of the display electrode signal is shifted according to the intensity of display data to modulate a pulse width of the selecting electrode signal produced by combining the selecting scanning electrode signal and the display electrode signal, and the selecting electrode signals are applied to the layer between the scanning electrode and the display electrode in a selecting period of the scanning electrode for developing an intermediate display state between the two bi - stable display states.   
     
     
       82. A liquid crystal optical device as claimed in claim  81 ; wherein the plurality of scanning electrodes and the plurality of display electrodes are disposed so as to intersect with each other to define a plurality of optical elements at the intersections. 
     
     
       83. A liquid crystal optical device as claimed in claim  82 ; wherein the drive means includes time- sharing means connected between the scanning electrodes and display electrodes to sequentially assign a time slot to each of the optical elements to drive the optical elements in a time - sharing mode.   
     
     
       84. A liquid crystal optical device as claimed in claim  83 ; wherein the time- sharing means includes means for applying a selecting signal to each optical element during the time slot assigned thereto and for applying a holding AC electric signal to each optical element during consecutive time slots assigned to the other optical elements.   
     
     
       85. A liquid crystal optical device as claimed in claim  84 ; wherein the driving means includes means for applying a selecting electric signal having an electric power sufficient to switch one of the two bi- stable states to the other bi - stable state and for applying a holding AC electric signal having an electric power insufficient to switch the bi - stable state so as to hold the bi - stable state.   
     
     
       86. A liquid crystal display device as claimed in claim  81 ; wherein the device comprises a liquid crystal display device. 
     
     
       87. A liquid crystal display device as claimed in claim  81 ; wherein the device comprises a liquid crystal shutter device. 
     
     
       88. A liquid crystal display device as claimed in claim  81 ; wherein the drive means includes means for applying A.C. electric signals having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       89. A liquid crystal display device as claimed in claim  81 ; wherein the drive means includes means for reducing the amplitude of the A.C. electric signals. 
     
     
       90. A liquid crystal display device as claimed in claim  81 ; wherein the holding A.C. electric signal is produced by combining the scanning electrode signals and the display electrode signals. 
     
     
       91. A liquid crystal display device as claimed in claim  45 ; wherein the holding A.C. electric signal comprises a pair of bipolar pulses occurring within a time period not greater than the time period of said each selecting scanning electrode signals. 
     
     
       92. A liquid crystal optical device comprising: a liquid crystal layer comprised of ferro- electric liquid crystal molecules aligned to establish two optically distinctive bi - stable states in the liquid crystal layer; a pair of opposed electrode means sandwiching therebetween the liquid crystal layer; and drive means connected between the pair of electrode means for applying a selecting electric signal to the liquid crystal layer to select one of the two bi - stable states and for applying a holding AC electric signal to the liquid crystal layer to hold the selected bi - stable state, wherein the AC electric signal comprises a pair of bipolar pulses occurring within a time period equal to a period of the selecting electric signal.   
     
     
       93. A liquid crystal optical device as claimed in claim  92 ; wherein the liquid crystal layer has a thickness smaller than a pitch of a spiral alignment of the ferroelectric liquid crystal molecules so that the ferro- electric liquid crystal molecules lose their spiral alignment and re - align in two bi - stable alignments so as to establish the two optically distinctive bi - stable states of the liquid crystal layer.   
     
     
       94. A liquid crystal optical device as claimed in claim  92 ; wherein the pair of opposed electrode means comprise two sets of a plurality of electrodes intersecting with each other to define a plurality of optical elements at the intersections. 
     
     
       95. A liquid crystal optical device as claimed in claim  94 ; wherein the drive means includes time- sharing means connected between the two sets of electrodes to sequentially assign a time slot to each of the optical elements to drive the optical elements in a time - sharing mode.   
     
     
       96. A liquid crystal optical device as claimed in claim  95 ; wherein the time- sharing means includes means for applying a selecting signal to each optical element during the slot assigned thereto and for applying a holding AC electric signal to each optical element during consecutive time slots assigned to the other optical elements.   
     
     
       97. A liquid crystal optical device as claimed in claim  96 ; wherein the means for applying the selecting and holding AC electric signals includes means for applying a selecting electric signal having an electric power sufficient to switch one of the two bi- stable states to the other bi - stable state and for applying a holding AC electric signal having an electric power insufficient to switch the bi - stable state so as to hold the bi - stable state.   
     
     
       98. A liquid crystal optical device as claimed in claim  92 ; wherein the device comprises a liquid crystal display device. 
     
     
       99. A liquid crystal optical device as claimed in claim  92 ; wherein the device comprises a liquid crystal shutter device. 
     
     
       100. A liquid crystal optical device as claimed in claim  92 ; wherein the selecting electric signal comprises a selecting electric voltage signal and the holding AC electric signal comprises a holding AC electric voltage signal. 
     
     
       101. A liquid crystal optical device as claimed in claim  92 ; wherein the drive means includes means for applying a holding AC electric signal having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       102. A liquid crystal optical device as claimed in claim  92 ; wherein the drive means includes means for reducing the amplitude of the holding A.C. electric signal. 
     
     
       103. A liquid crystal optical device as claimed in claim  92 ; wherein the A.C. holding electric signal comprises a pair of bipolar pulses occurring within a time period not greater than the time period of said each selecting signal. 
     
     
       104. A liquid crystal optical device comprising: a liquid crystal layer comprised of ferro- electric liquid crystal molecules aligned to establish two optically distinctive bi - stable states in the liquid crystal layer; a pair of opposed electrode means sandwiching therebetween the liquid crystal layer; and drive means connected between the pair of electrode means for applying a selecting electric signal to the liquid crystal layer to select one of the two bi - stable states and for applying a holding AC electric signal to the liquid crystal layer to hold the selected bi - stable state, wherein the AC electric signal has a pulse width which does not exceed a time period of the selecting electric signal.   
     
     
       105. A liquid crystal optical device as claimed in claim  104 ; wherein the liquid crystal layer has a thickness smaller than a pitch of a spiral alignment of the ferroelectric liquid crystal molecules so that the ferro- electric liquid crystal molecules lose their spiral alignment and re - align in two bi - stable alignments so as to establish the two optically distinctive bi - stable states of the liquid crystal layer.   
     
     
       106. A liquid crystal optical device as claimed in claim  104 ; wherein the pair of opposed electrode means comprise two sets of a plurality of electrodes intersecting with each other to define a plurality of optical elements at the intersections. 
     
     
       107. A liquid crystal optical device as claimed in claim  106 ; wherein the drive means includes time- sharing means connected between the two sets of electrodes to sequentially assign a time slot to each of the optical elements to drive the optical elements in a time - sharing mode.   
     
     
       108. A liquid crystal optical device as claimed in claim  107 ; wherein the time- sharing means includes means for applying a selecting signal to each optical element during the slot assigned thereto and for applying a holding AC electric signal to each optical element during consecutive time slots assigned to the other optical elements.   
     
     
       109. A liquid crystal optical device as claimed in claim  108 ; wherein the means for applying the selecting and holding AC electric signals includes means for applying a selecting electric signal having an electric power sufficient to switch one of the two bi- stable states to the other bi - stable state and for applying a holding AC electric signal having an electric power insufficient to switch the bi - stable state so as to hold the bi - stable state.   
     
     
       110. A liquid crystal optical device as claimed in claim  104 ; wherein the device comprises a liquid crystal display device. 
     
     
       111. A liquid crystal optical device as claimed in claim  104 ; wherein the device comprises a liquid crystal shutter device. 
     
     
       112. A liquid crystal optical device as claimed in claim  104 ; wherein the selecting electric signal comprises a selecting electric voltage signal and the holding AC electric signal comprises a holding AC electric voltage signal. 
     
     
       113. A liquid crystal optical device as claimed in claim  104 ; wherein the drive means includes means for applying a holding AC electric signal having a high frequency sufficient to avoid degradation of the optical transparent intensity of the ferro- electric liquid crystal.   
     
     
       114. A liquid crystal optical device as claimed in claim  104 ; wherein the drive means includes means for reducing the amplitude of the holding A.C. electric signal. 
     
     
       115. A liquid crystal optical device as claimed in claim  104 ; wherein the A.C. holding electric signal comprises a pair of bipolar pulses occurring within a time period not greater than the time period of said each selecting signal. 
     
     
       116. A liquid display device driven in a time- sharing mode, comprising:    
       
         a plurality of scanning electrodes and a plurality of display electrodes spaced apart from each other;  
       
         a ferro - electric liquid crystal layer disposed between the scanning electrodes and the display electrodes such that the layer loses a spiral molecular alignment thereof to establish two bi - stable molecular alignments;    
       
         drive means connected to the plurality of scanning electrodes for applying scanning electrode signals and sequentially applying selecting scanning electrode signals to each of the plurality of scanning electrodes and connected to the plurality of display electrodes for applying display electrode signals synchronized with the scanning electrode signals to the plurality of display electrodes; and  
       
         converting means for converting the two bi - stable molecular alignments to corresponding optical ON and OFF display states, respectively;    
         wherein selecting electrical signals produced by combining the selecting scanning electrode signals and the display electrode signals are applied to the layer between the scanning electrodes and the display electrodes in a selecting period of the scanning electrodes for selecting one of the two bi - stable molecular alignments by sufficiently changing one of the two bi - stable molecular alignments to the other bi - stable molecular alignment and A.C. electric signals produced by combining the scanning electrode signals and the display electrode signals, the A.C. electric signals having an amplitude and a pulse width insufficient to change the bi - stable molecular alignments, and are applied to the layer between the scanning electrodes and the display electrodes in a non - selecting period of the scanning electrodes to hold the selected bi - stable molecular alignment.

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