Liquid Crystal Displays. Ernst Lueder
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with permission by The Society for Information DisplayFigure 14.37 Determination of V1n from a given luminance L0 and from the previous frame value CLC,n − 1 and a family of CLC = Q/VLC hyperbolas with Q-values as parameters. This figure was reproduced from Lueder, E., SID 05 Seminar, p.M-5/9 with permission by The Society for Information DisplayFigure 14.38 Determination of V1n from a given luminance L0, the Q = CLCVLC curve and a family of straight lines for the charges CLC,n − 1VLC with the inclination CLC,n − 1 as parameters. This figure was reproduced from Lueder, E., SID 05 Seminar, p.M-5/9 with permission by The Society for Information DisplayFigure 14.39 The addressing waveform with a voltage pulse providing a boost of torque. This figure was reproduced from Lueder, E., Workshop Asia Display/IMID 04, p. 65 with permission by The Society for Information DisplayFigure 14.40 The addressing waveform for imposing a small pretilt in the previous frame. This figure was reproduced from Song, J. K. et al., SID04, p. 1346with permission by The Society for Information DisplayFigure 14.41 The turn-off and the turn-on time dependent on the voltage for the black stateFigure 14.42 Block diagram for the processing of the DCCII addressing method. This figure was reproduced from Song, J. K. et al., SID 04, p. 1346 with permission by The Society for Information DisplayFigure 14.43 The transient to the on-stage for various PVA based cells. This figure was reproduced from Song, J. K. et al., SID 04, p. 1346 with permission by The Society for Information DisplayFigure 14.44 Plot for intergrey response times of PVA with pretilt and overshoot (DCCII). This figure was reproduced from Song, J. K. et al., SID 04, p. 1346/7 with permission by The Society for Information DisplayFigure 14.45 (a) Cross-section and (b) top view of the CFFS cell. This figure was reproduced from Li, Y. et al., JSID 08, p. 1070 with permission by the Journal of the Society for Information DisplayFigure 14.46 (a) The anticlockwise rotation of an LC molecule towards the white state in the driving field from underneath; (b) the clockwise rotation towards black in an impulse of the E-field from above (relaxation)Figure 14.47 (a) The conventional FFS, (b) the undershoot switching and (c) the CFFS. This figure was reproduced from Li, Y. et al., JSID 08, p. 1071 with permission by the Journal of the Society for Information DisplayFigure 14.48 The decay of luminance to zero for the regular FFS (curve 1) and for CFFS (curve 2)Figure 14.49 The decay from a 100 percent to a 50 percent luminance for the three addressing modes in Figure 14.47: curve 1 for FFS, curve 2 for undershoot switching and curve 3 for CFFS. This figure was reproduced from Li, Y. et al., JSID 08, p. 1072 with permission by the Journal of the Society for Information DisplayFigure 14.50 The decay of luminance from 50 percent to 10 percent for the three addressing modes in Figure 14.49Figure 14.51 Addressing of two subpixels with a two capacitor charge sharing circuit (CS-S-PVA). This figure was reproduced from Park, S. B. et al., SID 07, p. 1252 with permission by The Society for Information DisplayFigure 14.52 Addressing of two subpixels with a one-capacitor charge sharing circuit (CS-PVA)Figure 14.53 Addressing of an array by charge sharing. This figure was reproduced from Kim, S. S., SID 08, p. 197 with permission by The Society for Information DisplayFigure 14.54 Cross-section of a BVA display. This figure was reproduced from Shih, P. S. et al., SID 06, p. 1067 with permission by The Society for Information DisplayFigure 14.55 The minimum bias voltage required in the BVA mode versus the pixel voltage. This figure was reproduced from Shih, P. S. et al., SID 06, p. 1067 with permission by The Society for Information DisplayFigure 14.56 Cross-section of a BVA display with a stacked bias electrode. This figure was reproduced from Shih, P. S. et al., SID 06, p. 1069 with permission by The Society for Information DisplayFigure 14.57 Transmittance versus pixel voltage Vp of a BVA cell. This figure was reproduced from Shih, P. S. et al., SID 06, p. 1068 with permission by The Society for Information DisplayFigure 14.58 Addressing circuit of a BVA cell and dot inversion. This figure was reproduced from Shih P.S. et al. SID 06, p. 1068 with permission by The Society for Information DisplayFigure 14.59 The delayed 10 percent to 90 percent (a) rise and (b) fall of luminance L versus time as a response to a stepwise stimulus (mostly voltage) at an LCDFigure 14.60 Blurred edge width (BEW) of a moving stripe displayed on an LCDFigure 14.61 The smooth pursuit of a movement on an LCDFigure 14.62 The integration and averaging of luminance along the path of smooth pursuitFigure 14.63 The spatial response on the retina to a spatial rectangular impulse of width w and speed υ >; w displayed on an LCDFigure 14.64 The spatial response to a rectangular impulse of width w and speed υ < wFigure 14.65 The spatial response to a rectangular impulse of width w and speed υ presented with a flash of light of duration t0 with
