JP2011150018A5 - - Google Patents

Description

As described above, also in the polymer network liquid crystal display element , it is necessary to perform AC driving by switching the level of the applied voltage. Therefore, the polymer network liquid crystal driving device sets the common electrode driving waveform COM to the first level in the AC cycle. From the second level to the second level, or from the second level to the first level, the segment electrode waveform SEG is displayed in a diffused state (SEG OFF state) or transparent state (SEG ON state). The common electrode drive waveform COM signal is switched between in-phase and anti-phase, and the output is switched from the first level to the second level or from the second level to the first level. It is supposed to be.

On the other hand, when manufacturing a polymer network liquid crystal panel in which the polymer network liquid crystal driving device is made into LSI and COG (Chip On Glass) is mounted on the liquid crystal panel glass, a large number of wiring patterns must be arranged in a limited space. Also in this polymer network liquid crystal panel, it is desired to increase the number of segments and narrow the frame of the polymer network liquid crystal display element to be mounted. For this reason, the wiring pattern is thinned, the interval between adjacent wiring patterns is very small, and the wiring resistance is increased.

As described above, a large current flows when switching to a wiring pattern having such a large wiring resistance, resulting in a large voltage drop, and a sufficient driving voltage cannot be applied to the polymer network liquid crystal display element . There arises a problem that a desired display state cannot be obtained. For this reason, it has been difficult to achieve narrowing of the frame of the polymer network liquid crystal panel in which the polymer network liquid crystal driving device is COG-mounted on the liquid crystal panel glass.

In order to achieve the above object, one aspect of the polymer network liquid crystal driving device of the present invention provides a driving signal that is switched at a predetermined cycle between the first level and the second level, for each segment of the plurality of polymer network liquid crystal display elements. In a polymer network liquid crystal driving device that inputs to an electrode and performs static driving, the plurality of polymer network liquid crystal display elements are grouped into two or more groups, and the first level and the second level of the driving signal Are driven at the same level, and output a ground level signal to a common electrode common to all polymer network liquid crystal display elements, and output to a segment electrode of the polymer network liquid crystal display element included in one group. Switching the level of the signal and the points included in other groups The drive signal output to each segment electrode of the plurality of polymer network liquid crystal display elements so as to be different from each other in switching of the level of the drive signal output to the segment electrode of the mer network liquid crystal display element It is characterized by controlling.
To achieve the above object, according to one aspect of the polymer network liquid crystal driving method of the present invention, a driving signal that is switched at a predetermined period between the first level and the second level is supplied to each of the plurality of polymer network liquid crystal display elements. The plurality of polymer network liquid crystal display elements are grouped into two or more groups when statically driven by inputting to the segment electrodes of the first and second levels of the drive signal. The ground level signal is output to the common electrode common to all polymer network liquid crystal display elements, and the drive signal output to the segment electrode of the polymer network liquid crystal display element included in one group is the same level. Switching of the level and a polymer network liquid crystal display element included in another group Controlling the drive signals to be output to the segment electrodes of the plurality of polymer network liquid crystal display elements so that the levels of the drive signals to be output to the segment electrodes are different from each other. It is characterized by.
In order to achieve the above object, one aspect of the polymer network liquid crystal panel of the present invention is:
A transparent substrate, a plurality of polymer network liquid crystal display element formed on the transparent substrate, wherein is COG-mounted on a transparent substrate, comprising a, a polymer network liquid crystal driving device of the forth and characterized in that To do.

FIG. 1A is a diagram showing a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the first embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. 2 (A) is a diagram for explaining the operation of the de-energized state of the polymer network liquid crystal display element, FIG. 2 (B) is a diagram for explaining the operation in same conductive voltage application. FIG. 3A is a diagram showing an optical path of a single-lens reflex camera for explaining an application example of the polymer network liquid crystal panel according to the first embodiment of the present invention, and FIG. It is a figure which shows the example of a display, and FIG.3 (C) and (D) are the figures for demonstrating the structural example of a polymer network liquid crystal panel, respectively. FIG. 4A is a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the second embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. FIG. 5A is a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the third embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. FIG. 6A is a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the fourth embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. FIG. 7A is a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the fifth embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. FIG. 8 (A) is a diagram showing a timing chart showing an applied voltage waveform at the time of ON display in the polymer network liquid crystal driving device and driving method according to the sixth embodiment of the present invention, and FIG. It is a figure which shows the timing chart showing the applied voltage waveform at the time of OFF display. FIG. 9A is a timing chart showing an applied voltage waveform at the time of ON display in the conventional polymer network liquid crystal driving device and driving method, and FIG. 9B is an applied voltage waveform at the same time of OFF display. It is a figure which shows the timing chart showing.

[First Embodiment]
A first embodiment of the present invention will be described below with reference to FIGS. Here, FIG. 1A is a diagram showing a timing chart showing an applied voltage waveform at the time of ON display in the polymer network (hereinafter abbreviated as PN) liquid crystal driving device and driving method according to the first embodiment. FIG. 1B is also a timing chart showing the applied voltage waveform during OFF display. Also, FIG. 2 (A) is a diagram for explaining the operation of the de-energized state of the PN liquid crystal display device, FIG. 2 (B) is a diagram for explaining the operation at the time same electrostatic voltage application . FIG. 3A is a diagram showing an optical path of a single-lens reflex camera for explaining an application example of the PN liquid crystal panel according to the first embodiment, and FIG. FIGS. 3C and 3D are diagrams for explaining a configuration example of a PN liquid crystal panel.

In such a structure, as shown in FIG. 2A, in a state where no electric field is formed between the common electrode 2 and the segment electrode 4, the liquid crystal molecules 6 dispersed in the PN5 are in any direction. It is suitable. In this case, if the refractive index of PN5 is different from the average refractive index of the liquid crystal molecules 6, the incident light 7 incident from the light source side transparent substrate 1 side is transmitted through the liquid crystal layer while being scattered, and the scattered light 8 is The light is emitted from the observation-side transparent substrate 3. Therefore, since the light incident on the liquid crystal layer in which the liquid crystal molecules 6 are directed in an arbitrary direction is scattered and emitted from the observation side transparent substrate 3 side, the light is observed as cloudy light from the observation side transparent substrate 3 side. .

As shown in FIG. 3C, the PN liquid crystal panel 16 is obtained by COG mounting a display unit 22 and a drive driver 23 on a liquid crystal panel glass 21. Here, the display unit 22 is provided with a plurality of PN liquid crystal display elements, and the liquid crystal panel glass 21 is used as the light source side transparent substrate 1. The drive driver 23 is an PN liquid crystal drive device that is made into an LSI for driving each PN liquid crystal display element. The liquid crystal panel glass 21 is connected to the segment electrode 4 and the common electrode of each PN liquid crystal display element from the drive driver 23. A wiring pattern 25 for supplying power to the common electrode 2 is formed. Further, a wiring for connecting between a flexible substrate 26 configured to supply a control signal from a camera control unit (not shown) configured in the camera body 11 and a terminal unit (not shown ) connected to an ACF (Anisotropic Conducting Film). A pattern 27 is also formed. The ACF connection is a connection form in which electrical connection is performed using an anisotropic conductive film.

By adopting the PN liquid crystal driving method as in the first embodiment, it is possible to disperse the current that flows when the level of the driving waveform in the static driving method is switched, that is, the current concentration can be suppressed. The drive voltage drop due to the large current is reduced. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

By adopting the PN liquid crystal driving method as in the second embodiment, the direction of the current flowing when the level of the driving waveform in the static driving method can be canceled without being made constant, that is, current concentration can be suppressed. As a result, the drive voltage drop due to a large current during level switching is reduced. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

By adopting the PN liquid crystal driving method as in the third embodiment, it is possible to disperse the current that flows when the level of the driving waveform in the static driving method is switched and cancel the current direction without making it constant. That is, since current concentration can be suppressed, a drop in drive voltage due to a large current at the time of level switching is reduced. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

By adopting the PN liquid crystal driving method as in the fourth embodiment, it is possible to disperse the current that flows when the level of the driving waveform in the static driving method is switched, as in the first embodiment. Since it can be suppressed, the drive voltage drop due to a large current at the time of level switching is reduced. Further, in the present embodiment, when the level of the drive waveform in the static drive method is switched, the signal that is output to the segment electrode is once set to the ground level signal state, so that the flowing current can be reduced. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

Also, off-display (diffusion state) at times, as shown in FIG. 7 (B), the segment electrode waveform SEG-A, SEG-B together, as with the common electrode driving waveform COM, while the voltage 0V (ground level) and To do.

By adopting the PN liquid crystal driving method as in the fifth embodiment, it is possible to cancel without making the direction of the current flowing at the time of switching the drive waveform level in the static driving method constant, as in the second embodiment. That is, since current concentration can be suppressed, a drop in drive voltage due to a large current at the time of level switching is reduced. Furthermore, in the present embodiment, when the level of the drive waveform in the static drive method is switched, the signal output to the segment electrode is once set to the ground level signal state, so that the flowing current can be reduced and the PN belonging to one group. The charge accumulated in the liquid crystal display element can be reused for charging the PN liquid crystal display element belonging to the other group, which contributes to power saving. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

When the predetermined period elapses and the segment electrode waveforms SEG-A and SEG-B are switched, the segment electrode waveform SEG-A is temporarily changed from the voltage Vseg- which is the first level to 0 V (ground). At the same time, the segment electrode waveform SEG-B is temporarily switched from the second level voltage Vseg + to 0 V (ground level). Thereafter, the segment electrode waveform SEG-A is switched from its 0V (ground level) to the second level voltage Vseg +, and at the same time, the segment electrode waveform SEG-B is changed from its 0V (ground level) to the first level. Switch to voltage Vseg-. During the level switching of the segment electrode waveforms SEG-A and SEG-B, the segment electrode waveform SEG-C remains at the first level voltage Vseg-, and the segment electrode waveform SEG-D is the second level. The voltage Vseg +, which is a level of If the levels of the segment electrode waveforms SEG-A and SEG-B are switched, then the segment electrode waveform SEG-C is temporarily switched from the first level voltage Vseg- to 0 V (ground level). At the same time, the segment electrode waveform SEG-D is temporarily switched from the second level voltage Vseg + to 0 V (ground level). Thereafter, the segment electrode waveform SEG-C is switched from the 0 V (ground level) to the second level voltage Vseg +, and at the same time, the segment electrode waveform SEG-D is changed from the 0 V (ground level) to the first level. Switch to voltage Vseg-. During the level switching of the segment electrode waveforms SEG-C and SEG-D, the segment electrode waveform SEG-A remains at the second level voltage Vseg +, and the segment electrode waveform SEG- B is the first level. The voltage Vseg− which is a level remains. Thus, the segment electrode waveforms SEG-A, SEG-B, SEG-C, and SEG-D are switched in the positive and negative directions.
The above level switching is performed alternately.

By adopting the PN liquid crystal driving method as in the sixth embodiment, as in the third embodiment, it is possible to disperse the current that flows when the level of the driving waveform in the static driving method is switched, and the direction of the current is constant. It is possible to cancel without setting, that is, current concentration can be suppressed, so that a drop in drive voltage due to a large current at the time of level switching is reduced. Further, in the present embodiment, when the level of the drive waveform in the static drive method is switched, the signal output to the segment electrode is once set to the ground level signal state, so that the flowing current can be suppressed small and the PN liquid crystal belonging to a certain group The charge accumulated in the display element can be reused for charging the PN liquid crystal display elements belonging to other groups, which contributes to power saving. Therefore, the PN liquid crystal display device, since as Ru can apply a sufficient voltage to the desired display state, a narrow frame PN liquid crystal panel in which the driver 23 has been turned into LSI on the liquid crystal panel glass 21 and COG mounting Can be manufactured.

Claims (14)

In a polymer network liquid crystal driving device that performs static driving by inputting a driving signal that switches between a first level and a second level at a predetermined period to each segment electrode of a plurality of polymer network liquid crystal display elements,
The plurality of polymer network liquid crystal display elements are grouped into two or more groups,
The first level and the second level of the drive signal are set to the same level of positive and negative,
A ground level signal is output to the common electrode common to all polymer network liquid crystal display elements.
Switching the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in one group;
Switching the level of the drive signal to be output to the segment electrode of a polymer network liquid crystal display element included in another group;
And controlling the drive signal output to each segment electrode of the plurality of polymer network liquid crystal display elements so as to be in different states.
A polymer network liquid crystal driving device. The different states are
Timing of switching the level of the drive signal to be output to a segment electrode of a polymer network liquid crystal display element included in one group;
Timing of switching the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in another group;
2. The polymer network liquid crystal driving device according to claim 1, wherein the timings do not overlap each other. Furthermore, the polymer network liquid crystal display elements included in each group are grouped into two subgroups,
The switching direction of the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in one subgroup,
A person direction you switch the positive and negative of the level of the drive signal output to segment electrodes of the polymer network liquid crystal display element included in the other subgroups,
The polymer network liquid crystal driving device according to claim 2, wherein the liquid crystal driving device is in the opposite direction. The different states are
Positive / negative switching direction of the level of the drive signal output to the segment electrode of the polymer network liquid crystal display element included in one group;
Switches and towards direction e of the positive and negative of the level of the drive signal output to segment electrodes of the polymer network liquid crystal display element included in the other groups,
The polymer network liquid crystal driving device according to claim 1, wherein the directions are opposite directions. Furthermore, the switches example towards direction is in the plurality of positive and negative inverse of the group pairs, polymer network liquid crystal driving device according to claim 4, characterized in that varying the timing of switching of each group pair to each other. As the drive signal to be output to the segment electrode, when the level is switched from the first level to the second level, the signal state at the ground level is temporarily output from the signal state at the first level for a predetermined time. And then outputting a signal that is in the second level signal state;
As the drive signal to be output to the segment electrode, a signal level of the first level is output after a ground level signal state is once output for a predetermined time when the level is switched from the second level to the first level. Outputting a signal to become a state,
Polymer network liquid crystal driving device according to any of claims 1 to 5, characterized in that performing at least one of.   7. The polymer network liquid crystal driving device according to claim 1, wherein the polymer network liquid crystal driving device is COG-mounted on a transparent substrate on which the plurality of polymer network liquid crystal display elements are formed. When a driving signal that is switched at a predetermined period between the first level and the second level is input to each segment electrode of a plurality of polymer network liquid crystal display elements to perform static driving,
The plurality of polymer network liquid crystal display elements are grouped into two or more groups,
The first level and the second level of the drive signal are set to the same level of positive and negative,
A ground level signal is output to the common electrode common to all polymer network liquid crystal display elements.
Switching the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in one group;
Switching the level of the drive signal to be output to the segment electrode of a polymer network liquid crystal display element included in another group;
And controlling the drive signal output to each segment electrode of the plurality of polymer network liquid crystal display elements so as to be in different states.
The polymer network liquid crystal drive method characterized by the above-mentioned. The different states are
Timing of switching the level of the drive signal to be output to a segment electrode of a polymer network liquid crystal display element included in one group;
Timing of switching the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in another group;
The polymer network liquid crystal driving method according to claim 8, wherein the timings are not overlapping each other. Furthermore, the polymer network liquid crystal display elements included in each group are grouped into two subgroups,
The switching direction of the level of the drive signal to be output to the segment electrode of the polymer network liquid crystal display element included in one subgroup,
The direction of positive / negative switching of the level of the drive signal output to the segment electrode of the polymer network liquid crystal display element included in the other subgroup;
10. The polymer network liquid crystal driving method according to claim 9, wherein the directions are opposite directions. The different states are
Positive / negative switching direction of the level of the drive signal output to the segment electrode of the polymer network liquid crystal display element included in one group;
Switches and towards direction e of the positive and negative of the level of the drive signal output to segment electrodes of the polymer network liquid crystal display element included in the other groups,
9. The polymer network liquid crystal driving method according to claim 8, wherein the directions are opposite directions. Furthermore, the switches example towards direction is in the plurality of positive and negative inverse of the group pairs, polymer network liquid crystal driving method according to claim 11, wherein varying the timing of switching of each group pair to each other. As the drive signal output to the segment electrode,
When the level is switched from the first level to the second level, a ground level signal state is temporarily output from the first level signal state for a predetermined time, and then the second level signal state is output. Output a signal that becomes
As the drive signal to be output to the segment electrode, a signal level of the first level is output after a ground level signal state is once output for a predetermined time when the level is switched from the second level to the first level. Outputting a signal to become a state,
13. The polymer network liquid crystal driving method according to claim 8 , wherein at least one of the following is performed. A transparent substrate;
A plurality of polymer network liquid crystal display elements formed on the transparent substrate;
The polymer network liquid crystal driving device according to any one of claims 1 to 6, which is COG-mounted on the transparent substrate;
It comprises a,
A polymer network liquid crystal panel characterized by that.