The present invention relates to a liquid crystal apparatus having a liquid crystal panel that uses ferroelectric liquid crystal.
Recently, liquid crystal apparatuses employing a liquid crystal panel are used in various manufactured products such as, for example, flat screen televisions, mobile telephones, tablet terminals, and liquid crystal shutters. Although this liquid crystal panel employing a liquid crystal apparatus typically uses a nematic liquid crystal, the response speed is several msec or greater and this slow response speed often poses problems. In particular, when a liquid crystal panel is used as an optical shutter in, for example, a laser projector, high-speed response is required and commonly known liquid crystal panels (hereinafter, ferroelectric liquid crystal panel) use ferroelectric liquid crystal as a liquid crystal material that satisfies this requirement.
[Description of ferroelectric liquid crystal display panel:
Here, although common knowledge, an overview of the behavior of ferroelectric liquid crystal and architecture of a ferroelectric liquid crystal panel capable of high-speed response will be described to aid in the understanding of the present invention. While ferroelectric liquid crystals include materials that have memory properties and materials that have no memory properties, the liquid crystal panel of the liquid crystal apparatus described here is taken as an example of architecture using a material of ferroelectric liquid crystal having no memory properties.
A structure of a liquid crystal panel that employs ferroelectric liquid crystal will be described with reference to
Here, in (a) of
In
On the outer side of the glass substrate 103a, as described above, the first polarizing film 101a is provided such that the molecular long axis direction of the first or the second state of the ferroelectric liquid crystal layer 102 is parallel; and on the outer side of the glass substrate 103b, the second polarizing film 101b is provided such that there is a 90 degree difference with the polarization axis of the first polarizing film 101a.
Operation of the liquid crystal panel 100 using ferroelectric liquid crystal will be described. When driving voltage VD applied to the liquid crystal panel 100 varies, optical transmissivity L of the light Lt (refer to (b) of
The optical transmissivity L ratio of the first state (non-transmission: black display) and the second state (transmission: white display) is the contrast ratio described above, and the greatest contrast ratio is when the switching angle θ of the molecular long axis direction is 45 degrees.
Thus, when driving voltage greater than or equal to the threshold of the ferroelectric liquid crystal is applied, the second state is selected for the liquid crystal panel 100 and when driving voltage greater than or equal to the threshold of the reverse polarity of the ferroelectric liquid crystal is applied, the first state is selected.
As a result, as depicted in (a) of
Thus, a liquid crystal panel that uses ferroelectric liquid crystal can select between the non-transmission state and the transmission state (the two states that switch the long axis direction of the liquid crystal molecule), switching the polarity of the driving voltage VD between positive and negative. The speed of transition between these two states (i.e., response speed) is a high speed of a few tens of μsec to a few hundred μsec and thus, is suitable for liquid crystal panels that require a high-speed response and ferroelectric liquid crystal panels are used in display elements, liquid crystal shutters, etc.
(for example, refer to Patent Document 1 below).
In Patent Document 1, a ferroelectric liquid crystal element is disclosed in which, in a first frame, a positive voltage pulse is applied during a first interval, which is a given period, and a positive voltage pulse that is smaller than the voltage pulse of the first interval is applied during a second interval that is a period longer than the first interval; and in a second frame, a negative voltage pulse is applied during the first interval that is a given period, and a negative voltage pulse that is smaller than the voltage pulse of the second interval is applied during the second interval that is a period longer than the first interval, the ferroelectric liquid crystal element adjusting the intensity of transmitted light to realize a high contrast ratio by changing the value of the applied voltage of the second interval of the first frame.
Patent Document 1: Japanese Patent No. 2665331 (page 3, FIG. 4)
Nonetheless, ferroelectric liquid crystal having the characteristic of high-speed response is temperature dependent and the response speed, which is the transition speed between states, has a characteristic of becoming slow when the temperature decreases and becoming fast when the temperature increases. Further, the switching angle θ of the molecular long axis direction increases when the temperature decreases and decreases when the temperature increases. Moreover, if the temperature is constant and the driving voltage to the ferroelectric liquid crystal made high, the response speed slows and the switching angle θ has a characteristic becoming large (details of the temperature characteristics and voltage characteristics of the ferroelectric liquid crystal will be described hereinafter).
Concerning performance generally required of a ferroelectric liquid crystal panel, the switching angle θ is required to be 45 degrees to maximize the contrast ratio as described above and the response speed is required to be as fast as possible.
However, for example, when the driving voltage is selected to obtain a 45-degree switching angle θ at a low temperature, a problem arises in that the switching angle θ becomes too small at high temperatures (refer to (b-1) of
Thus, since the ferroelectric liquid crystal panel is temperature dependent, when used over a wide temperature range, both the required response speed and switching angle cannot be achieved and therefore, realization of a liquid crystal apparatus having a response speed and switching angle that satisfy required performance is difficult. Further, orientation stability of the ferroelectric liquid crystal is temperature dependent and particularly when a high driving voltage is applied, a problem arises in that orientation deformation occurs more easily in states of high temperature.
Here, the driving method of the ferroelectric liquid crystal display element disclosed in Patent Document 1 does not consider such temperature dependencies of ferroelectric liquid crystal and therefore, the response speed and switching angle fluctuate consequent to temperature changes, inviting graduated changes and drops in the contrast ratio as well as drops in the response speed and the possibility of a significant problem occurring in the display quality. In particular, when a wide operating temperature range is required, the temperature dependency of ferroelectric liquid crystal cannot be ignored and even when the temperature varies greatly, the response speed and switching angle need to achieve the required performance.
To solve the problems above, one object of the present invention is to provide a liquid crystal apparatus that includes a ferroelectric liquid crystal panel that operates having a response speed and switching angle that over the operating temperature range, achieve the required performance.
The present invention is characterized in that a liquid crystal apparatus having a liquid crystal panel that uses a ferroelectric liquid crystal, a drive circuit that supplies a driving voltage to the liquid crystal panel, a waveform generation circuit that supplies a waveform signal to the drive circuit, and a control circuit that controls the waveform generation circuit further includes a sensor that measures temperature, where the drive circuit, in a first frame of the driving voltage, outputs during a first interval, a first voltage that is positive and outputs during a second interval that is longer than the first interval, a second voltage that is positive; and in a second frame, outputs during the first interval, the first voltage that is negative and outputs during the second interval that is longer than the first interval, the second voltage that is negative. The control circuit varies the first voltage and the second voltage according to the temperature measured by the sensor.
In this case, preferably, the control circuit varies the first voltage according to the temperature measured by the sensor, such that a response speed of the liquid crystal panel is stable at a given value.
Preferably, the control circuit further varies the second voltage according to the measured temperature, such that a switching angle of the ferroelectric liquid crystal is stable at a given value.
Preferably, the control circuit generates from temperature characteristics of a response speed of the liquid crystal panel and of a switching angle of the ferroelectric liquid crystal, a table of the first voltage and the second voltage for obtaining a given response speed and switching angle, refers to the table according to the measured temperature, and determines the first voltage and the second voltage.
Preferably, the table is structured having values of the first voltage and the second voltage at a given temperature step, and in a temperature region lower than a temperature at which the first voltage and the second voltage determined by the table become equivalent, when the measured temperature is between temperature steps of the table, a voltage value of a temperature step on a low temperature side is selected as the first voltage, and a voltage that corresponds to the measured temperature is employed as the second voltage.
Preferably, the table is structured having values of the first voltage and the second voltage at a given temperature step, and in a temperature region higher than a temperature at which the first voltage and the second voltage determined by the table become equivalent, a voltage that corresponds to the measure temperature is employed as the second voltage and the first voltage is set to a voltage value equivalent to the second voltage.
A pulse width of the first interval of the first frame and the second frame, respectively, may be determined according to the response speed of the liquid crystal panel.
According to the present invention, a liquid crystal apparatus can be provided that includes a ferroelectric liquid crystal panel that by respectively varying according to temperature, a first voltage and a second voltage of the driving voltage, achieves required performance with respect to temperature changes and has a high response speed and optimal switching angle. Further, a liquid crystal apparatus can be provided that by adjusting the driving voltage according to the required response speed and switching angle, does not apply high voltage exceeding that which is necessary and therefore, realizes uniform switching operation without unevenness and prevents the occurrence of orientation deformation.
Embodiments of the present invention will be described in detail with reference to the accompanying drawings.
An overview of overall architecture of a liquid crystal apparatus according to the present invention will be described with reference to
The ferroelectric liquid crystal panel 10 has the same architecture and operation as the liquid crystal panel 100 depicted in
The input circuit 70 receives display information, control information, etc. from an external apparatus (not depicted) and supplies the input signal P1 to the control circuit 40. The memory circuit 50 is configured by non-volatile memory and stores tables and the like for determining voltage values for the driving voltage, details will be described hereinafter. The temperature sensor 60 is configured by a semiconductor sensor, measures the ambient temperature, and outputs the temperature signal P2. Here, the drive circuit 20, the waveform generation circuit 30, the control circuit 40, the memory circuit 50, the input circuit 70, etc. may be configured by, for example, a single-chip microcomputer, a specifically customized IC, and the like.
An overview of internal architecture of the waveform generation circuit 30, which is one component of the liquid crystal apparatus 1, will be described with reference to
The D/A circuit 31a receives a voltage control signal P4a that is of digital information and a part of the control signal P4, performs digital-to-analog conversion based on a given reference voltage VR from the reference power source 32, and outputs a positive voltage V1 that has been converted to an analog value. The voltage V1 is a positive first voltage V1 of the driving voltage VD described hereinafter. Further, the inverter circuit 34a receives the voltage V1, inverts the voltage polarity, and outputs a negative voltage V3. The voltage V3 is a negative first voltage V3 of the driving voltage VD described hereinafter.
Similarly, the D/A circuit 31b receives a voltage control signal P4b that is of digital information and a part of the control signal P4, performs digital-to-analog conversion based on the given reference voltage VR from the reference power source 32, and outputs a positive voltage V2. The voltage V2 is a positive second voltage V2 of the driving voltage VD described hereinafter. Further, the inverter circuit 34b receives the voltage V2, inverts the voltage polarity, and outputs a negative voltage V4. The voltage V4 is a negative second voltage V4 of the driving voltage described hereinafter.
The timing generator circuit 33 receives a timing control signal P4c that is of digital information and a part of the control signal P4 and outputs a timing signal P44 based on the timing control signal P4c. The timing signal P44 is a signal that determines the length of each interval of the driving voltage VD.
The switch circuit 35 receives the voltages V1 to V4 and the timing signal P44, switches the voltages V1 to V4 according to the timing signal P44, outputs and supplies the waveform signal P5 that is the source of the voltage waveform of the driving voltage VD, to the drive circuit 20 described above. The drive circuit 20 receives the waveform signal P5 and outputs the driving voltage VD of a low impedance output that drives the ferroelectric liquid crystal panel 10 (refer to
An example of temperature characteristics and voltage characteristics for a response speed S and the switching angle θ of the ferroelectric liquid crystal panel 10 used by the liquid crystal apparatus of the present invention will be described with reference to
Table 1-1 of
Further, Table 2-1 of
In
In
As can be understood from (a-1) in
In
Further, as described above, although the contrast ratio is maximized when the switching angle θ=45 degrees, as can be clearly understood from this graph, the switching angle θ deviates from 45 degrees when the voltage value of the driving voltage is too high and when too low.
Accordingly, the switching angle θ has an optimal driving voltage for a given temperature.
An example of a voltage waveform of the driving voltage VD that drives the ferroelectric liquid crystal panel 10 of the present embodiment will be described with reference to
Further, the second frame is includes a first interval during which the negative first voltage V3 is applied and a second interval during which the negative second voltage V4 is applied, the second interval being an interval that is longer than the first interval. The absolute values of the first voltage V1 of the first frame and of the first voltage V3 of the second frame are set equivalently, and the absolute values of the second voltage V2 of the first frame and of the second voltage V4 of the second frame are set equivalently.
The first interval of the first frame is defined as pulse width PW1 and the second interval of the first frame is defined as pulse width PW2. Further, the first interval of the second frame is defined as pulse width PW3 and the second interval of the second frame is defined as pulse width PW4. The respective pulse widths are set to be PW1<PW2, PW3<PW4, PW1=PW3, PW2=PW4. Thus, the voltage and pulse width of the first frame and second frame are set whereby, the ferroelectric liquid crystal panel 10 is driven by alternating current without application of a direct current component.
The voltage values of the positive first voltage V1 (hereinafter, the first voltage V1) of the first interval of the first frame and the negative first voltage V3 (hereinafter, the first voltage V3) of the first interval of the second frame of the driving voltage VD1 can be varied according to temperature and further, the voltage values of the positive second voltage V2 (hereinafter, the second voltage V2) of the second interval of the first frame and the negative second voltage V4 (hereinafter, the second voltage V4) of the second interval of the second frame can be varied according to temperature whereby, characteristics of both the response speed S and the switching angle θ of the ferroelectric liquid crystal panel 10 can be maintained substantially constant with respect to temperature fluctuations and in keeping with required performance, a significant feature of the present invention.
More specifically, the ability to vary the first voltage V1 and the first voltage V3 according to temperature allows control to be performed such that over the operating temperature range, the response speed S of the ferroelectric liquid crystal panel 10 achieves required performance stably. Further, the ability to vary the second voltage V2 and the second voltage V4 according to temperature allows control to be performed such that over the operating temperature range, the switching angle θ of the ferroelectric liquid crystal panel 10 achieves required performance stably. Control to vary the first voltages V1, V3, and the second voltages V2, V4 of the driving voltage VD1 is implemented by the control circuit 40 described hereinafter controlling the waveform generation circuit 30.
Operation of the ferroelectric liquid crystal panel 10 by the driving voltage VD1 will be described with reference to
In
Next, at the first interval of the second frame, the negative first voltage V3 is applied and consequently, the ferroelectric liquid crystal panel 10 enters the first state (non-transmission state by long axis direction E of liquid crystal molecules (refer to (a) of
Operational changes of the ferroelectric liquid crystal panel 10 accompanying changes in the voltage value of the driving voltage VD1 will be described with reference to
In
Here, as depicted, the slope of the rising edge and falling edge in the first intervals is greater for the optical transmissivity L11 consequent to the application of the driving voltage VD11 than for the optical transmissivity L1. This is consequent to the response speed S of the ferroelectric liquid crystal becoming faster, as indicated by the graphs of (a-1) and (a-2) in
Further, since the second voltage V21 of the driving voltage VD11 is higher than the second voltage V2 of the driving voltage VD1, the switching angle θ of the ferroelectric liquid crystal becomes too large relative to 45 degrees and the optical transmissivity drops as indicated by the graphs of (b-1) and (b-2) in
As depicted, the slope of the rising edge and falling edge of the first intervals is smaller for the optical transmissivity L12 consequent to application of the driving voltage VD12 than for the optical transmissivity L1. This is consequent to the response speed S of the ferroelectric liquid crystal becoming slower as indicated by the graphs of (a-1) and (a-2) in
Further, since the second voltage V22 of the driving voltage VD12 is lower than the second voltage V2 of the driving voltage VD1, the switching angle θ of the ferroelectric liquid crystal becomes to small relative to 45 degrees and the optical transmissivity drops as indicated by the graphs of (a-1) and (a-2) in
Thus, the first voltages V1, V3 of the head first interval of the first frame and the second frame of the driving voltage VD1 greatly affect the response speed S of the ferroelectric liquid crystal panel 10 and therefore, by enabling the first voltages V1, V3 to be varied, the response speed S can be adjusted. Further, the second voltages V2, V4 of the second interval after the first interval of the first frame and the second frame of the driving voltage VD1 greatly affect the switching angle θ of the ferroelectric liquid crystal panel 10 and therefore, by enabling the second voltages V2, V4 to be varied, the switching angle θ can be optimally adjusted, enabling the optical transmissivity L to be increased (i.e., enabling the contrast ratio to be increased).
The response speed S and the switching angle θ of the ferroelectric liquid crystal panel 10 has voltage characteristics such as those above and the liquid crystal apparatus of the present invention uses the voltage characteristics of such a ferroelectric liquid crystal panel as the ferroelectric liquid crystal panel 10 and, by enabling the first voltages V1, V3 of the driving voltage VD1 to be varied, can correct the temperature characteristics of the response speed S and by enabling the second voltages V2, V4 of the driving voltage VD1 to be varied, can correct the temperature characteristics of the switching angle θ.
An operation example of an embodiment of the liquid crystal apparatus according to the present invention will be described with reference to the flowchart in
In the flowchart depicted in
In the present example, the obtaining of the temperature characteristics of the ferroelectric liquid crystal panel 10 (ST1 and ST2) need not be performed internally by the liquid crystal apparatus 1 and suffices to be by connection of the ferroelectric liquid crystal panel 10 to an external measuring apparatus though not depicted.
Next in the flowchart depicted in
Next, the control circuit 40 of the liquid crystal apparatus 1 generates by computation from the stored data of the temperature characteristics of the response speed S and switching angle θ, a table of the first voltages V1, V3 and the second voltages V2, V4 of the driving voltage for obtaining the required response speed S and switching angle θ over the operating temperature range and stores the tables to the memory circuit 50 (step ST4). Detailed description of table generation will be given hereinafter.
The control circuit 40 of the liquid crystal apparatus 1 determines the pulse width PW1 for the first interval and the pulse width PW2 for the second interval from the response speed S (step ST5). Detailed description of determination of the pulse width PW1 for the first interval and the pulse width PW2 for the second interval will be described hereinafter.
The control circuit 40 of the liquid crystal apparatus 1 receives the temperature signal P2 from the temperature sensor 60 (refer to
The control circuit 40 of the liquid crystal apparatus 1, from the table generated at step ST4, stores as a cross temperature Tcp, the temperature at which the voltage value of the first voltage V1 and the voltage value of the second voltage V2 cross, and determines if the cross temperature Tcp is greater than or equal to the measured temperature obtained at the step ST6 (ST7). Here, if the determination is negative (less than Tcp), the control circuit 40 proceeds to step ST8; and if the determination is positive (greater than or equal to Tcp), the control circuit 40 proceeds to step ST10.
At step ST7, if a negative determination is made, the control circuit 40 of the liquid crystal apparatus 1 determines the first voltage V1 from the table (step ST8). The control circuit 40 of the liquid crystal apparatus 1 determines the second voltage V2 from the table and proceeds to step ST11 (step ST9). Detailed description of determination concerning the cross temperature Tcp (ST7), and determination of the first voltage V1 and the second voltage V2 (ST8, ST9) will be given hereinafter.
At step ST7, if a positive determination is made, the control circuit 40 of the liquid crystal apparatus 1 determines the second voltage V2 from the table and further sets the first voltage V1=the second voltage V2, and proceeds to step ST11 (step ST10). Detailed description of determination of the second voltage V2 (ST10) will be given hereinafter.
The control circuit 40 of the liquid crystal apparatus 1 outputs as the control signal P4, digital information of PW1, PW2, V1, and V2, which are parameters of the determined driving voltage VD; and the waveform generation circuit 30 receives the control signal P4, internally generates the voltage waveform of the driving voltage VD, and outputs the voltage waveform as the waveform signal P5, to the drive circuit 20. The drive circuit 20 receives the waveform signal P5, converts the waveform signal P5 to the driving voltage VD of a low impedance, outputs the driving voltage VD, and drives the ferroelectric liquid crystal panel 10 (step ST11: refer to
Here, the D/A circuit 31a of the waveform generation circuit 30 described above generates the first voltage V1 and the D/A circuit 31b of the waveform generation circuit 30 generates the second voltage V2. Further, the inverter circuits 34a, 34b of the waveform generation circuit 30 described above respectively generate the first voltage V3 and the second voltage V4, which are negative voltages. The timing generator circuit 33 of the waveform generation circuit 30 generates the pulse widths PW1, PW2, and PW3, PW4 (refer to
The control hereafter involves returning to step ST6 from step ST11, recursively executing step ST6 to step ST11, and varying V1, V2, V3, and V4 according to temperature changes measured by the temperature sensor 60, whereby the response speed S and switching angle θ that achieve the required performance can be maintained stably with respect to temperature.
Details of the generation of the table of the first voltage V1 and the second voltage V2 at step ST4 in the flowchart described above (refer to
Hereinafter, although the case (corresponds to
The control circuit 40 of the liquid crystal apparatus 1 extracts necessary data from among the temperature characteristics and voltage characteristics of the response speed S (
The control circuit 40 calculates from the extracted data of the response speed S ((a-1) of
The control circuit 40 extracts the necessary data from among the temperature characteristics and voltage characteristics of the switching angle θ (
The control circuit 40 calculates from the extracted data of the switching angle θ ((b-1) of
Since the temperature step of Table T1 is coarse when 10° C., the control circuit 40 supplements the first voltage V1 and the second voltage V2 for the temperatures therebetween by computation by an arbitrary step and generates Table T2. Here, as one example, supplementation is performed at 35° C., 45° C., and 55° C.; and Table T2 of temperature steps of 5° C. within a temperature range of 30° C. to 60° C. is generated ((b-1) of
Here, the first voltage V1 of Table T2 in (b-1) of
In a case where even more precise control with respect to temperature is to be performed, the temperature step of Table T2 may be further refined, however, in this case, the measurement data depicted in Table 1-1 and Table 2-1 in
Determination of the pulse width PW1 of the first interval and of the pulse width PW2 of the second interval at step ST5 in the flowchart (refer to
Further, the pulse width PW2 of the second interval is determined by the interval of the first frame-PW1 and as described above, setting is performed such that PW1=PW3, PW2=PW4 and therefore, if the pulse widths PW1, PW2 are determined, the pulse widths PW3, PW4 are also automatically determined.
Here, as one example, the interval of the first frame is assumed to be 10 msec, and the first interval pulse width PW1=140 μsec is assumed. In this case, the pulse width PW2 of second interval is 10 msec-140 μsec=9.86 msec. Thus, the pulse widths PW1 to PW4 are determined by the frame interval and the response speed S required of the ferroelectric liquid crystal panel 10.
[Description of Determination of V1, V2 when Measured Temperature is less than Cross Temperature Tcp:
Details of the determination of the first voltage V1 and the second voltage V2 at steps ST8, ST9 executed when the measured temperature is less than the cross temperature Tcp, at step ST7 in the flowchart (refer to
Here, as one example, in a case where the measured temperature is 37° C., at step ST7 in the flowchart, the measured temperature is determined to be less than the cross temperature Tcp and the control proceeds to step ST8. Subsequently, at step ST8, the control circuit 40 uses the measured temperature to refer to Table T2 and determine the first voltage V1, however, if the measured temperature is between temperature steps of Table T2, the first voltage V1 suffices to employ the voltage value of the first voltage V1 of the temperature step on the side lower than the measured temperature.
More specifically, the control circuit 40 refers to Table T2, determines that the measured temperature of 37° C. (white circle S1 in (b-1) of
Further, as another example, in a case where the measured temperature is 40° C., at step ST7 in the flowchart, the measured temperature is determined to be less than the cross temperature Tcp and the control proceeds to step ST8. Subsequently, at step ST8, the control circuit 40 refers to Table T2, determines that the measured temperature of 40° C. coincides with the 40° C. temperature step, and employs the first voltage V1=2.4V that corresponds to the 40° C. temperature step (refer to (b-1) of
Thus, at step ST8, when a measured temperature is between temperature steps of Table T2, as the first voltage V1, which determines the response speed S, the voltage value of the first voltage V1 that corresponds to the temperature step on the side lower than the measured temperature is employed; and when the measured value coincides with a temperature step of Table T2, the value of the first voltage V1 that corresponds to the temperature step is employed.
Subsequently, at step ST9, when the measured value is between temperature steps of Table T2, as the second voltage V2, which determines the switching angle θ, the control circuit 40 suffices to supplement and calculate the second voltage V2 corresponding to the measured temperature and determine the second voltage V2.
More specifically, when the measured temperature is 37° C., the control circuit 40 refers to Table T2 and determines that the measured temperature of 37° C. is between the 35° C. temperature step and the 40° C. temperature step (white circle S2 in (b-1) of
Further, when the measured temperature coincides with a temperature step of Table T2, as might be expected, no supplementation is necessary and it suffices to employ the voltage value of the second voltage V2 that corresponds to the temperature step.
[Description of Determination of V1, V2 Greater than or Equal to Cross Temperature Tcp:
Details of the determination of the first voltage V1 and the second voltage V2 at step ST10 executed when the measured temperature is greater than or equal to the cross temperature Tcp at step ST7 in the flowchart (refer to
Here, as one example, when the measured temperature is 55° C., at step ST7 in the flowchart, the measured temperature is determined to be greater than or equal to the cross temperature Tcp and the control proceeds to step ST10. Subsequently, at step ST10, the control circuit 40 refers to Table T2, determines that the measured temperature of 55° C. coincides with the 55° C. temperature step of Table T2, and employs the second voltage V2=2.25V that corresponds to the 55° C. temperature step (refer to (b-1) of
Further, when the measured temperature is between temperature steps of Table T2, similar to a case where the measured temperature is less than the cross temperature Tcp, the control circuit 40 supplements and determines the second voltage V2 by computation corresponding to the measured temperature and sets the first voltage V1 to be equivalent to the second voltage V2.
[Description of Driving Voltage VD2 when Measured Temperature is Greater than or Equal to Cross Temperature Tcp:
An example of the voltage waveform of the driving voltage VD2 in a case where the measured temperature is the cross temperature Tcp or greater will be described with reference to
Here, when the measured temperature is the cross temperature Tcp or greater, the reason for setting the first voltage V1=the second voltage V2 and the first voltage V3=the second voltage V4 is because, according to Table T2 (refer to (b-1) of
Accordingly, in the temperature region that exceeds the cross temperature Tcp, the first voltages V1, V3 are set to be equal to the second voltages V2, V4, and even if the first voltages V1, V3 increase together with the second voltages V2, V4 accompanying temperature increases, no problem arises. Furthermore, by setting the first voltages V1, V3 to be equal to the second voltages V2, V4, affords an advantage of simplifying a portion of the control of the waveform generation circuit 30.
Operation of the ferroelectric liquid crystal panel 10 by the driving voltage VD2 will be described with reference to
Here, operation (the optical transmissivity L2) of the ferroelectric liquid crystal panel 10 by the driving voltage VD2 is the same as the operation by the driving voltage VD1 described above. In other words, as depicted in
The slope of the rising curve at this time determines the response speed S of the ferroelectric liquid crystal. During the second interval after the first interval, the positive second voltage V2 of the same voltage value is applied and the long axis direction F of the liquid crystal molecules is maintained, whereby the second state (transmission state) continues and the high state of the optical transmissivity L2 continues.
When the first interval of the second frame begins, the negative first voltage V3 is applied whereby, the first state (non-transmission state (refer to (a) of
Thus, even with operation (refer to
When the response speed S maintains the required speed, even in a temperature region that exceeds the cross temperature Tcp, although not depicted, it suffices to perform control that omits step ST7 depicted in the flowchart in
Here, in a temperature region that exceeds the cross temperature Tcp, by setting the first voltages V1, V3 to low voltage values according to Table T2 such that the response speed S maintains the required speed, i.e., the response speed S is not faster than required, an effect of suppressing the occurrence of orientation deformation of the ferroelectric liquid crystal in the high-temperature region can be expected.
As described, the liquid crystal apparatus of the present invention can vary respectively according to temperature, the first voltages V1, V3 and the second voltages V2, V4 of the driving voltage to correct the temperature dependency of the ferroelectric liquid crystal panel and thereby, can provide a liquid crystal apparatus that is equipped with a ferroelectric liquid crystal panel that has a fast response speed and optimal switching angle, and achieves the required performance with respect to temperature changes. Further, by adjusting the driving voltage according to the required response speed and switching angle, high voltage exceeding that which is necessary is not applied to the ferroelectric liquid crystal panel and therefore, the occurrence of orientation deformation of the ferroelectric liquid crystal is prevented, enabling a liquid crystal apparatus of high precision and high quality to be provided.
The block diagrams, flowcharts, etc. depicted in the embodiments of the present invention do not limit the invention, which includes modifications that fall fairly within the basic teaching herein.
The liquid crystal apparatus according to the present invention corrects the temperature dependency of a ferroelectric liquid crystal panel and achieves the realization of stable operation with respect to temperature changes, enabling wide use in applications requiring high-speed response such as laser projectors and liquid crystal shutters.
1 liquid crystal apparatus
10 ferroelectric liquid crystal panel
20 drive circuit
30 waveform generation circuit
31
a,
31
b digital-to-analog converter circuit (D/A circuit)
32 reference power source
33 timing generator circuit
34
a,
34
b inverter circuit
35 switch circuit
40 control circuit
50 memory circuit
60 temperature sensor
70 input circuit
P1 input signal
P2 temperature signal
P3 memory signal
P4 control signal
P5 waveform signal
VD, VD1, VD2 driving voltage
Number | Date | Country | Kind |
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2013-145475 | Jul 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/068640 | 7/11/2014 | WO | 00 |