FR2673027A1 - Liquid crystal display device - Google Patents

Abstract

In a liquid crystal display device having a liquid crystal layer and a plurality of electrodes to which a voltage is to be applied for display, the magnitude of the voltage to be applied to said plurality of electrodes is a function of temperature. of said liquid crystal. The voltage to be applied to the electrodes is continuously changed by the use of a positive thermistor (32). As an alternative, the voltage is changed in steps by the use of an electric circuit.

Description

LIQUID CRYSTAL DISPLAY DEVICE

  The present invention relates to a liquid crystal display device for displaying numbers, letters, etc. A liquid crystal device in which each segment comprises a segment electrode is widely known on the liquid crystal display device composed as above, a common electrode corresponding to the entire display surface of the device and a plurality of segment electrodes are arranged face to face, the liquid crystal being arranged between them The segment electrodes are arranged to produce shapes of letter, number, etc. With this structure, a voltage having a rectangular wave shape, of which amplitude is a reference bias voltage is applied to the common electrode A rectangular waveform whose phase is offset by 180 degrees from that applied to the common electrode is applied to the segment electrodes corresponding to the parts to display In addition, a rectangular waveform having the same phase as that applied to the common electrode is applied iqued to the segment electrodes corresponding to the parts not to be displayed. By which, only the part to be displayed of the liquid crystal is controlled to display letters, numbers, etc. In conventional liquid crystal displays, however, since the reference bias voltage is fixed, the amplitude of the rectangular wave to be applied to each segment electrode is constant. When the reference bias voltage, having substantially a constant value (i.e., the amplitude of the rectangular wave applied to each electrode is constant), there is a problem that, if the liquid crystal temperature drops, the intensity of the displayed segment is decreased and thereby the contrast is reduced In addition, when the liquid crystal temperature is increased, the intensity of the segments which are not controlled is increased, whereby the contrast of the display device is also reduced. It is therefore the objective of the present invention to create an improved liquid crystal display device in which the reduction of the display contrast can be prevented even if the temperature of the

liquid crystal varies.

  The present invention provides for this purpose a liquid crystal device comprising liquid crystal and a plurality of electrodes, a voltage being applied to the plurality of electrodes for display, the liquid crystal display device further comprising means for controlling the amplitude of the voltage to be applied to the plurality of electrodes as a function of the

liquid crystal temperature.

  As a variant, the control means comprises: means for establishing a reference voltage, the reference voltage being established as a function of the temperature of the liquid crystal; and means for producing a control signal to be applied to each of the plurality of electrodes in

  as a function of the reference voltage.

  As a further variant, the setting means establishes the reference voltage continuously. In addition, the liquid crystal display device comprises a current source for supplying a predetermined voltage to the setting means, and in which the establishment means comprises a thermistor element having a characteristic such that the lower the temperature, the lower its resistance, while the higher the temperature, the higher its resistance, the thermistor being connected in series between the current source and the means of

piloting signal production.

  As a variant, the establishment means establishes the reference voltage in stages. Furthermore, the establishment means comprises means for detecting the

liquid crystal temperature.

  In addition, the setting means comprises: a plurality of resistors connected in series, the voltage between the ends of one of the plurality of resistors being applied to the means for generating the control signal; and current control means for determining the number of resistors through which an electric current flows, among the plurality of resistors, whereby the voltage between the ends of one of the plurality of resistors is

  modified according to the amplitude of the electric current.

  Still further, the liquid crystal display device includes a current source for supplying a predetermined voltage, wherein the control means includes switching means for selectively connecting the current source to one of the positions in which an adjacent pair of the plurality of resistors is connected so that electric current flows through the determined number of resistors. In the liquid crystal display device, the liquid crystal is in the form of a layer, the plurality of electrodes comprises a plate electrode corresponding to the display area of the device, and a plurality of segment electrodes, the layer of liquid crystal is sandwiched between the plate electrodes

  and the plurality of segment electrodes.

  According to another aspect, the control signal production means produces: a first signal having an amplitude corresponding to the reference voltage; and a second signal having an amplitude corresponding to the reference voltage, the waveform of the second signal being substantially reversed from that of the first signal, and the first signal is applied to the plate electrode, and one of the first signal and the second signal is applied to each of the segment electrodes, the part of the liquid crystal layer corresponding to the segment electrodes to which the second signal is applied being displayed, while the part of the layer corresponding to the segment electrodes to which the first signal is

applied is not displayed.

  As a variant, the first and second signals comprise, respectively, first and second periodic signals, the phase of the second periodic signal being offset by 180 degrees relative to the first periodic signal. In addition, the first and second periodic signals

  have, respectively, rectangular waveforms.

  The characteristics and advantages of the invention

  will emerge from the description which follows

  by way of example with reference to the accompanying drawings, in which: FIG. 1 shows a first embodiment of a control unit of a liquid crystal display device; Fig. 2 is a plan view showing an electrode structure of the liquid crystal display device; Figure 3 is a sectional view of the liquid crystal display device, along a line III III of Figure 2; Figure 4 is a timing diagram showing the relationship between the waveforms applied to each electrode of the liquid crystal display device; and Figure 5 shows a second embodiment of a crystal display device control unit

  liquid according to the present invention.

  Figure 1 shows a first embodiment of a control unit of a liquid crystal display device according to the present invention. An LCD (liquid crystal display device) 10 is provided with seven segment assemblies 14 As shown in Figure 3, each segment 14 is provided with seven segment electrode elements 11, a plate electrode element 12 as a common electrode, and a layer of liquid crystal 13 disposed between the segment electrodes il and the plate electrode 12 The segment electrodes 11 and the common electrode 12 are controlled by a so-called static control method, namely the electrodes 11, 12 of the segments 14 to be displayed are individually and simultaneously controlled by an LCD control circuit 40 and a control control unit 20

which will be described below.

  As shown in FIG. 1, the control control unit 20 includes a reference voltage setting circuit 30, and the LCD control circuit 40 The reference voltage setting circuit 30 establishes the amplitude d rectangular wave to be applied to each electrode 11, 12 It should be noted that the reference bias voltage coincides with the amplitude value of the rectangular wave The control circuit of LCD 40 produces a rectangular wave having an amplitude equal to the reference bias voltage, and it causes the phases of the rectangular waves applied to the respective electrodes to be coincident

  or are offset from each other.

  The reference voltage setting circuit 30 includes a constant voltage current source 31, a thermistor with positive characteristic 32, and a fixed resistor 33. An example of thermistor with positive characteristic 32 is a solid resistance made of barium titanate by junction with lanthanum, strontium or selenium oxide The thermistor with positive characteristic 32 is connected to the constant voltage current source 31, and a fixed resistor 33 is connected in series with the thermistor with positive characteristic 32 It is note that the thermistor with positive characteristic 32 is defined as a thermistor having a characteristic such that the higher the temperature, the higher its resistance becomes, and such that the lower the temperature, the more its resistance decreases The first embodiment is so designed that the temperature of thermistor 32

  coincides with that of the liquid crystal layer 13.

  The control circuit of LCD 40 is connected to the reference voltage setting circuit 30, and the LCD 10 is connected to the output terminal of the control circuit of LCD 40 The control circuit of LCD 40 delivers the bias voltage of reference to the respective electrodes 11, 12, the phase of the rectangular waves between the respective electrodes 11 and 12 being in coincidence or being offset with respect to each other. A predetermined reference bias voltage is applied to the LCD control circuit 40 by the reference voltage setting circuit 30 The LCD control circuit 40 produces, as shown in Figure 4, the voltage wave rectangular (designated by the marks A; B and C) having an amplitude equal to the reference bias voltage A waveform of rectangular voltage A is applied in

  permanence at the plate electrode 12.

  At this stage, if the rectangular voltage waveform B, which has the same phase as that of the waveform A, is applied to the segment electrodes 11, no voltage difference is produced between

  the plate electrode 12 and the segment electrodes 11.

  In other words, no voltage is applied to the liquid crystal layer 13 of the segment 14 In this case, the

segment 14 is not displayed.

  If the rectangular voltage waveform C, the phase of which is offset by 180 degrees with respect to the form A, is applied to the segment electrodes 11, the resulting waveform applied to the liquid crystal layer 13 of the segment 14 is like waveform D, doing so in

so that the segment is displayed.

  When the temperature of the layer 13 of the liquid crystal is lowered, the resistance value of the thermistor 32 is decreased, and the reference bias voltage is increased Therefore, the amplitude of the rectangular voltage wave applied to the respective electrodes 11, 12 of the LCD 10 is increased, and the intensity of the segment 14 displayed cannot decrease.

  device display contrast remains high.

  While, if the temperature of the liquid crystal is increased, the resistance value of the thermistor 32 is increased and the reference bias voltage is decreased Therefore, the amplitude of the rectangular voltage wave applied to the respective electrodes 11, 12 is decreased, and the intensity of segment 14 which is not controlled cannot increase, whereby the contrast

  device display remains high.

  As described above, if the temperature of the liquid crystal varies, the amplitude of the rectangular waves applied to the electrodes is continuously changed as a function of the temperature of the liquid crystal, whereby a high contrast of the display device is obtained . FIG. 5 shows a second embodiment of the control control unit 50 according to the present invention A reference voltage setting circuit 60 is arranged in the control control unit 50 which comprises four elements of fixed resistance 63, 64, 65 and 66 connected in series and three switches 67, 68 and 69 interposed between the respective fixed resistors 63, 64, 65 and 66 In addition, a temperature detector circuit 61 and a microcomputer 62 are arranged in the piloting control unit 50 The detector circuit 61 is placed in the vicinity of the LCD 10 and detects the temperature of the layer 13 of the crystal

  liquid, and it converts it into an electrical signal.

  The microcomputer 62 switches on or off the switches 67, 68 and 69 as a function of the signal transmitted from the detector circuit.

temperature 61.

  The switch 67 is interposed between the constant voltage current source 31 and the point where the fixed resistors 63, 64 are connected The switch 68 is placed between the constant voltage current source 31 and the point where the fixed resistors 64 , 65 are connected Switch 69 is arranged between the constant voltage current source 31 and the point where the

  fixed resistors 65, 66 are connected.

  The microcomputer 62 controls the switches 67, 68 and 69 so that when the layer 13 of the liquid crystal is at a high temperature, all the switches 67, 68 and 69 are open and so that when the temperature of the layer 13 of the liquid crystal decreases, one or the other of the switches 67, 68,

69 is closed.

  In the control control circuit 50, the microcomputer 62 opens all the switches 67, 68 and 69 when the temperature of the layer 13 of the liquid crystal is high. Thus, the voltage from the constant voltage current source 31 is applied to the LCD control circuit 40 via the four fixed resistors 63, 64, 65 and 66 Namely, the reference bias voltage established by the reference voltage setting circuit 60 takes the value

minimum in the possible range.

  When the temperature of the layer 13 of the liquid crystal decreases, as a function of the signal coming from the temperature detector circuit 61, the microcomputer 62 only closes the switch 67, thus making so that the voltage coming from the voltage current source constant 31 is applied to the LCD control circuit via the three fixed resistors 64, 65 and 66 Consequently, the reference bias voltage established by the reference voltage setting circuit 60 is slightly increased, by comparison with the case where all the switches 67, 68 and 69 are open. When the temperature of the layer 13 of the liquid crystal is further lowered, the microcomputer 62 closes one or the other of the switches 68 or 69 depending on the signal from the temperature detector circuit 61 whereby the voltage from the source of constant voltage current 31 is applied to the LCD control circuit 40 via two fixed resistors 65, 66 or a fixed resistance 66 Namely, the reference bias voltage established by the circuit establishing reference voltage 60 is more

increased.

  As above, if the temperature of the liquid crystal varies, the amplitude of the rectangular waves applied to the electrodes is modified in stages as a function of the temperature of the liquid crystal, whereby a contrast

  display device is obtained.

  It should be noted that, in the embodiments mentioned above, each electrode is driven by the static driving process, but that the liquid crystal display devices in which each electrode is driven by a multiplex driving process can also be used In such a case, the effects of the pilot control unit according to the present invention

will be more remarkable.

  As described above, according to the present invention, the reduced contrast of a liquid crystal display device due to temperature variations of the

  layer of liquid crystal can be avoided.

Claims (11)

  1 liquid crystal display device comprising liquid crystal (13) and a plurality of electrodes (11, 12), a voltage being applied to said plurality of electrodes (11, 12) for display, said device liquid crystal display being characterized in that it further comprises means for controlling (20, 50) the amplitude of the voltage to be applied to said plurality of electrodes (11, 12) as a function of the temperature of said liquid crystal (13).   2 liquid crystal display device according to claim 1, characterized in that said control means (20) modifies the voltage to be applied to said   plurality of electrodes (11, 12) continuously.   3 liquid crystal display device according to claim 1, characterized in that said control means (20) comprises: means for establishing (30, 60) a reference voltage, said reference voltage being established in function of the temperature of said liquid crystal (13); and means for producing (40) a control signal to be applied to each of said plurality of electrodes (11,   12) as a function of said reference voltage.   4 liquid crystal display device according to claim 3, characterized in that said setting means (30) establishes said reference voltage continuously.   A liquid crystal display device according to claim 4, further comprising a current source (31) for supplying a predetermined voltage to said setting means (30), characterized in that said setting means (30) comprises a thermistor element (32) having a characteristic that the lower the temperature, the lower its resistance, while the higher the temperature, the higher its resistance, said thermistor (32) being connected in series between said current source (31) and said means of production (40) pilot signal.   6 liquid crystal display device according to claim 1, characterized in that said means for   control (50) changes the voltage in stages.   7 liquid crystal display device according to claim 3, characterized in that said setting means (60) establishes said reference voltage in stages.   8 A liquid crystal display device according to claim 7, characterized in that said establishment means (60) comprises a detection means (61) of   the temperature of said liquid crystal (13).   9 Liquid crystal display device according to claim 8, characterized in that said setting means (60) comprises means (62 to 69) for varying said reference voltage in stages as a function of the temperature detected by said detection means (61).   Liquid crystal display device according to claim 3, characterized in that said liquid crystal (13) is in the form of a layer, in that said plurality of electrodes (11, 12) comprises a plate electrode (12) corresponding to the display areas of said device, and a plurality of segment electrodes (11), said liquid crystal layer (13) being sandwiched between said plate electrode (12) and said   plurality of segment electrodes (11).   11 A liquid crystal display device according to claim 3, characterized in that said means for producing (40) control signal produces: a first signal having an amplitude corresponding to said reference voltage; and a second signal having an amplitude corresponding to said reference voltage, the waveform of said second signal being substantially inverted with respect to that of said first signal, and in that: said first signal is applied to the plate electrode ( 12), and one of said first signal and said second signal is applied to each of said segment electrodes (11), the part of said liquid crystal layer (13) corresponding to the segment electrodes (11) to which said second signal is applied being displayed, while the part of the layer corresponding to the segment electrodes (11) to which said first signal   is applied not being displayed.   12 Liquid crystal display device according to claim 11, characterized in that said first and second signals comprise, respectively, first and second periodic signals, the phase of said second periodic signal being offset by 180 degrees relative to said first periodic signal.   13 Liquid crystal display device according to claim 12, characterized in that said first and second periodic signals have, respectively, shapes rectangular wave.