DE3024530C2 - Liquid crystal control voltage circuit - Google Patents

Description

Edition, Berlin 1978, there Fig. 16.28 on page 387, as such known, a field effect transistor as a reference voltage source with current negative feedback for setting the desired voltage value Dimensioning to mean drain current to ensure a temperature-dependent reference voltage to use; according to Fig. 16.7 on page 371 is proposed in the same work to control the Conductance of a transistor actuator connected in series with the load to the reference voltage generator ίο a potentiometer to be connected downstream, the tap of which is connected to the base of the transistor. Die in the frame The measure taken according to the invention, however, has the advantage that the Current negative feedback resistance at the same time for setting the gate-source voltage and thus the reference voltage to be used for the change For the reference voltage, neither an additional component nor the reference voltage transmitter is required to have to burden additionally.

The comparison of the from the tracking voltage divider The reference variable obtained according to the ambient temperature and subject to the disturbance variable with the in Its size adjustable reference voltage in the reference voltage divider provides the advantage of a particularly simple comparator structure for revealing Possibilities to intervene in the control characteristics of the actuator; especially the Possibility of further development according to claim 2 to ensure a not too much dropping Output voltage as well as the possibility of a development according to claim 4 to optimize the dynamic behavior of the feedback circuit is opened

Further advantages of the invention emerge from the following description of one in the drawing with restriction to the essentials shown preferred embodiment of the invention Solution. The single figure of the drawing shows, partially symbolized as a block diagram, one according to the invention designed control voltage circuit for a multiplex-controlled liquid crystal display.

The control of a liquid crystal display 1 - for example in the form of a segment display for representation alphanumeric and / or graphic symbols, such as described in DE-OS 28 34 387 - takes place in usually via a multiplexer 2, as in the German patent application according to DE-OS 29 43 339 of the applicant is described if it is When the display 1 is the display unit of a portable clock, it is available as an unregulated power supply 3 also for the vibration. Splitter and logic sound 33 for time-dependent control of the multiplexer 2 (indicated in the drawing üur functionally) only one small and comparatively inefficient battery is available, such as a silver oxide battery with a Open circuit voltage of 1.60 V. The display 1 is fed via the multiplexer 2 in such cases because no mains supply with a higher adjustable voltage is possible, via the latter upstream Voltage doubler 4 in order to supply a supply voltage tailored to the operating requirements of the display 1 reach. As an unregulated supply voltage depending on the current load conditions, especially in the case of a battery supply, also depending on its age and state of charge, for comparison can fluctuate greatly, the »voltage doubler 4 is a control voltage circuit 5 with a constant voltage switching arrangement 6 upstream. This control voltage circuit 5, the vibration, divider ur.d Logic circuit 33, the multiplexer 2 and the voltage doubler 4 are integrated in a single one Circuit 34 can be implemented, with the exception of the large capacitors 35 to be connected externally for the Function of the voltage doubler 4, which is pumped with a frequency tapped from the circuit 33.

The response threshold voltage of multiplexable liquid crystal displays 1 is typically 1.05 V, where The »OFF« voltage is usually selected to be around 95% of this threshold voltage, i.e. around 1.00 V. Within the multiplexer 2 or an additional circuit to this are thus from the stabilized supply voltage depending on the multiplexer mode of operation - for example via voltage divider, not shown in the drawing - different voltages with to provide a voltage difference of 1.00 V in each case, in the case of a three-step multiplex operation towards 0.00 V. thus -1.00 V, -2.00 V and -3.00 - /. The internal resistance the control voltage circuit 5 should be low in order to avoid the stabilized nominal output voltage from 1.50 V at full load to less than 1.30 V. collapses because the circuit 33, which is also supplied by the control voltage circuit 5, underneath Could show malfunction in relation to their logical functions.

The constant voltage switching arrangement 6 consists essentially in a manner known per se from one Actuator 7 in the form of an emitter follower 8 with control via its base 9 from an adjustable Reference generator 10, which supplies an adjustable constant working voltage for the emitter follower '8 Due to the current amplification factor of the emitter follower 8, the load on the reference generator 10 is minimal, so that it acts as a voltage divider from a high series resistor in series with a reference switching element constructed and the unregulated input (connections U) of the control voltage circuit 5 in parallel can be switched. A junction field effect transistor 12 with lower is preferred as the reference element Threshold or gate-source voltage (e.g. Tl type BF 245 variant A) and a potentiometer 13 is used as a high-resistance series resistor, with control of the FET gate 14 from the potentiometer tap ^ l5. This reference generator 10 dimensioned in this way produces the setpoint tap 16 constant current extraction for feeding the emitter follower base 9 with adjustable setting a constant base bias voltage via the potentiometer tap 15, without a voltage that can be set for this to require an additional component; the low threshold voltage setting the required There is no base bias even with a low supply voltage across the input connections 11 enables

The setpoint tap 16 for controlling the actuator 7 is controlled by ambient heating Disturbance variable loading in the sense of decreasing actuator control and thus decreasing Voltage across the control voltage output terminals 17 of the control voltage circuit 5. For this purpose, a divider network 18 is provided, the one Has reference voltage divider 19, the purpose of which, however, is not to assign or change the from Reference generator 10 is the reference voltage supplied because, as explained, the current negative feedback potentiometer for this purpose 13 is used in the field effect transistor 12; rather, this (reference voltage divider

19 the function of a! Comparator according to the initially discussed, generic control voltage circuit to the below with little effort Realize further modifications explained with regard to the control characteristics of the actuator 7 to be able to. A tracking voltage divider 20 influences the control of the actuator 7, namely the dividing ratio for the actuator control voltage acting at the base 9 of the emitter follower 8. Therefore the (reference voltage divider 19 has at least one electronically controllable resistor 21 and at least one fixed resistor 22, 22 ', with the connection of the base 9 of the emitter follower 8 (or its Input stage in the case of a cascade connection) to the reference voltage divider tap 23 of the divider 19. Im The preferred implementation shown is the electronically controllable resistor 21 in the divider 19 as Transistor 24 implemented in the emitter circuit. The additional fixed resistance shown as Eminer resistance 22 'can also be omitted in the illustrated case of the tap 23 located at the collector if it is not off Stability reasons for negative feedback is required. The feeding of the divider network 18 and thus the The divider 19 takes place with the reference voltage of the reference generator 10 present at the setpoint tap 16. The temperature-dependent variation of the voltage present at tap 23 for controlling the emitter follower base 9 takes place via the tracking voltage divider 20. At least one of its divider resistances is as temperature-dependent self-variable resistance selected by an NTC resistor and / or a Find PTC resistor 26 use. The tracking divider tap 27 is connected to the control input 28 of the divider 19 Geschähet, in the implementation case shown, to the Base 29 of transistor 24.

The tracking voltage divider 20 is expediently fed with the already stabilized Output voltage across the control voltage output terminals 17, so that in so far as such known manner, a negative feedback sets, with the result that the transistor 24 as a control amplifier for Actuation of the actuator 7 acts, however, as a control amplifier with a non-constant emitter-base voltage in the case of the use of the negative feedback fixed resistor 22 '. Depending on the effective internal resistance scaling of the tracking voltage divider

20 is possibly in front of the transistor base 29 Protective resistor 30 to be provided.

When the ambient temperature rises, the effective resistance value of the NTC resistor decreases 25 and / or increases: t is the effective resistance value of the PTC resistor 26. With the result that the on Tracking divider tap 27 increases with respect to the reference potential 31 tapped potential and the transistor 24 in the divider 19 continues to open. As a result, the voltage present at its tap 23 decreases, based on Reference potential 31, with the result that the emitter follower 8 is closed; d. h, the output voltage about the output terminals 17 of the control voltage circuit 5 and thus also the control of the voltage doubler 4 drops below the voltage that is in itself would correspond to the setting of the reference generator 10. With appropriate dimensioning of the tracking voltage divider 20 and the divider 19 (in particular by selecting the temperature characteristics of the temperature-dependent resistors 25, 26 and by dimensioning the dividing ratio in the divider 19) is easily achievable in the temperature fluctuation range of interest that the lowering of the Output voltage across the output terminals 17 is just such an amount (or a slight amount greater amount) than the temperature-dependent fluctuating response threshold voltage (which decreases when the temperature rises) the segments of the liquid crystal display 1.

It is particularly advantageous in the solution according to the invention that the divider network 18 for

ίο temperature-dependent influencing of the control voltage on the actuator can also be retrofitted with external constant voltage sensors that are available for universal use without great effort, in order to convert them specifically for the control of LCD (liquid crystal!) displays 1. This is because the control line 32, which is always present in constant voltage sensors, needs to be disconnected between the reference sensor 10 and the actuator 7 and the simply structured dividing network is to be interposed for temperature-dependent influencing of the emitter follower control voltage, with the supply of this divider network 18 (namely its tracking voltage divider 20) from the Anyway accessible output connections 17 of the constant voltage transmitter. The negative feedback caused thereby desirably lowers the effective internal resistance of the control voltage circuit 5, as is known as such for regulating positions of this type.
By specifying the ratio of the fixed resistors 22/22 'in the divider 19 and the collector-emitter voltage of the transistor 24 and by dimensioning the tracking voltage divider 20 with the selection of its temperature-dependent resistor 25 and / or 26, it is possible to specify how much the reduction in the reference sensor 10 The set base voltage of the emitter follower 8 is due to the increase in temperature, i.e. due to the increase in voltage at the tracking divider tap 27 (with corresponding control of the transistor 24), in particular that the voltage across the output connections 17 - as explained above - does not drop below 13 V even if the ambient temperature rises sharply can.

In the case of the use of an NTC resistor (thermistor) 25 - for example type K 1t / 10% / 500 K from Siemens - is the negative feedback resistor 22 'in the emitter path of the transistor 24 in as such in the To reduce transistor switching practice in a known manner in such a way. that the switching on of the transistor 24 is limited to a specified value (up to 13 V) when the output voltage drops. That Occurrence of this minimum of the voltage across the output terminals 17 is at the occurrence of the to be oriented to the highest expected ambient temperature, so that in the working temperature range no temperature-dependent rise in the output voltage can occur.

The circuit dimensioning is less critical Circumstances when using a PTC resistor (PTC thermistor) 26; because such a point - for example

ω type P 270-11 from Siemens - has a high saturation value of its temperature-dependent resistance curve. The PTC thermistor type must therefore be selected so that this saturation ^{value is set at a typically high ambient temperature (e.g. 60 0} Q; then the voltage across the output terminals 17 remains constant with a further rise in temperature, i.e. a drop in the output voltage below the critical limit value is prevented . So can, together with

the selection of the resistance values for the fixed resistors 22 and 22 'and, if necessary, for one with the temperature-dependent resistor 25 or 26 in Series connected resistor within tracking voltage divider 20, the onset, the gradient, and the End of the temperature-dependent interference variable loading at the setpoint tap 16 for the function of the Determine constant voltage switch assembly 6.

List of reference symbols

1 liquid crystal display

2 multiplexers

3 Unregulated left-wing pension provision

4 voltage couplers

5 Control voltage circuit

6 constant voltage switching arrangement

7 actuator

8 I successor
4 base

10 referees / donors

11 F. input connections

12 [unct ion · field effect transistor

13 potentiometers

14 field effect transistor gate

15 Potentiometer tap

16 Setpoint tapping

17 output connections ι 18 divider network

19 (reference voltage) divider

20 tracking voltage divider

21 electronically controllable resistor

22 Fixed resistor in 23 (divider) tap

24 transistor in common emitter circuit

25 NTC resistor

26 PTC resistor

27 Tracking divider tap ii 28 Control input

29 base

30 protective resistor

31 reference potential

32 control line

in 33 oscillation divider and logic circuit

34 integrated circuit

35 capacitors

1 sheet of drawings

Claims (5)

Claims; 1.Liquid crystal control voltage circuit (5), to compensate the temperature influence on the switching behavior of liquid crystal cells, with a constant voltage switching arrangement (6) fed from an unregulated power supply (3), which has an actuator (7) controlled by a reference generator (10) a comparator is acted upon by the reference generator (10) and, depending on the temperature, from the tapping of a tracking voltage divider (20) connected in parallel to the control voltage output connections (17) in such a way that the conductance of the actuator (7) is acted upon by the comparator in the sense of falling voltage to the control voltage Output terminals (17) is controlled when the temperature rises, characterized in that the reference generator (10) as the power supply (3) parallel-connected voltage divider aas a junction field effect transistor (FET \ 2) with a low gate-source voltage as its reference element and from a Potentiometer (13) designed as a series resistor is, with the connection of the FET gate (14) to the potentiometer tap (15) and with the connection of the comparator between the field effect transistor (12) and the potentiometer (13), and that the comparator as a reference voltage divider (19) consists of an electronically controllable resistor ( 21) and at least one fixed resistor (22) is formed, with control of the controllable resistor (21) from the tracking voltage divider (27) -, nd with control of the actuator (7) in the form of an emitter follower (8) from the reference voltage divider AS ^ riff (23). 2. Control voltage circuit according to claim 1, characterized in that the divider ratio of the reference voltage divider (19) via its fixed resistor (22) and possibly additionally the division ratio of the tracking voltage divider (20) via the appropriate selection of the characteristic its temperature-dependent resistance (25 or 26) is limited so that the drop in the Output voltage across the output connections (17) when the ambient temperature rises below a minimum voltage value is prevented, which the specified minimum operating voltage for a Logic circuit (33) represents, from which one of the control voltage circuit (5) connected downstream Voltage doubler (4) can be pumped and / or a multiplexer connected upstream of the liquid crystal display (1) (2) is controllable. 3. Control voltage circuit according to claim 2, characterized in that the tracking voltage divider (20) has a PTC thermistor as a temperature-dependent changing resistor (26), whose saturation value of the temperature-dependent resistance curve at a typical, am highest expected ambient temperature is selected. 4. Control voltage circuit according to one of the preceding claims, characterized in that that the electronically controllable resistor (21) is a transistor (24). 5. Control voltage circuit according to claim 4, characterized in that the transistor (24) as Control amplifier is operated with regard to the control of the actuator (7) The invention relates to a control voltage circuit according to the preamble of claim 1, Such a control voltage circuit is from DE-AS 23 16 863 (there in particular in connection with Fig, 8a / 8b) known There is provided to compensate for the crosstalk behavior in dot matrix liquid crystal displays the electrode control voltage for switching the assigned display area to the state of dynamic scattering ίο increasing temperature to increase over a larger ambient temperature range the DS matrix arrangement with comparatively - and only after Determination of the temperature change of fluctuating - low voltage with a fixed predetermined driver pulse repetition frequency to be able to operate. This is done in a manner known from network constant circuit technology a negative feedback circuit with an electrically controllable conductance in series with the load provided, its control in accordance with the output of a comparator not described in detail takes place, on the one hand from a reference voltage unit not described in detail and on the other hand from what is known as an output voltage detector there, which is a The voltage divider connected in parallel to the output connections acts on one side of his Tap a thermistor and / or can have a PTC thermistor on the other side. The invention is based on the object of one of those Specify the corresponding control voltage circuit with little complex circuitry Structure in particular in connection with the implementation of a prior art as Comparator designated circuit part and its control better intervention options to determine the compensation behavior of the circuit opened, especially with regard to the use in the Multiplex control of liquid crystal displays, in which defined graded control voltages are available must be. The potential differences of these control voltage gradations must be just slightly below the Response threshold voltage of the segmented liquid crystal cells, that make up the display are, however, this threshold voltage is strong is temperature-dependent, namely typically a temperature coefficient of approx. -10 mV / deg. at a has a typical response threshold voltage of 1.0 V When the ambient temperature rises sharply. for example in the case of direct sunlight on a wristwatch or in the case of the installation of one Liquid crystal displays in the vicinity of heat radiating systems, so there is a risk that the effective response threshold voltage below the control voltage swing supplied by the power supply drops so that it is no longer possible to switch off the liquid crystal display. This critical one The operating state should be determined by the control voltage circuit to be created be safely prevented. According to the invention, the stated object is thereby achieved solved that in the control voltage circuit according to the preamble of claim 1, the additional Measures according to the characterizing part of claim 1 are taken. With regard to the extraction of small reference voltages, it is from the standard work of electronic circuit technology, U.Tietze / Ch. Schenk, "Semiconductor Circuit Technology", Springer-Verlag, 4.