DD284308A5 - INTEGRATED LCD CONTROLLER AND METHOD FOR OPERATING THE LIQUID CRYSTAL DISPLAY - Google Patents

Abstract

The invention relates to an integrated LCD drive circuit and a method for operating the liquid crystal display and is used in watches. The aim of the invention is u. a. the reduction of power consumption of the CMOS circuit. This is achieved according to the present invention by eliminating the buffer capacitor normally arranged at the output of the integrated voltage doubler and the drive signals for the multiplex operation of the liquid crystal display do not contain blanking intervals which periodically discharge the generated voltage doubler potential (UEE) to negative operating voltage potential (USS) at the rate of the voltage doubler cycle. Fig. 3 {liquid crystal display; control; voltage doubler; Save condenser; Multiplex drive; Blanking interval omitted; Voltage doubler potential generates e-function; Power consumption; CMOS}

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to a drive circuit for Flussigkristallplnplays and the design of the drive signals for the multiplexed to be used LCD display. The drive circuit is implemented in CM IS-Tech η ι к. The invention finds application in battery operated devices, such as watches.

Characteristic of the known state of the art

Known technical solutions assume that in a circuit AC signals are generated, depending on the application have different waveforms and control the designated as segments display units In conjunction with one or more jerk electrode signals of the LCD display results in a difference signal, which depending on the rms value Switch segment on or off To control an LCD display, the voltage rms values of the control signal with respect to the threshold voltage value of the display must comply with certain limit values. To realize these values, apart from the usual battery operating voltage of 1.55 volts, a doubled operating voltage generated in the circuits by means of two external capacitors is necessary.

The Schaltungspnnzip of such a voltage doubler is known (radio television electronics Berlin 38 [1989] 1 S 20, Figure 2) and requires two capacitors in a suitable switch arrangement The driving conditions for the LCD display must be met throughout Betnebsspannungsbereich practical practically often the two-way multiplexing Since the simple and doubled operating voltage does not correspond to the threshold voltage of the LCD display in the entire tolerance range, safe switching on and off of the display segments is only ensured by lowering the effective value of the control signal. This is done on the circuit by implementing a blanking gap the AC signal is additionally pulled to the lowest potential. A disadvantage of this is the fact that the output drivers for the LCD segment control consume more power because of the increased number of switching operations per unit of time in the data sheet of Toshiba's JT 6524 A-AS circuit

In the patent H 02 M 3/07, EP 0257810 another way is shown how a DC voltage can be generated from a DC voltage For this purpose, the charging of the buffer (storage) capacitor of the modified voltage doubler circuit via a comparator at the output of the DC A disadvantage is that a circuit in addition to digital circuit means and analog circuit means are needed, and that a certain reference voltage is difficult to produce, without the power consumption of the circuit is adversely affected

Object of the invention

The aim of the invention is to reduce the power consumption of battery-powered wristwatches with Flussigknstallplays and thus increasing the useful life of the watch without battery change The goal is also to reduce the manufacturing cost of such a wristwatch

Explanation of the essence of the invention

The object of the invention is to find a new solution for a low-loss control of LCD displays which operate in multiplex mode and an adaptation of the effective values of the drive voltage of the segments to the Schwellspannungswert the Flussigknstallsplays the segments require The task was based on a preferably two-multiplexing mode of the LCD Displays and using an integrated voltage doubler circuit as well as segment drive circuits and drive circuits for the at least two general return electrodes of the Flussigknstalldisplays erfmdungsgemaß solved by the fact that the output of the voltage doubler usually connected in parallel and discretely or integrated in a circuit arranged second capacitor which acts as a buffer capacitor, The capacitance of the liquid crystal display itself takes on the surprising function of the buffer capacitor, because the segment connections un d, the counter electrode terminals react via switch transistors of the output segment drivers of the segment drive circuits and the drive circuit for the jerk electrodes to the outputs of the voltage doubler

The solution of the problem is further characterized in that when using a Flussigknstalldisplays having a threshold voltage in the range of a minimum of 0.6 battery voltage to a maximum of 1.27 battery voltage, the first and the second common back electrode of the LCD display with a first and second jerk electrode signal is driven, which has no blanking gaps in any of the four equations signal phases of a period, but that repeat the following four voltage potentials cyclically

negative operation (Battene) voltage potential,

positive operating potential,

negative operating voltage potential,

generated, changing voltage doubler potential,

and that the segment electrodes of the Flussigknstalldisplays are driven with segment output signals, which also have no blanking gaps, but that repeats periodically independent of the respective phase angle of the segment output signals with respect to the jerk electrode signals two equal signal phases

- positive Betnebs (battery) voltage potential,

generated, changing voltage doubler potential,

that periodically realizes in a clock phase pot ent ι a! changes that correspond in absolute terms to the maximum battery voltage value. It is essential that this potential change approximates to an e-function with a time constant It also belongs to the essence of the invention that the difference signal between the signal electrode and the back electrode is not DC-free, but that the DC component! Kiemer is the maximum permissible DC component of the liquid crystal display

Contrary to the known state of the art, where it is ensured by the dimensioning of the buffer capacitor of the voltage doubler that the voltage across this capacitor remains almost constant during operation or where the charging of the buffer capacitor is complicatedly controlled, erfmdungsgemaß unloading the buffer capacitor acting as LCD Exploited advantageous displays

In addition to the saving of a discretely or integrated realized buffer capacitor at the output of the voltage doubler is reduced by the described method for driving the LCD display, the number of switching operations of the segment drive circuits and the drive circuits for the jerk electrodes, thus also the power losses that occur in each switching operation in CMIS It is now also part of the essence of the invention that adaptations to other threshold values of the liquid crystals or to other battery voltages are possible by deliberately changing the size of the capacitance of the buffer capacitor or the capacity of the LCD display

exemplary

Below, the invention will be explained with reference to an expedient realization variant. The following drawings are referred to

FIG. 1 LCD control circuit according to the invention, FIG.

FIG. 2 shows signal curves for a return electrode signal and a segment activation signal (segment switched on) with blanking gap and

Buffer capacitor C2 according to the prior art, Fig. 3 Signal curves for a back-electrode and a segment drive signal (segment off) without blanking gap and without buffer capacitor C2 according to the invention

1 shows the 512 Hz cycled voltage doubler 1 with the terminals DDC and UC1 for the charging capacitor C ^ and the three voltage potential outputs U ₀ D (positive Betnebsspannungspotential), U _S s (negative operating voltage potential), between which the battery voltage U ₅ is connected, and the generated Spannungsverdopplerpotential Uee Erfmdungsgemaß entfallt the buffer capacitor C2, which is uberlicherweise connected between U _D d and U _EE or U _S s and U _e e, the liquid crystal is play 4 with its first and second jerk electrode 41,42undden segment electrodes 411 4nhateme threshold voltage between 0.97V and 1.14V From the information signals M1, M2 Mn for determining the phase angle of the segment control signals S1, S2 Sn and the driver signals TS, which provide a level-converted, negated and unnegiertes 64Hz signal without blanking, are via the Segmentansteuerschaltungen LI or 2 1,2 2 2nfurdie Segment pairs the Segmentansteuersignale SI, S2 Sn generates, each of these segment control signals usually controls two segments and each of these two segments has a different return electrode (in Figure 1, only one segment electrode is drawn)

Due to the omission of a blanking gap, the generation of the drive signals TS is reduced in expenditure. The first and second jerk electrode signals C0M1 and COM2 are obtained from the drive signals CS1 for COMi and CS2 for COM2 via the drive circuits L2 and 3 1 and 3 2, respectively

While the effective value of the difference signal / COM 1-S1 / must be lowered for a display with о g threshold voltage and genanner battery voltage by blanking as shown in FIG 2, to achieve a safe switching off the segment provided that the buffer capacitor C2 is present, is omitting the buffer capacitor C2 and control of the segment electrodes with Segmentansteuersignalen S1, S2 Sn for the segment pairs without blanking gap and the jerk electrodes 4 1 and 4 2 with the jerk electrode signals COM 1 and COM 2 without blanking gaps according to the signal curves of FIG 3 same effect achieved The Parallelkapazitat the Flussigknstalldisplays 4 (all As a result of this current load, the capacitance of the flux ι gcristai! Displays 4 acting as buffer capacitor C2, as shown in FIG. 3, during a 512 Hz clock phase of the voltage doubler each of the generated Spannungsverdopplerpotent ial U _EE after an e-function almost discharged to the negative Betnebsspannungspotential Uss

This results under the conditions mentioned for the effective values / COM 1 -SV

Segment A 1.39 U _B Segment From 0.62 U ₈

and thus almost the same values as for the signal curves with blanking gap and buffer capacitor C2 according to FIG. 2 and prior art

Segment Em 1.37 U ₃ Segment From 0.61 U _a

The inventive solution thus surprisingly saves the external buffer capacitor C2 and also reduces the number of switching operations of the CMIS driver circuits in the segment drive circuits L1 for the segment pairs or in the drive circuits L2 for the jerk electrodes by eliminating the blanking gaps Circuit leads and thus extends the batten life for a wristwatch

The signal curve for the difference signal / COM 1 -S1 / during the time interval At ₁ is an indication that the DC voltage load of the Flussigknstalldisplays 4 increases somewhat by the inventive solution The used Flussigkristalldisplay 4 but allows much higher DC values than occur here, so that no Disadvantages arise

Claims (2)

An integrated LCD drive circuit having at least two generally usable segment electrodes on the liquid crystal display for a multiplex mode, an integrated voltage doubler circuit with two capacitors serving as Zwischenlade- and buffer capacitor and are arranged externally and discretely or integrated in the circuit, characterized in that the output the voltage doubler (1) usually parallel-connected buffer capacitor (2) is not present and the capacity of the liquid crystal display (4) itself acts as a buffer capacitor. 2. A method of operating the liquid crystal display according to claim 1, wherein the LCD display is driven in the two-multiplex method using a battery voltage and a voltage generated by the Spannungsverdopplerschaltung voltage is characterized in that at a liquid crystal threshold voltage value in the range of 0.6 · battery voltage U ₃ and 1.27-Ub, the first and second return electrode (4.1, 4.2) is driven with a first and second back electrode signal (COM 1, COM 2), which has no blanking gaps in any of the four equally long signal phases of the period, but that the following four voltage potentials repeat cyclically: negative operating voltage potential (U _S s) positive operating voltage potential (Udd) generated, changing voltage doubler potential (U _EE ), and that the segment electrodes (4.11 ... 4.1 n) with segment output signals (S 1, S2, ... Sn) are driven, which also have no blanking intervals, but that, regardless of of the respective phase position of the segment output signals, with respect to the back electrode signals to repeat two signal phases of equal length periodically: positive operating voltage potential (U _D d) generated, changing voltage doubler potential (U _EE ), wherein the generated voltage doubler potential (U _EE ) during a clock phase of the clock, with which the voltage doubler is operated, preferably z. B. 512Hz, is changed in the direction of the negative operating voltage potential with a time constant which is of the order of half of such a clock period.