KR950005569B1 - Driving method & circuit for ferroelectric lcd using stn drivnng ic - Google Patents

Abstract

The method improves the driving speed of displaying device, and prolongs the lifetime of ferroelectric LCD. The method includes the 1st state orienting step of ferroelectric LCD by the 2nd pulse, the 2nd state orienting step of ferroelectric LCD by the 6th pulse, and the pulse appllying step of image data. The method also includes an STN segment driving IC connecting step, an image data applying step to the data input terminal of STN common driving IC, a the sequential signal applying step.

Description

Driving Method and Driving Circuit of Ferroelectric Liquid Crystal Using STN Driving IC

1 is a driving waveform diagram of a ferroelectric liquid crystal by a conventional three-field method.

2 is a driving waveform diagram for driving a ferroelectric liquid crystal as a first embodiment according to the present invention.

3 is a driving waveform diagram for driving a ferroelectric liquid crystal as a second embodiment according to the present invention.

4A and 4C are explanatory diagrams of a vertical electrode driving IC for driving a general STN liquid crystal.

5A and 5C are explanatory diagrams of a horizontal electrode driving IC for driving a general STN liquid crystal.

6 is a circuit diagram for extracting an input signal input to the DF terminals of the vertical and horizontal electrode driving ICs of FIGS. 4 and 5;

7A and 7B are waveform diagrams of output signals according to bias voltages and input signals of FIG. 4;

8A and 8B are waveform diagrams of output signals according to bias voltages and input signals of FIG. 5;

FIG. 9 is a circuit diagram for generating a bias voltage input to each bias voltage terminal of an analog multiplexer for applying a bias voltage to the STN driving ICs of FIGS. 4 and 5. FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ferroelectric liquid crystal display device, and more particularly, to a method of driving the ferroelectric liquid crystal display device by a 3-pulse method using an STN driving IC and to generating a bias voltage applied to the STN (Super Twisted Nematic) driving IC. It relates to a bias voltage circuit.

The ferroelectric liquid crystal display device can display an image by simple multiplex driving without using an active element. Even when the power is turned off, the liquid crystal orientation is memorized. Even if the duty is small, the contrast does not fall, and the nema While switching of nematic liquid crystal is performed by weak interaction between dielectric anisotropy of liquid crystal and electric field, switching of ferroelectric liquid crystal is performed by strong interaction between spontaneous polarization (Ps) and electric field of liquid crystal. Very fast.

At this time, the basic properties to be considered when driving the ferroelectric liquid crystal display device, if the direct current component to the liquid crystal takes a long time, the liquid crystal is deteriorated by the electrochemical reaction and the direction in which the liquid crystal is oriented by the polarity of the pulse is changed. The DC component should not be left in the 1-cycle waveform that is applied and the presence of data will be indicated by applying a pulse of opposite polarity. In addition, the width of the pulse applied to the ferroelectric liquid crystal is limited by the liquid crystal material. If the pulse width is large, the threshold voltage at which the state transition starts to be lowered. That is, generally, the threshold voltage (Vth) x pulse width has a certain property. In order to lower the driving voltage, the pulse width must be widened, but in this case, it takes a long time to represent one pixel. In addition, the driving method of the ferroelectric liquid crystal display device includes the 5-pulse method, the 4-pulse method, the 3-pulse method, and the 3-pulse method according to the number of pulses required to represent one pixel. Currently, the research on the 4-pulse method is most active.

FIG. 1 is a drive waveform diagram of a ferroelectric liquid crystal by a three-pulse method published in US Patent No. 4,870,398 "DRIVE WAVEFORM FOR FEROELECTRIC DISPLAYS".

Referring to FIG. 1, the pixels 1 and 1 are sequentially supplied with voltages of + 5V, + 5V, and -10V as selection signals to the first type electrode during the first strobe period. Voltages of -10V, + 5V, and -5V are sequentially applied to the horizontal electrode, and are turned off by signals of + 15V, 0V, and -5V, which are erase signals, as a composite waveform of the two signals. The signals applied during the second and third strobe periods do not change the arranged state of the liquid crystal so that the state of the pixels 1, 1 is maintained.

In the case of the pixels 2 and 2, voltages of + 5V, -5V, and -10V are sequentially applied to the second type electrode during the second strobe period, and -10V, -5V, + 5V are applied to the second horizontal electrode. Are sequentially applied, and signals of + 15V, + 10V, and -15V, which are write down signals, are applied as the synthesized waveforms of the two signals, and the signals change the arranged state of the previous liquid crystal to change the pixel ( 2 and 2 are turned on and the signal applied during the third strobe period does not change the arranged state of the liquid crystal, so the on state of the pixels 2 and 2 is maintained.

The above method allows one line addressing, but as shown in FIG. 1 above, charge unbalance of the synthesized waveform occurs at the time of selection. This charge imbalance deteriorates the liquid crystal and shortens the lifetime of the liquid crystal display (LCD).

Accordingly, a first object of the present invention is to provide a drive waveform capable of driving the ferroelectric liquid crystal while preventing deterioration of the liquid crystal by a three-pulse method using a conventional STN driving IC.

The second object of the present invention is enclosed between a plurality of first electrode groups arranged in a line on the front plate and a plurality of second electrode groups arranged in a line perpendicular to the first electrode group on the back plate. COMMON-driven to apply a pixel cell formed at the intersection of the first electrode group and the second electrode group on the ferroelectric liquid crystal to the first electrode group and the second electrode group in order to drive the driving waveform as described above. It is to provide a waveform and a SEGMENT-drive waveform.

A third object of the present invention is to apply the COMMON-drive waveform and the SEGMENT-drive waveform to the ferroelectric liquid crystal display device using the conventional STN driving IC to the bias terminal and the control terminal of the STN driving IC. It is to provide a signal form.

A fourth object of the present invention is to provide a circuit for generating a bias voltage applied to the STN driver IC.

A fifth object of the present invention is to provide a circuit for generating a signal form applied to the control terminal of the STN driving IC.

The driving waveform of the present invention for achieving the first object is a ferroelectric liquid crystal display device, wherein three pulses are applied to each liquid crystal cell of the ferroelectric liquid crystal display device for one pixel period, and the pulses are electrically charged. When the first information is displayed during the selection period, the first pulse having the first polarity, the second pulse having the second polarity opposite to the first polarity, and the third pulse having the first polarity are sequentially applied. Thus, the first and the third pulse to be less than the saturation voltage of the second polarity and the second pulse to be more than the saturation voltage of the first polarity so that the ferroelectric liquid crystal is in a first state by the second pulse. In order to display the second information during the selection period, the fourth pulse having the first polarity, the fifth pulse having the second polarity opposite to the first polarity, and the sixth pulse having the first polarity. Sequentially And the fourth and sixth pulses are below the saturation voltage of the second polarity, and the fifth pulses are above the saturation voltage of the first polarity, so that the ferroelectric liquid crystal is formed by the fifth pulse. Three kinds of processes in which the two states are oriented, and the orientation of the liquid crystal is not changed in a period other than the selection period, and the phase is inverted from the first polarity to the second polarity or from the second polarity to the first polarity during one pixel period. And applying the pulse waveforms according to the image data to be displayed.

The driving waveform applied to the first electrode group and the second electrode group of the present invention for achieving the second object includes a scan electrode group and a signal electrode group, and a ferroelectric liquid crystal between the scan electrode group and the signal electrode group. In the ferroelectric liquid crystal display device formed by enclosing the semiconductor light emitting device, pulses including the first voltage level, the second voltage level, and the first voltage level are sequentially applied to the scan electrode group in the pixel period in which the scan signal is selected according to the scan signal. In the pixel period in which the scan signal is not selected, pulses each consisting of a third voltage level, a fourth voltage level, and a third voltage level are sequentially applied to determine an intermediate voltage level between the third voltage level and the fourth voltage level. In the reference voltage level, the first voltage level and the second voltage level have opposite polarities, and the signal electrode group includes a first information signal according to an information signal. In the present pixel period, the fifth voltage level, the sixth voltage level, and the seventh voltage level are configured, and the fifth voltage level and the seventh voltage level have the same polarity, and the sixth voltage level has the opposite polarity. And the eighth voltage level, the ninth voltage level, and the tenth voltage level in the pixel period during which the second information is displayed, wherein the eighth voltage level and the tenth voltage level have the same polarity, and the ninth voltage level is And applying a pulse having an opposite polarity, wherein the ferroelectric liquid crystal is arranged in a first state by a composite waveform of the second voltage level and the sixth voltage level, and the second voltage level and the tenth voltage level Arranged in the second state by the composite waveform, the voltage levels 5, 6, 7, 8, 9, and 10 of the third and fourth voltage levels applied to the scan electrode group and the pulses applied to the signal electrode group. It does not change state by composite wave form with By comprising a process characterized by comprising.

A signal applied to the STN driver IC of the present invention for achieving the third object includes a ferroelectric liquid crystal display having a scan electrode group and a signal electrode group and encapsulating a liquid crystal between the scan electrode group and the signal electrode group. A method of driving an element using a general STN driving IC, wherein the scan electrode group is connected with a common COM driving IC and the signal electrode group is connected with an STN driving driver. And applying a frame synchronization signal to the scan signal input terminal (I) of the STN common driver IC, and applying image data to the data input terminal (D) of the segment drive IC for the STN. The STN driving common driver IC Signal is applied to the alternating signal input terminal (DF) of the segment driving IC and the phases thereof are " high ", " low " and " high " levels sequentially during the pixel period, or " low ", " high " low And a process of applying a signal of a level.

A circuit for generating a signal form applied to the control terminal of the STN driving IC of the present invention for achieving the fourth object includes a bias terminal of the driving IC so as to generate a bias voltage applied to each driving IC. It is characterized in that at least five resistors are connected in series between a first power supply and a second power supply applied to an analog multiplexer connected to supply a bias voltage, or an IC such as a synchronous lamp is used.

A circuit for generating a signal type applied to the control terminal (DF) of the STN driving IC of the present invention for achieving the fifth purpose is a channel of an analog multiplexer connected to a bias terminal of each driving IC to supply a bias voltage. And a logic circuit for synthesizing the channel selection signal for selecting the signal so that the synthesized signal is at the "high", "low", "high" level, or at the "low", "high", "low" level. Characterized in that made.

That is, according to the present invention, one screen is configured as a 1-scan screen by adjusting the driven voltage level to a certain range, and the signals of the DF terminals are sequentially " high ", " low ", " Set it to "high" level, or "low", "high", or "low" level, and apply the voltage level of each bias terminal appropriately based on the level voltage to be driven, respectively. The voltage is properly divided by each of them to apply to each bias terminal.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

2 is a driving waveform diagram for driving a ferroelectric liquid crystal as a first embodiment according to the present invention.

Referring to FIG. 2, first, the vertical electrode is divided into a waveform when the selection signal is applied and a waveform when the selection signal is not applied. In each case, three voltage levels are applied during the period of the selection or non-selection signal. Will be displayed.

When the three voltage levels while the selection signal is applied are referred to as the first voltage level, the second voltage level, and the third voltage level, the first voltage level and the third voltage level have the same polarity that does not change the arrangement of the ferroelectric liquid crystals. The second voltage level is a voltage level of opposite polarity to the first and third voltage levels, and is a level causing a state transition. The waveform when the selection signal is not applied represents waveforms of the fourth voltage level, the fifth voltage level, and the sixth voltage level, wherein the fourth voltage level and the sixth voltage level are voltage levels of the same polarity, and the fifth voltage. The level is reverse polarity.

Looking at the waveform in the segment, when the first information (data "1") is applied, a pulse that is the seventh voltage level, the eighth voltage level and the ninth voltage level is applied and the second information (data "0") is applied. When applied, the tenth voltage level, the eleventh level voltage, and the twelfth voltage level are sequentially applied, and the seventh, ninth, tenth, and twelfth voltage levels, and the eighth and eleventh voltage levels have opposite polarities. .

When the waveform of the vertical electrode and the waveform of the segment electrode are synthesized based on 0V, the following synthesized waveforms are shown. That is, when the first information is displayed during the selection period, a first pulse having a first polarity is applied, and a second pulse having a second polarity opposite to the first polarity is applied after the second pulse is applied. A third pulse having a first polarity is applied. In this case, the second voltage level at the vertical electrode and the eighth voltage level at the segment electrode are adjusted to align the ferroelectric liquid crystal in the first state by the second pulse. In addition, when the second information is displayed during the selection period, a fourth pulse having a first polarity is applied, and after the fourth pulse is applied, a fifth pulse having a second polarity opposite to the first polarity is applied. And a sixth pulse having a first polarity is applied to adjust the second voltage level at the vertical electrode and the twelfth voltage level at the segment electrode so that the ferroelectric liquid crystal is oriented in the second state by the sixth pulse. Adjust

Also, the image to display pulse waveforms whose phase is not reversed in the non-selective period and whose phase is sequentially reversed from the first polarity to the second polarity or from the second polarity to the first polarity during the 1-pixel period Applied according to the data.

3 is a driving waveform diagram for driving a ferroelectric liquid crystal as a second embodiment according to the present invention.

First, the vertical electrode is divided into a waveform when the selection signal is applied and a waveform when the selection signal is not applied. In each case, three voltage levels are displayed during the period of the selection or non-selection signal.

When the three voltage levels while the selection signal is applied are referred to as the first voltage level, the second voltage level, and the third voltage level, the first voltage level and the third voltage level do not change the arrangement of the ferroelectric liquid crystal. Level, and the second voltage level becomes a level causing a state transition. The waveform when the selection signal is not applied represents waveforms of the fourth voltage level, the fifth voltage level, and the sixth voltage level, and the fourth voltage level and the sixth voltage level are the same voltage level.

Looking at the waveform in the segment, when the first information (data "1") is applied, a pulse that is the seventh voltage level, the eighth voltage level and the ninth voltage level is applied and the second information (data "0") is applied. When applied, the tenth voltage level, the eleventh voltage level, and the twelfth voltage level are applied, and the seventh, ninth, tenth, and twelfth voltage levels, and the eighth and eleventh voltage levels have opposite polarities.

When the waveform of the vertical electrode and the waveform of the segment electrode are synthesized based on 0V, the following synthesized waveform is shown. That is, when the first information is displayed during the selection period, a first pulse having a first polarity is applied, and a second pulse having a second polarity opposite to the first polarity is applied after the first pulse is applied. Then, a third pulse having a first polarity is applied. In this case, the second voltage level at the vertical electrode and the ninth voltage level at the segment electrode are adjusted to align the ferroelectric liquid crystal in the first state by the third pulse. In addition, when the second information is displayed during the selection period, a fourth pulse having a first polarity is applied, and after the fourth pulse is applied, a fifth pulse having a second polarity opposite to the first polarity is applied. A sixth pulse having a first polarity is then applied to cause the ferroelectric liquid crystal to be oriented in the second state by the fifth pulse.

In addition, in the period other than the selection period, the orientation of the liquid crystal is not changed, and in the image data to display pulse waveforms whose phase is inverted from the first polarity to the second polarity or from the second polarity to the first polarity during the 1-pixel period. Is applied accordingly.

4A and 4C are explanatory diagrams of a vertical electrode driving IC for driving a general STN liquid crystal.

FIG. 4A shows the configuration of the vertical electrode driving IC chip. Referring to FIG. 4A, a latch terminal for inputting data into an image and a latch terminal for inputting a control latch signal and a control signal for driving a STN are generally used. called bias is a bias voltage and the DF terminal to enter the M signals is the terminal _{(V 1, V 3, V} 4, V EE) and the enable terminal and the m kinds of m output terminals for outputting a signal to the electrodes respectively, (O ₁ ... O _m ). Referring to the latch signal, in general, the STN vertical electrode driving IC includes a latch means internally and inputs data in a predetermined unit (m1) so that all the data capable of driving the m vertical electrodes are input according to the data. By outputting a driving signal, the latch signal serves to indicate a point in time at which all the data capable of driving the m vertical electrodes are input.

4B is a truth table showing an output value of an input value of the vertical electrode IC. Referring to FIG. 4B, the voltage level output according to the input data and the signal applied to the DF terminal is one of the voltage levels applied to the bias terminal. It can be seen that. In particular, the voltage applied to the bias terminal has a relationship of V ₁ > V ₃ > V ₄ > V _EE .

FIG. 4C is a waveform diagram showing the truth value of FIG. 4B as a waveform. Referring to FIG. 4C, the output level varies depending on a signal applied to the DF terminal and input data.

5A and 5C are explanatory diagrams of a transverse electrode driving IC for driving a general STN liquid crystal.

FIG. 5A shows the configuration of the vertical electrode driving IC chip. Referring to FIG. 5A, a bias terminal (V ₁ , V ₂ , V ₅ , V _EE ) for inputting a bias voltage and a terminal I for inputting a synchronization signal, generally called a frame signal, are referred to. And a DF terminal and an enable terminal (E) for inputting a modulation signal when driving the STN liquid crystal, a latch terminal for inputting the first latch signal of the controller when driving the STN, and a driving signal for driving the n horizontal electrodes. A signal having an n-bit shift register internally having n output terminals (O ₁ ... O _n ) and being applied to the I terminal is shifted by one for each signal applied to the n-bit shift register and applied to the latch terminal. It serves as scan data for driving n horizontal electrodes. The voltage input to the bias terminal has a relationship of V ₁ > V ₂ > V ₅ > V _EE .

FIG. 5B is a truth table showing the output value of the input value of the vertical electrode IC. Referring to FIG. 5B, the signal applied to the DF terminal is applied to the n output terminals at a "high" level, and V ₂ according to the scan data. It can be seen that signals of V _EE , V ₅ and V ₁ are applied. In this case, the scan data generally have a value of " 1 ", so that images are displayed one line at a time.

FIG. 5C is a waveform diagram showing the truth value of FIG. 5B as a waveform. Referring to FIG. 5C, it can be seen that the output level varies depending on the signal and scan data applied to the DF terminal when enabled.

FIG. 6 is an explanatory diagram for extracting an input signal input to the DF terminals of the vertical and horizontal electrode driving ICs shown in FIGS. 4 and 5.

Referring to FIG. 6, the signals A, "high", "high", "high", "high", "high", "low", "low", which are channel selection signals applied to the analog multiplexer from the monostable multivibrator 11 Low, "high", "low", or "high", "low", or "low", "low" or "low" signals to the DF terminal of the STN driver IC using exclusive OR or exclusive NOR, High "signal. In this case, signals of "low", "high" and "low" are applied to the DF terminal to extract the driving waveform of FIG. 2, and "high" and "low" to the DF terminal to extract the driving waveform of FIG. , High signal is applied.

7A and 7B are waveform diagrams of output signals corresponding to bias voltages and input signals of FIG. 4.

Referring to FIG. 7A, signals of "low", "high" and "low" of FIG. 6 are input to the DF terminal of the vertical electrode driving IC, and bias voltages V ₁ = 0 V and V _EE = -20 V are applied. In this case, signals of -20V, 0V, and -20V are output by the two input signals. When the same signal as above is input to the DF terminal and the signals of -10V, -20V, -10V are sequentially applied as V ₂ = V ₅ , the signals of -10V, -20V, -10V are generated by the two input signals. Is output.

Referring to the Figure 7b, DF terminal of the lateral electrode driving IC, the sixth degree, "Low", "High", a signal "Low" is input to a bias voltage V ₁ -15V, -20V, -20V When sequentially applied, signals of -5V, -20V, and -15V are output by the two input signals. If the same signal as above is input to the DF terminal and the signals of -15V, -20V, -5V are sequentially applied as V ₃ = V ₄ , the signals of -15V, -20V, -5V are applied by the two input signals. Is output.

8A and 8B are waveform diagrams of output signals according to the bias voltage and the input signal of FIG. 5.

Referring to FIG. 8A, signals of "high", "low", and "high" in FIG. 6 are input to the DF terminal of the transverse electrode driving IC and bias voltages V ₁ = 0 V and V _EE = -20 V are applied. In this case, signals of 0V, -20V, and 0V are output by the two input signals. When the same signal as above is input to the DF terminal and the signals of -10V, 0V, -10V are sequentially applied as the bias voltage is V ₂ = V ₅ , the signals of -10V, 0V, -10V are output by the two input signals. do.

Referring to FIG. 8B, signals of "high", "low", and "high" in FIG. 6 are input to the DF terminal of the transverse electrode driving IC, and -5V, -15V, -15V are sequentially provided as bias voltages VEE. When applied as, signals of -5V, 0V, -15V are output by the two input signals. When the same signal as above is input to the DF terminal and the signals of -15V, 0V, -5V are sequentially applied as the bias voltage is V ₃ = V ₄ , the signals of -15V, 0V, -5V are output by the two input signals. do.

FIG. 9 is a circuit diagram for generating a bias voltage input to each bias voltage terminal of an analog multiplexer that applies a bias voltage to the STN driving ICs of FIGS. 4 and 5.

Referring to FIG. 9, voltages are distributed using two supply power sources and five or more resistors, and applied to each bias terminal of the analog multiplexer 21. This is because the voltage supply range of the analog multiplexer 21 is very limited as + 2V- + 12V, so that the first supply power supply (V _DD1 , 5V in the present invention) and the second supply power supply (-V _DD2 , in the present invention) The voltage level applied at -5V) is adjusted to output the appropriate voltage by adjusting each resistance value of five or more resistors.

Specifically, the control terminal input signal generation circuit for generating a signal type applied to the control terminal (alternating signal terminal) of the STN driving IC is " high " which is a channel selection signal for selecting a channel to the analog multiplexer. The signal A which is "low", "low", and the signal B which is "high", "high", and "low" is applied, and it outputs a bias voltage selectively, and inverts and does not input for input to the bias terminal of the said STN driving IC. Output from the analog multiplexer in an amplifier having a resistor (R6) connected between the non-inverting terminal and the ground voltage of the amplifier 22 having an inverting terminal and a variable resistor (R7) connected between the non-inverting terminal and the output terminal. The amplified or amplified signal is input to the bias terminal of the STN driver IC.

Therefore, in the ferroelectric liquid crystal display device of the present invention, since the driving waveform is completely neutral in one frame, it is possible to improve the lifespan by preventing the deterioration of the liquid crystal and to increase the number of pulses required for one line addressing to three large screens. High speed driving is also possible.

Claims (8)

A method of driving a ferroelectric liquid crystal display device, the method of driving a ferroelectric liquid crystal display device characterized by sequentially applying three pulses which are electrically neutral for one pixel period to each liquid crystal cell of the ferroelectric liquid crystal display device. . The method of claim 1, wherein the method of applying the pulses comprises: a first pulse having a first polarity and a second pulse having a second polarity opposite to the first polarity when displaying first information during a selection period; A third pulse having a single polarity is sequentially applied so that the first and third pulses are less than or equal to the saturation voltage of the second polarity, and the second pulses are equal to or greater than the saturation voltage of the first polarity. Causing the ferroelectric liquid crystal to be oriented in a first state by two pulses; When the second information is displayed during the selection period, the fourth pulse having the first polarity and the fifth pulse having the second polarity opposite to the first polarity and the sixth pulse having the first polarity are sequentially applied. The fourth and sixth pulses may be less than or equal to the saturation voltage of the second polarity, and the fifth pulse may be greater than or equal to the saturation voltage of the first polarity such that the ferroelectric liquid crystal is aligned in the second state by the sixth pulse. To make it possible; And three kinds of pulse waveforms whose phase is inverted from the first polarity to the second polarity or from the second polarity to the first polarity for one pixel period without changing the alignment of the liquid crystal during the period other than the selection period. A method of driving a ferroelectric liquid crystal display device, comprising the step of applying according to image data. A method of driving a ferroelectric liquid crystal display device comprising a scan electrode group and a signal electrode group, and encapsulating a ferroelectric liquid crystal between the scan electrode group and the signal electrode group, wherein the scan electrode has a scan signal according to a scan signal. Pulses consisting of the first voltage level, the second voltage level, and the first voltage level are sequentially applied to the selected pixel period, and the third voltage level, the fourth voltage level, and the third voltage are sequentially applied to the pixel period during which the scan signal is not selected. Applying a pulse consisting of a voltage level and causing the first voltage level and the second voltage level to have opposite polarities; The signal electrode group includes a fifth voltage level, a sixth voltage level, and a seventh voltage level in the pixel period in which the first information signal is displayed according to the information signal, and the fifth voltage level and the seventh voltage level are the same. And a sixth voltage level is applied with a pulse having an opposite polarity, and the eighth voltage level, the ninth voltage level, and the tenth voltage level in the pixel period in which the second information is displayed. Applying a pulse having the same polarity and the ninth voltage level having the opposite polarity; The ferroelectric liquid crystal is arranged in a first state by a composite waveform of the second voltage level and a sixth voltage level, and is arranged in a second state by a composite waveform of the second voltage level and the tenth voltage level, and the scanning is performed. The state waveform is not changed by the composite waveform between the third and fourth voltage levels applied to the electrode group and the voltage levels (5, 6, 7, 8, 9, and 10 voltage levels) of the pulses applied to the signal electrode group. A method of driving a ferroelectric liquid crystal display device, characterized in that it comprises a process that does not. A method for driving a ferroelectric liquid crystal display device having a scan electrode group and a signal electrode group and encapsulating a liquid crystal between the scan electrode group and the signal electrode group using a general STN driving IC, wherein the scan electrode group includes: Connecting a STN common driving IC and connecting the STN segment driving IC to the signal electrode group; Applying a frame synchronization signal to the scan signal input terminal (I) of the STN common driver IC and applying image data to the data input terminal (D) of the segment drive IC for the STN; A signal whose phase is sequentially "high", "low", "high" level is applied to the alternating signal input terminal DF of the STN driving common driving IC and the segment driving IC, or "low". A method of driving a ferroelectric liquid crystal display device, comprising the step of applying a signal of "high," "low" level. A drive circuit of a ferroelectric liquid crystal device having a bias terminal and a control terminal applied to a STN driving IC, the channel selection signal being input from a monostable multivibrator to output a bias voltage of the STN driving IC. A plurality of resistors connected in series between a first power supply and a second power supply and a plurality of resistors for implementing predetermined voltage values between the first power supply and the second power supply of the voltage applied to the bias terminal of the analog multiplexer, and between the analog multiplexer and the STN driving IC. And an amplifying part for amplifying or increasing the signal output from the analog multiplexer and inputting the signal to the bias terminal of the STN driving IC; And combining two channel selection signals for selecting a channel of an analog multiplexer connected to the bias terminal to supply a bias voltage, the synthesized signals being “high”, “low”, “high” or “low”, “high”. A drive circuit for a ferroelectric liquid crystal display device, characterized in that it comprises a control terminal input signal generation circuit composed of a logic circuit for bringing " low " level. The method of claim 5, wherein the channel selection signal comprises a first signal of "high", "low", "low" and a second signal of "high", "high", "low", characterized in that Driving circuit for ferroelectric liquid crystal display device. 6. The driving circuit of a ferroelectric liquid crystal display device according to claim 5, wherein the logic circuit is an EX-NOR circuit when the combined signal of the channel selection signal is "high", "low", or "high". 6. The driving circuit of a ferroelectric liquid crystal display device according to claim 5, wherein the logic circuit is an EX-OR circuit when the combined signal of the channel selection signal is "low", "high", or "low".