JP2000122619A - Driving method of liquid crystal display element - Google Patents
Driving method of liquid crystal display elementInfo
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- JP2000122619A JP2000122619A JP29114198A JP29114198A JP2000122619A JP 2000122619 A JP2000122619 A JP 2000122619A JP 29114198 A JP29114198 A JP 29114198A JP 29114198 A JP29114198 A JP 29114198A JP 2000122619 A JP2000122619 A JP 2000122619A
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- electrode
- selection potential
- scanning
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- Liquid Crystal Display Device Control (AREA)
- Control Of Indicators Other Than Cathode Ray Tubes (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、液晶表示素子の駆動方
法に関する。より詳しくは、STN液晶等を用いた単純
マトリクスパネルの駆動方法に関する。さらに詳しく
は、表示画面の一部分のみに表示を行うのに適した駆動
方法に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for driving a liquid crystal display device. More specifically, the present invention relates to a method for driving a simple matrix panel using an STN liquid crystal or the like. More specifically, the present invention relates to a driving method suitable for performing display on only a part of a display screen.
【0002】[0002]
【従来の技術】液晶表示パネルは複数本の走査電極が形
成されたガラス基板と、複数本の信号電極が形成された
ガラス基板とで、液晶を挟み込んだ構造をしている。図
2は液晶表示パネルの電極の配置を示す図で、走査電極
はCOM 1からCOM NまでのN本、信号電極はSE
G 1からSEG MまでのM本である。走査電極と信号
電極はマトリクス状に配置され、N本の走査電極とM本
の信号電極とのN・M個の交点が表示画素となる。2. Description of the Related Art A liquid crystal display panel has a structure in which liquid crystal is sandwiched between a glass substrate on which a plurality of scanning electrodes are formed and a glass substrate on which a plurality of signal electrodes are formed. FIG. 2 is a view showing an arrangement of electrodes of the liquid crystal display panel. N scanning electrodes are provided from COM 1 to COM N, and signal electrodes are provided as SE.
There are M lines from G1 to SEG M. The scanning electrodes and the signal electrodes are arranged in a matrix, and NM intersections between the N scanning electrodes and the M signal electrodes become display pixels.
【0003】図2に示すように、通常はこのN・M個の
画素の中で表示オンさせたい画素には選択電圧を印加し
選択画素とし、また表示オフさせたい画素には非選択電
圧を印加し非選択画素として画面の全体で表示を行な
う。これを以下「全画面表示」とする。ここで、表示す
べき情報量が少ない場合、例えば時刻表示や簡単なメッ
セージ表示のみ行なうような場合は、画面の一部分だけ
を使えば表示が可能である。このとき全画面表示と同じ
駆動のままで、表示に使用しない領域の画素には非選択
電圧を印加しておいてもよいが、その場合は表示に使用
する画素は少なくても全画面表示と同じ電力を消費して
しまう。時刻表示などは常に行なわれている場合が多い
ので、このときの消費電力は、特に液晶表示素子が電池
駆動の携帯用電子機器に搭載されている場合などに、そ
の機器の連続使用時間を決める主な要因の一つとなる。As shown in FIG. 2, normally, a selection voltage is applied to a pixel whose display is to be turned on among the N · M pixels, and the selected pixel is selected, and a non-selection voltage is applied to a pixel whose display is to be turned off. Display is performed on the entire screen as a non-selected pixel by applying the voltage. This is hereinafter referred to as “full screen display”. Here, when the amount of information to be displayed is small, for example, when only time display or simple message display is performed, the display can be performed by using only a part of the screen. At this time, it is possible to apply a non-selection voltage to pixels in an area not used for display while maintaining the same drive as that for full screen display. It consumes the same power. In many cases, such as time display is always performed, so the power consumption at this time determines the continuous use time of the device, especially when the liquid crystal display element is mounted on a portable electronic device driven by a battery. One of the main factors.
【0004】そこで、画面の一部分だけを使えば表示が
可能なときには、全画面表示のときとは駆動方法を変え
て消費電力の低減を図る場合がある。これを以下「部分
表示」とする。部分表示の一例を図3に示す。図3のよ
うに部分表示時にはCOM1からCOM nまでの走査
電極上の画素(以下表示部とする)には、選択電圧また
は非選択電圧を印加し表示を行うが、残りのCOM(n
+1)からCOMNまでの走査電極上の画素(以下非表
示部とする)には非選択電圧以下の電圧しか印加せず表
示を行わない。ここで、nは1≦n<Nを満足する整数
とする。なお、図3では非表示部が画面の上部に位置し
ているが、対応する走査電極を変えれば非表示部の位置
を変えることができる。Therefore, when display is possible by using only a part of the screen, the driving method may be changed from that for full screen display to reduce power consumption. This is hereinafter referred to as “partial display”. FIG. 3 shows an example of the partial display. As shown in FIG. 3, at the time of partial display, display is performed by applying a selection voltage or a non-selection voltage to pixels on the scan electrodes from COM1 to COMn (hereinafter referred to as a display unit), while the remaining COM (n
Only a voltage equal to or lower than the non-selection voltage is applied to pixels on the scanning electrodes from +1) to COMN (hereinafter referred to as a non-display portion), and display is not performed. Here, n is an integer satisfying 1 ≦ n <N. In FIG. 3, the non-display portion is located at the top of the screen, but the position of the non-display portion can be changed by changing the corresponding scanning electrode.
【0005】このような部分表示を行う方法としては、
例えば、全画面表示時には1/Nデューティ駆動をして
いたものを、部分表示時には1/nデューティ駆動に切
り換える方法がある。このとき、 COM 1からCOM
nまでの走査電極には1/nデューティ駆動の選択電
圧を印加し、残りのCOM(n+1)からCOM Nま
での走査電極は常に非選択電位を保持する。このとき部
分表示時の走査電極選択電位と信号電極に印加する電位
の比を適当に選べば、非表示部印加電圧を表示部の非選
択電圧より小さくできる。また、この方法によれば全画
面表示時に比較して部分表示時には駆動周波数、および
走査電極選択電位がともに低減し、かつ、部分表示時に
は非表示部に対応する走査電極駆動回路は走査のための
動作を停止できるので低電力化の効果が大きい。[0005] As a method of performing such partial display,
For example, there is a method of switching from 1 / N duty driving during full screen display to 1 / n duty driving during partial display. At this time, from COM 1 to COM
A selection voltage of 1 / n duty drive is applied to the scan electrodes up to n, and the remaining scan electrodes from COM (n + 1) to COM N always hold the non-selection potential. At this time, the voltage applied to the non-display portion can be made smaller than the non-selection voltage of the display portion by appropriately selecting the ratio between the scanning electrode selection potential during partial display and the potential applied to the signal electrode. Further, according to this method, the driving frequency and the scanning electrode selection potential are both reduced during partial display as compared with full screen display, and the scan electrode driving circuit corresponding to the non-display section is used for scanning during partial display. Since the operation can be stopped, the effect of reducing power consumption is great.
【0006】[0006]
【発明が解決しようとする課題】しかし、この方法には
次のような欠点が有った。すなわち、Nに比較してnが
小さくなるほど、1/Nデューティ駆動と1/nデュー
ティ駆動の走査電極選択電位の差が拡大する。したがっ
て、1つのドライバICにより全画面表示と部分表示を
切り換えて行うためには、全画面表示のみ行なう場合に
比較して、ドライバICの動作電圧範囲を大幅に拡大し
なければならず、ICの製造上困難だったり、またIC
のチップ面積が増大し高コスト化するなどの欠点が有っ
た。また、全画面表示と部分表示を切り換えるたびに、
走査電極選択電位を調整しなければならなかったり、ま
たnが変わると走査電極選択電位と信号電極に印加する
電位との比も変えないといけないなどの煩雑さも有っ
た。However, this method has the following disadvantages. That is, as n becomes smaller than N, the difference between the scan electrode selection potentials of 1 / N duty drive and 1 / n duty drive increases. Therefore, in order to switch between full-screen display and partial display by one driver IC, the operating voltage range of the driver IC must be greatly expanded as compared with the case where only full-screen display is performed. Difficult to manufacture and IC
However, there are disadvantages such as an increase in chip area and an increase in cost. Also, every time you switch between full screen display and partial display,
There was also a trouble such that the scanning electrode selection potential had to be adjusted, and when n changed, the ratio between the scanning electrode selection potential and the potential applied to the signal electrode had to be changed.
【0007】[0007]
【課題を解決するための手段】上述した従来の技術の課
題に鑑み、本発明は、部分表示を全画面表示と同一の走
査電極選択電位あるいは、全画面表示に近い走査電極選
択電位で行い、かつ、部分表示時には全画面表示時より
低消費電力とすることを目的とする。かかる目的を達成
するために以下の手段を講じた。SUMMARY OF THE INVENTION In view of the above-mentioned problems of the prior art, the present invention provides a method of performing partial display at the same scan electrode selection potential as at full screen display or at scan electrode selection potential close to full screen display. It is another object of the present invention to reduce power consumption during partial display compared to full screen display. The following measures were taken in order to achieve this purpose.
【0008】方式1 N本の走査電極(Nは2以上の整数)と複数の信号電極
とからなるマトリクス型液晶表示素子の駆動方法におい
て、第一のモードと第二のモードを持ち、第一のモード
では全ての走査電極に期間τの選択電位を1フレーム毎
にL回(Lは自然数)印加し、選択電位を印加しない期
間は常に非選択電位に保持し、信号電極に信号電極と走
査電極との交点の画素の表示データと走査電極の選択電
位との対応で決まる電位を印加し、第二のモードではN
本の走査電極をn本の走査電極(nはn<Nなる整数)
からなる第一の走査電極群と残りの(N−n)本の走査
電極からなる第二の走査電極群に分割し、また、フレー
ム周期を第一の期間と第二の期間に分け、第一の走査電
極群の各走査電極には第一の期間に期間τの選択電位を
1フレーム毎にL回印加し、第一の期間において選択電
位を印加しない期間は常に非選択電位を保持し、第二の
期間は常に非選択電位を保持し、第二の走査電極群の各
走査電極はフレーム周期の全体にわたって常に非選択電
位を保持し、信号電極には第一の期間に信号電極と第一
の走査電極群の各走査電極との交点の画素の表示データ
と走査電極の選択電位との対応で決まる電位を印加し、
第二の期間にあらかじめ決めた所定の電位を印加する。Method 1 In a method for driving a matrix type liquid crystal display element comprising N scanning electrodes (N is an integer of 2 or more) and a plurality of signal electrodes, the method has a first mode and a second mode, In the mode, the selection potential in the period τ is applied L times (L is a natural number) per frame to all the scanning electrodes, and the non-selection potential is always held during the period in which the selection potential is not applied. The potential determined by the correspondence between the display data of the pixel at the intersection with the electrode and the selection potential of the scanning electrode is applied.
N scan electrodes (n is an integer such that n <N)
And a second scan electrode group consisting of the remaining (N-n) scan electrodes, and the frame period is divided into a first period and a second period. A selection potential in a period τ is applied L times per frame to each scanning electrode of one scanning electrode group during a first period, and a non-selection potential is always held during a period in which no selection potential is applied in the first period. , The second period always holds the non-selection potential, each scan electrode of the second scan electrode group always holds the non-selection potential over the entire frame period, and the signal electrode has the signal electrode during the first period. Applying a potential determined by the correspondence between the display data of the pixel at the intersection with each scanning electrode of the first scanning electrode group and the selection potential of the scanning electrode,
In the second period, a predetermined potential is applied.
【0009】方式1(1) 方式1の液晶表示素子の駆動方法で、走査電極の選択電
位を第一のモードと第二のモードとで同じ値にしたとき
に、選択画素に印加される実効電圧が第一のモードと第
二のモードとで等しくなるように、第二のモードにおい
て信号電極に第二の期間に印加する電位を決める。Method 1 (1) In the method of driving a liquid crystal display element of method 1, when the selection potential of the scan electrode is set to the same value in the first mode and the second mode, the effective voltage applied to the selected pixel is set. In the second mode, the potential applied to the signal electrode in the second period is determined so that the voltage is equal between the first mode and the second mode.
【0010】方式1(2) 方式1、または方式2の液晶表示素子の駆動方法で、第
二のモードにおいて信号電極に第二の期間に印加する電
位の極性を全体の半数またはほぼ半数の信号電極と残り
の信号電極とで反転させる。 方式1(3) 方式1、または方式2の液晶表示素子の駆動方法で、第
二のモードにおいて信号電極に第二の期間に印加する電
位の極性を隣り合う信号電極ごとに反転させる。Method 1 (2) In the liquid crystal display element driving method of method 1 or 2, the polarity of the potential applied to the signal electrode in the second mode in the second period is half or almost half of the signal polarity. It is inverted between the electrode and the remaining signal electrode. Method 1 (3) In the liquid crystal display element driving method of Method 1 or 2, the polarity of the potential applied to the signal electrodes in the second mode in the second mode is inverted for each adjacent signal electrode.
【0011】方式1(4) 方式1の液晶表示素子の駆動方法で、第二のモードにお
いて信号電極に第二の期間に印加する電位を走査電極の
非選択電位とする。 方式2 N本の走査電極(Nは2以上の整数)と複数の信号電極
とからなるマトリクス型液晶表示素子の駆動方法におい
て、第一のモードと第二のモードを持ち、第一のモード
では全ての走査電極に期間τの選択電位を1フレーム毎
にL回(Lは自然数)印加し、選択電位を印加しない期
間は常に非選択電位に保持し、信号電極に信号電極と走
査電極との交点の画素の表示データと走査電極の選択電
位との対応で決まる電位を印加し、第二のモードではN
本の走査電極をn本の走査電極(nはn<Nなる整数)
からなる第一の走査電極群と残りの(N−n)本の走査
電極からなる第二の走査電極群に分割し、また、フレー
ム周期を第一の期間と第二の期間に分け、第一の走査電
極群の各走査電極には第一の期間に期間τの選択電位を
1フレーム毎にL回印加し、第一の期間において選択電
位を印加しない期間は常に非選択電位を保持し、第二の
期間にατの期間(0<α≦1)の選択電位を1フレー
ム毎にL回印加し、第二の期間において選択電位を印加
しない期間は常に非選択電位を保持し、第二の走査電極
群の各走査電極はフレーム周期の全体にわたって常に非
選択電位を保持し、信号電極には第一の期間に信号電極
と第一の走査電極群の各走査電極との交点の画素の表示
データと走査電極の選択電位との対応で決まる電位を印
加し、第二の期間に走査電極の非選択電位を印加する。Method 1 (4) In the liquid crystal display element driving method of Method 1, the potential applied to the signal electrode in the second mode in the second period is set as the non-selection potential of the scanning electrode. Method 2 A method for driving a matrix-type liquid crystal display element including N scanning electrodes (N is an integer of 2 or more) and a plurality of signal electrodes has a first mode and a second mode. The selection potential in the period τ is applied L times (L is a natural number) per frame to all the scanning electrodes, and is kept at the non-selection potential during the period in which the selection potential is not applied. A potential determined by the correspondence between the display data of the pixel at the intersection and the selection potential of the scanning electrode is applied.
N scan electrodes (n is an integer such that n <N)
And a second scan electrode group consisting of the remaining (N-n) scan electrodes, and the frame period is divided into a first period and a second period. A selection potential of a period τ is applied to each scanning electrode of one scanning electrode group L times in each frame during a first period, and a non-selection potential is always held during a period when no selection potential is applied in the first period. In the second period, the selection potential in the period of ατ (0 <α ≦ 1) is applied L times for each frame, and in the second period, the non-selection potential is always held during the period in which the selection potential is not applied. Each scan electrode of the two scan electrode groups always holds a non-selection potential over the entire frame period, and the signal electrode has a pixel at the intersection of the signal electrode and each scan electrode of the first scan electrode group during the first period. And the potential determined by the correspondence between the display data and the selection potential of the scanning electrode. Applying a non-selection potential of the scan electrodes.
【0012】方式2(1) 方式2の液晶表示素子の駆動方法で、走査電極の選択電
位を第一のモードと第二のモードとで同じ値にしたとき
に、選択画素に印加される実効電圧が第一のモードと第
二のモードとで等しくなるようにαの値を選ぶ。 方式2(2) 方式2の液晶表示素子の駆動方法で、α=1とする。Method 2 (1) In the method of driving a liquid crystal display element of method 2, when the selection potential of the scanning electrode is set to the same value in the first mode and the second mode, the effective voltage applied to the selected pixel is set. The value of α is selected so that the voltage is equal in the first mode and the second mode. Method 2 (2) In the method of driving the liquid crystal display element of method 2, α = 1.
【0013】方式3 N本の走査電極(Nは2以上の整数)と複数の信号電極
とからなるマトリクス型液晶表示素子の駆動方法におい
て、第一のモードと第二のモードを持ち、第一のモード
では全ての走査電極に期間τの選択電位を1フレーム毎
にL回(Lは自然数)印加し、選択電位を印加しない期
間は常に非選択電位に保持し、信号電極に信号電極と走
査電極との交点の画素の表示データに対応して決まる電
位を印加し、第二のモードではN本の走査電極をn本の
走査電極(nはn<Nなる整数)からなる第一の走査電
極群と残りの(N−n)本の走査電極からなる第二の走
査電極群に分割し、また、フレーム周期を第一の期間と
第二の期間に分け、第一の走査電極群の各走査電極には
第一の期間に期間β・τの選択電位(1<β≦2、n<
N/β)を1フレーム毎にL回印加し、第一の期間にお
いて選択電位を印加しない期間は常に非選択電位を保持
し、第二の期間は常に非選択電位を保持し、第二の走査
電極群の各走査電極はフレーム周期の全体にわたって常
に非選択電位を保持し、信号電極には第一の期間に信号
電極と第一の走査電極群の各走査電極との交点の画素の
表示データと走査電極の選択電位との対応で決まる電位
を印加し、第二の期間に走査電極の非選択電位を印加す
る。Method 3 In a method for driving a matrix type liquid crystal display element comprising N scanning electrodes (N is an integer of 2 or more) and a plurality of signal electrodes, the method has a first mode and a second mode, In the mode, the selection potential in the period τ is applied L times (L is a natural number) per frame to all the scanning electrodes, and the non-selection potential is always held during the period in which the selection potential is not applied. A potential determined according to the display data of the pixel at the intersection with the electrode is applied, and in the second mode, N scan electrodes are replaced with a first scan composed of n scan electrodes (n is an integer of n <N). The first scan electrode group is divided into a first scan electrode group and a second scan electrode group including a second scan electrode group including the electrode group and the remaining (N−n) scan electrodes. Each scanning electrode has a selection potential (1 <β ≦ 2, n <
N / β) is applied L times for each frame. In the first period, the non-selection potential is always held during the period when the selection potential is not applied, and the second period is always held at the non-selection potential. Each scan electrode of the scan electrode group always holds a non-selection potential over the entire frame period, and the signal electrode displays a pixel at the intersection of the signal electrode and each scan electrode of the first scan electrode group during the first period. A potential determined by the correspondence between the data and the selection potential of the scan electrode is applied, and a non-selection potential of the scan electrode is applied in the second period.
【0014】方式3(1) 方式3の液晶表示素子の駆動方法で、走査電極の選択電
位を第一のモードと第二のモードとで同じ値にしたとき
に、選択画素に印加される実効電圧が第一のモードと第
二のモードとで等しくなるようにβの値を選ぶことを特
徴とする液晶表示素子の駆動方法。Method 3 (1) In the method of driving a liquid crystal display element of method 3, when the selection potential of the scanning electrode is set to the same value in the first mode and the second mode, the effective voltage applied to the selected pixel is set. A method of driving a liquid crystal display element, wherein a value of β is selected so that a voltage is equal between a first mode and a second mode.
【0015】方式3(2) 方式3の液晶表示素子の駆動方法で、β=2とする。本
発明の液晶表示素子の駆動方法によれば、第一のモード
で全画面表示をすることができ、第二のモードで部分表
示をすることができる。また、本発明の部分表示方法で
は、部分表示時には非表示部に対応する走査電極駆動回
路は走査のための動作を停止でき、また、部分表示時の
第二の期間には信号電極駆動回路への表示データの転送
や信号電極駆動回路での表示データから駆動出力への変
換動作などが不要になり、さらに、非表示部への印加電
圧を全画面表示時の非選択電圧より小さくできるので液
晶表示素子の駆動回路の消費電力を低減することができ
る。Method 3 (2) In the method of driving a liquid crystal display element of method 3, β = 2. According to the liquid crystal display element driving method of the present invention, full-screen display can be performed in the first mode, and partial display can be performed in the second mode. Further, in the partial display method of the present invention, the scan electrode driving circuit corresponding to the non-display portion can stop the operation for scanning at the time of partial display, and the signal electrode drive circuit is turned on during the second period at the time of partial display. This eliminates the need for transfer of display data and the conversion of display data to drive output in the signal electrode drive circuit, and the voltage applied to the non-display section can be made lower than the non-selection voltage for full-screen display. The power consumption of the display element driver circuit can be reduced.
【0016】また、本発明の部分表示方法では、部分表
示を全画面表示と同一の走査電極選択電位あるいは、全
画面表示に近い走査電極選択電位で行うことができる。
したがって、1つのドライバICにより全画面表示と部
分表示を切り換えて行う場合でも、全画面表示のみ行な
う場合に比較して、ドライバICの動作電圧範囲はほぼ
同じで良く、ICのチップ面積の増大などの問題は発生
しない。また、全画面表示と部分表示を切り換えても、
走査電極選択電位の調整はほとんど必要ない。また、部
分表示部のコモン電極本数nが変わっても走査電極選択
電位と信号電極に印加する電位の比や走査電極選択電位
を変える必要はほとんどない。Further, in the partial display method of the present invention, partial display can be performed at the same scan electrode selection potential as in full screen display or at scan electrode selection potential close to full screen display.
Therefore, even when switching between full screen display and partial display is performed by one driver IC, the operating voltage range of the driver IC may be substantially the same as in the case where only full screen display is performed, and the chip area of the IC increases. The problem does not occur. Also, even if you switch between full screen display and partial display,
Adjustment of the scanning electrode selection potential is hardly necessary. Further, even if the number n of the common electrodes in the partial display section changes, it is almost unnecessary to change the ratio of the scanning electrode selection potential to the potential applied to the signal electrode or the scanning electrode selection potential.
【0017】[0017]
【発明の実施の形態】以下図面を参照して本発明の好適
な実施例を詳細に説明する。 (実施の形態1)全画面表示での駆動方法を図4、およ
び図5を参照して説明する。図4は全画面表示を線順次
駆動(1ライン選択駆動)で行なう場合の走査電極駆動
波形と信号電極駆動波形の一例である。走査電極の選択
電位は+VCまたは−VC 、走査電極の非選択電位は
0電位である。COM 1、COM 2、COM 3、…
の順に時間をずらしながら期間τの走査電極選択電位を
印加して行き、COM Nまで印加し終わると1回の走
査が完了する。1回の走査に要する期間をフレーム周期
と呼び、N・τの長さとなる。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below in detail with reference to the drawings. (Embodiment 1) A driving method in full-screen display will be described with reference to FIGS. FIG. 4 shows an example of scan electrode drive waveforms and signal electrode drive waveforms when full-screen display is performed by line-sequential driving (one-line selection driving). The selection potential of the scanning electrode is + VC or -VC, and the non-selection potential of the scanning electrode is 0 potential. COM 1, COM 2, COM 3, ...
The scan electrode selection potential for the period τ is applied while shifting the time in the order of, and when the application to COM N is completed, one scan is completed. A period required for one scan is called a frame period, and has a length of N · τ.
【0018】一方、信号電極には、走査電極選択電圧が
印加されている走査電極上の画素を選択(表示オン)す
る場合は信号電極選択電位を、非選択(表示オフ)する
場合は信号電極非選択電位を印加する。ここで、走査電
極選択電位が+VCの場合は信号電極非選択電位が+V
S、信号電極選択電位が−VS、また、走査電極選択電
位が−VCの場合は信号電極非選択電位が−VS、信号
電極選択電位が+VSとなる。液晶表示パネルの劣化防
止のため1フレームごとに各駆動波形の極性を反転させ
る。On the other hand, the signal electrode has a signal electrode selection potential when a pixel on the scanning electrode to which the scanning electrode selection voltage is applied is selected (display ON), and a signal electrode is selected when the pixel is not selected (display OFF). Apply a non-selection potential. Here, when the scanning electrode selection potential is + VC, the signal electrode non-selection potential is + V
S, when the signal electrode selection potential is -VS, and when the scanning electrode selection potential is -VC, the signal electrode non-selection potential is -VS and the signal electrode selection potential is + VS. The polarity of each drive waveform is inverted every frame to prevent deterioration of the liquid crystal display panel.
【0019】図5はこのときに走査電極と信号電極に印
加される電位の差、すなわち表示画素に印加される電圧
である。この表示画素への印加電圧の実効値を式で表わ
すと、非選択電圧VOFFおよび選択電圧VONはそれ
ぞれ、 VOFF={(VC-VS)2/N+(N-1)・VS2/N}1/2 (数1) VON={(VC+VS)2/N+(N-1)・VS2/N}1/2 (数2) 次に、部分表示での各種駆動方法を説明する。FIG. 5 shows the difference between the potentials applied to the scanning electrodes and the signal electrodes at this time, that is, the voltages applied to the display pixels. When the effective value of the voltage applied to the display pixel is expressed by an equation, the non-selection voltage VOFF and the selection voltage VON are respectively VOFF = {(VC−VS) 2 / N + (N−1) · VS 2 / N} 1 / 2 (Equation 1) VON = {(VC + VS) 2 / N + (N−1) · VS 2 / N} 1/2 (Equation 2) Next, various driving methods in partial display will be described.
【0020】方式1 図6に示すように、 ・期間N・τのフレーム周期を前半の期間n・τの第一
の期間と残りの期間(N−n)・τの第二の期間に分け
る。 ・表示部の走査電極(COM 1〜COM n)には、第
一の期間に期間τの選択電位を順次時間をずらしながら
印加する。選択電位の印加されていない期間は常に非選
択電位を保持する。Method 1 As shown in FIG. 6, the frame period of the period N · τ is divided into a first period of the first half period n · τ and a second period of the remaining period (N−n) · τ. . In the first period, the selection potential in the period τ is applied to the scan electrodes (COM 1 to COM n) of the display unit while sequentially shifting the time. The non-selection potential is always maintained during the period when the selection potential is not applied.
【0021】・非表示部の走査電極(COM n+1〜
COM N)は、フレーム周期の全体にわたって常に非
選択電位を保持する。・また、信号電極(SEG1〜S
EG M)には、第一の期間にその信号電極と走査電極
(COM 1〜COM n)との交点の画素の表示データ
と走査電極の選択電位との対応で全画面表示のときと同
様にして決まる電位を印加する。また、第二の期間にあ
らかじめ決めた所定の電位を印加する。Scanning electrodes (COM n + 1 to COM n + 1)
COM N) always holds the non-selection potential throughout the frame period.・ In addition, signal electrodes (SEG1-SEG)
EGM) includes, in the first period, the correspondence between the display data of the pixel at the intersection of the signal electrode and the scanning electrode (COM1 to COMn) and the selection potential of the scanning electrode in the same manner as in full-screen display. Is applied. In addition, a predetermined potential is applied in the second period.
【0022】・全画面表示時と同様に、液晶表示パネル
の劣化防止のため1フレームごとに各駆動波形の極性を
反転させる。 方式1(1) 方式1で走査電極の選択電位を全画面表示時と部分表示
時とで同じ値にしたときに、選択画素に印加される実効
電圧が全画面表示時と部分表示時とで等しくなるよう
に、部分表示時において信号電極に第二の期間に印加す
る電位を決める。そのためには、部分表示時において信
号電極に第二の期間に印加する電位を全画面表示時と同
じにすればよく、そのときに非表示部に想定する表示デ
ータは任意である。したがって、低電力化のためには、
信号電極選択電位、または信号電極非選択電位を第二の
期間中でなるべく電位の変化が少ないように選ぶのが望
ましい。その一例として、図6に第二の期間中の全てに
わたって信号電極非選択電位を印加する場合の信号電極
駆動波形を示す。As in the case of full-screen display, the polarity of each drive waveform is inverted for each frame to prevent deterioration of the liquid crystal display panel. Method 1 (1) When the selection potential of the scan electrode is set to the same value in the full screen display and the partial display in the method 1, the effective voltage applied to the selected pixel changes between the full screen display and the partial display. The potential to be applied to the signal electrode during the second period during partial display is determined so as to be equal. For this purpose, the potential applied to the signal electrode during the second period during the partial display may be the same as that during the full-screen display, and the display data assumed in the non-display portion at that time is arbitrary. Therefore, for low power,
It is desirable to select the signal electrode selection potential or the signal electrode non-selection potential so that the potential change during the second period is as small as possible. As an example, FIG. 6 shows a signal electrode drive waveform when a signal electrode non-selection potential is applied over the entire period during the second period.
【0023】このときに走査電極と信号電極に印加され
る電位の差、すなわち表示画素に印加される電圧を図7
に示す。このときの表示部の非選択電圧、選択電圧、お
よびの非表示部の印加電圧の実効値をそれぞれVOFF
1、VON1、およびVN1とすると、 VOFF1={(VC-VS)2/N+(N-1)・VS2/N}1/2 (数3) VON1={(VC+VS)2/N+(N-1)・VS2/N}1/2 (数4) VN1=VS (数5) 方式1(2) 方式1(1)で部分表示時において複数の信号電極に第
二の期間に印加する電位の極性を全体の半数またはほぼ
半数の信号電極と残りの信号電極とで反転させる。例え
ば、全体の半数またはほぼ半数の信号電極には第二の期
間中の全てにわたって信号電極非選択電位を印加し、残
りの信号電極には第二の期間中の全てにわたって信号電
極選択電位を印加する。これにより、液晶表示素子の充
放電電流が相殺するので駆動回路の消費電力を低減でき
る。このときの表示部の非選択電圧、選択電圧、および
の非表示部の印加電圧の実効値は、方式1(1)と同一
である。At this time, the difference between the potentials applied to the scanning electrodes and the signal electrodes, that is, the voltage applied to the display pixels is shown in FIG.
Shown in At this time, the non-selection voltage of the display unit, the selection voltage, and the effective value of the applied voltage of the non-display unit are set to VOFF, respectively.
1, VON1, and When VN1, VOFF1 = {(VC- VS) 2 / N + (N-1) · VS 2 / N} 1/2 ( number 3) VON1 = {(VC + VS) 2 / N + ( N-1) · VS 2 / N} 1/2 (Equation 4) VN1 = VS (Equation 5) Method 1 (2) Applying to a plurality of signal electrodes during partial display in method 1 (1) during the second period The polarity of the potential is inverted between half or almost half of the signal electrodes and the remaining signal electrodes. For example, a signal electrode non-selection potential is applied to all or a half of the entire signal electrodes during the second period, and a signal electrode selection potential is applied to all of the remaining signal electrodes during the second period. I do. As a result, the charge and discharge currents of the liquid crystal display element cancel each other, so that the power consumption of the drive circuit can be reduced. At this time, the non-selection voltage of the display unit, the selection voltage, and the effective value of the applied voltage of the non-display unit are the same as those in the method 1 (1).
【0024】方式1(3) 方式1(1)で部分表示時において複数の信号電極に第
二の期間に印加する電位の極性を隣り合う信号電極ごと
に反転させる。例えば、奇数番目の信号電極には第二の
期間中の全てにわたって信号電極非選択電位を印加し、
偶数番目の信号電極には第二の期間中の全てにわたって
信号電極選択電位を印加する。これにより、液晶表示素
子の充放電電流が相殺するので駆動回路の消費電力を低
減できる。このときの表示部の非選択電圧、選択電圧、
およびの非表示部の印加電圧の実効値は、方式1(1)
と同一である。Method 1 (3) In the method 1 (1), the polarity of the potential applied to the plurality of signal electrodes in the second period is inverted for each adjacent signal electrode during partial display. For example, a signal electrode non-selection potential is applied to the odd-numbered signal electrodes throughout the second period,
A signal electrode selection potential is applied to the even-numbered signal electrodes throughout the second period. As a result, the charge and discharge currents of the liquid crystal display element cancel each other, so that the power consumption of the drive circuit can be reduced. At this time, the non-selection voltage, selection voltage,
The effective value of the applied voltage of the non-display part is calculated by the method 1 (1)
Is the same as
【0025】方式1(4) 方式1で部分表示時において信号電極に第二の期間に印
加する電位を走査電極非選択電位とする。このときの走
査電極駆動波形と信号電極駆動波形を図8に示す。ま
た、このときの走査電極と信号電極に印加される電位の
差、すなわち表示画素に印加される電圧を図9に示す。
このときの表示部の非選択電圧、選択電圧、およびの非
表示部の印加電圧の実効値をそれぞれVOFF2、VO
N2、およびVN2とすると、 VOFF2={(VC-VS)2/N+(n-1)・VS2/N}1/2 (数6) VON2={(VC+VS)2/N+(n-1)・VS2/N}1/2 (数7) VN2=VS・(n/N)1/2 (数8) N=240で、全画面表示時と部分表示時に共通にVC
=18.12(V)、VS=1.17(V)の条件で、
n=8、16、32、64、および120のときの各
電圧を計算し、全画面表示、方式1(1)、および方式
1(4)を比較すると、Method 1 (4) The potential applied to the signal electrode during the second period in the partial display in the method 1 is defined as a scanning electrode non-selection potential. FIG. 8 shows the scan electrode drive waveform and the signal electrode drive waveform at this time. FIG. 9 shows the difference between the potentials applied to the scanning electrodes and the signal electrodes at this time, that is, the voltages applied to the display pixels.
At this time, the effective values of the non-selection voltage of the display unit, the selection voltage, and the applied voltage of the non-display unit are VOFF2 and VO, respectively.
N2, and if the VN2, VOFF2 = {(VC- VS) 2 / N + (n-1) · VS 2 / N} 1/2 ( number 6) VON2 = {(VC + VS) 2 / N + (n- 1) · VS 2 / N} 1/2 (Equation 7) VN2 = VS · (n / N) 1/2 (Equation 8) When N = 240, VC is common during full screen display and partial display.
= 18.12 (V), VS = 1.17 (V),
Computing each voltage when n = 8, 16, 32, 64, and 120, and comparing full screen display, method 1 (1), and method 1 (4),
【0026】[0026]
【表1】 [Table 1]
【0027】方式1(1)は、nによらず、部分表示時
の非選択電圧、選択電圧ともに全画面表示時と同じで、
非表示部印加電圧は非選択電圧の約68%となる。した
がって、部分表示時にも全画面表示時と同じコントラス
ト比で表示ができ、しかも非表示部への印加電圧が全画
面表示時より低減される。方式1(4)では、 非表示
部印加電圧が方式1(1)のときより小さくなるが、部
分表示時の非選択電圧、および選択電圧が全画面表示時
より小さくなってしまう。 また、nが小さくなるほど
部分表示時の各電圧も小さくなる。したがって、VC、
VSを一定にしたままでは部分表示部の電圧が不足し、
表示しなくなってしまうので、部分表示時には全画面表
示時よりもVC、VSを大きくする必要がある。In the method 1 (1), the non-selection voltage and the selection voltage in the partial display are the same as those in the full-screen display regardless of n.
The non-display portion applied voltage is about 68% of the non-selection voltage. Therefore, the display can be performed with the same contrast ratio as in the full-screen display even in the partial display, and the voltage applied to the non-display portion is reduced as compared with the full-screen display. In the method 1 (4), the non-display portion applied voltage is lower than in the method 1 (1), but the non-selection voltage and the selection voltage in the partial display are lower than in the full screen display. Further, as n becomes smaller, each voltage at the time of partial display also becomes smaller. Therefore, VC,
If the VS is kept constant, the voltage of the partial display becomes insufficient,
Since the display is not performed, it is necessary to make VC and VS larger in partial display than in full screen display.
【0028】以上のように、方式1(4)は非表示部印
加電圧を方式1(1)のときより小さくできるという利
点があるが、部分表示部に表示するためにはVC、VS
を全画面表示時より大きくしなければならないという欠
点を有する。そこで、その欠点の改善を図ったのが以下
の方式2、および方式3である。 方式2 図1に示すように、 ・期間N・τのフレーム周期を前半の期間n・τの第一
の期間と残りの期間(N−n)・τの第二の期間に分け
る。As described above, although the method 1 (4) has an advantage that the non-display portion applied voltage can be made smaller than that of the method 1 (1), VC and VS are required for displaying on the partial display portion.
Has to be made larger than in full-screen display. Therefore, the following methods 2 and 3 have attempted to improve the disadvantage. Method 2 As shown in FIG. 1, the frame period of the period N · τ is divided into the first period of the first half period n · τ and the second period of the remaining period (N−n) · τ.
【0029】・表示部の走査電極(COM 1〜COM
n)には、第一の期間に期間τの選択電位を順次時間を
ずらしながら印加し、第二の期間に期間α・τの選択電
位(0<α≦1)を印加する。選択電位の印加されてい
ない期間は常に非選択電位を保持する。 ・非表示部の走査電極(COM n+1〜COM N)
は、フレーム周期の全体にわたって常に非選択電位を保
持する。Scanning electrodes of the display section (COM 1 to COM
In n), the selection potential of the period τ is applied while sequentially shifting the time during the first period, and the selection potential (0 <α ≦ 1) of the period α · τ is applied during the second period. The non-selection potential is always maintained during the period when the selection potential is not applied. -Scan electrode of non-display part (COM n + 1 to COM N)
Keeps the non-selection potential at all times during the entire frame period.
【0030】・また、信号電極(SEG1〜SEG
M)には、第一の期間にその信号電極と走査電極(CO
M 1〜COM n)との交点の画素の表示データと走査
電極の選択電位との対応で全画面表示のときと同様にし
て決まる電位を印加する。また、第二の期間に走査電極
非選択電位を印加する。 ・全画面表示時と同様に、液晶表示パネルの劣化防止の
ため1フレームごとに各駆動波形の極性を反転させる。The signal electrodes (SEG1-SEG)
M) has its signal electrode and scan electrode (CO
A potential determined in the same manner as in the case of full-screen display is applied by the correspondence between the display data of the pixel at the intersection with M 1 to COM n) and the selection potential of the scanning electrode. In addition, a scanning electrode non-selection potential is applied in the second period. As in the case of full screen display, the polarity of each drive waveform is inverted for each frame to prevent deterioration of the liquid crystal display panel.
【0031】このとき、走査電極と信号電極に印加され
る電位の差、すなわち表示画素に印加される電圧を図1
0に示す。表示部の非選択電圧、選択電圧、およびの非
表示部の印加電圧の実効値をそれぞれVOFF3、VO
N3、およびVN3とすると、 VOFF3={(VC-VS)2/N+(n-1)・VS2/N+α・VC2/N}1/2 (数9) VON3={(VC+VS)2/N+(n-1)・VS2/N+α・VC2/N}1/2 (数10) VN3=VS・(n/N)1/2 (数11) 方式2(1) 方式2で走査電極の選択電位を全画面表示時と部分表示
時とで同じ値にしたときに、選択画素に印加される実効
電圧が全画面表示時と部分表示時とで等しくなるように
αの値を決める。部分表示時のVCと全画面表示時のV
Cを同じ値に、かつ部分表示時のVSと全画面表示時の
VSを同じ値にしたときに、選択電圧を等しくするため
の条件は、VON3=VONより α=(N-n)・(VS/VC)2 (数12) N=240で、全画面表示時と部分表示時に共通にVC
=18.12(V)、VS=1.17(V)の条件で、
n=8、16、32、64、および120のときの各
電圧を計算し、全画面表示、方式1(1)、および方式
2(1)を比較すると、At this time, the difference between the potentials applied to the scanning electrodes and the signal electrodes, that is, the voltage applied to the display pixels is shown in FIG.
0 is shown. The effective values of the non-selection voltage of the display unit, the selection voltage, and the applied voltage of the non-display unit are VOFF3 and VO, respectively.
N3, and when the VN3, VOFF3 = {(VC- VS) 2 / N + (n-1) · VS 2 / N + α · VC 2 / N} 1/2 ( number 9) VON3 = {(VC + VS ) 2 / N + (n−1) · VS 2 / N + α · VC 2 / N} 1/2 (Equation 10) VN3 = VS · (n / N) 1/2 (Equation 11) Method 2 (1) When the selection potential of the scanning electrode is set to the same value in the full screen display and the partial display in the method 2, α is set so that the effective voltage applied to the selected pixel is equal between the full screen display and the partial display. Determine the value of VC at partial display and V at full screen display
When C is set to the same value and VS at the time of partial display and VS at the time of full screen display are set to the same value, the condition for equalizing the selected voltage is as follows: VON3 = VON, α = (Nn) · (VS / VC) 2 (Equation 12) When N = 240, VC is common to both full screen display and partial display.
= 18.12 (V), VS = 1.17 (V),
Computing each voltage when n = 8, 16, 32, 64, and 120, and comparing full screen display, method 1 (1), and method 2 (1),
【0032】[0032]
【表2】 [Table 2]
【0033】方式2(1)によれば、全画面表示時と同
一の非選択電圧、および選択電圧を保ったまま、非表示
部印加電圧を方式1(1)よりも低減することができ
る。nが小さいほど非表示部印加電圧の低減効果が大き
く、例えばn=8の場合、方式2(1)の非表示部印加
電圧は全画面表示時の非選択電圧の約13%となる。ま
た n=8の場合、方式2(1)の非表示部印加電圧は
方式1(1)の非表示部印加電圧の約18%となる。According to the method 2 (1), the non-display portion applied voltage can be reduced as compared with the method 1 (1) while maintaining the same non-selection voltage and the same selection voltage as in full-screen display. The smaller the value of n, the greater the effect of reducing the non-display portion applied voltage. For example, when n = 8, the non-display portion applied voltage in the method 2 (1) is about 13% of the non-selection voltage during full screen display. When n = 8, the applied voltage of the non-display portion in the method 2 (1) is about 18% of the applied voltage of the non-display portion in the method 1 (1).
【0034】ここで、図1では期間αの選択電位をCO
M 1からCOM nまでの走査電極に、同一の位相で印
加しているが、第二の期間内であれば位相は任意に選べ
る。例えば走査電極ごとに異なる位相にしてもよく、そ
のときの印加電圧は同一の位相のときと変わらない。 方式2(2) 方式2(1)で、部分表示時と全画面表示時とでVCお
よびVSを同じ電圧とし、かつ選択電圧も同一にするた
めのαの値は表2のように整数ではない。したがって、
表示タイミングを作るための基本クロックを全画面表示
時より高周波数にしなけれならず、その部分での電力増
加が伴うのと、表示タイミングを作るための分周回路の
構成が若干複雑になるという欠点がある。Here, in FIG. 1, the selection potential in the period α is CO
Although the same phase is applied to the scan electrodes from M1 to COMn, the phase can be arbitrarily selected within the second period. For example, a different phase may be set for each scanning electrode, and the applied voltage at that time is the same as that at the same phase. Method 2 (2) In method 2 (1), in order to make VC and VS the same voltage during partial display and full screen display, and to make the selection voltage the same, the value of α is an integer as shown in Table 2. Absent. Therefore,
The drawback is that the basic clock for creating the display timing must be higher than that for full-screen display, which increases the power in that part and complicates the configuration of the frequency divider circuit for creating the display timing. There is.
【0035】そこで、上記の欠点を改善するために、方
式2(2)では、方式2において、α=1に固定する。
α=1に固定すると、走査電極に印加する選択電位の期
間は全て等しくτになるので、全画面表示時より高周波
数の表示タイミングは不要である。N=240で、全画
面表示時と部分表示時に共通にVC=18.12
(V)、VS=1.17(V)の条件で、 n=8、1
6、32、64、および120のときの各電圧を計算
し、全画面表示、方式1(1)、および方式2(2)を
比較すると、Therefore, in order to improve the above-mentioned disadvantage, in method 2 (2), α = 1 is fixed in method 2.
When α is fixed to 1, the period of the selection potential applied to the scanning electrode is equal to τ, so that the display timing of a higher frequency than in the full screen display is unnecessary. When N = 240, VC = 18.12 is common to both full screen display and partial display.
(V), VS = 1.17 (V), n = 8, 1
Computing each voltage at 6, 32, 64 and 120 and comparing full screen display, method 1 (1) and method 2 (2),
【0036】[0036]
【表3】 [Table 3]
【0037】方式2(2)の場合、非表示部印加電圧は
方式2(1)と同じで、部分表示時の選択電圧、非選択
電圧ともに全画面表示時より若干大きくなる。ただし、
n≦8のときは、部分表示時の選択電圧、非選択電圧と
もに全画面表示時とほぼ同じ電圧となるので、VC、V
Sは全画面表示時のままでも部分表示時の表示部の表示
が可能である。In the case of the method 2 (2), the non-display portion applied voltage is the same as that of the method 2 (1), and both the selection voltage and the non-selection voltage at the time of partial display are slightly higher than at the time of full screen display. However,
When n ≦ 8, both the selection voltage and the non-selection voltage at the time of partial display are substantially the same as those at the time of full-screen display.
S can be displayed on the display unit at the time of partial display even if it is at the time of full screen display.
【0038】nが増えるにしたがって、部分表示時の選
択電圧、非選択電圧ともに高くなるので、表示が濃くな
り過ぎた場合は、VCおよびVSを下げるように電圧調
整する必要がある。ただし、この電圧調整幅は通常表示
時に1/Nデューティ駆動をしていたものを、部分表示
時に1/nデューティ駆動に切り換える方法に比較して
かなり小さいので、ドライバICの駆動電圧範囲は問題
にならない。As n increases, both the selection voltage and the non-selection voltage at the time of partial display become higher. If the display becomes too dark, it is necessary to adjust the voltage so as to lower VC and VS. However, since this voltage adjustment width is much smaller than the method of performing 1 / N duty drive during normal display, but switching to 1 / n duty drive during partial display, the drive voltage range of the driver IC is problematic. No.
【0039】方式3 図11に示すように、 ・期間N・τのフレーム周期を前半の期間n・β・τの
第一の期間(1<β≦2、n<N/β)と残りの期間
(N−n・β )・τの第二の期間に分ける。 ・表示部の走査電極(COM 1〜COM n)には、第
一の期間に期間β・τの選択電位を順次時間をずらしな
がら印加する。選択電位の印加されていない期間は常に
非選択電位を保持する。Method 3 As shown in FIG. 11, the frame period of the period N · τ is divided into the first period (1 <β ≦ 2, n <N / β) of the first half period n · β · τ. The period is divided into a second period of (N−n · β) · τ. -To the scanning electrodes (COM1 to COMn) of the display unit, the selection potentials of the periods β and τ are applied while sequentially shifting the time during the first period. The non-selection potential is always maintained during the period when the selection potential is not applied.
【0040】・非表示部の走査電極(COM n+1〜
COM N)は、フレーム周期の全体にわたって常に非
選択電位を保持する。 ・また、信号電極(SEG1〜SEG M)には、第一
の期間にその信号電極と走査電極(COM 1〜COM
n)との交点の画素の表示データと走査電極の選択電位
との対応で全画面表示のときと同様にして決まる電位を
印加する。また、第二の期間に走査電極非選択電位を印
加する。Scanning electrodes in the non-display area (COM n + 1 to COM n + 1)
COM N) always holds the non-selection potential throughout the frame period. The signal electrodes (SEG1-SEGM) have their signal electrodes and scanning electrodes (COM1-COM) in the first period.
A potential determined in the same manner as in full-screen display is applied in correspondence with the display data of the pixel at the intersection with n) and the selection potential of the scanning electrode. In addition, a scanning electrode non-selection potential is applied in the second period.
【0041】・全画面表示時と同様に、液晶表示パネル
の劣化防止のため1フレームごとに各駆動波形の極性を
反転させる。このとき、走査電極と信号電極に印加され
る電位の差、すなわち表示画素に印加される電圧を図1
2に示す。表示部の非選択電圧、選択電圧、およびの非
表示部の印加電圧の実効値をそれぞれVOFF4、VO
N4、およびVN4とすると、 VOFF4={β・(VC-VS)2/N+β・(n-1)・VS2/N}1/2 (数13) VON4={β・(VC+VS)2/N+β・(n-1)・VS2/N}1/2 (数14) VN4=VS・(β・n/N)1/2 (数15) 方式3(1) 方式3で走査電極の選択電位を全画面表示時と部分表示
時とで同じ値にしたときに、選択画素に印加される実効
電圧が全画面表示時と部分表示時とで等しくなるように
βの値を決める。部分表示時のVCと全画面表示時のV
Cを同じ値に、かつ部分表示時のVSと全画面表示時の
VSを同じ値にしたときに、選択電圧を等しくするため
の条件は、VON4=VONより β={(VC+VS)2+(N-1)・VS2}/{(VC+VS)2+(n-1)・VS2} (数16) N=240で、全画面表示時と部分表示時に共通にVC
=18.12(V)、VS=1.17(V)の条件で、
n=8、16、32、64、および120のときの各
電圧を計算し、全画面表示、方式1(1)、および方式
3(1)を比較すると、As in the case of full-screen display, the polarity of each drive waveform is inverted for each frame to prevent deterioration of the liquid crystal display panel. At this time, the difference between the potentials applied to the scanning electrodes and the signal electrodes, that is, the voltage applied to the display pixels is shown in FIG.
It is shown in FIG. The effective values of the non-selection voltage of the display unit, the selection voltage, and the applied voltage of the non-display unit are VOFF4 and VO, respectively.
Assuming that N4 and VN4, VOFF4 = {β · (VC−VS) 2 / N + β · (n−1) · VS 2 / N} 1/2 (Equation 13) VON4 = {β · (VC + VS ) 2 / N + β · (n−1) · VS 2 / N} 1/2 (Equation 14) VN4 = VS · (β · n / N) 1/2 (Equation 15) Method 3 (1) Method 3 When the selection potential of the scan electrode is set to the same value in full screen display and partial display, the value of β is set so that the effective voltage applied to the selected pixel is equal in full screen display and partial display. Decide. VC at partial display and V at full screen display
When C is set to the same value and VS at the time of partial display and VS at the time of full-screen display are set to the same value, the condition for making the selected voltages equal is as follows: VON4 = VON, β = {(VC + VS) 2 + (N−1) · VS 2 } / {(VC + VS) 2 + (n−1) · VS 2 } (Equation 16) When N = 240, VC is common in both full screen display and partial display.
= 18.12 (V), VS = 1.17 (V),
Computing each voltage when n = 8, 16, 32, 64, and 120 and comparing full screen display, method 1 (1), and method 3 (1),
【0042】[0042]
【表4】 [Table 4]
【0043】方式3(1)によれば、全画面表示時と同
一の選択電圧を保ったまま、部分表示時の非選択電圧、
および非表示部の印加電圧を方式1(1)よりも低減す
ることができる。nが小さいほど非表示部の印加電圧低
減効果が大きく、例えばn=8の場合、方式3(1)の
非表示部印加電圧は全画面表示時の非選択電圧の約18
%、方式3(1)の非選択電圧は全画面表示時の非選択
電圧の約94%となる。また、方式3(1)の非表示部
印加電圧は方式1(1)の非表示部印加電圧の約25%
となる。According to the method 3 (1), while maintaining the same selection voltage as in full screen display, the non-selection voltage in partial display,
Further, the applied voltage to the non-display portion can be reduced as compared with the method 1 (1). The smaller the value of n, the greater the effect of reducing the applied voltage of the non-display section.
%, The non-selection voltage of the method 3 (1) is about 94% of the non-selection voltage at the time of full screen display. Further, the non-display portion applied voltage of the method 3 (1) is about 25% of the non-display portion applied voltage of the method 1 (1).
Becomes
【0044】同一のnについて方式2(1)と方式3
(1)を比較すると、非表示部の印加電圧は方式3
(1)より方式2(1)の方が低い。一方、表示部の非
選択電圧は方式2(1)より方式3(1)の方が低い。
すなわち方式2(1)より方式3(1)の方が表示部の
駆動マージンが大きい。以上のように、方式2(1)、
または方式3(1)によれば、VC、VSを一定にした
まま、部分表示時でも、全画面表示時と同じ選択電圧を
表示部に印加でき、かつ、非表示部の印加電圧は方式1
(1)より小さくすることができる。Method 2 (1) and Method 3 for the same n
Comparing (1), the applied voltage of the non-display part is determined by the method 3
The method 2 (1) is lower than the method (1). On the other hand, the non-selection voltage of the display unit is lower in the method 3 (1) than in the method 2 (1).
That is, the driving margin of the display unit is larger in the method 3 (1) than in the method 2 (1). As described above, method 2 (1),
Alternatively, according to method 3 (1), the same selection voltage as in full screen display can be applied to the display unit even in partial display while VC and VS are kept constant, and the applied voltage in the non-display unit is the same as in method 1 (1).
(1) It can be smaller.
【0045】方式3(2) 方式3(1)で、部分表示時と全画面表示時とでVCお
よびVSを同じ電圧とし、かつ選択電圧も同一にするた
めのβの値は表4のように整数ではない。したがって、
表示タイミングを作るための基本クロックを全画面表示
時より高周波数にしなけれならず、その部分での電力増
加が伴うのと、表示タイミングを作るための分周回路の
構成が若干複雑になるという欠点がある。Method 3 (2) In method 3 (1), the values of β for making the same voltage VC and VS and the same selection voltage in partial display and full screen display are shown in Table 4. Is not an integer. Therefore,
The drawback is that the basic clock for creating the display timing must be higher than that for full-screen display, which increases the power in that part and complicates the configuration of the frequency divider circuit for creating the display timing. There is.
【0046】そこで、上記の欠点を改善するために、方
式3(2)では、方式3において、β=2に固定する。
β=2に固定すると、走査電極に印加する選択電位の期
間は全て等しく2・τになるので、表示タイミングの周
波数を全画面表示時の1/2に低減できる。N=240
で、全画面表示時と部分表示時に共通にVC=18.1
2(V)、VS=1.17(V)の条件で、 n=8、
16、32、64、および120のときの各電圧を計算
し、全画面表示、方式1(1)、および方式3(2)を
比較すると、Therefore, in order to improve the above-mentioned disadvantage, in method 3 (2), β is fixed to 2 in method 3.
When β is fixed to 2, the period of the selection potential applied to the scanning electrodes is all equal to 2 · τ, so that the frequency of the display timing can be reduced to の of that in full-screen display. N = 240
Thus, VC = 18.1 is common to the full screen display and the partial display.
2 (V), VS = 1.17 (V), n = 8,
Computing each voltage at 16, 32, 64, and 120, and comparing full screen display, method 1 (1), and method 3 (2),
【0047】[0047]
【表5】 [Table 5]
【0048】方式3(2)の場合、部分表示時の選択電
圧、非選択電圧、および非表示部印加電圧の全てが方式
3(1)より大きくなる。ただし、n≦16のときは、
非選択電圧が全画面表示時より小さく、選択電圧が全画
面表示時より大きいので、VC、VSは全画面表示時の
ままでも表示部の表示が可能である。また、例えばn=
8の場合、方式3(2)の非表示部印加電圧は全画面表
示時の非選択電圧の約19%、方式3(2)の非表示部
印加電圧は方式1(1)の非表示部印加電圧の約26%
となる。nが増えるにしたがって、部分表示時の選択電
圧、非選択電圧ともに高くなるので、表示が濃くなり過
ぎた場合は、VCおよびVSを下げるように電圧調整す
る必要がある。ただし、この電圧調整幅は通常表示時に
1/Nデューティ駆動をしていたものを、部分表示時に
1/nデューティ駆動に切り換える方法に比較してかな
り小さいので、ドライバICの駆動電圧範囲は問題にな
らない。In the case of the method 3 (2), the selection voltage, the non-selection voltage, and the non-display portion applied voltage at the time of partial display are all higher than the method 3 (1). However, when n ≦ 16,
Since the non-selection voltage is lower than in the full-screen display and the selection voltage is higher than in the full-screen display, the display section can be displayed even when VC and VS remain in the full-screen display. Also, for example, n =
In the case of No. 8, the non-display part applied voltage of the method 3 (2) is about 19% of the non-selection voltage in full screen display, and the non-display part applied voltage of the method 3 (2) is the non-display part of the method 1 (1). About 26% of applied voltage
Becomes As n increases, both the selection voltage and the non-selection voltage at the time of partial display increase, so when the display becomes too dark, it is necessary to adjust the voltage so as to lower VC and VS. However, since this voltage adjustment width is much smaller than the method of performing 1 / N duty drive during normal display, but switching to 1 / n duty drive during partial display, the drive voltage range of the driver IC is problematic. No.
【0049】(実施の形態2)実施例1では、本発明を
全画面表示が線順次駆動の場合に適用した例について説
明したが、本発明は線順次駆動に限定されるわけではな
く、全画面表示が複数ライン同時選択駆動(MLA駆
動)の場合にも適用可能である。部分表示での駆動方法
は全画面表示がMLA駆動の場合でも実施例1の各種方
式と類似なので、以下全画面表示がMLA駆動の場合の
実施例として、実施例1の方式1および方式3に対応す
る例のみを説明する。(Embodiment 2) In the first embodiment, an example in which the present invention is applied to a case where the full-screen display is line-sequential driving has been described. However, the present invention is not limited to line-sequential driving. The present invention is also applicable to a case where the screen display is a multiple line simultaneous selection drive (MLA drive). The driving method in the partial display is similar to the various methods of the first embodiment even when the full screen display is the MLA drive. Only corresponding examples will be described.
【0050】図13は全画面表示を2ラインMLA駆動
で行なう場合の走査電極駆動波形と信号電極駆動波形の
一例である。走査電極の選択電位は+VCまたは−V
C、走査電極の非選択電位は0電位である。COM 1
とCOM 2、COM 3とCOM 4、…の順に2本の
走査線の組ごとに時間をずらしながら期間τの走査電極
選択電位の組を2回ずつ印加して行き、COM N−1
とCOM Nの組まで印加し終わると1回の走査が完了
する。1回の走査に要する期間をフレーム周期と呼び、
N・τの長さとなる。液晶表示パネルの劣化防止のため
1フレームごとに各駆動波形の極性を反転させる。ここ
で、期間τの走査電極選択電位の組の2回の印加は連続
している必要はなく、期間τの走査電極選択電位の組を
フレーム周期中に分散させても良いことは一般に知られ
ている。以下では簡単化のため分散させない場合につい
てのみ説明する。FIG. 13 shows an example of scan electrode drive waveforms and signal electrode drive waveforms when full-screen display is performed by two-line MLA driving. The selection potential of the scanning electrode is + VC or -V
C, the non-selection potential of the scanning electrode is 0 potential. COM 1
, COM2, COM3 and COM4,..., While applying a scan electrode selection potential set in a period τ twice while shifting the time for each set of two scan lines, COM N−1
One scan is completed when the application of up to the set of COMN is completed. The period required for one scan is called a frame period,
N · τ. The polarity of each drive waveform is inverted every frame to prevent deterioration of the liquid crystal display panel. Here, it is generally known that the two applications of the set of the scanning electrode selection potentials in the period τ need not be continuous, and the set of the scanning electrode selection potentials in the period τ may be dispersed in the frame period. ing. In the following, only the case of not dispersing will be described for simplification.
【0051】信号電極には、走査電極選択電圧が印加さ
れている走査電極上の画素の表示データと走査電極選択
電位との対応から表6のように決まる電位を印加する。
なお表6において同時に選択電位を印加する2本の走査
電極の選択電位の組を(C0、C1)とし、+1は+V
C、−1は−VCに対応するものとする。また、その走
査電極上の画素の表示データを(D0、D1) とし、
+1は表示オフ、−1は表示オンに対応するものとす
る。また、そのときの信号電極への印加電位をSとし、
+1は+VS、0は0電位、−1は−VSに対応するも
のとする。A potential determined as shown in Table 6 is applied to the signal electrode from the correspondence between the display data of the pixel on the scanning electrode to which the scanning electrode selection voltage is applied and the scanning electrode selection potential.
In Table 6, the set of the selection potentials of the two scanning electrodes to which the selection potential is applied simultaneously is (C0, C1), and +1 is + V
C and -1 correspond to -VC. Further, the display data of the pixel on the scanning electrode is (D0, D1),
It is assumed that +1 corresponds to display off and -1 corresponds to display on. Also, let S be the potential applied to the signal electrode at that time,
+1 corresponds to + VS, 0 corresponds to 0 potential, and -1 corresponds to -VS.
【0052】[0052]
【表6】 [Table 6]
【0053】液晶表示パネルの劣化防止のため1フレー
ムごとに各駆動波形の極性を反転させる。図14はこの
ときに走査電極と信号電極に印加される電位の差、すな
わち表示画素に印加される電圧である。この表示画素へ
の印加電圧の実効値を式で表わすと、非選択電圧VOF
F*および選択電圧VON*はそれぞれ、 VOFF*={(VC-VS)2/N+(N/2-1)・VS2/N+VC2/N}1/2 (数17) VON*={(VC+VS)2/N+(N/2-1)・VS2/N+VC2/N}1/2 (数18) 次に、部分表示での各種駆動方法を説明する。In order to prevent the deterioration of the liquid crystal display panel, the polarity of each drive waveform is inverted every frame. FIG. 14 shows the difference between the potentials applied to the scanning electrodes and the signal electrodes at this time, that is, the voltages applied to the display pixels. When the effective value of the voltage applied to the display pixel is expressed by an equation, the non-selection voltage VOF
F * and select voltage VON * each, VOFF * = {(VC- VS) 2 / N + (N / 2-1) · VS 2 / N + VC 2 / N} 1/2 ( number 17) VON * = {(VC + VS) 2 / N + (N / 2-1) · VS 2 / N + VC 2 / N} 1/2 ( number 18) will now be described various drive method in the partial display.
【0054】方式1* 図15に示すように、 ・期間N・τのフレーム周期を前半の期間n・τの第一
の期間と残りの期間(N−n)・τの第二の期間に分け
る。 ・表示部の走査電極(COM 1〜COM n)には、第
一の期間に2本の走査線の組ごとに時間をずらしながら
期間τの選択電位を2回ずつ印加する。選択電位の印加
されていない期間は常に非選択電位を保持する。Method 1 * As shown in FIG. 15, the frame period of the period N · τ is divided into the first period of the first half period n · τ and the second period of the remaining period (N−n) · τ. Separate. The selection potential in the period τ is applied twice to the scan electrodes (COM 1 to COM n) of the display unit while shifting the time for each pair of two scan lines in the first period. The non-selection potential is always maintained during the period when the selection potential is not applied.
【0055】・非表示部の走査電極(COM n+1〜
COM N)は、フレーム周期の全体にわたって常に非
選択電位を保持する。 ・また、信号電極(SEG1〜SEG M)には、第一
の期間にその信号電極と走査電極(COM 1〜COM
n)との交点の画素の表示データと走査電極の選択電位
との対応で全画面表示のときと同様にして決まる電位を
印加する。また、第二の期間にあらかじめ決めた所定の
電位を印加する。Scanning electrode (COM n + 1 to COM n + 1)
COM N) always holds the non-selection potential throughout the frame period. The signal electrodes (SEG1-SEGM) have their signal electrodes and scanning electrodes (COM1-COM) in the first period.
A potential determined in the same manner as in full-screen display is applied in correspondence with the display data of the pixel at the intersection with n) and the selection potential of the scanning electrode. In addition, a predetermined potential is applied in the second period.
【0056】・全画面表示時と同様に、液晶表示パネル
の劣化防止のため1フレームごとに各駆動波形の極性を
反転させる。 方式1*(1) 方式1*で走査電極の選択電位を全画面表示時と部分表
示時とで同じ値にしたときに、選択画素に印加される実
効電圧が全画面表示時と部分表示時とで等しくなるよう
に、部分表示時において信号電極に第二の期間に印加す
る電位を決める。そのためには、部分表示時において信
号電極に第二の期間に印加する電位を全画面表示時と同
じにすればよく、そのときに非表示部に想定する表示デ
ータは任意である。図15に第二の期間中に印加する電
位を非表示部に全オフ表示を想定して決めた場合の信号
電極駆動波形を示す。また、このときに走査電極と信号
電極に印加される電位の差、すなわち表示画素に印加さ
れる電圧を図16に示す。As in the case of full-screen display, the polarity of each drive waveform is inverted every frame to prevent deterioration of the liquid crystal display panel. Method 1 * (1) When the selection potential of the scanning electrode is set to the same value in the full screen display and the partial display in the method 1 *, the effective voltage applied to the selected pixel is in the full screen display and the partial display. The potential to be applied to the signal electrode during the second period at the time of partial display is determined so that For this purpose, the potential applied to the signal electrode during the second period during the partial display may be the same as that during the full-screen display, and the display data assumed in the non-display portion at that time is arbitrary. FIG. 15 shows a signal electrode drive waveform in the case where the potential applied during the second period is determined on the assumption that the non-display portion is fully turned off. FIG. 16 shows the difference between the potentials applied to the scanning electrodes and the signal electrodes at this time, that is, the voltages applied to the display pixels.
【0057】ここで、部分表示時において信号電極に第
二の期間に印加する電位は、実効電圧を変えなければ自
由に決められるので、低電力化のためには、部分表示時
において信号電極に第二の期間に印加する電位をなるべ
く電位の変化が少ないように選ぶのが望ましい。その一
例として、図17に第二の期間の前半の1/2の期間に
+VC、後半の1/2の期間に0電位を印加する場合の
信号電極駆動波形を示す。また、第二の期間の開始時と
終了時に印加電位が0電位となるように図18のように
電位を設定してもよい。第一の期間との境目の電位差が
最大VCに抑えられるので、表示部の表示データの影響
を少なくできる。Here, the potential applied to the signal electrode during the second period during the partial display can be freely determined unless the effective voltage is changed. Therefore, to reduce the power, the potential applied to the signal electrode during the partial display is reduced. It is desirable to select the potential applied in the second period so that the change in potential is as small as possible. As an example, FIG. 17 shows a signal electrode drive waveform when + VC is applied in the first half of the second period and 0 potential is applied in the second half of the second period. Alternatively, the potential may be set as shown in FIG. 18 so that the applied potential becomes 0 at the start and end of the second period. Since the potential difference at the boundary with the first period is suppressed to the maximum VC, the influence of display data on the display unit can be reduced.
【0058】このときの表示部の非選択電圧、選択電
圧、およびの非表示部の印加電圧の実効値をそれぞれV
OFF1*、VON1*、およびVN1*とすると、 VOFF1*={(VC-VS)2/N+(N/2-1)・VS2/N+VC2/N}1/2 (数19) VON1*={(VC+VS)2/N+(N/2-1)・VS2/N+VC2/N}1/2 (数20) VN1*=VS/21/2 (数21) 方式1*(2) 方式1*(1)で部分表示時において複数の信号電極に
第二の期間に印加する電位の極性を全体の半数またはほ
ぼ半数の信号電極と残りの信号電極とで反転させる。こ
れにより、液晶表示素子の充放電電流が相殺するので駆
動回路の消費電力を低減できる。このときの表示部の非
選択電圧、選択電圧、およびの非表示部の印加電圧の実
効値は、方式1*(1)と同一である。At this time, the non-selection voltage of the display unit, the selection voltage, and the effective value of the applied voltage of the non-display unit are represented by V, respectively.
OFF1 *, VON1 *, and when the VN1 *, VOFF1 * = {( VC-VS) 2 / N + (N / 2-1) · VS 2 / N + VC 2 / N} 1/2 ( number 19) VON1 * = {(VC + VS) 2 / N + (N / 2-1) ・ VS 2 / N + VC 2 / N} 1/2 (Equation 20) VN1 * = VS / 2 1/2 (Equation 21) In the 1 * (2) method 1 * (1), during partial display, the polarity of the potential applied to the plurality of signal electrodes in the second period is inverted between half or almost half of the entire signal electrodes and the remaining signal electrodes. . As a result, the charge and discharge currents of the liquid crystal display element cancel each other, so that the power consumption of the drive circuit can be reduced. At this time, the non-selection voltage of the display unit, the selection voltage, and the effective value of the applied voltage of the non-display unit are the same as those in the method 1 * (1).
【0059】方式1*(3) 方式1*(1)で部分表示時において複数の信号電極に
第二の期間に印加する電位の極性を隣り合う信号電極ご
とに反転させる。これにより、液晶表示素子の充放電電
流が相殺するので駆動回路の消費電力を低減できる。こ
のときの表示部の非選択電圧、選択電圧、およびの非表
示部の印加電圧の実効値は、方式1*(1)と同一であ
る。Method 1 * (3) In method 1 * (1), during partial display, the polarity of the potential applied to the plurality of signal electrodes in the second period is inverted for each adjacent signal electrode. As a result, the charge and discharge currents of the liquid crystal display element cancel each other, so that the power consumption of the drive circuit can be reduced. At this time, the non-selection voltage of the display unit, the selection voltage, and the effective value of the applied voltage of the non-display unit are the same as those in the method 1 * (1).
【0060】N=240で、全画面表示時と部分表示時
に共通にVC=12.81(V)、VS=1.65
(V)の条件で、 n=8、16、32、64、および
120のときの各電圧を計算し、全画面表示と方式1*
(1)を比較すると、When N = 240, VC = 12.81 (V) and VS = 1.65 are common to the full screen display and the partial display.
Under the condition of (V), each voltage when n = 8, 16, 32, 64, and 120 is calculated, and full screen display and method 1 *
Comparing (1),
【0061】[0061]
【表7】 [Table 7]
【0062】方式1*(1)は、nによらず、部分表示
時の非選択電圧、選択電圧ともに全画面表示時と同じ
で、非表示部印加電圧は非選択電圧の約68%となる。
したがって、部分表示時にも全画面表示時と同じコント
ラスト比で表示ができ、しかも非表示部への印加電圧が
全画面表示時より低減される。 方式3* 図19に示すように、 ・期間N・τのフレーム周期を前半の期間n・β・τの
第一の期間(1<β≦2、n<N/β)と残りの期間
(N−n・β)・τの第二の期間に分ける。In the method 1 * (1), the non-selection voltage and the selection voltage at the time of partial display are the same as those at the time of full-screen display regardless of n, and the voltage applied to the non-display portion is about 68% of the non-selection voltage. .
Therefore, the display can be performed with the same contrast ratio as in the full-screen display even in the partial display, and the voltage applied to the non-display portion is reduced as compared with the full-screen display. Method 3 * As shown in FIG. 19, the frame period of the period N · τ is divided into the first period (1 <β ≦ 2, n <N / β) of the first half period n · β · τ and the remaining period ( N−n · β) · τ.
【0063】・表示部の走査電極(COM 1〜COM
n)には、第一の期間に2本の走査線の組ごとに時間を
ずらしながら期間β・τの選択電位を2回ずつ印加す
る。選択電位の印加されていない期間は常に非選択電位
を保持する。 ・非表示部の走査電極(COM n+1〜COM N)
は、フレーム周期の全体にわたって常に非選択電位を保
持する。Scanning electrodes of the display section (COM 1 to COM
In n), the selection potential of the period β · τ is applied twice while shifting the time for each pair of two scanning lines in the first period. The non-selection potential is always maintained during the period when the selection potential is not applied. -Scan electrode of non-display part (COM n + 1 to COM N)
Keeps the non-selection potential at all times during the entire frame period.
【0064】・また、信号電極(SEG1〜SEG
M)には、第一の期間にその信号電極と走査電極(CO
M 1〜COM n)との交点の画素の表示データと走査
電極の選択電位との対応から表6のように決まる電位を
印加する。また、第二の期間に走査電極非選択電位を印
加する。 ・全画面表示時と同様に、液晶表示パネルの劣化防止の
ため1フレームごとに各駆動波形の極性を反転させる。Also, signal electrodes (SEG1-SEG)
M) has its signal electrode and scan electrode (CO
A potential determined as shown in Table 6 is applied from the correspondence between the display data of the pixel at the intersection with M1 to COM n) and the selection potential of the scanning electrode. In addition, a scanning electrode non-selection potential is applied in the second period. As in the case of full screen display, the polarity of each drive waveform is inverted for each frame to prevent deterioration of the liquid crystal display panel.
【0065】このとき、走査電極と信号電極に印加され
る電位の差、すなわち表示画素に印加される電圧を図2
0に示す。表示部の非選択電圧、選択電圧、およびの非
表示部の印加電圧の実効値をそれぞれVOFF4*、V
ON4*、およびVN4*とすると、 VOFF4*={β・(VC-VS)2/N+β・(n/2-1)・VS2/N+β・VC2/N}1/2 (数22) VON4*={β・(VC+VS)2/N+β・(n/2-1)・VS2/N+β・VC2/N}1/2 (数23) VN4*=VS・{β・n/(2N)}1/2 (数24) 方式3*(1) 方式3*で走査電極の選択電位を全画面表示時と部分表
示時とで同じ値にしたときに、選択画素に印加される実
効電圧が全画面表示時と部分表示時とで等しくなるよう
にβの値を決める。部分表示時のVCと全画面表示時の
VCを同じ値に、かつ部分表示時のVSと全画面表示時
のVSを同じ値にしたときに、選択電圧を等しくするた
めの条件は、VON4*=VON*より β={(VC+VS)2+(N/2-1)・VS2+VC2}/{(VC+VS)2+(n/2-1)・VS2+VC2} (数25) N=240で、全画面表示時と部分表示時に共通にVC
=12.81(V)、VS=1.65(V)の条件で、
n=8、16、32、64、および120のときの各
電圧を計算し、全画面表示、方式1*(1)、および方
式3*(1)を比較すると、At this time, the difference between the potentials applied to the scanning electrodes and the signal electrodes, that is, the voltage applied to the display pixels is shown in FIG.
0 is shown. The effective values of the non-selection voltage of the display unit, the selection voltage, and the applied voltage of the non-display unit are represented by VOFF4 * and VOFF4, respectively.
ON4 *, and when the VN4 *, VOFF4 * = {β · (VC-VS) 2 / N + β · (n / 2-1) · VS 2 / N + β · VC 2 / N} 1/2 ( Equation 22) VON4 * = {β · (VC + VS) 2 / N + β · (n / 2-1) · VS 2 / N + β · VC 2 / N} 1/2 (Equation 23) VN4 * = VS · {β · n / (2N)} 1/2 (Equation 24) Method 3 * (1) When the selected potential of the scan electrode is set to the same value in full screen display and partial display in method 3 * The value of β is determined so that the effective voltage applied to the selected pixel is equal between the full screen display and the partial display. When VC at the time of partial display and VC at the time of full screen display have the same value, and VS at the time of partial display and VS at the time of full screen display have the same value, the condition for equalizing the selected voltage is VON4 * = VON * β = {(VC + VS) 2 + (N / 2-1) · VS 2 + VC 2 } / {(VC + VS) 2 + (n / 2-1) · VS 2 + VC 2 } (Equation 25) When N = 240, the common VC is used for both full screen display and partial display.
= 12.81 (V), VS = 1.65 (V),
Computing each voltage when n = 8, 16, 32, 64, and 120, and comparing full screen display, method 1 * (1), and method 3 * (1),
【0066】[0066]
【表8】 [Table 8]
【0067】表8と表4とを比較すれば明らかなよう
に、nと各種電圧値の対応関係は全く同じである。した
がって、方式3(1)と同様に方式3*(1)によれ
ば、 VC、VSを一定にしたまま、かつ全画面表示時
と同一の選択電圧を保ったまま、例えばn=8の場合、
方式3*(1)の非表示部印加電圧は全画面表示時の非
選択電圧の約18%、方式3*(1)の非選択電圧は全
画面表示時の非選択電圧の約94%に低減できる。ま
た、方式3*(1)の非表示部印加電圧は方式1*
(1)の非表示部印加電圧の約25%となる。As is clear from comparison between Table 8 and Table 4, the correspondence between n and various voltage values is exactly the same. Therefore, according to the method 3 * (1), as in the method 3 (1), when VC and VS are kept constant and the same selection voltage is maintained as in full-screen display, for example, when n = 8 ,
The non-display part applied voltage of method 3 * (1) is about 18% of the non-selection voltage at the time of full screen display, and the non-selection voltage of method 3 * (1) is about 94% of the non-selection voltage at the time of full screen display. Can be reduced. In addition, the non-display portion applied voltage in method 3 * (1) is
This is about 25% of the voltage applied to the non-display section in (1).
【0068】方式3*(2) 方式3*(1)で、部分表示時と全画面表示時とでVC
およびVSを同じ電圧とし、かつ選択電圧も同一にする
ためのβの値は表8のように整数ではない。したがっ
て、表示タイミングを作るための基本クロックを全画面
表示時より高周波数にしなけれならず、その部分での電
力増加が伴うのと、表示タイミングを作るための分周回
路の構成が若干複雑になるという欠点がある。Method 3 * (2) In method 3 * (1), VC is used for partial display and full screen display.
And VS are the same voltage, and the value of β for making the selection voltage the same is not an integer as shown in Table 8. Therefore, the basic clock for generating the display timing must be higher in frequency than when displaying the full screen, and the power is increased in that part, and the configuration of the frequency dividing circuit for generating the display timing is slightly complicated. There is a disadvantage that.
【0069】そこで、上記の欠点を改善するために、方
式3*(2)では、方式3*において、β=2に固定す
る。β=2に固定すると、走査電極に印加する選択電位
の期間は全て等しく2・τになるので、表示タイミング
の周波数を全画面表示時の1/2に低減できる。N=2
40で、全画面表示時と部分表示時に共通にVC=1
2.81(V)、VS=1.65(V)の条件で、 n
=8、16、32、64、および120のときの各電圧
を計算し、全画面表示と方式3*(2)を比較すると、Therefore, in order to improve the above-mentioned disadvantage, in method 3 * (2), β = 2 is fixed in method 3 *. When β is fixed to 2, the period of the selection potential applied to the scanning electrodes is all equal to 2 · τ, so that the frequency of the display timing can be reduced to の of that in full-screen display. N = 2
40, VC = 1 for both full screen display and partial display
Under the conditions of 2.81 (V) and VS = 1.65 (V), n
= 8, 16, 32, 64, and 120, and comparing the full screen display with the method 3 * (2),
【0070】[0070]
【表9】 [Table 9]
【0071】表9と表5とを比較すれば明らかなよう
に、nと各種電圧値の対応関係は全く同じである。した
がって、方式3(2)と同様に方式3*(2)の場合、
n≦16のときは、非選択電圧が全画面表示時より小さ
く、選択電圧が全画面表示時より大きいので、VC、V
Sは全画面表示時のままでも表示部の表示が可能であ
る。また、例えばn=8の場合、方式3*(2)の非表
示部印加電圧は全画面表示時の非選択電圧の約19%、
方式3*(2)の非表示部印加電圧は方式1*(1)の
非表示部印加電圧の約26%となる。As is clear from comparison between Table 9 and Table 5, the correspondence between n and various voltage values is exactly the same. Therefore, in the case of method 3 * (2) as in method 3 (2),
When n ≦ 16, the non-selection voltage is lower than that during full-screen display and the selection voltage is higher than during full-screen display.
S can be displayed on the display unit even during full screen display. Further, for example, when n = 8, the non-display portion applied voltage of the method 3 * (2) is about 19% of the non-selection voltage in full screen display,
The applied voltage of the non-display part in the method 3 * (2) is about 26% of the applied voltage of the non-display part in the method 1 * (1).
【0072】nが増えるにしたがって、部分表示時の選
択電圧、非選択電圧ともに高くなるので、表示が濃くな
り過ぎた場合は、VCおよびVSを下げるように電圧調
整する必要がある。ただし、この電圧調整幅は通常表示
時に1/Nデューティ駆動をしていたものを、部分表示
時に1/nデューティ駆動に切り換える方法に比較して
かなり小さいので、ドライバICの駆動電圧範囲は問題
にならない。As n increases, both the selection voltage and the non-selection voltage at the time of partial display increase, so if the display becomes too dark, it is necessary to adjust the voltage so as to lower VC and VS. However, since this voltage adjustment width is much smaller than the method of performing 1 / N duty drive during normal display, but switching to 1 / n duty drive during partial display, the drive voltage range of the driver IC is problematic. No.
【0073】以上、2ラインMLA駆動について説明し
たが、2ラインを超える本数のMLAに関しても同様に
して本発明が適用できる。Although the two-line MLA drive has been described above, the present invention can be similarly applied to MLAs having more than two lines.
【0074】[0074]
【発明の効果】以上説明したように、本発明によれば、
部分表示時には非表示部に対応する走査電極駆動回路は
走査のための動作を停止でき、また、部分表示時の第二
の期間には信号電極駆動回路への表示データの転送や信
号電極駆動回路での表示データから駆動出力への変換動
作などが不要になり、さらに、非表示部への印加電圧を
全画面表示時の非選択電圧より小さくできるので液晶表
示素子の駆動回路の消費電力を低減することができると
いう優れた効果を有する。As described above, according to the present invention,
At the time of partial display, the scan electrode drive circuit corresponding to the non-display portion can stop the operation for scanning, and during the second period at the time of partial display, transfer of display data to the signal electrode drive circuit and signal electrode drive circuit This eliminates the need to convert the display data to drive output in the LCD, and further reduces the voltage applied to the non-display area from the non-selection voltage during full-screen display, thus reducing the power consumption of the liquid crystal display element drive circuit. It has an excellent effect that it can be performed.
【0075】また、本発明の部分表示方法では、部分表
示を全画面表示と同一の走査電極選択電位あるいは、全
画面表示に近い走査電極選択電位で行うことができる。
したがって、1つのドライバICにより全画面表示と部
分表示を切り換えて行う場合でも、全画面表示のみ行な
う場合に比較して、ドライバICの動作電圧範囲はほぼ
同じで良く、ICのチップ面積の増大などは伴わない。
また、全画面表示と部分表示を切り換えても、走査電極
選択電位の調整はほとんど必要ない。またnが変わって
も走査電極選択電位と信号電極の電位の比や走査電極選
択電位を変える必要はほとんどないなどの優れた効果を
有する。Further, in the partial display method of the present invention, the partial display can be performed at the same scan electrode selection potential as the full screen display or at the scan electrode selection potential close to the full screen display.
Therefore, even when switching between full screen display and partial display is performed by one driver IC, the operating voltage range of the driver IC may be substantially the same as in the case where only full screen display is performed, and the chip area of the IC increases. Does not accompany.
Also, even when switching between full screen display and partial display, there is almost no need to adjust the scanning electrode selection potential. In addition, even if n changes, there is an excellent effect that there is almost no need to change the ratio of the scanning electrode selection potential to the signal electrode potential or the scanning electrode selection potential.
【図1】本発明にかかる部分表示時の走査電極駆動波形
と信号電極駆動波形の一例を示す図である。FIG. 1 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図2】液晶表示パネルの電極の配置と全画面表示の一
例を示す図である。FIG. 2 is a diagram illustrating an example of an arrangement of electrodes of a liquid crystal display panel and a full screen display.
【図3】本発明にかかる部分表示の一例を示す図であ
る。FIG. 3 is a diagram showing an example of a partial display according to the present invention.
【図4】全画面表示を線順次駆動で行なう場合の走査電
極駆動波形と信号電極駆動波形の一例を示す図である。FIG. 4 is a diagram showing an example of scan electrode drive waveforms and signal electrode drive waveforms when full-screen display is performed by line-sequential driving.
【図5】図4のときに表示画素に印加される電圧を示す
図である。FIG. 5 is a diagram showing a voltage applied to a display pixel in FIG. 4;
【図6】本発明にかかる部分表示時の走査電極駆動波形
と信号電極駆動波形の一例を示す図である。FIG. 6 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図7】図6のときに表示画素に印加される電圧を示す
図である。FIG. 7 is a diagram showing a voltage applied to a display pixel in FIG. 6;
【図8】本発明にかかる部分表示時の走査電極駆動波形
と信号電極駆動波形の一例を示す図である。FIG. 8 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図9】図8のときに表示画素に印加される電圧を示す
図である。9 is a diagram illustrating a voltage applied to a display pixel in FIG.
【図10】図1のときに表示画素に印加される電圧を示
す図である。FIG. 10 is a diagram showing a voltage applied to a display pixel in FIG.
【図11】本発明にかかる部分表示時の走査電極駆動波
形と信号電極駆動波形の一例を示す図である。FIG. 11 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図12】図11のときに表示画素に印加される電圧を
示す図である。12 is a diagram showing a voltage applied to a display pixel in FIG.
【図13】全画面表示を2ライン同時選択駆動で行なう
場合の走査電極駆動波形と信号電極駆動波形の一例を示
す図である。FIG. 13 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform when performing full-screen display by two-line simultaneous selection drive.
【図14】図13のときに表示画素に印加される電圧を
示す図である。FIG. 14 is a diagram showing a voltage applied to a display pixel in FIG.
【図15】本発明にかかる部分表示時の走査電極駆動波
形と信号電極駆動波形の一例を示す図である。FIG. 15 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図16】図15のときに表示画素に印加される電圧を
示す図である。16 is a diagram showing a voltage applied to a display pixel in FIG.
【図17】本発明にかかる部分表示時の走査電極駆動波
形と信号電極駆動波形の一例を示す図である。FIG. 17 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図18】本発明にかかる部分表示時の走査電極駆動波
形と信号電極駆動波形の一例を示す図である。FIG. 18 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図19】本発明にかかる部分表示時の走査電極駆動波
形と信号電極駆動波形の一例を示す図である。FIG. 19 is a diagram showing an example of a scan electrode drive waveform and a signal electrode drive waveform during partial display according to the present invention.
【図20】図19のときに表示画素に印加される電圧を
示す図である。20 is a diagram showing a voltage applied to a display pixel in FIG. 19;
21 非選択画素 22 選択画素 31 表示部 32 非表示部 33 表示部の非選択画素 34 表示部の選択画素 35 非表示部の画素 21 Non-selected pixel 22 Selected pixel 31 Display unit 32 Non-display unit 33 Non-selected pixel of display unit 34 Selected pixel of display unit 35 Pixel of non-display unit
─────────────────────────────────────────────────────
────────────────────────────────────────────────── ───
【手続補正書】[Procedure amendment]
【提出日】平成11年2月15日(1999.2.1
5)[Submission date] February 15, 1999 (1999.2.1
5)
【手続補正1】[Procedure amendment 1]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】特許請求の範囲[Correction target item name] Claims
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【特許請求の範囲】[Claims]
【手続補正2】[Procedure amendment 2]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】0011[Correction target item name] 0011
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【0011】方式1(4) 方式1の液晶表示素子の駆動方法で、第二のモードにお
いて信号電極に第二の期間に印加する電位を走査電極の
非選択電位とする。 方式2 N本の走査電極(Nは2以上の整数)と複数の信号電極
とからなるマトリクス型液晶表示素子の駆動方法におい
て、第一のモードと第二のモードを持ち、第一のモード
では全ての走査電極に期間τの選択電位を1フレーム毎
にL回(Lは自然数)印加し、選択電位を印加しない期
間は常に非選択電位に保持し、信号電極に信号電極と走
査電極との交点の画素の表示データと走査電極の選択電
位との対応で決まる電位を印加し、第二のモードではN
本の走査電極をn本の走査電極(nはn<Nなる整数)
からなる第一の走査電極群と残りの(N−n)本の走査
電極からなる第二の走査電極群に分割し、また、フレー
ム周期を第一の期間と第二の期間に分け、第一の走査電
極群の各走査電極には第一の期間に期間τの選択電位を
1フレーム毎にL回印加し、第一の期間において選択電
位を印加しない期間は常に非選択電位を保持し、第二の
期間にατの期間(0<α<N−n)の選択電位を1フ
レーム毎にL回印加し、第二の期間において選択電位を
印加しない期間は常に非選択電位を保持し、第二の走査
電極群の各走査電極はフレーム周期の全体にわたって常
に非選択電位を保持し、信号電極には第一の期間に信号
電極と第一の走査電極群の各走査電極との交点の画素の
表示データと走査電極の選択電位との対応で決まる電位
を印加し、第二の期間に走査電極の非選択電位を印加す
る。Method 1 (4) In the liquid crystal display element driving method of Method 1, the potential applied to the signal electrode in the second mode in the second period is set as the non-selection potential of the scanning electrode. Method 2 A method for driving a matrix-type liquid crystal display element including N scanning electrodes (N is an integer of 2 or more) and a plurality of signal electrodes has a first mode and a second mode. The selection potential in the period τ is applied L times (L is a natural number) per frame to all the scanning electrodes, and is kept at the non-selection potential during the period in which the selection potential is not applied. A potential determined by the correspondence between the display data of the pixel at the intersection and the selection potential of the scanning electrode is applied.
N scan electrodes (n is an integer such that n <N)
And a second scan electrode group consisting of the remaining (N-n) scan electrodes, and the frame period is divided into a first period and a second period. A selection potential of a period τ is applied to each scanning electrode of one scanning electrode group L times in each frame during a first period, and a non-selection potential is always held during a period when no selection potential is applied in the first period. In the second period, the selection potential in the period of ατ ( 0 <α <N−n ) is applied L times for each frame, and in the second period, the non-selection potential is always held during the period in which the selection potential is not applied. , Each scanning electrode of the second scanning electrode group always holds a non-selection potential over the entire frame period, and the signal electrode has an intersection between the signal electrode and each scanning electrode of the first scanning electrode group in the first period. A potential determined by the correspondence between the display data of the pixel and the selection potential of the scanning electrode, During that time, a non-selection potential of the scanning electrode is applied.
【手続補正3】[Procedure amendment 3]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】0013[Correction target item name] 0013
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【0013】方式3 N本の走査電極(Nは2以上の整数)と複数の信号電極
とからなるマトリクス型液晶表示素子の駆動方法におい
て、第一のモードと第二のモードを持ち、第一のモード
では全ての走査電極に期間τの選択電位を1フレーム毎
にL回(Lは自然数)印加し、選択電位を印加しない期
間は常に非選択電位に保持し、信号電極に信号電極と走
査電極との交点の画素の表示データに対応して決まる電
位を印加し、第二のモードではN本の走査電極をn本の
走査電極(nはn<Nなる整数)からなる第一の走査電
極群と残りの(N−n)本の走査電極からなる第二の走
査電極群に分割し、また、フレーム周期を第一の期間と
第二の期間に分け、第一の走査電極群の各走査電極には
第一の期間に期間β・τの選択電位(1<β<N/n)
を1フレーム毎にL回印加し、第一の期間において選択
電位を印加しない期間は常に非選択電位を保持し、第二
の期間は常に非選択電位を保持し、第二の走査電極群の
各走査電極はフレーム周期の全体にわたって常に非選択
電位を保持し、信号電極には第一の期間に信号電極と第
一の走査電極群の各走査電極との交点の画素の表示デー
タと走査電極の選択電位との対応で決まる電位を印加
し、第二の期間に走査電極の非選択電位を印加する。Method 3 In a method for driving a matrix type liquid crystal display element comprising N scanning electrodes (N is an integer of 2 or more) and a plurality of signal electrodes, the method has a first mode and a second mode, In the mode, the selection potential in the period τ is applied L times (L is a natural number) per frame to all the scanning electrodes, and the non-selection potential is always held during the period in which the selection potential is not applied. A potential determined according to the display data of the pixel at the intersection with the electrode is applied, and in the second mode, N scan electrodes are replaced with a first scan composed of n scan electrodes (n is an integer of n <N). The first scan electrode group is divided into a first scan electrode group and a second scan electrode group including a second scan electrode group including the electrode group and the remaining (N−n) scan electrodes. each scan electrode selection potential period beta · tau in the first period (1 <β <n / n
Is applied L times for each frame, the non-selection potential is always held during the period in which the selection potential is not applied in the first period, the non-selection potential is always held in the second period, and the second scan electrode group Each scan electrode always holds a non-selection potential over the entire frame period, and the signal electrode has display data of the pixel at the intersection of the signal electrode and each scan electrode of the first scan electrode group with the scan electrode during the first period. And a non-selection potential of the scanning electrode is applied in the second period.
【手続補正4】[Procedure amendment 4]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】0029[Correction target item name] 0029
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【0029】・表示部の走査電極(COM 1〜COM
n)には、第一の期間に期間τの選択電位を順次時間を
ずらしながら印加し、第二の期間に期間α・τの選択電
位(0<α<N−n)を印加する。選択電位の印加され
ていない期間は常に非選択電位を保持する。Scanning electrodes of the display section (COM 1 to COM
In n), the selection potential in the period τ is applied while sequentially shifting the time in the first period, and the selection potential (0 <α < N−n ) in the period α · τ is applied in the second period. The non-selection potential is always maintained during the period when the selection potential is not applied.
【手続補正5】[Procedure amendment 5]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】0039[Correction target item name] 0039
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【0039】方式3 図11に示すように、 ・期間N・τのフレーム周期を前半の期間n・β・τの
第一の期間(1<β<N/n)と残りの期間(N−n・
β )・τの第二の期間に分ける。 ・表示部の走査電極(COM 1〜COM n)には、第
一の期間に期間β・τの選択電位を順次時間をずらしな
がら印加する。選択電位の印加されていない期間は常に
非選択電位を保持する。 ・非表示部の走査電極(COM n+1〜COM N)
は、フレーム周期の全体にわたって常に非選択電位を保
持する。Method 3 As shown in FIG. 11, the frame period of the period N · τ is divided into a first period (1 <β <N / n ) of the first half period n · β · τ and a remaining period (N− n
β) · τ is divided into the second period. -To the scanning electrodes (COM1 to COMn) of the display unit, the selection potentials of the periods β and τ are applied while sequentially shifting the time during the first period. The non-selection potential is always maintained during the period when the selection potential is not applied. -Scan electrode of non-display part (COM n + 1 to COM N)
Keeps the non-selection potential at all times during the entire frame period.
【手続補正5】[Procedure amendment 5]
【補正対象書類名】明細書[Document name to be amended] Statement
【補正対象項目名】0062[Correction target item name] 0062
【補正方法】変更[Correction method] Change
【補正内容】[Correction contents]
【0062】方式1*(1)は、nによらず、部分表示
時の非選択電圧、選択電圧ともに全画面表示時と同じ
で、非表示部印加電圧は非選択電圧の約68%となる。
したがって、部分表示時にも全画面表示時と同じコント
ラスト比で表示ができ、しかも非表示部への印加電圧が
全画面表示時より低減される。 方式3* 図19に示すように、 ・期間N・τのフレーム周期を前半の期間n・β・τの
第一の期間(1<β<N/n)と残りの期間(N−n・
β)・τの第二の期間に分ける。In the method 1 * (1), the non-selection voltage and the selection voltage at the time of partial display are the same as those at the time of full-screen display regardless of n, and the voltage applied to the non-display portion is about 68% of the non-selection voltage. .
Therefore, the display can be performed with the same contrast ratio as in the full-screen display even in the partial display, and the voltage applied to the non-display portion is reduced as compared with the full-screen display. Method 3 * As shown in FIG. 19, the frame period of the period N · τ is divided into the first period (1 <β <N / n ) of the first half period n · β · τ and the remaining period (N−n ·
β) · τ is divided into the second period.
───────────────────────────────────────────────────── フロントページの続き (51)Int.Cl.7 識別記号 FI テーマコート゛(参考) G09G 3/20 622 G09G 3/20 622R 650 650A Fターム(参考) 2H093 NA10 NA20 NA26 NA33 NA79 NC90 ND39 ND49 ND60 NF13 5C006 AA01 AC02 AC23 AC24 AC28 AF34 AF44 AF52 AF71 BB12 BB14 BC03 BC12 EB05 FA05 FA16 FA47 FA51 5C080 AA10 BB05 DD25 DD26 EE32 FF12 JJ04 ──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. 7 Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 622 G09G 3/20 622R 650 650A F-term (Reference) 2H093 NA10 NA20 NA26 NA33 NA79 NC90 ND39 ND49 ND60 NF13 5C006 AA01 AC02 AC23 AC24 AC28 AF34 AF44 AF52 AF71 BB12 BB14 BC03 BC12 EB05 FA05 FA16 FA47 FA51 5C080 AA10 BB05 DD25 DD26 EE32 FF12 JJ04
Claims (14)
数、と複数の信号電極とからなるマトリクス型液晶表示
素子の駆動方法において、 第一のモードと第二のモードを持ち、 前記第一のモードで、全ての走査電極に期間τの選択電
位を1フレーム毎にL回、ただしLは自然数、印加し、
選択電位を印加しない期間は常に非選択電位に保持し、 前記信号電極に、前記信号電極と前記走査電極との交点
の画素の表示データと走査電極の選択電位から求まる電
位を印加し、 前記第二のモードで、N本の走査電極をn本の走査電
極、ただしnはn<Nなる整数、からなる第一の走査電
極群と残りの(N−n)本の走査電極からなる第二の走
査電極群に分割し、 かつ、フレーム周期を第一の期間と第二の期間に分け、 前記第一の走査電極群の各走査電極には前記第一の期間
に期間τの選択電位を1フレーム毎にL回印加し、前記
第一の期間において選択電位を印加しない期間は常に非
選択電位を保持し、前記第二の期間は常に非選択電位を
保持し、前記第二の走査電極群の各走査電極はフレーム
周期の全体にわたって常に非選択電位を保持し、 前記信号電極には第一の期間に前記信号電極と第一の走
査電極群の各走査電極との交点の画素の表示データと前
記走査電極の選択電位から求まる電位を印加し、前記第
二の期間にあらかじめ決めた所定の電位を印加すること
を特徴とする液晶表示素子の駆動方法。1. A method for driving a matrix-type liquid crystal display device comprising N scanning electrodes, where N is an integer of 2 or more, and a plurality of signal electrodes, comprising: a first mode and a second mode; In the first mode, the selection potential in the period τ is applied L times to all the scanning electrodes every frame, where L is a natural number, and
A period in which the selection potential is not applied is always maintained at a non-selection potential, and a potential obtained from display data of a pixel at an intersection of the signal electrode and the scanning electrode and a selection potential of the scanning electrode is applied to the signal electrode; In the second mode, N scan electrodes are replaced with n scan electrodes, where n is an integer satisfying n <N, and a second scan electrode group including the remaining (N−n) scan electrodes. And the frame period is divided into a first period and a second period, and each scan electrode of the first scan electrode group is supplied with a selection potential in a period τ during the first period. The voltage is applied L times per frame, and the non-selection potential is always held during a period when the selection potential is not applied in the first period, and the non-selection potential is always held during the second period. Each scan electrode in the group always has a non-selection potential throughout the frame period. Applying a potential determined from display data of a pixel at an intersection of the signal electrode and each scanning electrode of the first scanning electrode group and a selection potential of the scanning electrode to the signal electrode during a first period, A method for driving a liquid crystal display element, wherein a predetermined potential determined in advance is applied in a second period.
において、前記走査電極の選択電位を前記第一のモード
と前記第二のモードとで同じ値にしたときに、前記選択
画素に印加される実効電圧が前記第一のモードと前記第
二のモードとで等しくなるように、前記第二のモードに
おいて前記信号電極に前記第二の期間に印加する電位を
決めることを特徴とする液晶表示素子の駆動方法。2. The method for driving a liquid crystal display element according to claim 1, wherein the selection potential of the scanning electrode is applied to the selected pixel when the same potential is set in the first mode and the second mode. Determining a potential applied to the signal electrode during the second period in the second mode so that an effective voltage to be applied is equal between the first mode and the second mode. A method for driving a display element.
示素子の駆動方法において、前記第二のモードにおいて
前記複数の信号電極に前記第二の期間に印加する電位の
極性を全体の半数またはほぼ半数の信号電極と残りの信
号電極とで反転させることを特徴とする液晶表示素子の
駆動方法。3. The method of driving a liquid crystal display element according to claim 1, wherein the polarity of the potential applied to the plurality of signal electrodes in the second mode in the second period is half of the total. Alternatively, a method of driving a liquid crystal display element, wherein the inversion is performed by almost half of the signal electrodes and the remaining signal electrodes.
示素子の駆動方法において、前記第二のモードにおいて
前記複数の信号電極に前記第二の期間に印加する電位の
極性を隣り合う信号電極ごとに反転させることを特徴と
する液晶表示素子の駆動方法。4. The method for driving a liquid crystal display element according to claim 1, wherein the polarity of a potential applied to the plurality of signal electrodes in the second mode in the second period is adjacent to the signal electrodes. A method for driving a liquid crystal display element, wherein the method is reversed for each electrode.
において、前記第二のモードにおいて前記信号電極に前
記第二の期間に印加する電位を前記走査電極の非選択電
位とすることを特徴とする液晶表示素子の駆動方法。5. The method of driving a liquid crystal display element according to claim 1, wherein a potential applied to the signal electrode in the second period in the second mode is a non-selection potential of the scanning electrode. Driving method of the liquid crystal display element.
数、と複数の信号電極とからなるマトリクス型液晶表示
素子の駆動方法において、 第一のモードと第二のモードを持ち、 前記第一のモードで全ての走査電極に期間τの選択電位
を1フレーム毎にL回ただし、Lは自然数、印加し、選
択電位を印加しない期間は常に非選択電位に保持し、 前記信号電極に前記信号電極と前記走査電極との交点の
画素の表示データと前記走査電極の選択電位から求まる
電位を印加し、 前記第二のモードで前記N本の走査電極をn本の走査電
極ただし、nはn<Nなる整数、からなる第一の走査電
極群と残りの(N−n)本の走査電極からなる第二の走
査電極群に分割し、 かつ、フレーム周期を第一の期間と第二の期間に分け、 前記第一の走査電極群の各走査電極には前記第一の期間
に期間τの選択電位を1フレーム毎にL回印加し、前記
第一の期間において選択電位を印加しない期間は常に非
選択電位を保持し、前記第二の期間にα・τの期間ただ
し、0<α≦1、の選択電位を1フレーム毎にL回印加
し、前記第二の期間において選択電位を印加しない期間
は常に非選択電位を保持し、 前記第二の走査電極群の各走査電極はフレーム周期の全
体にわたって常に非選択電位を保持し、 前記信号電極には前記第一の期間に信号電極と前記第一
の走査電極群の各走査電極との交点の画素の表示データ
と走査電極の選択電位から求まる電位を印加し、前記第
二の期間に走査電極の非選択電位を印加することを特徴
とする液晶表示素子の駆動方法。6. A method of driving a matrix-type liquid crystal display element comprising N scanning electrodes, where N is an integer of 2 or more, and a plurality of signal electrodes, wherein the driving method has a first mode and a second mode, In the first mode, the selection potential in the period τ is applied L times to all the scanning electrodes per frame, where L is a natural number, and is always kept at the non-selection potential during the period in which the selection potential is not applied. A display data of a pixel at an intersection of the signal electrode and the scanning electrode and a potential determined from a selection potential of the scanning electrode are applied. In the second mode, the N scanning electrodes are replaced with n scanning electrodes, where n is a scanning electrode. Is divided into a first scan electrode group consisting of n <N, and a second scan electrode group consisting of the remaining (N−n) scan electrodes, and the frame period is divided into a first period and a first period. Each scan of the first scan electrode group The electrode is applied with the selection potential for a period τ L times per frame during the first period, and during the period in which the selection potential is not applied in the first period, the non-selection potential is always held. Where a selection potential of 0 <α ≦ 1 is applied L times for each frame, and a non-selection potential is always held during a period in which the selection potential is not applied in the second period. Each scanning electrode of the second scanning electrode group always holds a non-selection potential over the entire frame period, and the signal electrode includes a signal electrode and a scanning electrode of the first scanning electrode group during the first period. A method for driving a liquid crystal display element, wherein a potential determined from display data of a pixel at an intersection and a selection potential of a scanning electrode is applied, and a non-selection potential of a scanning electrode is applied during the second period.
において、前記走査電極の選択電位を前記第一のモード
と前記第二のモードとで同じ値にしたときに、前記選択
画素に印加される実効電圧が前記第一のモードと前記第
二のモードとで等しくなるようにαの値を選ぶことを特
徴とする液晶表示素子の駆動方法。7. The method of driving a liquid crystal display element according to claim 6, wherein the selection potential of the scanning electrode is applied to the selected pixel when the same potential is set in the first mode and the second mode. A method of driving the liquid crystal display element, wherein the value of α is selected so that the effective voltage to be applied is equal between the first mode and the second mode.
において、α=1であることを特徴とする液晶表示素子
の駆動方法。8. The method for driving a liquid crystal display device according to claim 6, wherein α = 1.
数、と複数の信号電極とからなるマトリクス型液晶表示
素子の駆動方法において、 第一のモードと第二のモードを持ち、 前記第一のモードで全ての走査電極に期間τの選択電位
を1フレーム毎にL回ただし、Lは自然数、印加し、選
択電位を印加しない期間は常に非選択電位に保持し、 前記信号電極に信号電極と走査電極との交点の画素の表
示データから求まる電位を印加し、 前記第二のモードでN本の走査電極をn本の走査電極、
nはn<Nなる整数、からなる第一の走査電極群と残り
の(N−n)本の走査電極からなる第二の走査電極群に
分割し、 かつ、フレーム周期を第一の期間と第二の期間に分け、 前記第一の走査電極群の各走査電極には前記第一の期間
に期間β・τの選択電位ただし、1<β≦2、かつn<
N/βを1フレーム毎にL回印加し、前記第一の期間に
おいて選択電位を印加しない期間は常に非選択電位を保
持し、前記第二の期間は常に非選択電位を保持し、 前記第二の走査電極群の各走査電極はフレーム周期の全
体にわたって常に非選択電位を保持し、 前記信号電極には第一の期間に信号電極と第一の走査電
極群の各走査電極との交点の画素の表示データと走査電
極の選択電位から求まる電位を印加し、前記第二の期間
に走査電極の非選択電位を印加することを特徴とする液
晶表示素子の駆動方法。9. A method for driving a matrix-type liquid crystal display device comprising N scanning electrodes, where N is an integer of 2 or more, and a plurality of signal electrodes, the method comprising: a first mode and a second mode; In the first mode, the selection potential in the period τ is applied to all the scanning electrodes L times per frame, where L is a natural number, and is always kept at the non-selection potential during the period in which the selection potential is not applied. Applying a potential determined from the display data of the pixel at the intersection of the signal electrode and the scan electrode; and in the second mode, the N scan electrodes are replaced by n scan electrodes,
n is divided into a first scan electrode group consisting of n <N and an second scan electrode group consisting of the remaining (N−n) scan electrodes, and the frame period is defined as a first period. Divided into a second period, each scanning electrode of the first scanning electrode group has a selection potential in a period β · τ during the first period, provided that 1 <β ≦ 2 and n <
N / β is applied L times for each frame, a non-selection potential is always held during a period in which the selection potential is not applied in the first period, and a non-selection potential is always held in the second period. Each scan electrode of the second scan electrode group always holds a non-selection potential over the entire frame period, and the signal electrode has an intersection of a signal electrode and each scan electrode of the first scan electrode group in a first period. A method for driving a liquid crystal display element, comprising applying a potential determined from display data of a pixel and a selection potential of a scanning electrode, and applying a non-selection potential of a scanning electrode during the second period.
法において、前記走査電極の選択電位を前記第一のモー
ドと前記第二のモードとで同じ値にしたときに、選択画
素に印加される実効電圧が前記第一のモードと前記第二
のモードとで等しくなるようにβの値を選ぶことを特徴
とする液晶表示素子の駆動方法。10. The method of driving a liquid crystal display element according to claim 9, wherein the selection potential of the scanning electrode is set to the same value in the first mode and the second mode, and is applied to the selected pixel. Wherein the value of β is selected so that the effective voltage becomes equal in the first mode and the second mode.
法において、β=2であることを特徴とする液晶表示素
子の駆動方法。11. The method of driving a liquid crystal display device according to claim 9, wherein β = 2.
とする請求項1ないし請求項11いずれか1項記載の液
晶表示素子の駆動方法。12. The method of driving a liquid crystal display device according to claim 1, wherein the driving is performed for a plurality of lines simultaneously.
とを随時切り替えて表示することを特徴とする請求項1
ないし請求項12いずれか1項記載の液晶表示素子の駆
動方法。13. The display according to claim 1, wherein the first mode and the second mode are switched and displayed as needed.
13. A method for driving a liquid crystal display device according to claim 12.
整数、と複数の信号電極とからなるマトリクス型液晶表
示素子の駆動方法において、 前記N本の走査電極をn本の走査電極、ただしnはn<
Nなる整数、からなる第一の走査電極群と残りの(N−
n)本の走査電極からなる第二の走査電極群に分割し、
かつ、フレーム周期を第一の期間と第二の期間に分け、 前記第一の走査電極群の各走査電極には前記第一の期間
に期間τの選択電位を1フレーム毎にL回印加し、前記
第一の期間において選択電位を印加しない期間は非選択
電位を保持し、前記第二の期間は非選択電位を保持し、 前記第二の走査電極群の各走査電極はフレーム周期の間
に非選択電位を保持し、前記信号電極には第一の期間に
信号電極と第一の走査電極群の各走査電極との交点の画
素の表示データと走査電極の選択電位から求まる電位を
印加し、前記第二の期間に電位を印加することを特徴と
する液晶表示素子の駆動方法。14. A method for driving a matrix-type liquid crystal display element comprising N scan electrodes, where N is an integer of 2 or more, and a plurality of signal electrodes, wherein the N scan electrodes are n scan electrodes, Where n is n <
A first scan electrode group consisting of an integer N and the remaining (N−
n) dividing into a second scan electrode group consisting of scan electrodes;
Further, the frame period is divided into a first period and a second period, and a selection potential of a period τ is applied L times to each scan electrode of the first scan electrode group in each frame during the first period. In the first period, the non-selection potential is maintained during the period in which the selection potential is not applied, and the non-selection potential is maintained during the second period. Each scan electrode of the second scan electrode group is connected during a frame period. A non-selection potential is applied to the signal electrode, and a potential obtained from display data of a pixel at an intersection of the signal electrode and each scanning electrode of the first scanning electrode group and a selection potential of the scanning electrode is applied to the signal electrode during the first period. And applying a potential during the second period.
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JP29114198A JP2000122619A (en) | 1998-10-13 | 1998-10-13 | Driving method of liquid crystal display element |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2000055837A1 (en) * | 1999-03-15 | 2000-09-21 | Seiko Epson Corporation | Liquid-crystal display and method of driving liquid-crystal display |
WO2002015164A1 (en) * | 2000-08-11 | 2002-02-21 | Seiko Epson Corporation | Method of driving display device, drive circuit, display device, and electronic device |
WO2003094141A1 (en) * | 2002-04-30 | 2003-11-13 | Sony Corporation | Liquid crystal display device, drive method thereof, and mobile terminal |
KR100423624B1 (en) * | 2001-03-09 | 2004-03-22 | 세이코 엡슨 가부시키가이샤 | Method of driving display elements and electronic apparatus using the driving method |
JP2005202030A (en) * | 2004-01-14 | 2005-07-28 | Seiko Epson Corp | Optoelectronic device and circuit and method for driving same, and electronic equipment |
-
1998
- 1998-10-13 JP JP29114198A patent/JP2000122619A/en active Pending
Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2000055837A1 (en) * | 1999-03-15 | 2000-09-21 | Seiko Epson Corporation | Liquid-crystal display and method of driving liquid-crystal display |
US6657610B1 (en) | 1999-03-15 | 2003-12-02 | Seiko Epson Corporation | Liquid-crystal display device and method of driving the same |
WO2002015164A1 (en) * | 2000-08-11 | 2002-02-21 | Seiko Epson Corporation | Method of driving display device, drive circuit, display device, and electronic device |
US7034816B2 (en) | 2000-08-11 | 2006-04-25 | Seiko Epson Corporation | System and method for driving a display device |
KR100423624B1 (en) * | 2001-03-09 | 2004-03-22 | 세이코 엡슨 가부시키가이샤 | Method of driving display elements and electronic apparatus using the driving method |
WO2003094141A1 (en) * | 2002-04-30 | 2003-11-13 | Sony Corporation | Liquid crystal display device, drive method thereof, and mobile terminal |
US8159438B2 (en) | 2002-04-30 | 2012-04-17 | Sony Corporation | Liquid crystal display device, drive method thereof, and mobile terminal |
JP2005202030A (en) * | 2004-01-14 | 2005-07-28 | Seiko Epson Corp | Optoelectronic device and circuit and method for driving same, and electronic equipment |
JP4661051B2 (en) * | 2004-01-14 | 2011-03-30 | セイコーエプソン株式会社 | Electro-optical device, driving circuit and driving method thereof, and electronic apparatus |
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