201020657 六、發明說明: 【發明所屬之技術領域】 本發明係關於一種液晶顯示裝置,特別關於一種液晶 . 顯不裝置、液晶顯不面板及液晶顯不面板的驅動方式。 【先前技術】 一般而言,液晶顯示裝置主要包含一液晶顯示面板 (LCD Panel)以及一背光模組(Backlight Module )。其中, ^ 液晶顯不面板主要具有·一薄膜電晶體基板、一彩色滤光基 板以及一夾設於兩基板間的液晶層,且兩基板與液晶層形 成複數個陣列設置的晝素。背光模組可將一光源的光線均 勻地分佈到液晶顯示面板,並經由各晝素顯示色彩而形成 一圖案。另外,為增加液晶顯示面板之視角,現階段有廣 視角技術的產生。 廣視角技術其中之一為平面内轉換型(In-Plane φ Switching,IPS )面板,其將類梳狀圖案晝素電極層與共同 電極層配置於同一平面,例如兩電極層均配置於薄膜電晶 體基板並藉由液晶沿電場方向轉向,以擴展觀看者之視 角。然而,IPS型液晶顯示面板之晝素電極係由不透明金 - 屬製成,使其開口率及透光率減低,致使背光模組需提供 ' 較高之亮度。為改善上述缺失,習知技術另有一種邊緣電 場轉換型(Fringe Field Switching,FFS)液晶顯示面板。 請參照圖1所示,一種習知之液晶顯示面板1 〇包含 一第一基板11、一第二基板12以及一液晶層13。液晶顯 4 201020657 :面板1G係為邊緣電場轉換型㈤s)液晶顯示面板。第 二基板12與第-基板11相對而設。液晶層13設置於第 板Γ與第二基板12之間。第二基板12為彩色遽光 具有彩色遽光片及黑色矩陣層(圖未顯示)。第 基板U為薄膜電晶體陣列(TFT)基板,並具有一玻璃 基板⑴、-共同電極層112、—絕緣層ιΐ3及—畫素電極 層 114。 共同電極層112及晝素電極層114為鋼錫氧化物 (ITO)之透明電極層,透光率比Ips型液晶顯示面板高 j 2倍以上。晝素電極層114具有—電極圖案⑴|,其為 -梳狀圖案之電極層’梳狀電極圖案114,均為正電極或均 $負電極。當晝素電極層114與共同電極層⑴由驅動電 夏所驅動液晶層13之液晶分別被邊緣電場驅動而轉 向,使其液晶顯示面板10視角可達16〇度之廣視角。 當畫素電極層114由驅動電壓所驅動時,液晶就能依 據驅動電壓快速到達定位(這一段時間稱為上升時程 nsnig trnie));然而,驅動電壓僅能控制液晶之上升時 而在由下一驅動電壓驅動之前(這一段時間稱為下降 日守程(falling time))’液晶僅能藉由液晶本身之回復力而 =复,使得下降時程不受控制,因而無法加快液晶及顯示 面板之反應速率。 ——* 〇 因此,如何提供一種液晶顯示裝置、液晶顯示面板及 ,晶顯示面板的驅動方法’可提升液晶之反應速率,進而 提升影像顯示品質已成為重要課題之 5 201020657 【發明内容】 有鑑於上述課題,本發明之目的為提供一種能夠提升 . 液晶之反應速率,進而提升影像顯示品質之液晶顯示裝 置、液晶顯不面板及液晶顯不面板的驅動方法。 為達上述目的,依據本發明之一種液晶顯示面板包含 一第一基板、一第二基板、一液晶層以及一第二晝素電極 層。第一基板具有一第一晝素電極層及一第一共同電極 層,且第一晝素電極層具有一第一電極圖案。第二基板與 第一基板相對而設。液晶層設置於第一基板與第二基板之 間。第二晝素電極層係與第一晝素電極層不在同一平面 上,並具有一第二電極圖案,第二電極圖案與第一電極圖 案係相互交錯。 為達上述目的,依據本發明之一種液晶顯示面板包含 一第一基板、一第二基板、一液晶層以及一第二晝素電極 層。第一基板具有一第一晝素電極層及一第一共同電極 φ 層。第二基板與第一基板相對而設。液晶層設置於第一基 板與第二基板之間。第二晝素電極層係與第一晝素電極層 不在同一平面上。第一晝素電極層控制液晶層之液晶產生 一第一轉向,第二晝素電極層控制液晶層之液晶產生一第 二轉向。 ' 為達上述目的,依據本發明之一種液晶顯示裝置包含 一液晶顯示面板以及一背光模組。液晶顯示面板具有一第 一基板、一第二基板、一液晶層及一第二晝素電極層。第 一基板具有一第一晝素電極層及一第一共同電極層,且第 6 201020657 一晝素電極層具有一第一電極圖案。第二基板與第一基板 相對而設,液晶層設置於第一基板與第二基板之間。第二 晝素電極層係與第一晝素電極層不在同一平面上,並具有 . 一第二電極圖案,第二電極圖案與第一電極圖案係相互交 疊。 為達上述目的,依據本發明之一種液晶顯示裝置包含 一液晶顯示面板以及一背光模組。液晶顯示面板具有一第 一基板、一第二基板、一液晶層以及一第二晝素電極層。 • 第一基板具有一第一晝素電極層及一第一共同電極層。第 二基板與第一基板相對而設,液晶層設置於第一基板與該 第二基板之間。第二晝素電極層係與第一晝素電極層不在 同一平面上。第一晝素電極層控制液晶層之液晶產生一第 一轉向,第二晝素電極層控制液晶層之液晶產生一反向作 用力。背光模組與液晶顯示面板相對設置。 為達上述目的,依據本發明之一種液晶顯示面板的驅 Φ 動方法。液晶顯示面板具有一第一晝素電極層、一第二晝 素電極層及一液晶層,液晶顯示面板的驅動方法包含以下 步驟:輸入一第一驅動訊號至該第一晝素電極層以驅動液 晶層之液晶轉向;輸入一第二驅動訊號至第一晝素電極 - 層;第二驅動訊號小於第一驅動訊號時,則於第一驅動訊 號與第二驅動訊號之間輸入一插入驅動訊號至第二晝素 電極層以驅動液晶層之液晶轉向,其中第一晝素電極層與 第二晝素電極層係在不同平面上。 承上所述,依據本發明之一種液晶顯示裝置、液晶顯 7 201020657 不面板及液晶顯不面板的驅動方法5措由設置兩晝素電極 層位於液晶顯示面板之不同平面,其中一晝素電極層可控 制液晶在上升時程之轉向,另一晝素電極層可控制液晶在 . 下降時程之轉向,例如是藉由兩晝素電極層之電極圖案相 互交疊以分別控制液晶之轉向,因而加快液晶上升及回復 之反應速率,以提升液晶顯示裝置之影像顯示品質。 【實施方式】 翁 以下將參照相關圖式,說明依據本發明較佳實施例之 一種液晶顯示裝置、液晶顯示面板及液晶顯示面板的驅動 方法,其中相同的元件將以相同的參照符號加以說明。 第一實施例 請參照圖2A所示,本發明第一實施例之一種液晶顯 示面板20包含一第一基板21、一第二基板22、一液晶層 23以及一第二晝素電極層24。液晶顯示面板20包含複數 φ 個晝素,其係以陣列式訊號線定義(圖未顯示),本實施 例係以一晝素為例說明。 第一基板21與第二基板22相對而設。液晶層23設 置於第一基板21與第二基板22之間。第一基板21具有 一第一晝素電極層214及一第一共同電極層212,且第一 ' 晝素電極層214具有一第一電極圖案214'。第二晝素電極 層24係與第一晝素電極層214不在同一平面上,第二晝 素電極層24可設置於第一基板21或第二基板22,在本實 施例中,第二晝素電極層24係設置於第一基板21,並具 8 201020657 有一第二電極圖案24'。 第一畫素電極層214接收一驅動訊號而控制液晶層23 之液晶產生一第一轉向,第二晝素電極層24接收另一驅 . 動訊號而控制液晶層23之液晶產生一第二轉向。在本實 施例中,第一畫素電極層214用以控制液晶於上升時程 (rising time )的轉向,而第二晝素電極層24用以控制液 晶於下降時程(falling time )的轉向。當然,亦可反過來, 第二晝素電極層24用以控制液晶於上升時程的轉向,而 ® 第一晝素電極層214用以控制液晶於下降時程的轉向。 本實施例係藉由第二電極圖案24'與第一電極圖案 214'相互交疊而達到上述目的。在本實施例中,第一電極 圖案214'及第二電極圖案24'為梳狀或栅狀,並相互交錯。 圖2B係為第一基板21及第二晝素電極層24的俯視示意 圖,請參考圖2A及圖2B所示,其中至少部分第二電極圖 案24’與至少部分第一電極圖案214’交疊之夾角Θ介於80 φ 度至90度,於此係以90度為例。需注意的是,交錯之夾 角Θ係以兩梳狀電極圖案214'、24'之直條電極VI、V2交 錯之夾角Θ為例。 以下說明第一晝素電極層214及第二晝素電極層24 • 的驅動情形。當第一畫素電極層214受驅動電壓驅動時, ' 由於驅動電場係由第一晝素電極層214到達下方的第一共 同電極層212 ’故對液晶而言’所文到的電場方向為垂直 於直條電極V2的方向,而液晶又沿電場方向而轉向,故 液晶受驅動轉向並垂直於直條電極V2 (第一轉向)。同樣 9 201020657 的原則,當第二晝素電極層24受另一驅動電壓驅動時, 由於驅動電場係由第二晝素電極層24到達下方的第一共 同電極層212,故對液晶而言,所受到的電場方向為垂直 於直條電極VI的方向,而液晶又沿電場方向而轉向,故 液晶受驅動而垂直於直條電極VI (第二轉向)。承上述, 在本實施例中,當第一畫素電極層214受驅動時,液晶之 第一轉向係為順時針旋轉,當第二晝素電極層24受驅動 時,液晶之第二轉向係為逆時針旋轉,兩方向係相反。 在本實施例中,第一晝素電極層214與第二晝素電極 層24係於不同時間控制液晶層23之液晶,例如可分別於 同一圖框時間内的不同時間來控制液晶、或是分別於相鄰 圖框時間來控制液晶。另外,在本實施例中,第一晝素電 極層214與第二畫素電極層24的相對位置可互換。 於本實施例中,第一基板21為薄膜電晶體(TFT)基 板,而第二基板22為彩色濾光(CF)基板。於本實施例 中,第一畫素電極層214係為一主要驅動電極層(控制液 晶之上升時程),而第二晝素電極層24為一輔助驅動電極 層(控制液晶之下降時程)。當然,第一晝素電極層214 依設計需求不同亦可為一輔助驅動電極層,而第二晝素電 極層24可為一主要驅動電極層。 另外,於本實施例中,第一共同電極層212設置於一 玻璃基板211上並與第一晝素電極層214間隔一絕緣層 213'。第二晝素電極層24與第一晝素電極層214之間亦具 有一絕緣層213。第一晝素電極層214與第二晝素電極層 10 201020657 24共同藉由第一共同電極層212產生電位差以驅動液晶層 23之液晶轉向。當然,亦可設置例如兩層第一共同電極層 212分別與第一晝素電極層214及第二晝素電極層24產生 • 電位差以驅動液晶層之液晶轉向。 第二實施例 請參照圖3所示,本發明之一種液晶顯示面板30包 含一第一基板31、一第二基板32、一液晶層33以及一第 二晝素電極層34。與上述實施例主要不同之處在於,於本 — 實施例中,第二晝素電極層34設置於第二基板32。另外, 液晶顯示面板30更包含一第二共同電極層35設置於第二 基板32之一玻璃基板321上。第二畫素電極層34與第二 共同電極層35之間係具有一絕緣層36以提供電性隔絕。 在本實施例中,液晶顯示面板30藉由第一晝素電極層314 與第一共同電極層312作為液晶層33之主要驅動電極 層,第二晝素電極層34與第二共同電極層35作為液晶層 φ 33之輔助驅動電極層。 在本實施例中,液晶可使用負型液晶,以降低第一基 板21與第二基板22之間的垂直電場對液晶之轉向的影 響。 • 請參照圖4A、圖4B及圖4C以說明本發明之一種液 晶顯不面板的驅動方法’本貫施例之驅動方法係以液晶顯 示面板20為例。圖4A為驅動方法的流程圖,並配合圖4B 及圖4C之第一晝素電極層與第二晝素電極層所接收之驅 動訊號的示意圖。 11 201020657 如圖4 A所示,液晶顯示面板2 〇之驅動方法包含步驟 S1至步驟S3。步驟S1係輸入一第一驅動訊號至第—金素 電極層214以驅動液晶層23之液晶轉向。請參照圖所 示,例如在第Ν1圖框中,第一驅動訊號%為3V。 步驟S2係輸入一第二驅動訊號至第—晝素電極層 214。請參照圖4Β所示,例如在第Ν2圖框中, 一·· _ 訊號Vi為2V。201020657 VI. Description of the Invention: [Technical Field] The present invention relates to a liquid crystal display device, and more particularly to a driving method of a liquid crystal display device, a liquid crystal display panel, and a liquid crystal display panel. [Prior Art] In general, a liquid crystal display device mainly includes a liquid crystal display panel (LCD Panel) and a backlight module (Backlight Module). Wherein, the liquid crystal display panel mainly has a thin film transistor substrate, a color filter substrate, and a liquid crystal layer interposed between the two substrates, and the two substrates and the liquid crystal layer form a plurality of arrays of halogens. The backlight module uniformly distributes the light of a light source to the liquid crystal display panel, and displays a color through each of the pixels to form a pattern. In addition, in order to increase the viewing angle of the liquid crystal display panel, there is a wide viewing angle technology at this stage. One of the wide viewing angle technologies is an In-Plane φ Switching (IPS) panel, in which a comb-like patterned halogen electrode layer and a common electrode layer are disposed on the same plane, for example, both electrode layers are disposed on the thin film. The crystal substrate is turned by the liquid crystal in the direction of the electric field to expand the viewer's viewing angle. However, the halogen electrode of the IPS type liquid crystal display panel is made of an opaque gold-based genus, which reduces the aperture ratio and the light transmittance, so that the backlight module needs to provide 'higher brightness. In order to improve the above-mentioned defects, the prior art has another Fringe Field Switching (FFS) liquid crystal display panel. Referring to FIG. 1, a conventional liquid crystal display panel 1 includes a first substrate 11, a second substrate 12, and a liquid crystal layer 13. Liquid crystal display 4 201020657: Panel 1G is a fringe field electric conversion type (five) s) liquid crystal display panel. The second substrate 12 is provided opposite to the first substrate 11. The liquid crystal layer 13 is disposed between the first plate Γ and the second substrate 12. The second substrate 12 is a color green light having a color light-emitting sheet and a black matrix layer (not shown). The first substrate U is a thin film transistor array (TFT) substrate and has a glass substrate (1), a common electrode layer 112, an insulating layer ι 3 and a pixel electrode layer 114. The common electrode layer 112 and the halogen electrode layer 114 are transparent electrode layers of steel tin oxide (ITO), and the light transmittance is 2 times or more higher than that of the Ips liquid crystal display panel. The halogen electrode layer 114 has an electrode pattern (1)| which is an electrode layer of a comb pattern, and a comb electrode pattern 114, both of which are positive electrodes or negative electrodes. When the halogen electrode layer 114 and the common electrode layer (1) are driven by the fringe electric field by the liquid crystal driven by the driving liquid crystal layer 13, the liquid crystal display panel 10 has a wide viewing angle of 16 degrees. When the pixel electrode layer 114 is driven by the driving voltage, the liquid crystal can quickly reach the positioning according to the driving voltage (this period is called the rising time period nsnig trnie); however, the driving voltage can only control the rise of the liquid crystal when Before the next driving voltage is driven (this period of time is called the falling day), the liquid crystal can only be recovered by the restoring force of the liquid crystal itself, so that the falling time period is not controlled, and thus the liquid crystal and the display cannot be accelerated. The reaction rate of the panel. ——* 〇 Therefore, how to provide a liquid crystal display device, a liquid crystal display panel, and a driving method of a crystal display panel can improve the reaction rate of the liquid crystal, thereby improving the image display quality. 5 201020657 [Invention content] In view of the above problems, an object of the present invention is to provide a liquid crystal display device, a liquid crystal display panel, and a liquid crystal display panel driving method capable of improving the reaction rate of liquid crystal and improving image display quality. To achieve the above object, a liquid crystal display panel according to the present invention comprises a first substrate, a second substrate, a liquid crystal layer and a second halogen electrode layer. The first substrate has a first halogen electrode layer and a first common electrode layer, and the first halogen electrode layer has a first electrode pattern. The second substrate is disposed opposite to the first substrate. The liquid crystal layer is disposed between the first substrate and the second substrate. The second halogen electrode layer is not in the same plane as the first halogen electrode layer, and has a second electrode pattern, and the second electrode pattern and the first electrode pattern are interlaced with each other. To achieve the above object, a liquid crystal display panel according to the present invention comprises a first substrate, a second substrate, a liquid crystal layer and a second halogen electrode layer. The first substrate has a first halogen electrode layer and a first common electrode φ layer. The second substrate is disposed opposite to the first substrate. The liquid crystal layer is disposed between the first substrate and the second substrate. The second halogen electrode layer is not in the same plane as the first halogen electrode layer. The first halogen electrode layer controls the liquid crystal of the liquid crystal layer to generate a first turn, and the second halogen electrode layer controls the liquid crystal of the liquid crystal layer to generate a second turn. In order to achieve the above object, a liquid crystal display device according to the present invention comprises a liquid crystal display panel and a backlight module. The liquid crystal display panel has a first substrate, a second substrate, a liquid crystal layer and a second halogen electrode layer. The first substrate has a first halogen electrode layer and a first common electrode layer, and the sixth 201020657 monolayer electrode layer has a first electrode pattern. The second substrate is disposed opposite to the first substrate, and the liquid crystal layer is disposed between the first substrate and the second substrate. The second halogen electrode layer is not in the same plane as the first halogen electrode layer, and has a second electrode pattern, and the second electrode pattern and the first electrode pattern overlap each other. In order to achieve the above object, a liquid crystal display device according to the present invention comprises a liquid crystal display panel and a backlight module. The liquid crystal display panel has a first substrate, a second substrate, a liquid crystal layer and a second halogen electrode layer. • The first substrate has a first halogen electrode layer and a first common electrode layer. The second substrate is disposed opposite to the first substrate, and the liquid crystal layer is disposed between the first substrate and the second substrate. The second halogen electrode layer is not in the same plane as the first halogen electrode layer. The first halogen electrode layer controls the liquid crystal of the liquid crystal layer to generate a first turn, and the second halogen electrode layer controls the liquid crystal of the liquid crystal layer to generate a reverse force. The backlight module is disposed opposite to the liquid crystal display panel. In order to achieve the above object, a method of driving a liquid crystal display panel according to the present invention is provided. The liquid crystal display panel has a first halogen electrode layer, a second halogen electrode layer and a liquid crystal layer. The driving method of the liquid crystal display panel comprises the steps of: inputting a first driving signal to the first halogen electrode layer to drive The liquid crystal layer of the liquid crystal layer is turned; a second driving signal is input to the first pixel electrode layer; when the second driving signal is smaller than the first driving signal, an insertion driving signal is input between the first driving signal and the second driving signal. The liquid crystal layer is driven to the second halogen electrode layer to drive the liquid crystal layer, wherein the first halogen electrode layer and the second halogen electrode layer are on different planes. According to the present invention, a liquid crystal display device according to the present invention, a liquid crystal display 7 201020657, a panel and a liquid crystal display panel driving method 5 are provided with two halogen electrode layers on different planes of the liquid crystal display panel, wherein one of the halogen electrodes The layer can control the turning of the liquid crystal in the rising time course, and the other elemental electrode layer can control the turning of the liquid crystal during the falling time, for example, by mutually overlapping the electrode patterns of the two halogen electrode layers to respectively control the steering of the liquid crystal. Therefore, the reaction rate of the liquid crystal rising and returning is accelerated to improve the image display quality of the liquid crystal display device. [Embodiment] Hereinafter, a liquid crystal display device, a liquid crystal display panel, and a driving method of a liquid crystal display panel according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings, wherein the same elements will be described with the same reference numerals. First Embodiment As shown in FIG. 2A, a liquid crystal display panel 20 according to a first embodiment of the present invention includes a first substrate 21, a second substrate 22, a liquid crystal layer 23, and a second halogen electrode layer 24. The liquid crystal display panel 20 includes a plurality of φ pixels, which are defined by an array of signal lines (not shown). This embodiment is described by taking a single element as an example. The first substrate 21 is opposed to the second substrate 22. The liquid crystal layer 23 is disposed between the first substrate 21 and the second substrate 22. The first substrate 21 has a first halogen electrode layer 214 and a first common electrode layer 212, and the first 'halogen electrode layer 214 has a first electrode pattern 214'. The second halogen electrode layer 24 is not in the same plane as the first halogen electrode layer 214, and the second halogen electrode layer 24 may be disposed on the first substrate 21 or the second substrate 22, in this embodiment, the second layer The element electrode layer 24 is disposed on the first substrate 21 and has a second electrode pattern 24' with 8 201020657. The first pixel electrode layer 214 receives a driving signal to control the liquid crystal of the liquid crystal layer 23 to generate a first steering, and the second halogen electrode layer 24 receives another driving signal to control the liquid crystal of the liquid crystal layer 23 to generate a second steering. . In this embodiment, the first pixel electrode layer 214 is used to control the liquid crystal in the rising time of the rising time, and the second pixel electrode layer 24 is used to control the liquid crystal in the falling time of the turning time. . Of course, in turn, the second halogen electrode layer 24 is used to control the liquid crystal in the rising time course, and the first halogen electrode layer 214 is used to control the liquid crystal in the down time. This embodiment achieves the above object by overlapping the second electrode patterns 24' and the first electrode patterns 214'. In the present embodiment, the first electrode pattern 214' and the second electrode pattern 24' are comb-like or grid-like and are interlaced with each other. 2B is a top plan view of the first substrate 21 and the second halogen electrode layer 24, as shown in FIG. 2A and FIG. 2B, wherein at least a portion of the second electrode patterns 24' overlap at least a portion of the first electrode patterns 214'. The angle Θ is between 80 φ and 90 degrees, for example, 90 degrees. It should be noted that the interlaced angles are exemplified by the angle Θ of the straight electrodes VI and V2 of the two comb-shaped electrode patterns 214', 24'. The driving situation of the first halogen electrode layer 214 and the second halogen electrode layer 24 will be described below. When the first pixel electrode layer 214 is driven by the driving voltage, 'because the driving electric field is from the first halogen electrode layer 214 to the lower first common electrode layer 212', the direction of the electric field to the liquid crystal is Straight to the direction of the straight electrode V2, and the liquid crystal is turned in the direction of the electric field, the liquid crystal is driven to be turned and perpendicular to the straight electrode V2 (first turn). Similarly, in the principle of 201020657, when the second halogen electrode layer 24 is driven by another driving voltage, since the driving electric field is passed from the second halogen electrode layer 24 to the lower first common electrode layer 212, for the liquid crystal, The direction of the electric field received is perpendicular to the direction of the straight electrode VI, and the liquid crystal is turned in the direction of the electric field, so that the liquid crystal is driven perpendicular to the straight electrode VI (second turn). In the above embodiment, when the first pixel electrode layer 214 is driven, the first steering system of the liquid crystal rotates clockwise, and when the second halogen electrode layer 24 is driven, the second steering system of the liquid crystal For counterclockwise rotation, the two directions are opposite. In this embodiment, the first halogen electrode layer 214 and the second halogen electrode layer 24 control the liquid crystal of the liquid crystal layer 23 at different times, for example, the liquid crystal can be controlled at different times within the same frame time, or The liquid crystals are controlled at adjacent frame times. Further, in the present embodiment, the relative positions of the first halogen electrode layer 214 and the second pixel electrode layer 24 are interchangeable. In the present embodiment, the first substrate 21 is a thin film transistor (TFT) substrate, and the second substrate 22 is a color filter (CF) substrate. In this embodiment, the first pixel electrode layer 214 is a main driving electrode layer (controlling the rise time of the liquid crystal), and the second halogen electrode layer 24 is an auxiliary driving electrode layer (controlling the falling time of the liquid crystal) ). Of course, the first halogen electrode layer 214 may also be an auxiliary driving electrode layer according to design requirements, and the second halogen electrode layer 24 may be a main driving electrode layer. In addition, in the embodiment, the first common electrode layer 212 is disposed on a glass substrate 211 and spaced apart from the first halogen electrode layer 214 by an insulating layer 213'. An insulating layer 213 is also provided between the second halogen electrode layer 24 and the first halogen electrode layer 214. The first halogen electrode layer 214 and the second halogen electrode layer 10 201020657 24 collectively generate a potential difference by the first common electrode layer 212 to drive the liquid crystal steering of the liquid crystal layer 23. Of course, it is also possible to provide, for example, two layers of the first common electrode layer 212 respectively generating a potential difference with the first halogen electrode layer 214 and the second halogen electrode layer 24 to drive the liquid crystal steering of the liquid crystal layer. Second Embodiment Referring to FIG. 3, a liquid crystal display panel 30 of the present invention includes a first substrate 31, a second substrate 32, a liquid crystal layer 33, and a second halogen electrode layer 34. The main difference from the above embodiment is that, in the present embodiment, the second halogen electrode layer 34 is disposed on the second substrate 32. In addition, the liquid crystal display panel 30 further includes a second common electrode layer 35 disposed on one of the second substrates 32. An insulating layer 36 is provided between the second pixel electrode layer 34 and the second common electrode layer 35 to provide electrical isolation. In the present embodiment, the liquid crystal display panel 30 uses the first halogen electrode layer 314 and the first common electrode layer 312 as the main driving electrode layer of the liquid crystal layer 33, and the second halogen electrode layer 34 and the second common electrode layer 35. As the auxiliary driving electrode layer of the liquid crystal layer φ 33 . In the present embodiment, the liquid crystal may use a negative liquid crystal to reduce the influence of the vertical electric field between the first substrate 21 and the second substrate 22 on the steering of the liquid crystal. A method of driving a liquid crystal display panel according to the present invention will be described with reference to Figs. 4A, 4B and 4C. The driving method of the present embodiment is exemplified by the liquid crystal display panel 20. 4A is a flow chart of a driving method, together with the driving signals received by the first halogen electrode layer and the second halogen electrode layer of FIGS. 4B and 4C. 11 201020657 As shown in FIG. 4A, the driving method of the liquid crystal display panel 2 includes steps S1 to S3. Step S1 is to input a first driving signal to the first-thickness electrode layer 214 to drive the liquid crystal of the liquid crystal layer 23 to turn. Please refer to the figure. For example, in the first frame, the first driving signal % is 3V. Step S2 inputs a second driving signal to the first halogen element layer 214. Referring to FIG. 4A, for example, in the second frame, the signal ____ is 2V.
步驟S3係當第二驅動訊號小於第一驅動訊號時,則 ,第一驅動訊號與第二驅動訊號之間輸入—插入驅動訊 唬至第二晝素電極層24以驅動液晶層之液晶轉向。需注 意的是,第一驅動訊號與插入驅動訊號於不同時間分別輸 入第一畫素電極層214及第二畫素電極層24,相同地,第 二驅動訊號與插入驅動訊號於不同時間分別輸入第一晝 素電極層214及第二畫素電極| 24。在本實施财,由二 第二驅動訊號(2V)小於第一驅動訊號(3V),故如圖4c 所不,在N1’時間輸入一插入驅動訊號%至第二晝素電極 層24以驅動液晶層之液晶轉向,插入驅動訊號%之值 IV。 金由於第二驅動訊號之值小於第一驅動訊號,這代表該 晝素的液晶受第二驅動訊號驅動所轉動的角度要小於受 第驅動訊號驅動所轉動的角度,即在第N2圖框時,液 曰曰需反轉,而本實施例藉由在第N1圖框及第N2圖框之間 的N1時間内,第二晝素電極層24受插入驅動訊號的驅 動,使彳于液晶的下降時程得受控制並在第N2圖框之前先 12 201020657 行反轉,進而加速液晶的反應速率,並提升影像顯示品質。 在本實施例中,第一驅動訊號及第二驅動訊號之值係 以正極性為例,當兩者為不同極性或為負極性時,係以絕 對值來比較。另外,本實施例之插入驅動訊號可依據一對 照表(lookup table )查表而得,當然亦可依據第一驅動訊 號及第二驅動訊號來進行計算而得知。 在本實施例中,ΝΓ時間可為一圖框時間,或是第N1 圖框時間的一部分,或是第N2圖框時間的一部分。 m W 另外,在輸入插入驅動訊號至第二畫素電極層24之 前或同時,可輸入一 0V的電壓或是與第一共同電極層212 之共同電壓相同的電壓至第一晝素電極層214以先行對該 晝素的液晶電容及儲存電容進行放電,以便插入驅動訊號 能夠提供更快速的反應速率。需注意者,上述用以放電之 電壓訊號可由於與插入驅動訊號之配合作動而改變其值。 另外,本實施例之驅動方法亦可應用於上述第二實施 φ 例之液晶顯示面板30。需注意者,由於液晶顯示面板30 與液晶顯示面板20之第二晝素電極層的設置位置不同, 故插入驅動訊號可依實際情況而調整,也就是說,兩者的 對照表可不相同。 請參照圖5所示,本發明較佳實施例之一種液晶顯示 裝置4包含一液晶顯示面板20 (或30)以及一背光模組 40。由於液晶顯示面板20、30已於上述實施例詳述,故 不再贅述。背光模組40可為側光式(Side-Edge Type)背 光模組或直下式背光模組,於此背光模組40係以側光式 13 201020657 背光模組為例,其與液晶顯示面板20相對設置。背光模 組40可具有一光源組件、一導光板及光學膜,以提供液 晶顯示面板20可用之光源。 綜上所述,依據本發明之一種液晶顯示裝置、液晶顯 不面板及液晶顯不面板的驅動方法5糟由設置兩晝素電極 層位於液晶顯示面板之不同平面,其中一晝素電極層可控 制液晶在上升時程之轉向,另一晝素電極層可控制液晶在 下降時程之轉向,例如是藉由兩晝素電極層之電極圖案相 ® 互交錯以分別控制液晶之轉向,因而加快液晶上升及回復 之反應速率,以提升液晶顯示裝置之影像顯示品質。 以上所述僅為舉例性,而非為限制性者。任何未脫離 本發明之精神與範疇,而對其進行之等效修改或變更,均 應包含於後附之申請專利範圍中。 【圖式簡單說明】 參 圖1為依據一種習知之液晶顯示面板之示意圖; 圖2A為依據本發明第一實施例之一種液晶顯示面板 之不意圖, 圖2B為圖2A之第一基板及第二晝素電極層之俯視示 意圖; 圖3為依據本發明第二實施例之一種液晶顯示面板之 不意圖, 圖4A為依據本發明之一種液晶顯示面板之驅動方法 14 201020657 之流程圖; 圖4B為依據本發明之液晶顯示面板之驅動方法中, 第一晝素電極層所接收之驅動訊號的示意圖; 圖4C為依據本發明之液晶顯示面板之驅動方法中, 第二晝素電極層所接收之驅動訊號的示意圖;以及 圖5為依據本發明較佳實施例之一種液晶顯示裝置之 示意圖。 *【主要元件符號說明】 10、 20、30.液晶顯不面板 11、 21、31 :第一基板 111、211、311、321 :玻璃基板 112 :共同電極層 113、213、213'、313、36 :絕緣層 114:晝素電極層 φ 1M,:電極圖案 12、 22、32 :第二基板 13、 23、33 :液晶層 212、312 :第一共同電極層 214、314 :第一晝素電極層 214'、314’ :第一電極圖案 24、34 :第二晝素電極層 24'、34’ :第二電極圖案 35 :第二共同電極層 15 201020657 4 .液晶顯不裝置 40 :背光模組 S1〜S3 :驅動方法的步驟 VI、V2 :直條電極 Θ :夾角Step S3: When the second driving signal is smaller than the first driving signal, inputting between the first driving signal and the second driving signal-inserting the driving signal to the second halogen electrode layer 24 to drive the liquid crystal layer of the liquid crystal layer to turn. It should be noted that the first driving signal and the insertion driving signal are respectively input to the first pixel electrode layer 214 and the second pixel electrode layer 24 at different times. Similarly, the second driving signal and the insertion driving signal are respectively input at different times. The first halogen electrode layer 214 and the second pixel electrode |24. In this implementation, the second driving signal (2V) is smaller than the first driving signal (3V). Therefore, as shown in FIG. 4c, an insertion driving signal % is input to the second pixel electrode layer 24 to drive at time N1'. The liquid crystal of the liquid crystal layer is turned, and the value IV of the driving signal is inserted. Since the value of the second driving signal is smaller than the first driving signal, the angle indicating that the liquid crystal of the pixel is driven by the second driving signal is smaller than the angle rotated by the driving of the driving signal, that is, in the N2 frame. The liquid helium needs to be reversed. In this embodiment, the second halogen electrode layer 24 is driven by the insertion of the driving signal during the N1 time between the N1 frame and the N2 frame, so that the liquid crystal is inserted. The descent time course is controlled and the 12 201020657 line is inverted before the N2 frame, which accelerates the reaction rate of the liquid crystal and improves the image display quality. In this embodiment, the values of the first driving signal and the second driving signal are taken as positive examples. When the two are of different polarity or negative polarity, they are compared by absolute values. In addition, the insertion driving signal of the embodiment can be obtained by looking up a table according to a pair of lookup tables, and can of course be calculated based on the first driving signal and the second driving signal. In this embodiment, the time of the frame may be a frame time, or part of the N1 frame time, or part of the N2 frame time. In addition, a voltage of 0 V or the same voltage as the common voltage of the first common electrode layer 212 may be input to the first halogen electrode layer 214 before or at the same time as the input of the driving signal to the second pixel electrode layer 24 is input. The liquid crystal capacitor and the storage capacitor of the halogen are discharged first, so that the insertion of the driving signal can provide a faster reaction rate. It should be noted that the voltage signal for discharging described above may change its value due to cooperation with the insertion of the driving signal. Further, the driving method of the present embodiment can also be applied to the liquid crystal display panel 30 of the second embodiment. It should be noted that since the liquid crystal display panel 30 and the second halogen electrode layer of the liquid crystal display panel 20 are disposed at different positions, the insertion driving signal can be adjusted according to actual conditions, that is, the comparison table of the two can be different. Referring to FIG. 5, a liquid crystal display device 4 according to a preferred embodiment of the present invention includes a liquid crystal display panel 20 (or 30) and a backlight module 40. Since the liquid crystal display panels 20 and 30 have been described in detail in the above embodiments, they will not be described again. The backlight module 40 can be a Side-Edge Type backlight module or a direct-lit backlight module. The backlight module 40 is an edge-light type 13 201020657 backlight module, and the liquid crystal display panel 20 is used as an example. Relative settings. The backlight module 40 can have a light source assembly, a light guide plate, and an optical film to provide a light source for the liquid crystal display panel 20. In summary, a liquid crystal display device, a liquid crystal display panel, and a liquid crystal display panel driving method according to the present invention provide a two-dimensional electrode layer on different planes of the liquid crystal display panel, wherein a halogen electrode layer can be Controlling the liquid crystal's turn in the rising time course, another elementary electrode layer can control the liquid crystal's turning in the falling time course, for example, by interlacing the electrode pattern phases of the two halogen electrode layers to control the liquid crystal steering separately, thereby speeding up The reaction rate of rising and returning of the liquid crystal to improve the image display quality of the liquid crystal display device. The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of the present invention are intended to be included in the scope of the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a conventional liquid crystal display panel; FIG. 2A is a schematic diagram of a liquid crystal display panel according to a first embodiment of the present invention, and FIG. 2B is a first substrate of FIG. FIG. 3 is a schematic diagram of a liquid crystal display panel according to a second embodiment of the present invention, and FIG. 4A is a flow chart of a driving method 14 201020657 of a liquid crystal display panel according to the present invention; FIG. 4B In the driving method of the liquid crystal display panel according to the present invention, a schematic diagram of the driving signal received by the first halogen electrode layer; FIG. 4C is a diagram of the driving method of the liquid crystal display panel according to the present invention, the second halogen element layer is received A schematic diagram of a driving signal; and FIG. 5 is a schematic diagram of a liquid crystal display device in accordance with a preferred embodiment of the present invention. * [Description of main component symbols] 10, 20, 30. Liquid crystal display panel 11, 21, 31: first substrate 111, 211, 311, 321 : glass substrate 112: common electrode layers 113, 213, 213', 313, 36: insulating layer 114: halogen electrode layer φ 1M, electrode pattern 12, 22, 32: second substrate 13, 23, 33: liquid crystal layer 212, 312: first common electrode layer 214, 314: first halogen Electrode layers 214', 314': first electrode patterns 24, 34: second halogen electrode layers 24', 34': second electrode patterns 35: second common electrode layer 15 201020657 4. Liquid crystal display device 40: backlight Modules S1 to S3: Steps VI, V2 of the driving method: Straight electrode Θ: Angle
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