201005364 nKj\j 26571twf.doc/n 九、發明說明: 【發明所屬之技術領域】 本發明是有關於一種觸控式顯示面板、光電裝置及上 述各種裝置的製造方法,且特別是有關於一種有助於簡化 模組製程的觸控式顯示面板、光電裝置及上述各種裝置的 製造方法。 【先前技術】 在一般的觸控式顯示面板設計中,以觸控感測模式的 設計原理分類,大致可分為電容式、電阻式、感光式等; 以結構組成分類,則可分為外貼式(Added type )及内建 式(integrated type)兩種。電容式觸控感測設計使得觸控 式顯示面板具有較高的開口率及較好的訊噪比而成為目前 觸控式顯示面板的主流。另外,内建式結構設計的產品比 外貼式結構設計的產品更為輕薄。因此,結合電容式觸控 感測設計原理與内建式之結構組成使得觸控式顯示面板的 β 產品規格及顯示表現更為理想。 圖1為習知觸控式顧示面板之剖面圖。請參照圖1, 觸控式顯示面板100包括一對向基板110、一陣列基板 120、一控制電路14〇、/驅動電路150以及一顯示介質層 160。控制電路14〇配置於對向基板110上,而對向基板 110内建有電容式觸控感測元件(未繪示)。當使用者觸 碰對向基板110時,觸控感測元件(未繪示)中所產生的 電容變化可藉由此控制電路140傳輸後進行計算並產生對 6 201005364 /\υυ / j5 2657 ltwf.doc/n 應的訊號。驅動電路150配置於陣列基板12〇上,其用以 控制觸控式顯示面板100内之顯示介質層16〇以進行顯示。 陣列基板120上的驅動電路15〇及對向基板1上的 控制電路140分別連接於兩基板11〇、12〇接觸顯示介質層 160的表面上。因此,以模組製程來看,若先將驅動電路 150連接在陣列基板12〇上,則需把組立好的觸控式顯示 面板100翻面後,才能再將控制電路140連接在對向基板 鲁 110上’反之亦然。因此’驅動電路150與控制電路140 的配置增加了模組製程的複雜度及困難度。進一步來說, 在不同的基板(110、120)上分別配置不同的電路(14〇、 150)使得觸控式顯示面板1〇〇的製作良率受到限制。 【發明内容】 本發明提供一種觸控式顯示面板,其設計有助於簡化 觸控式顯示面板的製程。 本發明另提供一種觸控式顯示面板的製造方法,其可 降低觸控式顯示面板之模組製程的複雜度及困難度。 本發明再提供一種光電裝置’具有上述的觸控式顯示 面板。 本發明更提供一種光電裴置的製造方法’具有較高的 製程良率。 本發明&出—種觸控式顯示面板,其具有一顯示區以 及位於顯示區周邊的一第一周邊線路區。觸控式顯示面板 包括一陣列基板、—對向基板、多個訊號傳輸物、一控制 7 201005364 26571twf.doc/n 電路以及-顯不介質層。對向基板配置於陣列基板上方, 其中對向基板具有-觸控感測層、一共用電極以及多個導 电接塾。導電接墊位於第一周邊線路區中且電性連接觸控 感測層。此外,共用電極與導電接墊電性絕緣。訊號傳輸 物配置於陣列基板及對向基板之間,且位於第一周邊線路 區中。控制電路配置於陣列基板上,以使得控制電路藉由 訊號傳輸物電性連接觸控感測層。顯示介質層配置於對向 | 基板與陣列基板之間。 本發明另提出一種觸控式顯示面板的製造方法,適於 製造具有一顯示區以及一第一周邊線路區的一觸控式顯示 面板’其中第一周邊線路區位於顯示區周邊。觸控式顯示 面板的製造方法包括:提供一對向基板,其具有一觸控感 測層、一共用電極以及多個導電接墊。導電接墊位於第一 周邊線路區中’且電性連接觸控感測層,而共用電極與導 電接墊電性絕緣。接著,提供一陣列基板。然後,配置一 控制電路於陣列基板上。之後’配置多個訊號傳輸物於陣 _ 列基板及對向基板之間,且訊號傳輸物位於第一周邊線路 區中’以使得控制電路電性連接導電接墊。再者,失設一 顯示介質層於對向基板以及陣列基板之間。 本發明又提出一種光電裝置’其包括如上述之觸控式 顯示面板。 本發明更提出一種光電裝置的製造方法,其包括如上 述之觸控式顯示面板的製造方法。 本發明的觸控式顯示面板以及光電裝置中,觸控感測 8 26571twf.doc/n 201005364 層之控制電路以及驅動晝素結構之驅動電路皆配置於陣列 基板上。因此’製造本發明的觸控式顯示面板以及光電裝 置的過程中,不需將已組立好的觸控式顯示面板翻轉,就 可以使驅動電路與控制電路連接至對應的元件。換言之, 本發明的觸控式顯示面板以及光電裝置的設計可降低觸控 式顯示面板之模組製程的複雜度及困難度。 為讓本發明之上述特徵和優點能更明顯易懂,下文特 舉較佳實施例,並配合所附圖式,作詳細說明如下。 【實施方式】 圖2A及圖2B分別緣示為本發明一實施例之觸控式顯 示面板的上視圖及剖面圖,其中圖2B為根據圖2A中橫截 面線cc’之剖面。請參照圖2A及圖2B,觸控式顯示面板 200具有一顯示區AA、一第一周邊線路區B1以及一第二 ,邊線路區B2 ’其中第一周邊線路區B1及第二周邊線路 區B2位於顯示區AA周邊,且第二周邊線路區B2與第一 周邊線路區B1未重疊。在本實施例中,第一周邊線路區 B1及第二周邊線路區B2分別位於顯示區AA相對的兩側 邊1在其他實施例中,第一周邊線路區B1及第二周邊線 路區B2也可以分別位於顯示區AA相鄰的兩侧邊或者是 位於顯不區AA相鄰的同一側邊,而使得第一周邊線路區 B1相鄰於第二周邊線路區B2。 觸控式顯示面板200包括一對向基板21〇、一陣列基 板220、一控制電路240、一驅動電路250以及一顯示介質 201005364 26571twf.doc/n 層260。顯示介質層260之材料包含液晶、有機發光材料、 或上述之組合。對向基板210 _配置有觸控元件(未繪 不),且控制電路240配置於陣列基板22〇上。當使用者 觸碰對向基板210時,對向基板21〇中的觸控元件(未繪 =)可產生對應的一電容變化。此時,控制電路24〇便可 藉由此電容變化產生對應的訊號來判斷使用者的觸碰位 置。另外,驅動電路250也配置於陣列基板22〇上,其用 _ 來控制顯示介質層260的狀態以進行晝面的顯示。 由圖2B可知,控制電路240及驅動電路250皆配置 於陣列基板220上。因此’在製作觸控式顯示面板2〇〇時, 依序配置控制電路240及驅動電路250的過程中不需將組 立好的觸控式顯示面板2〇〇翻轉。亦即,觸控式顯示面板 2〇〇的製程較為簡單、容易,而有助於提升觸控式顯示面 板200的製程良率。本實施例中,控制電路24〇及驅動電 路250分別位於第一周邊線路區B1與第二周邊線路區 中。當然,本發明並不限定控制電路24〇在陣列基板22〇 上所配置的位置。在其他實施方式中,控制電路240及驅 動電路250也可以同時配置於第一周邊線路區Bi或是第 —周邊線路區B2中。此外,以下將以數個實施範例進_ :^說月本發明所提出的觸控式顯示面板2〇〇,但以下實. 範例並非用以限定本發明。 實包 一圖3繪示為本發明另一實施例之觸控式顯示面板的剖 面示意圖。請參照圖3,觸控式顯示面板300具有一顯示 區AA、—第一周邊線路區B1以及一第二周邊線路區B2。 201005364 AUU/uyu^j 26571twf.doc/n 第一周邊線路區B1及第二周邊線路區B2位於顯示區AA 周邊,且第一周邊線路區B2與第一周邊線路區B1未重疊。 在本實施例中’第一周邊線路區B1及第二周邊線路 區B2分別位於顯示區AA相對的兩侧邊。在其他實施例 中,第一周邊線路區B1及第二周邊線路區B2也可以分別 位於顯示區AA相鄰的兩側邊或者是位於顯示區AA相鄰 的同一侧邊,而使得第一周邊線路區Bi相鄰於第二周邊 φ 線路區B2。此觸控式顯示面板3〇〇包括一對向基板31〇、 一陣列基板320、多個訊號傳輸物33〇(圖3中僅繪示一個 為例)、一控制電路340、一驅動電路350、一顯示介質層 360以及一框膠370。陣列基板32〇具有多個晝素結構 322,畫素結構322陣列排列於顯示區中。 舉例而§,晝素結構322包含一分別電性連接於訊號 線(未繪示)及晝素電極(未繪示)之切換元件(未繪示)。 對向基板310配置於陣列基板32〇上方,且對向基板31〇 具有一觸控感測層310a、一共用電極31〇b、多個導電接墊 # 31〇c (圖3中僅繪示-個為例)、多個彩色濾光圖案蓮 以及一介電層310e。 控制電路340 g己置於陣列基板32〇上,以使得控制電 路340藉由訊號傳輸物33〇電性連接觸控感測層31如,其 中控制電路340與畫素結構322電性絕緣。顯示介質層36〇 配置於對向基板310與陣列基板32〇之間。驅動電路35〇 配置於陣列基板320上,其電性連接至晝素結構奶,此 外,驅動電路350與控制電路34〇電性絕緣。介電層3i〇e 11 26571twf.doc/n 201005364 位於共用電極310b以及觸控感測層310a之間,且介電層 31〇e具有至少一接觸窗312e (圖3中僅繪示一個為例)θ, 但不限於此,亦可不具有接觸窗312e。接觸窗312e位於 第一周邊線路區B1中,而導電接墊3l〇c藉由接觸窗319 電性連接觸控感測層31〇a。 導電接墊310c位於第一周邊線路區B1中,且導電接 墊310c電性連接觸控感測層31〇a,而共用電極3i〇b與導 電接墊310c電性絕緣。訊號傳輸物33〇配置於陣列基板 320及對向基板310之間,且位於第一周邊線路區B1中。 在本實施例中,訊號傳輸物330例如是由一柱狀凸起332 以及覆蓋在柱狀凸起332上的導電件334所構成,且配置 於對向基板310上為例。導電件334與導電接墊31〇c電性 連接’以使觸控感測層310a實際上與訊號傳輸物33〇電性 連接。本實施例的導電件334可與導電接墊31〇c 一起製 作,但在其他實施方式中,導電件334與導電接墊31〇c 也可分別以不同製程步驟製作。 舉例來說,訊號傳輸物330的導電件334以及柱狀凸 起332可以製作在對向基板31〇上、訊號傳輸物33〇的導 電件334以及柱狀凸起332可以製作在陣列基板32〇之控 制電路340上、訊號傳輸物33〇例如是由一柱狀凸起332 配置於陣列基板320上且位於控制電路34〇下、訊號傳輸 物330同時配置於對向基板31〇與陣列基板32〇上、或上 述訊號傳輸物330所提及配置位置之組合。 其他實施範例也可利用任何製程方法將訊號傳輸物 12 201005364 /\υυ/υ^υ.)3 26571twf.doc/n201005364 nKj\j 26571twf.doc/n IX. Description of the Invention: [Technical Field] The present invention relates to a touch display panel, an optoelectronic device, and a method of manufacturing the above various devices, and more particularly to A touch display panel, an optoelectronic device, and a method of manufacturing the above various devices are provided to simplify the module process. [Prior Art] In the general touch display panel design, the design principle of the touch sensing mode can be roughly classified into a capacitive type, a resistive type, a photosensitive type, etc.; Added type and built-in type. The capacitive touch sensing design makes the touch display panel have a high aperture ratio and a good signal-to-noise ratio, and has become the mainstream of the current touch display panel. In addition, the built-in structure design products are lighter and thinner than the externally-structured products. Therefore, combined with the capacitive touch sensing design principle and the built-in structure, the β display specification and display performance of the touch display panel are more ideal. 1 is a cross-sectional view of a conventional touch-sensitive display panel. Referring to FIG. 1 , the touch display panel 100 includes a pair of substrates 110 , an array substrate 120 , a control circuit 14 , a driving circuit 150 , and a display medium layer 160 . The control circuit 14 is disposed on the opposite substrate 110, and a capacitive touch sensing element (not shown) is built in the opposite substrate 110. When the user touches the opposite substrate 110, the capacitance change generated in the touch sensing component (not shown) can be calculated by the control circuit 140 and then generated and generated. 6 201005364 /\υυ / j5 2657 ltwf .doc/n signal. The driving circuit 150 is disposed on the array substrate 12A for controlling the display medium layer 16 in the touch display panel 100 for display. The driving circuit 15A on the array substrate 120 and the control circuit 140 on the opposite substrate 1 are respectively connected to the surfaces of the two substrates 11A, 12A contacting the display medium layer 160. Therefore, in the module process, if the driving circuit 150 is first connected to the array substrate 12, the assembled touch display panel 100 needs to be turned over before the control circuit 140 can be connected to the opposite substrate. Lu 110 on the 'and vice versa. Therefore, the configuration of the driving circuit 150 and the control circuit 140 increases the complexity and difficulty of the module process. Further, disposing different circuits (14〇, 150) on different substrates (110, 120) respectively limits the manufacturing yield of the touch display panel 1〇〇. SUMMARY OF THE INVENTION The present invention provides a touch display panel, which is designed to simplify the process of the touch display panel. The invention further provides a method for manufacturing a touch display panel, which can reduce the complexity and difficulty of the module process of the touch display panel. The present invention further provides an optoelectronic device' having the touch display panel described above. The present invention further provides a method of manufacturing a photovoltaic device having a high process yield. The present invention relates to a touch display panel having a display area and a first peripheral line area located around the display area. The touch display panel comprises an array substrate, an opposite substrate, a plurality of signal transmissions, a control circuit, and a display medium layer. The opposite substrate is disposed above the array substrate, wherein the opposite substrate has a touch sensing layer, a common electrode, and a plurality of conductive interfaces. The conductive pads are located in the first peripheral line region and are electrically connected to the touch sensing layer. In addition, the common electrode is electrically insulated from the conductive pads. The signal transmission is disposed between the array substrate and the opposite substrate and located in the first peripheral line region. The control circuit is disposed on the array substrate such that the control circuit is electrically connected to the touch sensing layer by the signal transmission object. The display medium layer is disposed between the opposite substrate and the array substrate. The invention further provides a method for manufacturing a touch display panel, which is suitable for manufacturing a touch display panel having a display area and a first peripheral line area, wherein the first peripheral line area is located around the display area. The method for manufacturing a touch display panel includes: providing a pair of substrates having a touch sensing layer, a common electrode, and a plurality of conductive pads. The conductive pads are located in the first peripheral line region and are electrically connected to the touch sensing layer, and the common electrode is electrically insulated from the conductive pads. Next, an array substrate is provided. Then, a control circuit is disposed on the array substrate. Thereafter, a plurality of signal transmissions are disposed between the array substrate and the opposite substrate, and the signal transmission is located in the first peripheral line region to cause the control circuit to electrically connect the conductive pads. Furthermore, a display medium layer is disposed between the opposite substrate and the array substrate. The invention further proposes an optoelectronic device' which comprises a touch sensitive display panel as described above. The present invention further provides a method of fabricating an optoelectronic device comprising the method of fabricating a touch display panel as described above. In the touch display panel and the optoelectronic device of the present invention, the control circuit of the touch sensing layer and the driving circuit for driving the pixel structure are all disposed on the array substrate. Therefore, in the process of manufacturing the touch display panel and the photoelectric device of the present invention, the drive circuit and the control circuit can be connected to the corresponding components without flipping the assembled touch display panel. In other words, the design of the touch display panel and the optoelectronic device of the present invention can reduce the complexity and difficulty of the module process of the touch display panel. The above described features and advantages of the present invention will become more apparent from the following description. 2A and 2B are respectively a top view and a cross-sectional view of a touch display panel according to an embodiment of the present invention, wherein Fig. 2B is a cross section according to the cross-sectional line cc' in Fig. 2A. 2A and 2B, the touch display panel 200 has a display area AA, a first peripheral line area B1, and a second side line area B2', wherein the first peripheral line area B1 and the second peripheral line area B2 is located around the display area AA, and the second peripheral line area B2 does not overlap with the first peripheral line area B1. In this embodiment, the first peripheral line area B1 and the second peripheral line area B2 are respectively located on opposite sides 1 of the display area AA. In other embodiments, the first peripheral line area B1 and the second peripheral line area B2 are also The first peripheral line area B1 may be adjacent to the second peripheral line area B2, respectively, on either side adjacent to the display area AA or the same side adjacent to the display area AA. The touch display panel 200 includes a pair of substrates 21, an array substrate 220, a control circuit 240, a driving circuit 250, and a display medium 201005364 26571 twf.doc/n layer 260. The material of the display dielectric layer 260 comprises a liquid crystal, an organic light emitting material, or a combination thereof. The opposite substrate 210_ is provided with a touch element (not shown), and the control circuit 240 is disposed on the array substrate 22A. When the user touches the opposite substrate 210, the corresponding touch capacitance (not drawn =) in the opposite substrate 21 can generate a corresponding capacitance change. At this time, the control circuit 24 can determine the touch position of the user by generating a corresponding signal by the change of the capacitance. Further, the driving circuit 250 is also disposed on the array substrate 22, which controls the state of the display medium layer 260 by _ to perform the display of the face. As can be seen from FIG. 2B, both the control circuit 240 and the driving circuit 250 are disposed on the array substrate 220. Therefore, in the process of fabricating the touch display panel 2, the control touch panel 2 and the drive circuit 250 are not required to be flipped during the process of sequentially arranging the control circuit 240 and the drive circuit 250. That is, the process of the touch display panel 2 is relatively simple and easy, and helps to improve the process yield of the touch display panel 200. In this embodiment, the control circuit 24 and the driving circuit 250 are respectively located in the first peripheral line area B1 and the second peripheral line area. Of course, the present invention does not limit the position at which the control circuit 24 is disposed on the array substrate 22A. In other embodiments, the control circuit 240 and the driving circuit 250 may be simultaneously disposed in the first peripheral line region Bi or the first peripheral circuit region B2. In addition, in the following, the touch display panel 2〇〇 proposed by the present invention will be described in several embodiments, but the following examples are not intended to limit the present invention. FIG. 3 is a cross-sectional view showing a touch display panel according to another embodiment of the present invention. Referring to FIG. 3, the touch display panel 300 has a display area AA, a first peripheral line area B1, and a second peripheral line area B2. 201005364 AUU/uyu^j 26571twf.doc/n The first peripheral line area B1 and the second peripheral line area B2 are located around the display area AA, and the first peripheral line area B2 and the first peripheral line area B1 do not overlap. In the present embodiment, the first peripheral line region B1 and the second peripheral line region B2 are respectively located on opposite sides of the display area AA. In other embodiments, the first peripheral line area B1 and the second peripheral line area B2 may also be located on two sides adjacent to the display area AA or on the same side adjacent to the display area AA, so that the first periphery The line area Bi is adjacent to the second periphery φ line area B2. The touch display panel 3 includes a pair of substrates 31 , an array substrate 320 , a plurality of signal transmissions 33 〇 (only one is shown in FIG. 3 ), a control circuit 340 , and a driving circuit 350 . A dielectric layer 360 and a sealant 370 are displayed. The array substrate 32 has a plurality of pixel structures 322, and the array of pixel structures 322 is arranged in the display area. For example, the tiling structure 322 includes a switching element (not shown) electrically connected to a signal line (not shown) and a halogen electrode (not shown). The opposite substrate 310 is disposed above the array substrate 32, and the opposite substrate 31 has a touch sensing layer 310a, a common electrode 31〇b, and a plurality of conductive pads #31〇c (only shown in FIG. 3) - for example), a plurality of color filter pattern lotuses and a dielectric layer 310e. The control circuit 340g is placed on the array substrate 32A such that the control circuit 340 is electrically connected to the touch sensing layer 31 by means of the signal transmission material 33, wherein the control circuit 340 is electrically insulated from the pixel structure 322. The display medium layer 36 is disposed between the opposite substrate 310 and the array substrate 32A. The driving circuit 35 is disposed on the array substrate 320, and is electrically connected to the halogen structure milk. Further, the driving circuit 350 is electrically insulated from the control circuit 34. The dielectric layer 3i〇e 11 26571 twf.doc/n 201005364 is located between the common electrode 310b and the touch sensing layer 310a, and the dielectric layer 31〇e has at least one contact window 312e (only one is shown in FIG. 3 as an example). θ, but is not limited thereto, and may not have the contact window 312e. The contact window 312e is located in the first peripheral line region B1, and the conductive pads 31a are electrically connected to the touch sensing layer 31A via the contact window 319. The conductive pad 310c is located in the first peripheral line region B1, and the conductive pad 310c is electrically connected to the touch sensing layer 31〇a, and the common electrode 3i〇b is electrically insulated from the conductive pad 310c. The signal transmission material 33 is disposed between the array substrate 320 and the opposite substrate 310 and located in the first peripheral line region B1. In the present embodiment, the signal transmission material 330 is composed of, for example, a columnar protrusion 332 and a conductive member 334 covering the columnar protrusion 332, and is disposed on the opposite substrate 310 as an example. The conductive member 334 is electrically connected to the conductive pad 31〇c such that the touch sensing layer 310a is actually electrically connected to the signal transmission member 33. The conductive member 334 of the present embodiment can be fabricated together with the conductive pads 31 〇 c, but in other embodiments, the conductive members 334 and the conductive pads 31 〇 c can also be fabricated in different process steps. For example, the conductive member 334 of the signal transmission material 330 and the columnar protrusion 332 can be formed on the opposite substrate 31, and the conductive member 334 and the columnar protrusion 332 can be fabricated on the array substrate 32. The signal transmission device 33 is disposed on the array substrate 320 by a columnar protrusion 332 and located under the control circuit 34, and the signal transmission object 330 is disposed on the opposite substrate 31 and the array substrate 32 at the same time. A combination of the configuration locations mentioned above or the signal transmissions 330 mentioned above. Other implementation examples can also use any process method to transmit signals 12 201005364 /\υυ/υ^υ.)3 26571twf.doc/n
DL\J Φ ❹ 330或其它類型的訊號傳輸物33〇配置於二基板31〇 之間’以使訊號傳輸物330與導電接墊310c可以電性連 接。值得一提的是,配置於對向基板31〇與陣列基板320 之間的訊號傳輸物330是用以將觸控感測層310a所感測的 訊號傳輸至控制電路340中。因此,訊號傳輸物330也可 以是導電性膠體或是其他的導電材質製成,例如是銀膠、 聚合物體表面上覆有導電材料、可導電之聚合物體、或上 述之混合使用,並不限於上述材質。 進一步說明驅動電路350的驅動方式,請繼續參照圖 3,由於驅動電路350·與陣列基板32〇上之晝素結構幻2 電性連接,因此驅動電路350可傳送掃描訊號及資料訊號 ,畫素結構322,其中傳送掃描訊號及資料訊號的方向如 前頭A1的方向所示。此外,驅動電路35〇亦可將陣列基 板320上的共用電極訊號傳送至對向基板上310的共用電 電Γ號的方式可以是利用框膠370内 導電材料表面上覆有 衣(AuBall)、銀球、銅球算、墓 ====爾㈣#料輪用電極= 他材質傳遞。亦即,傳或可供導電的其 質並不限定;體=覆=號的介 13 201005364 Λυυ 26571twf.doc/n 導電膠或其組合’或其他可以傳送共用電極訊號的介質。 另一方面’控制電路340與觸控感測層的訊號 傳遞關係可由箭頭A2的路徑方向得知。介電層31如具有 接觸窗312e為例,使觸控感測層310a與導電接墊3ι〇β'得 以接觸’但亦可不具有接觸窗312e。所以,當使用者觸碰 到對向基板310上的某一任意位置p時,觸碰的動作使觸 控感測層310a因電容變化產生一感測訊號。 〇 換句話說,觸控感測層31〇a及共用電極31〇b之間具 有-電容效應,所有此觸控結構之總電容效應為上述電^ 效應之總和。因此,當使用者以帶有接地訊號或電位之物 件,例如:使用者手指或其它物件,觸碰觸控結構時,因 觸控感測層310a與使用者之觸碰點之間產生電容效應,進 而導致總電容效應變化,而產生感測訊號。接著,從觸控 感測層310a傳至導電接塾31〇c。由於導電接塾3i〇c與訊 號傳輸物33G之電性接觸’使感測訊號可藉著訊號傳輸物 330之導電件334傳至陣列基板320之控制電路340中。 攀,特別的是’當訊號傳輸物330的形式或配置略作調整 時,箭頭A2的路徑亦可隨之略作調整,但箭頭八2的路徑 =向仍維持從對向基板31〇至陣列基板32〇的方向 。也就 疋說本貝細例之感測訊號的傳遞方向與共用電極訊號的 傳遞方向大致上相反。 〇此外,除了利用上述之訊號傳輪物33〇來傳遞感測訊 號,亦可利用其他的導電物質來傳遞感測訊號。換言之, 訊號傳輸物330並不限於上述形式,訊號傳輸物33〇也可 201005364 26571twf.doc/n 以由一膠體及分布於其中的多數個聚合物體表面上覆有導 電材料,例如·金球(AuBaii)、銀球、銅球等、可導電 之聚合物體、或其他可供導電的材質。此外,較特別的是, 當訊號傳輸物330的形式或配置位置略作調整時,箭頭A2 的路徑亦可隨之略作調整,但箭頭A2的路徑方向仍維持 從對向基板310至陣列基板320的方向。另外,每一個導 電接墊31 〇c可以對應的與一個訊號傳輸物33〇或是多個訊 號傳輸物330電性連接。 ° 觸控式顯示面板3〇〇可以利用多個間隙物(未繪示), 例如球間隙物(Ball Spacer )、光阻間隙物(Ph〇t〇 Spacer )、 或上述之組合,來維持對向基板31〇以及陣列基板32〇之 間隙。其中,配置球間隙物的製程方法例如是將球間隙物 灑佈在對向基板310的顯示區AA中,然後’再將對向基 板310及陣列基板320進行組立。在其它實施例上,可將 球間隙物灑佈在陣列基板320上,抑或將球間隙物同時灑 佈在陣列基板320與對向基板31〇上。 承上述,其他實施例也可用不同形式來維持二基板 310、320之間隙,例如使用光阻間隙物。圖4繪示為本發 月再只知*例之觸控式顯示面板的剖面示意圖。請參照圖 4’觸控式顯示面板400與上述的觸控式顯示面板3〇〇大致 相似,其對向基板310更具有多個光阻間隙物4i〇f。光阻 間隙物410f位於顯示區AA中,用以維持對向基板31〇以 及陣列基板320之間隙。實務上,在對向基板31〇的製程 步驟中’可將光阻間隙物41〇f配置在對向基板31〇上,然 15 201005364 Αυυ/uwoo 26571twf.doc/n ^對向基板310及陣列基板32()進行組立。絲知此技 藝者可製作任何形式、任何材質之間隙物、以上述任何間 ,之組合、或以_物之位置來維持對向基板31〇以及 陣列基板320之間的間隙。 ❹ 在其它實施例上,可將光阻間隙物41〇f配置在陣列基 板320上,抑或將光阻間隙物撕同時配置在陣列基板 32〇與對向基板谓上。在另一其它實施例中,若間隔物 以光阻間隙物410f為例且訊號傳輸物33〇以柱狀凸起332 為例時,則光阻間隙物410f與柱狀凸起332較佳地可同時 形成’但亦可不同時形成。 實際上,觸控感測層31〇a整合於對向基板310上的 設計可以有多種不同的方式,以下將舉數個範例以進一步 說明觸控感測層310a (繪示於圖3、圖4)之結構設計。 圖5繪示為一種觸控感測層整合於對向基板的局部放大剖 面圖。請參照圖5’對向基板310具有一觸控感測層310a、 一共用電極310b、多個彩色濾光圖案310d以及一介電層 310e。觸控感測層310a包括多個黑矩陣圖案511及至少一 觸控感測電極513。當然’對向基板310還具有多個與觸 控感測層31〇a電性連接的導電接墊(未繪示),以將觸控 感測層31〇a測得的訊號傳輸至控制電路當中。 實際上,對向基板310例如是上述觸控式顯示面板300 或400的構件。黑矩陣圖案511與觸控感測電極513例如 是電性連接至導電接墊(未繪示),且各個黑矩陣圖案511 具有多個位於顯示區AA中的開口 511h。值得一提的是, 16 201005364 auu/u^ujJ 26571twf.doc/n 彩色濾光圖案310d配置於開口 511h中,以使觸控式顯示 面板300或400達到多彩化顯示的效果。彩色濾光圖案 310d與共用電極310b位於顯示區(未繪示)中,而共用 電極310b位於彩色濾光圖案310d以及顯示介質層(未繪 示)之間。另外,觸控感測電極513配置於彩色濾光圖案 310d上,並電性連接導電接墊(未繪示)。 承上述’請同時參照圖3 (或圖4)及圖5,黑矩陣圖 案5Π及觸控感測電極513為兩層導電材料層,而彩色滤 光圖案310d為分布在黑矩陣圖案511及觸控感測電極513 之間的介電材料。當觸控式顯示面板300(或400)被驅動, 且使用者之觸碰便使得觸控感測層310a因觸控感測電極 513與使用者之觸碰點(例如位置p)之間產生電容效應, 並因電容變化而產生感測訊號。換句話說,黑矩陣圖案511 及觸控感測電極513之間、觸控感測電極513及共用電極 31〇b之間、黑矩陣圖案511及共用電極3l〇b之間皆具有 一電容效應,所有此觸控結構之總電容效應為上述電容效 ❷ 應之總和。因此’當使用者以帶有接地訊號或電位之物件, 例如·使用者手指或其它物件,觸碰觸控結構時,因觸控 感測電極513與使用者之觸碰點之間產生電容效應,進而 導致總電容效應變化,而產生感測訊號。之後,藉著訊號 傳輸物330之導電件334使感測訊號傳遞至陣列基板320 之控制電路340 ’以使控制電路340感測觸控點的位置。 另一方面’觸控感測層310a (繪示於圖3、圖4)也 可用不同的結構來達成感測觸控的功能。圖6繪示為另一 17 201005364 Λυυ/υ>υ->-> 2657 ltwf.doc/n 種觸控感測層整合於對向基板的局部放大剖面圖。請參照 圖6’配置於對向基板310上的觸控感測層310a包括多個 黑矩陣圖案611。黑矩陣圖案611例如是電性連接至導電 接墊(未繪示),且各個黑矩陣圖案611具有多個位於顯 示區(未繪示)中的開口 611h,彩色濾光圖案310d則配 置於開口 611h中。 承上述,請同時參照圖3 (或圖4)及圖6,黑矩陣圖 案611具有由一第一導電層615、一絕緣層617以及—第 二導電層619所組成的疊層結構。因此,當觸控式顯示面 板300 (或400)被驅動時,黑矩陣圖案611的第一導電層 615及第二導電層619間可產生電容效應。使用者之觸碰 便使付觸控感測層310a與使用者之觸碰點(例如位置p ) 之間產生電容效應,並因為電容變化而產生感測訊號。換 句話說’黑矩陣圖案611與共用電極31〇b之間具有一總電 容效應。也就是,第一導電層615及第二導電層619之間 與第二導電層619及共用電極31〇b之間皆具有一電容效 應,所有此觸控結構之總電容效應為上述電容效應之總 和。因此,當使用者以帶有接地訊號或電位之物件,例如: 使用者手指或其它物件,觸碰觸控結構時,因觸控感測層 =0a與使用者之觸碰點之間產生電容效應,進而導致總電 容效應變化,而產生感測訊號。此外,感測訊號藉著訊號 傳輸物330之導電件334傳遞至陣列基板32〇之控制電路 340 ’使控制電路340感測觸控點的位置。 本發明以上述二種觸控感測層31〇a設計結構為實施 201005364 26571 twf.doc/n 例揭露如上,但本發明並非限制於此。本發明所屬觸控感 測層310a亦可適用其他合適的設計。 圖7繪示為本發明-實施例之觸控式顯示面板的製造 綠餘圖。崎造綠適於製造具有—絲區以及一第 -周邊線路區的-觸控式顯示面板。舉例來說,本實施例 所提出的製造方法可用於製作上述之觸控式顯示面板 200、300或400。請參照圖7,在步驟7〇1中,提供一對 φ 向基板,而此對向基板具有一觸控感測層、一共用電極以 及多個導電接墊。其中,導電接墊位於第一周邊線路區中, 且其電性連接觸控感測層,而共用電極與導電接墊電性絕 緣。 , 接著,在步驟中,提供一陣列基板,其中陣列基 板上形成多個位於顯示區中晝素結構以及一驅動電路,且 晝素結構與驅動電路電性連接。舉例而言,晝素結構包含 刀別電性連接於訊號線(未繪示)及晝素電極(未纟會示) 之切換元件(未繪示)。 ❹ 然後’在步驟705中,配置一控制電路於陣列基板上, 其中控制電路與畫素結構電性絕緣。值得一提的是,在步 驟703及705中,無需翻轉觸控式顯示面板即可分別將驅 動電路及控制電路配置於陣列基板上。因此,本實施例之 觸控式面板的製造方法可降低模組製程之複雜度。組立好 的觸控式顯示面板也不易因為翻轉的動作而受到損壞。 之後,在步驟707中,配置多個訊號傳輸物於對向基 板及陣列基板之間,且訊號傳輸物位於第一周邊線路區DL\J Φ ❹ 330 or other type of signal transmission material 33〇 is disposed between the two substrates 31〇” so that the signal transmission material 330 and the conductive pads 310c can be electrically connected. It is to be noted that the signal transmission 330 disposed between the opposite substrate 31 and the array substrate 320 is used to transmit the signal sensed by the touch sensing layer 310a to the control circuit 340. Therefore, the signal transmission material 330 may also be made of a conductive colloid or other conductive material, such as silver paste, a conductive material coated on the surface of the polymer body, a conductive polymer body, or a mixture thereof, and is not limited thereto. The above materials. Further, the driving method of the driving circuit 350 is further described. Referring to FIG. 3, since the driving circuit 350· is electrically connected to the pixel structure on the array substrate 32, the driving circuit 350 can transmit the scanning signal and the data signal, and the pixel Structure 322, wherein the direction in which the scan signal and the data signal are transmitted is as indicated by the direction of the head A1. In addition, the driving circuit 35 can also transmit the common electrode signal on the array substrate 320 to the common electric signal of the opposite substrate 310. The surface of the conductive material in the sealant 370 can be covered with clothing (AuBall) and silver. Ball, copper ball calculation, tomb ==== er (four) # electrode wheel electrode = his material transmission. That is, the quality of the conductive or conductive material is not limited; the body = the cover of the number 13 201005364 Λυυ 26571 twf. doc / n conductive adhesive or a combination thereof or other medium that can transmit the common electrode signal. On the other hand, the signal transmission relationship between the control circuit 340 and the touch sensing layer can be known from the path direction of the arrow A2. For example, the dielectric layer 31 has a contact window 312e, such that the touch sensing layer 310a and the conductive pad 3 〇β' are in contact with each other but may not have the contact window 312e. Therefore, when the user touches an arbitrary position p on the opposite substrate 310, the touch action causes the touch sensing layer 310a to generate a sensing signal due to the capacitance change. 〇 In other words, the touch sensing layer 31〇a and the common electrode 31〇b have a-capacitance effect, and the total capacitance effect of all the touch structures is the sum of the above-mentioned electrical effects. Therefore, when the user touches the touch structure with an object with a ground signal or potential, such as a user's finger or other object, a capacitive effect occurs between the touch sensing layer 310a and the user's touch point. , which in turn causes a change in the total capacitance effect to produce a sensing signal. Then, it is transmitted from the touch sensing layer 310a to the conductive pads 31〇c. The sensing signal can be transmitted to the control circuit 340 of the array substrate 320 via the conductive member 334 of the signal transmission 330 due to the electrical contact between the conductive interface 3i〇c and the signal transmission member 33G. Climbing, in particular, 'when the form or configuration of the signal transmission 330 is slightly adjusted, the path of the arrow A2 can also be slightly adjusted, but the path of the arrow VIII is still maintained from the opposite substrate 31 to the array. The direction of the substrate 32〇. In other words, the direction of transmission of the sensing signal of this example is substantially opposite to the direction of transmission of the common electrode signal. In addition, in addition to using the above-mentioned signal wheel 33 传递 to transmit the sensing signal, other conductive materials can be used to transmit the sensing signal. In other words, the signal transmission material 330 is not limited to the above form, and the signal transmission material 33 can also be coated with a conductive material such as a golden ball by a colloid and a plurality of polymer bodies distributed therein. AuBaii), silver spheres, copper spheres, etc., electrically conductive polymer bodies, or other materials that are electrically conductive. In addition, more specifically, when the form or arrangement position of the signal transmission 330 is slightly adjusted, the path of the arrow A2 may be slightly adjusted, but the path direction of the arrow A2 is maintained from the opposite substrate 310 to the array substrate. The direction of 320. In addition, each of the conductive pads 31 〇c can be electrically connected to a signal transmission material 33 〇 or a plurality of signal transmission materials 330 . ° The touch display panel 3〇〇 can maintain a pair by using a plurality of spacers (not shown), such as a ball spacer (Ball Spacer), a photoresist spacer (Ph〇t〇Spacer), or a combination thereof. A gap is formed between the substrate 31A and the array substrate 32. Here, the method of arranging the ball spacers is, for example, sprinkling the ball spacers in the display area AA of the opposite substrate 310, and then arranging the opposite substrate 310 and the array substrate 320. In other embodiments, the ball spacers may be sprinkled on the array substrate 320, or the ball spacers may be simultaneously sprinkled on the array substrate 320 and the opposite substrate 31. In view of the above, other embodiments may also use different forms to maintain the gap between the two substrates 310, 320, such as using a photoresist spacer. FIG. 4 is a cross-sectional view showing the touch display panel of the present invention. Referring to FIG. 4, the touch display panel 400 is substantially similar to the above-described touch display panel 3A, and the opposite substrate 310 further has a plurality of photoresist spacers 4i〇f. The photoresist spacer 410f is located in the display area AA for maintaining the gap between the opposite substrate 31 and the array substrate 320. In practice, in the process of the opposite substrate 31, the photoresist spacers 41〇f can be disposed on the opposite substrate 31, and then 15 201005364 Αυυ/uwoo 26571 twf.doc/n ^ the opposite substrate 310 and the array The substrate 32() is assembled. It is known that the skilled artisan can fabricate gaps of any form, any material, with any of the above, combinations thereof, or with the position of the object to maintain the gap between the opposing substrate 31A and the array substrate 320.其它 In other embodiments, the photoresist spacers 41〇f may be disposed on the array substrate 320, or the photoresist spacers may be torn off and disposed on the array substrate 32〇 and the opposite substrate. In another embodiment, if the spacer is exemplified by the photoresist spacer 410f and the signal transmission object 33 is exemplified by the columnar protrusion 332, the photoresist spacer 410f and the columnar protrusion 332 are preferably Can be formed simultaneously 'but can also be formed at different times. In fact, there are many different ways for the touch sensing layer 31A to be integrated on the opposite substrate 310. Several examples will be used to further illustrate the touch sensing layer 310a (shown in FIG. 3 and FIG. 4) The structural design. FIG. 5 is a partially enlarged cross-sectional view showing a touch sensing layer integrated on a counter substrate. Referring to FIG. 5', the opposite substrate 310 has a touch sensing layer 310a, a common electrode 310b, a plurality of color filter patterns 310d, and a dielectric layer 310e. The touch sensing layer 310a includes a plurality of black matrix patterns 511 and at least one touch sensing electrode 513. Of course, the opposite substrate 310 further has a plurality of conductive pads (not shown) electrically connected to the touch sensing layer 31A to transmit the signals measured by the touch sensing layer 31A to the control circuit. among. Actually, the opposite substrate 310 is, for example, a member of the above-described touch display panel 300 or 400. The black matrix pattern 511 and the touch sensing electrode 513 are electrically connected to a conductive pad (not shown), for example, and each of the black matrix patterns 511 has a plurality of openings 511h in the display area AA. It is worth mentioning that 16 201005364 auu/u^ujJ 26571twf.doc/n The color filter pattern 310d is disposed in the opening 511h to achieve the effect of the colorful display of the touch display panel 300 or 400. The color filter pattern 310d and the common electrode 310b are located in a display area (not shown), and the common electrode 310b is located between the color filter pattern 310d and the display medium layer (not shown). In addition, the touch sensing electrode 513 is disposed on the color filter pattern 310d and electrically connected to the conductive pads (not shown). According to FIG. 3 (or FIG. 4) and FIG. 5, the black matrix pattern 5 and the touch sensing electrode 513 are two layers of conductive material, and the color filter pattern 310d is distributed in the black matrix pattern 511 and The dielectric material between the sensing electrodes 513 is controlled. When the touch display panel 300 (or 400) is driven, the touch of the user causes the touch sensing layer 310a to be generated between the touch sensing electrodes 513 and the touch point of the user (for example, the position p). Capacitance effect, and the sensing signal is generated due to the change of capacitance. In other words, there is a capacitive effect between the black matrix pattern 511 and the touch sensing electrode 513, between the touch sensing electrode 513 and the common electrode 31〇b, between the black matrix pattern 511 and the common electrode 31b The total capacitance effect of all the touch structures is the sum of the above capacitance effects. Therefore, when the user touches the touch structure with an object with a ground signal or potential, such as a user's finger or other object, a capacitive effect occurs between the touch sensing electrode 513 and the user's touch point. , which in turn causes a change in the total capacitance effect to produce a sensing signal. Thereafter, the sense signal is transmitted to the control circuit 340' of the array substrate 320 by the conductive member 334 of the signal transfer 330 to cause the control circuit 340 to sense the position of the touch point. On the other hand, the touch sensing layer 310a (shown in FIG. 3 and FIG. 4) can also realize the function of sensing touch with different structures. 6 is a partially enlarged cross-sectional view showing another 17 201005364 Λυυ/υ>υ->-> 2657 ltwf.doc/n touch sensing layer integrated on the opposite substrate. Referring to FIG. 6', the touch sensing layer 310a disposed on the opposite substrate 310 includes a plurality of black matrix patterns 611. The black matrix pattern 611 is electrically connected to the conductive pads (not shown), and each of the black matrix patterns 611 has a plurality of openings 611h in the display area (not shown), and the color filter patterns 310d are disposed in the openings. 611h. In the above, referring to FIG. 3 (or FIG. 4) and FIG. 6, the black matrix pattern 611 has a laminated structure composed of a first conductive layer 615, an insulating layer 617, and a second conductive layer 619. Therefore, when the touch display panel 300 (or 400) is driven, a capacitive effect can be generated between the first conductive layer 615 and the second conductive layer 619 of the black matrix pattern 611. The user's touch causes a capacitive effect between the touch sensing layer 310a and the user's touch point (e.g., position p), and a sensing signal is generated due to the capacitance change. In other words, there is a total capacitance effect between the black matrix pattern 611 and the common electrode 31〇b. That is, there is a capacitive effect between the first conductive layer 615 and the second conductive layer 619 and between the second conductive layer 619 and the common electrode 31〇b, and the total capacitance effect of all the touch structures is the above-mentioned capacitive effect. sum. Therefore, when the user touches the touch structure with an object with a ground signal or potential, such as a user's finger or other object, a capacitance is generated between the touch sensing layer=0a and the user's touch point. The effect, which in turn causes a change in the total capacitance effect, produces a sensing signal. In addition, the sensing signal is transmitted to the control circuit 340' of the array substrate 32 via the conductive member 334 of the signal transmission 330 to cause the control circuit 340 to sense the position of the touch point. The present invention is based on the above two types of touch sensing layer 31〇a design structure. The above is disclosed in the above. However, the present invention is not limited thereto. The touch sensing layer 310a to which the present invention pertains can also be applied to other suitable designs. FIG. 7 is a diagram showing the manufacturing of the touch display panel according to the embodiment of the present invention. Sakizawa Green is suitable for manufacturing a touch-sensitive display panel having a silk region and a first-peripheral line region. For example, the manufacturing method proposed in this embodiment can be used to fabricate the touch display panel 200, 300 or 400 described above. Referring to FIG. 7, in step 7〇1, a pair of φ-direction substrates are provided, and the opposite substrate has a touch sensing layer, a common electrode, and a plurality of conductive pads. The conductive pad is located in the first peripheral line region, and is electrically connected to the touch sensing layer, and the common electrode and the conductive pad are electrically insulated. Then, in the step, an array substrate is provided, wherein a plurality of pixel structures in the display area and a driving circuit are formed on the array substrate, and the halogen structure is electrically connected to the driving circuit. For example, the halogen structure includes a switching element (not shown) electrically connected to the signal line (not shown) and the halogen electrode (not shown). ❹ Then, in step 705, a control circuit is disposed on the array substrate, wherein the control circuit is electrically insulated from the pixel structure. It is worth mentioning that in steps 703 and 705, the driving circuit and the control circuit can be respectively disposed on the array substrate without flipping the touch display panel. Therefore, the manufacturing method of the touch panel of the embodiment can reduce the complexity of the module process. A well-established touch display panel is also not easily damaged by the flipping action. Then, in step 707, a plurality of signal transmission objects are disposed between the opposite substrate and the array substrate, and the signal transmission object is located in the first peripheral circuit region.
201005364 〜v'v/Mj 26571twf.doc/n :,以使得控制電路電性連接於導電接塾。例如: 傳輸物包括柱狀凸起與導電件,即如圖3與圖:冷: 的結構時,可以在製作柱狀凸起的同時形成多個挺狀= 物於陣列基板及對向基板之間。當然,柱狀凸起盘多杜 狀間隙物也可以採用不同的步驟製作。此外,訊^傳輪^ 亦可採用如本發明上述實施例所述之類別。 再者,在步驟7G9中’夾設顯示介質層於對向基板以 及陣列基板之間’餅㈣的是,顯示介質層之材料包含 液晶、有機發光材料、或上述之組合,此外,顯示介質層 的材料為非自發光材,例如:液晶、電泳材時,形成顯二 川質層的方法例如是真空注入法或滴下式注入法,但不限 於上述方法。至於本製造方法之其餘細節已包含在上述實 施例中,故在此不加贅述。必需說明的是’步驟7〇5亦^ 在步驟707完成後施行或是步驟709後施行。 再者,本發明上述實施例圖3及圖4所述之框膠37〇 以位於訊號傳輸物330之外侧為例,但不限於此。在其它 實施例中,框膠370可位於訊號傳輸物33〇之内側、框膠 370可位於訊號傳輸物330所存在的位置上、或上述之^ 合0 圖8緣示為本發明一實施例之一種光電裂置的示意 圖。請參照圖8,光電裝置800包括一觸控式顯示面板8〇2 以及與此面板電性連接的一電子元件804。實質上,觸控 式顯示面板802可以是上述各種實施例所述之觸控式顯示 面板200、300、400令任何一種。在此,電子元件804包 20 201005364 26571twf.doc/n 括如:控制元件、操作元件、處理元件、輸入元件、記憶 元件、驅動元件、發光元件、保護元件、感測元件、偵測 元件、或其它功能元件、或前述之組合。而光電裝置8〇〇 之類型包括可攜式產品(如手機、攝影機、照相機、筆記 型電腦、遊戲機、手錶、音樂播放器、電子信件收發器、 地圖導航器、數位相片、或類似之產品)、影音產品(如 影音放映器或類似之產品)、螢幕、電視、看板、投影機 内之面板等。 一般而言,觸控式顯示面板802之成品至少包含一畫 素陣列基板、一對向基板及一顯示介質(display media) 的材料設置於晝素陣列基板與對向基板之間。當顯示介質 之材料為液晶材料時’觸控式顯示面板8〇2可以稱為液晶 顯示面板(如:穿透型顯示面板、半穿透型顯示面板、反 射型顯示面板、彩色渡光片於主動層上(c〇l〇r创如〇n array)之顯示面板、主動層於彩色濾光片上(array on color filter)之顯示面板、垂直配向型(VA)顯示面板、水平 切換型(IPS)顯示面板、多域垂直配向型(MVA)顯 示面板、扭曲向列型(TN)顯示面板、超扭曲向列型( STN) 顯示面板、圖案垂直配向型(PVA)顯示面板、超級圖案 垂直配向型(S-PVA)顯示面板、先進大視角型(ASV) 顯示面板、邊緣電場切換型(FFS)顯示面板、連續焰火 狀排列型(CPA)顯示面板、軸對稱排列微胞型(ASM) 顯示面板、光學補償彎曲排列型(〇CB)顯示面板、超 級水平切換型(S-IPS)顯示面板、先進超級水平切換型 21 26571twf.d〇c/n 201005364 (AS-IPS)顯示面板、極端邊緣電場切換型(UFFS)顯 示面板、高分子穩定配向型顯示面板、雙視角型 (dual-view )顯示面板、三視角型(tripie_view )顯示 面板、二維顯不面板(three-dimensional)、雙面顯示器、 二面顯示器、或其它型面板、或上述之組合)。另外,當 顯不介質之材料為有機電激發光材料時,則觸控式顯示面 板802也可稱為有機電激發光顯示面板(如:螢光有機電 激發光顯示面板、磷光有機電激發光顯示面板、或上述之 組合),或上述之組合。其中,有機電激發光顯示面板之 有機電激發光材料包含小分子發光材料、高分子發光材 料、或上述之組合。 綜上所述,本發明之觸控式顯示面板之控制電路及驅 動電路皆配置於_基板上。因此,以模組製程來看,若 先將驅動電路配置在陣列基板後,無需翻轉組立好的觸控 式顯示面板,便可再將控制電路配置在陣列基板上。相對 先將控制電路配置在陣列基板後,欲將驅動電路配置 ^車歹]基板時’亦無需將觸控式顯示面板進行翻面的動 \所以,本發明之觸控式顯示面板的設計可簡化模組製 程相技術,本發财助於降_控絲示面板 製程的複雜度及困難度,進而提高模組製程的良 此’本㈣之觸控式顯示面板及其光電裝置可減少 製程中不必要的損失以及節省成本。 本發明已哺佳實酬揭露如上,然其並非用以 疋本發明’任何所屬技術領域中具有通常知識者’在不 22 201005364 auu/uvudd 26571twf.doc/n 脫離本發明之精神和範圍内,當可作些許之更動與潤飾, 本發明之保護範圍當視後附之申請專利範圍所界定者 【圖式簡單說明】 圖1為習知觸控式顯示面板之剖面圖。 圖2A繪示為本發明一實施例之觸控式顯示 赢 視圖。 町上 圖2B繪示為本發明一實施例之觸控式顯示面板的剖 面圖。 一圖3繪示為本發明另一實施例之觸控式顯示面板的剖 面示意圖。 σ 圖4繪示為本發明再一實施例之觸控式顯示面板的剖 面示意圖。 圖5繪示為一種觸控感測層整合於對向基板的局部放 大剖面圖。 謇 圖6繪示為另一種觸控感測層整合於對向基板的局部 放大剖面圖。 圖7繪示為本發明一實施例之觸控式顯示面板的製造 方法流程圖。 圖8繪示為本發明一實施例之一種光電裝置的示意 圖。 【主要元件符號說明】 23 201005364 Αυυ/υνυ^5 26571twf.doc/n 100 :習知觸控式顯示面板 110 :習知對向基板 120 :習知陣列基板 140 :習知控制電路 150 :習知驅動電路 160 ··習知顯示介質層 200、300、400 :觸控式顯示面板 210、310 :對向基板 ® 220、320 :陣列基板 240、340 :控制電路 250、350 :驅動電路 260、360 :顯示介質層 330 :訊號傳輸物 322 :晝素結構 310a :觸控感測層 310b :共用電極 _ 310c:導電接墊 310d :彩色濾光圖案 310e :介電層 312e :接觸窗 332 :柱狀凸起 334 :導電件 370 :框膠 410f:光阻間隙物 24 201005364 26571twf.doc/n 511、611 :黑矩陣圖案 513 :觸控感測電極 511h、611h :開口 615 :第一導電層 617 :絕緣層 619 :第二導電層 7(H、703、705、707、709 :步驟 800 :光電裝置 802 :觸控式顯示面板 804 :電子元件 A A :顯示區 A卜A2 :箭頭 B1 :第一周邊線路區 B2 :第二周邊線路區 CC’ :橫截面線 P :位置 25201005364 ~v'v/Mj 26571twf.doc/n : so that the control circuit is electrically connected to the conductive interface. For example: the transport object includes a columnar protrusion and a conductive member, that is, as shown in FIG. 3 and FIG.: cold: a plurality of stiff shapes can be formed at the same time as the columnar bumps are formed on the array substrate and the opposite substrate. between. Of course, the multi-duplex spacers of the columnar lobes can also be fabricated in different steps. In addition, the transmission wheel can also adopt the category as described in the above embodiment of the present invention. Furthermore, in step 7G9, 'the display medium layer is interposed between the opposite substrate and the array substrate', the material of the display medium layer comprises liquid crystal, organic light-emitting material, or a combination thereof, and further, the display medium layer When the material is a non-self-luminous material, for example, a liquid crystal or an electrophoretic material, a method of forming a smectic layer is, for example, a vacuum injection method or a dropping method, but is not limited to the above method. The remaining details of the manufacturing method are included in the above embodiment, and therefore will not be described herein. It must be noted that the step 7〇5 is also performed after the completion of step 707 or after step 709. Furthermore, the frame glue 37〇 described in FIG. 3 and FIG. 4 of the above embodiment of the present invention is exemplified on the outer side of the signal transmission object 330, but is not limited thereto. In other embodiments, the sealant 370 may be located inside the signal transmission member 33〇, the sealant 370 may be located at a position where the signal transmission object 330 exists, or the above-mentioned combination. FIG. 8 is an embodiment of the present invention. A schematic diagram of a photoelectric crack. Referring to FIG. 8 , the optoelectronic device 800 includes a touch display panel 8 〇 2 and an electronic component 804 electrically connected to the panel. In essence, the touch display panel 802 can be any of the touch display panels 200, 300, and 400 described in the above various embodiments. Here, the electronic component 804 package 20 201005364 26571 twf.doc/n includes: a control element, an operation element, a processing element, an input element, a memory element, a driving element, a light-emitting element, a protection element, a sensing element, a detecting element, or Other functional elements, or a combination of the foregoing. The types of optoelectronic devices include portable products (such as mobile phones, cameras, cameras, notebook computers, game consoles, watches, music players, e-mail transceivers, map navigators, digital photos, or the like). ), audio and video products (such as video projectors or similar products), screens, TVs, billboards, panels in projectors, etc. Generally, the finished product of the touch display panel 802 includes at least one pixel array substrate, a pair of substrates, and a display media material disposed between the pixel array substrate and the opposite substrate. When the material of the display medium is a liquid crystal material, the touch display panel 8〇2 may be referred to as a liquid crystal display panel (eg, a transmissive display panel, a transflective display panel, a reflective display panel, a color light-emitting sheet). Display panel on the active layer (c〇l〇r 〇n array), display panel on the active layer on the color filter (array on color filter), vertical alignment type (VA) display panel, horizontal switching type ( IPS) display panel, multi-domain vertical alignment (MVA) display panel, twisted nematic (TN) display panel, super twisted nematic (STN) display panel, pattern vertical alignment type (PVA) display panel, super pattern vertical Alignment type (S-PVA) display panel, advanced large viewing angle (ASV) display panel, edge electric field switching type (FFS) display panel, continuous flame-like arrangement (CPA) display panel, axisymmetric array microcell type (ASM) Display panel, optical compensation curved alignment type (〇CB) display panel, super horizontal switching type (S-IPS) display panel, advanced super level switching type 21 26571twf.d〇c/n 201005364 (AS-IPS) display panel, extreme Edge electricity Field switching type (UFFS) display panel, polymer stable alignment display panel, dual-view display panel, tripie_view display panel, two-dimensional display, three-sided Display, two-sided display, or other type of panel, or a combination of the above). In addition, when the material of the display medium is an organic electroluminescent material, the touch display panel 802 may also be referred to as an organic electroluminescent display panel (eg, a fluorescent organic electroluminescent display panel, a phosphorescent organic electroluminescent panel). A display panel, or a combination thereof, or a combination thereof. The organic electroluminescent material of the organic electroluminescent display panel comprises a small molecule luminescent material, a high molecular luminescent material, or a combination thereof. In summary, the control circuit and the driving circuit of the touch display panel of the present invention are all disposed on the substrate. Therefore, in the module process, if the driving circuit is disposed on the array substrate, the control circuit can be disposed on the array substrate without flipping the assembled touch display panel. After the control circuit is disposed on the array substrate, the touch display panel is not required to be turned over when the driver circuit is configured to be mounted on the substrate. Therefore, the touch display panel of the present invention can be designed. Simplify the process of the process of the module, the cost of the _ control wire panel process is complicated and difficult, and thus improve the module process. The touch display panel and its optoelectronic device of the present (4) can reduce the process. Unnecessary losses and cost savings. The present invention has been disclosed as above, but it is not intended to be used in the spirit and scope of the present invention as described in the ''''''''''' The scope of protection of the present invention is defined by the scope of the appended claims. [FIG. 1 is a cross-sectional view of a conventional touch display panel. 2A is a view of a touch display win view according to an embodiment of the invention. Figure 2B is a cross-sectional view showing a touch display panel according to an embodiment of the present invention. FIG. 3 is a cross-sectional view showing a touch display panel according to another embodiment of the present invention. FIG. 4 is a cross-sectional view showing a touch display panel according to still another embodiment of the present invention. FIG. 5 is a partial enlarged cross-sectional view showing a touch sensing layer integrated on a counter substrate. FIG. 6 is a partially enlarged cross-sectional view showing another touch sensing layer integrated on the opposite substrate. FIG. 7 is a flow chart showing a method of manufacturing a touch display panel according to an embodiment of the invention. FIG. 8 is a schematic view of an optoelectronic device according to an embodiment of the invention. [Description of main component symbols] 23 201005364 Αυυ/υνυ^5 26571twf.doc/n 100 : conventional touch display panel 110 : conventional counter substrate 120 : conventional array substrate 140 : conventional control circuit 150 : conventional Driving circuit 160 · · Known display medium layer 200, 300, 400: touch-sensitive display panel 210, 310: opposite substrate ® 220, 320: array substrate 240, 340: control circuit 250, 350: drive circuit 260, 360 Display medium layer 330: signal transmission material 322: halogen structure 310a: touch sensing layer 310b: common electrode_310c: conductive pad 310d: color filter pattern 310e: dielectric layer 312e: contact window 332: columnar The protrusion 334: the conductive member 370: the sealant 410f: the photoresist spacer 24 201005364 26571twf.doc/n 511, 611: the black matrix pattern 513: the touch sensing electrodes 511h, 611h: the opening 615: the first conductive layer 617: Insulation layer 619: second conductive layer 7 (H, 703, 705, 707, 709: step 800: optoelectronic device 802: touch display panel 804: electronic component AA: display area A A2: arrow B1: first periphery Line area B2: second peripheral line area CC': cross section line P: position 25