200921471 九、發明說明: 【發明所屬之技術領域】 本發明係關於一 態視覺化 種以觸碰遮蔽面積及形狀決定動 内容其縮放比率或縮放區域之觸控式使用者介面I統,特別是 指-種新㈣人機介面互動設計,透過觸控感應技術,經演算 法計算觸碰位置、遮蔽面積、形狀及視覺化内容,㈣定視覺 化内容縮放比率,並在特定狀況下回復原始視覺化内容縮放比 率〇 【先前技術】200921471 IX. Description of the Invention: [Technical Field] The present invention relates to a touch-type user interface for determining a zoom ratio or a zoom area of a moving content by touching a masked area and a shape, in particular Refers to the new (4) human-machine interface interaction design, through touch sensing technology, through the algorithm to calculate the touch position, shielding area, shape and visual content, (4) to set the visual content scaling ratio, and return to the original vision under certain conditions Content scaling ratio 〇 [prior art]
Ο 控式介面常見㈣人數位助理、手機、數位相機 ' 一、| M 呆 自動化系統、互動式展mPGS系統及提款機等,而最 近上市之⑽㈣咖更是掀起—股觸控式介面的風潮。觸控 式介面可透過尖銳物體(如:筌 聿)或是手指直接控制,操作上 相當直覺,·其巾,又以手指直接 伐铞作敢為方便。但手指操作的 主要問題就是手指會遮蔽到書 — 上,.肩不的内各,以及不易定位 7特定視覺化元件㈣題。為解決這樣的問題,在設計手指操 作的視覺化介面時,往往需將視覺化元件設計得較大,使手指 迫蔽面積不至於大於該亓杜 距離崎 積,且使視覺化元件間有足狗的 離’讓手指不會誤觸到其他 仁故樣的方法限制了視謦 设計所能夠使用的面積,且 .?^ . 、動態產生的内容可能無法產 的視覺化元件供使用者點用 ΛΛ _ i 巾冉加上目前裝置小型化 的趨勢,螢幕大小也相當受限, 田又限此—方法會帶料多限制。 200921471 解決此問題的先前技術有:(A) Offset Cursor,⑻ 3匕出,及(〇美國專利仍6,567,1〇2,兹分述如下: η (A) Offset CurSGr⑴:在觸碰點固定距離處呈現一虛擬 指標,使用者透過移動觸碰點,移動該虛擬指標,以達到指向 及定位的目的。0ffset Cursor可用圖—來說明。其中,箭頭游 標代表觸碰點,可以是尖銳物品或手指;觸碰點上方有一十字 點,代表虛擬游標。從畫面中我們可以看到,此設計透過—特 定位移(offset),解決觸碰點可能的遮蔽效果及不易定位的問 題。 (B) Shift [2]:在觸碰點附近,以一小範圍將觸碰點下的 視覺化元件放大,並建立一虛擬游標,讓使用者可以精確選取 特定視覺化元件。Shift可以用圖二來說明。其中,箭頭游標代 表觸碰點,可以是尖銳物品或手指;觸碰點上方有一放大區域, 放大字觸碰點下方之畫面。此一放大區域還有一十字點,代表 ^ 虛擬游標。從畫面中我們可以看到,此設計透過一特定位移的 放大及虛擬游標,解決觸碰點可能的遮蔽效果及不易定位的問 題。 (C) 美國專利US 6, 567, 102 [3]:此專利透過觸控農置所 傳回的壓力值及位置,決定晝面縮放比例及區域。雖然此專利 主要目的是要提出一種新穎的縮放比例及區域的控制方式,但 此方式也可用在解決觸碰點可能的遮蔽效果及不易定位的問題 200921471 上0 針對以上所提諸多限制,本案發明人乃極思加以改良創 新’終於成功研發完成本件—種明碰㈣㈣及形狀決定動 態視覺化内容其㈣比率或㈣區域之财式使用者介面系 【發明内容】 △本發明主要目的在於提供—種以觸碰遮蔽面積及形狀決定 動態視覺化内容其縮放比率或縮放區域之觸控式使用者介面系 統,亦解決使用觸控式介面時,視覺化元件相對於觸碰位置其 面積大小及形狀不適當所可能產生的視覺化元件被遮蔽問題及 不易定位問題。 發月人目的在於提供一種以觸碰遮蔽面積及形狀決定 動恶視覺化内容其縮放比率或縮放區域之觸控式使用者介面系 、 要正s觸控感應器所得之觸碰所遮蔽的面積、形狀及顯 不面板所呈現之視覺化内容’以決定視覺化内容的縮放比率及 縮放區域。 本發明另一目的在於提供一種以觸碰遮蔽面積及形狀決定 心視覺化内谷其縮放比率或縮放區域之觸控式使用者介面系 統’係解決手指直接控制所產生視覺化内容被手指所遮蔽及不 易定位的問題到’亦以特^視覺化内容縮放的方法有效解決此 問題。 200921471 &為達成上述發明目的之一種以觸碰遮蔽面積及形狀決定動 態視覺化内容其縮放比率或縮放區域之觸控式使用者介面系 統,包含: 一觸控感應器,提供感應施於感應器上之觸碰的位置、面 積及形狀; 一顯不面板,提供顯示面板用來呈現視覺化内容; 一控制器’係連接到顯示面板及觸控感應器,·以及 其中’該控制器將觸控感應器所得之觸碰所遮蔽的面積、 形狀及顯示面板所呈現之視覺化内容加以解讀,以決定視覺化 内容的縮放比率及縮放區域;控制器在特定狀況下會自動將視 覺化内容回復到縮放前的狀態’例如當某視覺化元件再被選取 的狀況或另一個視覺化元件在被選取的狀況。 【實施方式】 閱圖一本發明所提供之以觸碰遮蔽面積及形狀決定 動態視覺化内容其縮放比率或縮放區域之觸控式使用者介面系 統’主要包括有:-觸控感應器⑴、一顯示面板⑵以及一控 制器(3)所構成。 該觸控感應ϋ(1),更包括觸控控制器(⑴,亦提供感應施 於觸控感應器⑴上之觸碰位置(22),該觸碰位置⑽亦可為觸 碰面積及觸碰形狀;該觸控感應器⑴依其所採用之技術不同 (如.光學、電阻或電容等),可傳回觸碰位置(U)之直角座標 200921471 、、所觸碰之面積及形狀等 ·#。本發明主要 之直角座標位置 位置、所施之壓力大小、 以觸控感應技術水平需能夠傳回觸碰位置(22) 及觸碰位置(22)之面積及形狀; 該顯示控制器(21) 該顯示面板(2),更包括顯示控制器(21),該 負責呈現視覺化内容(24); 该控制器(3)係連接到顯示面板⑵及觸控感應器⑴,控制 器(3)部份可由軟體、硬體絲體實做;或由微處理器⑷分配 處理觸控控制器(⑴、顯示面板⑵或控制器⑶之視覺化内容 (24)的縮放比率及縮放區域(25),該控制器(3)主要整合觸控感 應器⑴所得之觸碰位置(22)所遮蔽的面積、形狀及顯示面板⑵ 所呈現之視覺化内容(24),以決定視覺化内容(24)的縮放比率 及縮放區域(25),該控制器(3)並判斷觸碰位置(22)是否存在衝 突(該衝突即觸碰位置(22)其面積及形狀無法清楚對應到視覺 化π件(23)),亦解決衝突後,透過顯示面板(2)呈現放大後的 視覺化内容(24)。其中,控制器(3)部份應以軟體設計最為簡 便;以及 其中’該控制器(3)將觸控感應器(1)所得之觸碰位置(22) 所遮蔽的面積、形狀及顯示面板(2)所呈現之視覺化内容(24)加 以解讀’以決定視覺化内容(24)的縮放比率及縮放區域(25); 控制器(3)在特定狀況下會自動將視覺化内容(24)回復到縮放 前的狀態’例如當某視覺化元件(23)再被選取的狀況或另一個 200921471 視覺化元件(23)在被選取的狀況。 為更清楚說明本發明内容,以下就透過圖四與圖五所示之 程式畫面’以說明本發明的使用實施例。 實施例一:當使用者的觸碰位置(22)其面積及形狀,與其 所對應到的視覺化元件(23)沒有衝突時(亦即,清楚對應到一 個視覺化元件⑵)),雜㈣⑶不進行任何縮放,直接點選 該元件;此實施例如圖五所示,半透明之楕圓型代表觸碰位置 (22)形狀。 實施例二:當使用者的觸碰位置(22)其面積及形狀,與其 所對應到的視覺化元件⑽有衝突時(即無法清楚或准確對應 到一個視覺化元件(2 3)(也就是說觸碰位置(2 2)同時對應到一 個以上之視覺化元件(23)),則控制器(3)進行視覺化内容(24) 放大,其放大倍數以解決衝突為原則。 在使用者尚未結束觸碰動作時,若使用者向(x,y)*向移動 觸碰位置(22) ’則畫面向(〜x,_y)平移,且平程過程中仍會偵 測是否有前述之衝突存在,若有,亦以適當之晝面縮放解決衝 突。 此實鈿例如圖六所示,此實施例中,半透明之楕圓型代表 觸碰位置(22)形狀。圖六(a)為放大前,衝突出現時之示意圖; )為放大後’衝突解決;灰色區域為放大後沒有被顯示出來的 邛知之不意圖;(c)為使用者移動觸碰位置(22)往右方,系統將 200921471 畫面向另一側平移之示意圖;(d)為使用者移動觸碰位置(22)往 下方’系統發現沒有衝突,回復原顯示比例之示意圖。 請參閱圖七,係為觸碰遮蔽面積及形狀決定動態視覺化内 奋(24)其縮放比率或縮放區域(25)之觸控式使用者方法其流程 示意圖; 流程10,係使用者開始觸碰其視覺化元件(23),接續執行 流程11 ;Ο Control interface is common (4) number of assistants, mobile phones, digital cameras' I, | M stay automation system, interactive exhibition mPGS system and cash machine, etc., and recently listed (10) (four) coffee is a pick-up - touch interface The tide. The touch interface can be directly controlled by a sharp object (such as 筌 或是) or a finger, which is quite intuitive in operation, and its towel is easy to cut with a finger. However, the main problem with finger operation is that the finger will obscure the book—up, the shoulders, and the 7 visual indicators (4). In order to solve such a problem, when designing the visual interface of the finger operation, it is often necessary to design the visualized component to be large, so that the finger concealing area is not larger than the 亓Du distance and the visual component is sufficient. The dog's method of "not allowing the finger to touch the other fingers is limited to the area that the visual design can use, and the visually generated components that may not be produced by the dynamically generated content are available to the user. With the ΛΛ _ i 冉 冉 plus the current trend of miniaturization of the device, the size of the screen is also quite limited, and the field is limited to this - the method will bring more restrictions. 200921471 The prior art to solve this problem is: (A) Offset Cursor, (8) 3, and (〇 US patent still 6,567,1〇2, as follows: η (A) Offset CurSGr (1): fixed distance at the touch point A virtual indicator is presented, and the user moves the virtual indicator by moving the touch point to achieve the purpose of pointing and positioning. The 0ffset Cursor can be illustrated by a graph, wherein the arrow cursor represents a touch point, which can be a sharp object or a finger. There is a cross point above the touch point, which represents the virtual cursor. From the picture we can see that this design solves the possible shadowing effect of the touch point and the problem of difficulty in positioning through the specific offset (B) Shift [ 2]: In the vicinity of the touch point, the visual component under the touch point is enlarged by a small range, and a virtual cursor is created, so that the user can accurately select a specific visual component. Shift can be illustrated by Figure 2. The arrow cursor represents the touch point, which can be a sharp object or a finger; there is an enlarged area above the touch point, and the picture below the touch point is enlarged. There is also a zoom area. The cross point, which stands for ^ virtual cursor. As you can see from the picture, this design solves the problem of possible shadowing and difficulty of positioning of the touch point through a specific displacement magnification and virtual cursor. (C) US Patent US 6, 567, 102 [3]: This patent determines the scaling and area of the surface through the pressure value and position returned by the touch farm. Although the main purpose of this patent is to propose a novel scaling and area control method. However, this method can also be used to solve the problem of possible shielding effect and difficult positioning of the touch point. 200921471 On the above mentioned many restrictions, the inventor of this case is thinking and improving and innovating 'finally successfully developed this part - kind of touch (4) (4) and The shape determines the dynamic visualized content, and the (four) ratio or (four) regional financial user interface system. [Inventive content] The main purpose of the present invention is to provide a zooming ratio or zooming area for dynamically visualizing content by touching the shielding area and shape. The touch-type user interface system also solves the problem that the visual component is opposite to the touch position when the touch interface is used Visual elements that may be generated due to improper size and shape are obscured and difficult to locate. The purpose of the Moon is to provide a touch that determines the zoom ratio or zoom area of the visually visual content by touching the masked area and shape. The user interface, the area, the shape and the visual content presented by the touch panel obtained by the touch sensor are used to determine the zoom ratio and zoom area of the visualized content. The object of the invention is to provide a touch-sensitive user interface system that determines the zoom ratio or zoom area of the inner visible valley by touching the shielding area and the shape, and the visualized content generated by the direct finger control is blocked by the finger and is difficult to locate. The problem is that 'the problem is also effectively solved by the method of visualizing the content. 200921471 & A touch-sensitive user interface system for determining the zoom ratio or zoom area of a dynamic visual content by touching the masked area and shape for the purpose of the above invention, comprising: a touch sensor providing sensing The position, area and shape of the touch on the device; a display panel for providing visualized content; a controller 'connected to the display panel and the touch sensor, and wherein the controller will The area and shape of the touch sensor and the visual content presented by the display panel are interpreted to determine the zoom ratio and zoom area of the visual content; the controller automatically visualizes the content under certain conditions. Revert to the state before scaling 'for example, when a visual component is selected again or another visual component is in a selected state. [Embodiment] The touch-sensitive user interface system provided by the present invention for determining the zoom ratio or the zoom area of the dynamic visualized content by the touch shielding area and shape mainly includes: - a touch sensor (1), A display panel (2) and a controller (3) are formed. The touch sensor (1) further includes a touch controller ((1), which also provides a touch position (22) on the touch sensor (1), and the touch position (10) can also be a touch area and touch Touch shape; the touch sensor (1) can return the right angle coordinate 200921471 of the touch position (U) according to the different technology (such as optical, resistance or capacitance), the area and shape of the touch, etc. ·#. The position of the main right angle coordinate of the present invention, the magnitude of the applied pressure, and the area and shape of the touch position (22) and the touch position (22) required by the touch sensing technology level; (21) The display panel (2) further includes a display controller (21) for presenting visualized content (24); the controller (3) is connected to the display panel (2) and the touch sensor (1), the controller (3) The part can be made by software or hard body; or the microprocessor (4) can distribute the zoom ratio and zoom area of the touch controller ((1), display panel (2) or controller (3) visual content (24) (25), the controller (3) mainly integrates the touch of the touch sensor (1) The area, shape, and visual content (24) of the display panel (2) are used to determine the zoom ratio of the visualized content (24) and the zoom area (25), and the controller (3) determines Whether there is a conflict in the touch position (22) (the conflict, that is, the touch position (22), the area and shape thereof cannot be clearly corresponded to the visualized π piece (23)), and after the conflict is resolved, the display panel (2) is enlarged. The visual content (24), in which the controller (3) part should be the easiest to design with software; and the 'the controller (3) will touch the touch sensor (1) to the touch position (22) The shaded area, shape, and visual content (24) presented by the display panel (2) are interpreted 'to determine the zoom ratio and zoom area (25) of the visualized content (24); the controller (3) under certain conditions The visualized content (24) is automatically reverted to the state before scaling 'e.g., when a certain visualization component (23) is re-selected or another 200921471 visualization component (23) is selected. The content of the present invention is as follows through FIG. The program screen shown in FIG. 5 is used to explain the use embodiment of the present invention. Embodiment 1: When the touch position (22) of the user has an area and shape that does not conflict with the corresponding visual element (23) ( That is, clearly corresponding to a visual element (2))), miscellaneous (4) (3) without any scaling, directly click on the element; this embodiment is shown in Figure 5, the translucent rounded shape represents the shape of the touch position (22). Embodiment 2: When the touch position (22) of the user has an area and a shape that conflicts with the corresponding visual component (10) (ie, it cannot clearly or accurately correspond to a visual component (2 3) (also That is to say, the touch position (2 2) corresponds to more than one visual element (23), and the controller (3) performs visual content (24) amplification, and the magnification is based on the principle of conflict resolution. When the user has not finished the touch action, if the user moves the touch position (22) to (x, y)*, the screen is shifted to (~x, _y), and the flat process still detects whether There are conflicts mentioned above, and if so, the conflicts are resolved with appropriate scaling. This embodiment is shown, for example, in Fig. 6. In this embodiment, the translucent rounded shape represents the shape of the touch position (22). Figure 6 (a) is a schematic diagram of the conflict before the enlargement; ) is the 'conflict resolution after the enlargement; the gray area is the unintended intention of not being displayed after the enlargement; (c) the user moves the touch position (22) To the right, the system translates the 200921471 screen to the other side; (d) for the user to move the touch position (22) to the bottom 'the system finds no conflict, and returns to the original display scale. Please refer to FIG. 7 , which is a schematic diagram of a touch-sensitive user method for determining a zooming area and a shape of a touch visual area and a zooming area (25); Touching its visual component (23), followed by execution flow 11;
流程11,觸控事件發生(其觸控事件發生於觸控位置產生 時)’接續執行流程12 ; 爪程12控制器(3 )讀取觸控感應器(1)所傳回之觸控位置 資訊’接續執行流程13 ; 桃耘13,控制器(3)讀取顯示面板(2)目前視覺化内容 (24) ’接續執行流程14 ; 机程14,控制器(3)根據觸控位置資訊及視覺化内容 (24) ’判斷是否存在衝突(該衝突即為觸碰位置(22)面積以及 形狀無法清楚對應到—個視覺化元件⑽時),若判斷為是,則 續執仃抓程15,若判定結果為否,則回到流程18,繼續執行 程式判定; 々流程15’控制器⑶以解決衝突為目的,亦決定—視覺化 谷(24)之縮放比例,並依此比例調整視覺化内容(⑷(其縮 放過程中,係能以平順之動畫呈現’以降低突然變化所產生的 12 200921471 .唐突感)’接續執行流程16 ; • 流程16,控制器(3)判斷觸控點是否移動(判定觸控位置 是否移動,可使用-動態或靜態臨界值,以避免不經意的輕微 移動被判定為移動),若判斷為是,則接續執行流程17,若判定 結果為否,則回到流程18,繼續執行程式判定; 流程Π,控制器(3)依照觸控位置移動方向,移動或平移 》視覺化内容(24)(觸控感應器⑴所得之觸碰位置(22)移動時, 顯不面板(2)所顯示的視覺化内容(24)亦會做適當的平移,並在 平移後重新判斷縮放比率及縮放區域(25)),接續執行流程η ; 流程18,依據觸控點座標,選取視覺化元件(23),接續執 行流程19 ; 机程19,控制器(3)偵測觸碰位置(22)是否消失,若判斷 為疋則接續執行流程20,若判定結果為否,則回到流程16, ^ 繼續執行程式判定; ) 抓程20,觸控事件結束(觸控感應器(1)之觸控位置消滅 至觸控事件結束可存在一時間差,以防觸控位置只是短暫消滅 又立即出現在同一位置)。 本發明所設計以觸碰遮蔽面積及形狀決定動態視覺化内容 其縮放比率或縮放區域之觸控式使用者介面系統,具有如下略 舉出別於前述先前技術之特點: L本發明提出一新穎的觸控式使用者介面系統,動態根據 13 200921471 觸碰遮蔽面積及形狀決定動態視覺化内容其縮放比率 或縮放區域,解決視覺化元件相對於觸碰位置其面積大 小及形狀不適當時,所可能產生的視覺化元件被遮蔽問 題及不易定位問題。 2·本發明相較於〇ffset Curs〇r及SMft,本方法不需要 額外的指標,較為直接。相較於us 6, 567, 1〇2,本方 法不採用壓力大小決定畫面縮放,減少使用者額外的出 力負荷。 3 ·本發明在操作過程中,本方法會在觸控位置移動時,提 t、平移的功能,且在完成視覺化元件選取動作後,可自 動回復到縮放前的狀態;故本方法減少使用者的介入, 暗自結合觸碰所遮蔽的面積、形狀及顯示面板所呈現之 視覺化内容,自動替使用者變換適合的縮放比率。In the process 11, the touch event occurs (the touch event occurs when the touch position is generated), and the execution process 12 is continued; the claw 12 controller (3) reads the touch position returned by the touch sensor (1). Information 'Continuous Execution Process 13; Taoyuan 13, Controller (3) Read Display Panel (2) Current Visualization Content (24) 'Continuous Execution Flow 14; Machine 14 and Controller (3) Based on Touch Location Information And visualized content (24) 'Determine whether there is a conflict (this conflict is the touch position (22) area and shape can not clearly correspond to a visual component (10)), if the judgment is yes, then continue to grasp 15. If the result of the determination is no, return to the process 18, and continue to execute the program determination; 々 the process 15' controller (3) for the purpose of resolving the conflict, and also determines the zoom ratio of the visualization valley (24), and adjust according to the ratio Visualized content ((4) (in the process of zooming, it can be rendered in a smooth animation to reduce the sudden change of 12 200921471. Tang sensation) 'Continuous execution flow 16; • Flow 16, controller (3) determines touch Whether the point moves (determines the touch position If it is moved, you can use - dynamic or static threshold to avoid inadvertent slight movement and be judged to be moving. If the judgment is yes, proceed to flow 17 and if the result is no, return to flow 18 and continue execution. The program determines that the controller (3) moves or pans according to the direction of movement of the touch position, and the visual content (24) (when the touch position (22) obtained by the touch sensor (1) moves, the panel is displayed (2) The displayed visual content (24) will also be properly translated, and the zoom ratio and zoom area (25) will be re-evaluated after panning, and the flow η will be executed; Flow 18, according to the touch point coordinates, select the visualization The component (23) is connected to the execution flow 19; the machine 19, the controller (3) detects whether the touch position (22) disappears, and if it is determined to be 疋, the process 20 is continued, and if the determination result is no, the process returns to the flow. 16, ^ Continue to execute the program judgment; ) Grab 20, the touch event ends (the touch position of the touch sensor (1) is wiped to the end of the touch event, there may be a time difference, in case the touch position is only temporarily eliminated and immediately Appear in A position). The touch-sensitive user interface system designed to determine the zoom ratio or zoom area of the dynamic visualized content by touching the masked area and shape has the following features that are slightly different from the prior art: L The present invention proposes a novel The touch-based user interface system dynamically determines the zoom ratio or zoom area of the dynamic visual content according to the touch mask area and shape of 13 200921471, and solves the problem that the size and shape of the visual component relative to the touch position are inappropriate. The resulting visual components are obscured and difficult to locate. 2. Compared with 〇ffset Curs〇r and SMft, the present invention does not require additional indicators and is relatively straightforward. Compared with us 6, 567, 1〇2, this method does not use the pressure to determine the screen zoom, reducing the user's extra output load. 3. During the operation of the present invention, the method can perform the functions of t and panning when the touch position is moved, and can automatically return to the state before the zooming after completing the visual component selection action; The intervention of the person, in combination with the area, shape and visual content presented by the display panel, automatically adjusts the appropriate zoom ratio for the user.
综上所述,本案不但在空間型態上確屬創新,並能較習用 曰進上述夕項功效,應已充分符合新穎性及進步性之法定 發明專利要件’爰㈣提”請,料#局核准本件發明專 矛J申叫案,以勵發明,至感德便。 【圖式簡單說明】In summary, this case is not only innovative in terms of space type, but also can be used in the above-mentioned effects of the above-mentioned eve, and should be fully in line with the novelty and progressiveness of the statutory invention patent requirements '爰(四)提”,料# The bureau approved the invention of the special spear J application, in order to invent the invention, to the sense of virtue. [Simplified description]
CurS〇r❹介面之虛擬指標使用示 圖—為習知其〇ffset 意圖; 圖一為習知Sh i f t以一 小範圍將觸碰點下的視覺化元件放 14 200921471 大後以虛擬游標使用之示意圖; 圖一係本發明以觸碰遮蔽面積及形狀決定動態視覺化内容 其縮放比率或縮放區域 a之觸控式使用者介面系統之功能示意 圖。 圖四為本發明尚未點選程式畫面之示意圖。 圖五為本發明於按鍵人施以觸碰之程式晝面示意圖。 圖/、(a)為本發明另—實施例,為放大前,衝突出現時。半 透明之楕圓型代表觸碰位置形狀。 圖六(b)為本發明另—實施例,為放大後,衝突解決;灰色 區域為放大後沒有被顯示出來的部份。 圖六(c)為本發明再—實施例,為使用者移動觸碰位置往右 方’系統將畫面向左方平移。 圖六(d)為本發明再一實施例’為使用者移動觸碰位置往下 方,系統發現沒有衝突,回復原顯示比例。 圖七為本發明觸碰遮蔽面積及形狀決定動態視覺化内容其 縮放比率或縮放區域之觸控式使用者介面系統運作流程圖。 【主要元件符號說明】 1觸控感應器 11觸控控制器 2顯示面板 21顯示控制器 15 200921471 22觸碰位置 23視覺化元件 24視覺化内容 25縮放區域 3控制器 4微處理器The virtual indicator of the CurS〇r❹ interface uses the diagram—for the purpose of knowing the ffset intention; Figure 1 is the schematic diagram of the visual component placed under the touch point by a small range of Sh ift 14 200921471 FIG. 1 is a schematic diagram showing the function of the touch-sensitive user interface system for determining the zoom ratio or the zoom area a of the dynamic visualized content by touching the masked area and shape. Figure 4 is a schematic diagram of the screen of the program not yet selected. FIG. 5 is a schematic diagram of a program for touching a button on a button. Figure /, (a) is another embodiment of the present invention, before the enlargement, when the conflict occurs. The translucent round shape represents the shape of the touch position. Fig. 6(b) shows another embodiment of the present invention. After the enlargement, the conflict is resolved; the gray area is the portion which is not displayed after being enlarged. Fig. 6(c) shows a further embodiment of the present invention in which the user moves the touch position to the right side to shift the picture to the left. Fig. 6(d) shows still another embodiment of the present invention. When the user moves the touch position to the lower side, the system finds that there is no conflict and returns the original display ratio. FIG. 7 is a flow chart showing the operation of the touch-sensitive user interface system for determining the zoom ratio or the zoom area of the dynamic visualized content according to the touch shielding area and shape of the present invention. [Main component symbol description] 1 Touch sensor 11 Touch controller 2 Display panel 21 Display controller 15 200921471 22 Touch position 23 Visualization component 24 Visualization content 25 Zoom area 3 Controller 4 Microprocessor