M394470 五、新型說明: 【新型所屬之技術領域】 本創作係有關於一種三維(3D)顯示之調校裝置,特別是有關於一種將三 維顯示中的三維顯示畫面更新頻率之影像與快門鏡上的快門整合同步的一 種調校裝置。 【先前技術】 近年來由於3D(3維/Three Dimensional)電影盛行,人們對於 3D影片的需求曰趨增多。相對的3D產品亦從電影轉至LCD產 業。首先,人類為什麼能透過視覺看出深度、並感覺到立體感, 最主要的一點就是,人眼的視覺是可以感覺出深度的,也就是「深 度知覺(depth perception)」;而有了深度的資訊後,才能判斷出立 體空間中的相對位置。由於人的兩個眼睛的位置不一樣,一般人 兩眼間距約5到7公分,所以看到的東西會有兩眼視差 (binocular parallax) ’而人腦會再將這兩個影像做融合 (convergence)’而產生出立體的感覺;而這就是所謂的「bin〇cular cues」。另外,人類亦可從眼睛對遠近焦距的調適 (accommodation)、動態視差(motion paraUax)、透視(perspective) 或光影等來判斷物體的遠近,亦即使人類只有單眼亦可判斷遠近。 因此’為了使在2D(2維/Two Dimensional)平面的影片變成3d 立體感的影片,必須使人類左、右的眼睛分別看到不同的影像(即 是一般視物的兩眼視差),在經由大腦融合,2D影片即可變為栩栩 如生的3D影片。 在現有技術中’是運用快門鏡(shutterglasses),此種技術的基 本原理就是’在螢幕上以兩倍的頻率交互地顯示左眼和右眼的影 像,而眼鏡則會去動態地屏蔽使用者的左眼和右眼,在螢幕顯示 M394470 左眼影像時遮住右眼、在螢幕顯示右眼影像時遮隹左眼,以此遠 到讓兩眼看到各自不同的影像。雖然在這種狀況下,沒有兩隻眼 睛是同時看到影像的,但是由於人眼的視覺暫留等機制的效果, 還是能感覺到兩眼都有看到各自不同的影像,進而產生立體感。 此項技術首先需由連接顯示器上的訊號發射器將影像顯系# 率傳送至快門鏡上的接收器’並藉此訊说決定快門鏡上左、右目艮 快門開、關的時機及開、關需持續多久的時間^ —般在市售的3口 ' 電視(LCD),即是運用此技術。但由於市售電視會將快門鏡的啟動 ▲ 時間固定在顯示器垂直訊號發送後的一段特定時間(如顯示器粢 直訊號發送後4毫秒)啟動、快門鏡的開啟時間(保持在啟動狀態 的時間)固定在一特定時間(如1.5毫秒)’而不進行精確的微調。闺 此,在啟動時間太晚或開啟時間過短的任一種情況下,可能造成 畫面偏灰暗,或者在啟動時間太早或開啟時間過長的任一種情况 下,會造成畫面的疊影、3D無法成像、以致觀賞者造成嘔吐、暈 眩...等不適的情況。 此外’市售的3D-LCD顯示器會將3D訊號發射器30内建 (build-in)在LCD顯示器内或外接於顯示器外,因此,只需再打開 • LCD在3D顯示模式下,3D訊號發射器30便根據LCD垂直同步 訊號進行3D訊號的發送。但賭買的3D-LCD顯示器經過一段時間 之操作後,或是經過不同觀賞者調整3D訊號發射器30之設定後, 都有可能會產生LCD顯示器所發射出的3D影像訊號的更新時間 點(Timing)之與快門鏡上的快門啟動時間不同步,而造成3d影像 效果變差之情形,因此,在一較佳之設計中,需内建一套自調整 系統於3D-LCD顯示器中,可讓消費者自行調整。 因此,本創作提供一種可在LCD顯示器或電視出廠前,將畫面 更新頻率之影像與快門鏡上的快門整合同步的一種微調系統,使 M394470 市售之LCD顯示器或電視售至客戶時,即有精確的3D影像。此 外,本創作進一步在LCD顯示器或電視上配置一自調裝置,使得 即使LCD顯示器或電視於操作一段時間後,可能造成LCD顯示 器或電視與快門鏡產生同步偏差,或是經由另一觀賞者調整後, 目前之觀賞者等,均可依據本創作所提供之方法藉由自調裝置自 行調整。 【新型内容】 依據上述之狀況,本創作之一主要目的在提供一種三維(3D) 顯示之調校系統,利用此調校系統對三維畫面更新影像與快門鏡 上的快門進行同步校正。 本創作之另一主要目的,係提供一種三維(3D)顯示之調校系 統,利用此調校系統之校正過程,可準確的將快門鏡上的快門, 開啟在最大的限度(亦即螢幕晝面停留的時間等於快門保持在開 啟狀態的時間)。 本創作之再一主要目的,係提供一種三維顯示之自調校系 統,可在三維晝面更新之影像與快門鏡上的快門之同步發生偏差 時,可自行調整,不需在送回廠商校準。 基於上述之目的,本創作首先提供一種三維(3D)顯示之調校 系統,包括:一顯示器,具有一矩形之顯示螢幕,用以顯示影像; 一 3D訊號發射器,係配置於顯示器中或外接於顯示器外,並提供 一連_之3D影像訊號,每一 3D影像訊號上之一對角上,配置一 第一顏色之圖案以及一第二顏色之圖案,其中第一顏色之圖案以 及第二顏色之圖案中的顏色對比色不相同;一對第一感應器,係 配置在顯示器之顯示螢幕之一對角上且相應第一顏色之圖案以及 第二顏色之圖案;一快門眼鏡測試座,放置於顯示器之矩形顯示 M394470M394470 V. New Description: [New Technology Field] This creation is about a three-dimensional (3D) display adjustment device, especially for an image that updates the frequency of the three-dimensional display in the three-dimensional display and the shutter mirror. The shutter integrates a synchronization adjustment device. [Prior Art] In recent years, due to the prevalence of 3D (3D/Three Dimensional) movies, the demand for 3D movies has increased. Relative 3D products have also moved from film to LCD industry. First of all, why can humans see the depth through the visual and feel the three-dimensional sense? The most important point is that the human eye can feel the depth, that is, the "depth perception"; After the information, the relative position in the three-dimensional space can be judged. Since the position of the two eyes of the person is different, the average distance between the two eyes is about 5 to 7 cm, so there is a binocular parallax when the object is seen, and the human brain will merge the two images together (convergence). )' produces a three-dimensional feeling; and this is called "bin〇cular cues". In addition, humans can also judge the distance of the object from the eye's adaptation to the near and far focal length, motion paraUax, perspective or light and shadow, and even if the human eye has only one eye, it can judge the distance. Therefore, in order to make a 2D (Two Dimensional) plane film into a 3D stereoscopic film, it is necessary to make the left and right eyes of the human being see different images (that is, the binocular parallax of the general object). Through brain fusion, 2D movies can become lifelike 3D movies. In the prior art, 'shutterglasses' are used. The basic principle of this technique is to 'display the images of the left and right eyes interactively on the screen at twice the frequency, and the glasses will dynamically shield the user. The left and right eyes cover the right eye when the M394470 left eye image is displayed on the screen, and conceal the left eye when the screen displays the right eye image, so that the two eyes can see different images. Although in this situation, no two eyes see the image at the same time, but because of the effect of the visual persistence of the human eye, it is still possible to feel that both eyes have different images, and thus a three-dimensional effect. . This technology first needs to be transmitted to the receiver on the shutter mirror by the signal transmitter connected to the display, and the timing and opening of the shutter on the left and right of the shutter mirror are determined. How long does it take for a long time? ^ The general 3-port TV (LCD) is a technology that uses this technology. However, since the commercially available TV will fix the shutter ▲ start time to a certain time after the vertical signal transmission of the display (such as 4 milliseconds after the display of the direct signal is sent), the shutter mirror is turned on (the time kept in the startup state). Fixed at a specific time (such as 1.5 milliseconds)' without precise fine-tuning. In this case, in any case where the startup time is too late or the startup time is too short, the screen may be grayed out, or in any case where the startup time is too early or the startup time is too long, the image may be superimposed, 3D. Unable to image, such as vomiting, dizziness, etc., caused by discomfort. In addition, the 'commercial 3D-LCD display will build-in the 3D signal transmitter 30 inside or outside the LCD display, so it only needs to be turned back on. • LCD in 3D display mode, 3D signal transmission The device 30 transmits the 3D signal according to the LCD vertical sync signal. However, after a period of operation of the gambling 3D-LCD display or after adjusting the settings of the 3D signal transmitter 30 by different viewers, the update time of the 3D video signal emitted by the LCD display may be generated ( Timing) is not synchronized with the shutter start time on the shutter mirror, which causes the 3D image to be inferior. Therefore, in a preferred design, a self-adjusting system needs to be built in the 3D-LCD display. Consumers adjust themselves. Therefore, this creation provides a fine-tuning system that synchronizes the image of the image update frequency with the shutter on the shutter mirror before the LCD display or the TV is shipped from the factory, so that when the M394470 commercially available LCD display or TV is sold to the customer, Accurate 3D images. In addition, the present invention further configures a self-adjusting device on the LCD display or the television, so that even after the LCD display or the television is operated for a period of time, the LCD display or the television and the shutter mirror may be synchronously offset, or may be adjusted by another viewer. After that, the current viewers, etc., can adjust themselves by the self-adjusting device according to the method provided by the creation. [New content] According to the above situation, one of the main purposes of this creation is to provide a three-dimensional (3D) display calibration system, which uses this calibration system to synchronize the correction of the three-dimensional image update image with the shutter on the shutter mirror. Another main purpose of this creation is to provide a three-dimensional (3D) display calibration system that utilizes the calibration process of the calibration system to accurately open the shutter on the shutter mirror to the maximum extent (ie, the screen) The time the face stays is equal to the time the shutter stays open. Another main purpose of this creation is to provide a self-tuning system for three-dimensional display, which can be adjusted when the image of the three-dimensional surface update is out of sync with the shutter on the shutter mirror, and does not need to be returned to the manufacturer for calibration. . For the above purposes, the present invention first provides a three-dimensional (3D) display calibration system, comprising: a display having a rectangular display screen for displaying images; a 3D signal transmitter configured in the display or externally connected Outside the display, a 3D image signal is provided, and a pattern of the first color and a pattern of the second color are arranged on one of the diagonals of each 3D image signal, wherein the pattern of the first color and the second color The color contrast color is different in the pattern; a pair of first sensors are arranged on a diagonal of one of the display screens of the display and corresponding to the pattern of the first color and the pattern of the second color; a shutter glasses test seat is placed on Display rectangle display M394470
螢幕前,並具有一放置面;一左側光源,放置於快門眼鏡測試座 前緣左侧;一右側光源,放置於快門眼鏡測試座前緣右側;一左 第二感應器’放置於快門眼鏡測試座之放置面上並放置於左側光 源之相對之另一側上;一右第二感應器’放置於快門眼鏡測試座 之放置面上並放置於右侧光源之相對之另一側上;一快門眼鏡’ 係放置於快門眼鏡測試座之放置面上’並放置於左側光源、右側 光源與左第二感應器、右第二感應器之間’快門眼鏡上配置有一 接收裝置用以接收3D訊號發射器所發射之該3D影像同步訊號, 以使該快門眼鏡依序開關左鏡與右鏡;及一校準器,係配置在顯 示器上,並電性連接於3D訊號發射器。 本創作接著提供另一種三維(3D)顯示之調校系統,包括:一 顯示器,具有一矩形之顯示螢幕,用以顯示影像;一 3D訊號發射 器,係配置於顯示器中或外接於顯示器外,並提供一連串之3D影 像訊號,每一 3D影像訊號上之一對角上’配置一第一顏色之圖案 以及一第二顏色之圖案’其中第一顏色之圖案以及第二顏色之圖 案中的顏色對比色不相同;一框架,係配置於顯示螢幕上,且於 相對顯示螢幕之區域為一透明層’並於透明層上配置複數個第一 感應器,每一第一感應器係相應第一顏色之圖案以及第二顏色之 圖案之位置;一快門眼鏡測試座,放置於顯示器之矩形顯示螢幕 前,並具有一放置面;一左側光源’放置於快門眼鏡測試座前緣 左側;一右側光源,放置於快門眼鏡測試座前緣右側;一左第二 感應器,放置於快門眼鏡測試座之放置面上並放置於左側光源之 相對之另一側上;一右第二感應器’放置於快門眼鏡測試座之放 置面上並放置於右側光源之相對之另一側上;一快門眼鏡,係放 置於快門眼鏡測試座之放置面上’並放置於左側光源、右側光源 與左第二感應器、右第二感應器之間,快門眼鏡上配置有一接收 □ 7 M394470 裝置用以接收該3D訊號發射器所發射之該3D影像同步訊號,以 使快門眼鏡依序開關左鏡與右鏡;及一校準器,係配置在顯示器 上,並電性連接於該3D訊號發射器。 本創作再提供一種三維顯示之自調校系統,包括:一顯示器, 具有一矩形之顯示螢幕,用以顯示影像;一 3D訊號發射器,係配 置於顯示器中或外接於顯示器外,並提供一 3D影像訊號,而3D 影像訊號由一左眼測試畫面與一右眼測試畫面交替重複顯示;一 屏幕視控裝置,係配置於3D訊號發射器中,屏幕視控裝置係由一 延遲時間調整電路與一開啟時間調整電路所組成;一快門眼鏡, 具有一接收裝置用以接收3D訊號發射器所發射之3D影像訊號, 以使快門眼鏡依序開關左鏡與右鏡;及一終端控制器,係用以啟 動3D訊號發射器提供3D影像訊號;其中,藉由終端控制器來調 整延遲啟動時間調整電路與開啟(保持在啟動狀態)時間調整電路。 經由本創作所提供之設計,可經由精準的調整,將畫面更新 頻率之影像與快門鏡上的快門整合同步,使顯現出的三維畫面不 會過於陰暗或發生疊影的情況,以達到最佳的三維效果。 【實施方式】 本創作主要在揭露一種三維(3D)顯示之調校系統及其調校方 法,故配置於調校系統中之具有提供三維畫面的顯示器及快門鏡 等均為習知技術,故對於顯示器及快門鏡之詳細結構及三維晝面 之編輯或製作等,並未描述於細節中,以避免造成本創作不必要 之限制。然而,對於與本創作之三維(3D)顯示之調校系統及其調 校方法的較佳實施例,則會詳細描述如下,然而除了這些詳細描 述之外,本創作還可以廣泛地施行在其他的實施例中,其以之後 的專利範圍為準。為使本創作所運用之技術内容、創作目的及其 M394470 達成之功效有更完整且清楚的揭露,茲於下詳細說明之,並請一 併參閱所揭之圖示及圖號。 一般液晶電視(LCD TV)之晝面是由一連串靜態畫面持續更新 畫面來形成,由於人眼有殘影功能,因此,在一連串靜態畫面持 續更新晝面中,會形成一動態畫面。液晶電視畫面更新有以下幾 種·由右上至左下更新、由左上至右下更新、由上至下更新及由 下至上更新。一般液晶電視更新頻率為60hz(每秒6〇次),人眼殘 • 影約為1/16〜1/24秒(相對顯示頻率為i6hz〜24hz),因此有足夠時 % 間形成動態畫面。 要顯示三維畫面(以下將三維以3D表示),首先,必須要將左、 <畫面交替穿插更新,且由於是交替穿插更新,因此更新頻率必 提升至人眼殘影頻率的兩倍以上至6〇hz〜12〇hz ’或者更高至 24〇uIn front of the screen, and has a placement surface; a left side light source placed on the left side of the front edge of the shutter glasses test seat; a right side light source placed on the right side of the front edge of the shutter glasses test seat; a left second sensor 'placed in the shutter glasses test The placement surface of the seat is placed on the opposite side of the left side light source; a right second sensor is placed on the placement surface of the shutter glasses test stand and placed on the opposite side of the right side light source; The shutter glasses are placed on the placement surface of the shutter glasses test stand and placed between the left side light source, the right side light source and the left second sensor, and the right second sensor. The shutter glasses are provided with a receiving device for receiving the 3D signal. The 3D image synchronization signal emitted by the transmitter is such that the shutter glasses sequentially switch the left mirror and the right mirror; and a calibrator is disposed on the display and electrically connected to the 3D signal transmitter. The present invention then provides another three-dimensional (3D) display calibration system, including: a display having a rectangular display screen for displaying images; and a 3D signal transmitter disposed in the display or externally connected to the display. And providing a series of 3D video signals, one diagonally on each of the 3D video signals, a pattern of the first color and a pattern of the second color, wherein the pattern of the first color and the color of the pattern of the second color The contrast color is different; a frame is disposed on the display screen and is a transparent layer in the area opposite to the display screen and a plurality of first sensors are disposed on the transparent layer, and each of the first sensors is corresponding to the first color a pattern and a position of the pattern of the second color; a shutter glasses test stand placed in front of the rectangular display screen of the display and having a placement surface; a left side light source 'placed on the left side of the front edge of the shutter glasses test seat; a right side light source, Placed on the right side of the front edge of the shutter glasses test stand; a left second sensor placed on the placement surface of the shutter glasses test stand and placed on the left On the opposite side of the side light source; a right second sensor 'placed on the placement surface of the shutter glasses test stand and placed on the opposite side of the right side light source; a shutter glasses placed on the shutter glasses test The mounting surface of the seat is placed between the left side light source, the right side light source and the left second sensor, and the right second sensor. The shutter glasses are provided with a receiving device. 7 M394470 device is used to receive the 3D signal transmitter. The 3D image synchronizing signal is such that the shutter glasses sequentially switch the left mirror and the right mirror; and a calibrator is disposed on the display and electrically connected to the 3D signal transmitter. The present invention further provides a self-tuning system for three-dimensional display, comprising: a display having a rectangular display screen for displaying images; and a 3D signal transmitter disposed in the display or externally connected to the display and providing a 3D video signal, and the 3D video signal is alternately displayed by a left eye test picture and a right eye test picture; a screen visual control device is disposed in the 3D signal transmitter, and the screen visual control device is controlled by a delay time adjustment circuit. And a turn-on time adjustment circuit; a shutter glasses having a receiving device for receiving a 3D image signal emitted by the 3D signal transmitter, so that the shutter glasses sequentially switch the left mirror and the right mirror; and a terminal controller, It is used to activate the 3D signal transmitter to provide a 3D video signal; wherein the terminal controller adjusts the delay start time adjustment circuit and the on (hold in start state) time adjustment circuit. Through the design provided by this creation, the image of the image update frequency can be synchronized with the shutter on the shutter mirror through precise adjustment, so that the displayed three-dimensional image is not too dark or superimposed to achieve the best. The three-dimensional effect. [Embodiment] The present invention mainly discloses a calibration system for a three-dimensional (3D) display and a calibration method thereof. Therefore, a display and a shutter mirror provided with a three-dimensional image disposed in the calibration system are known technologies, and thus The detailed structure of the display and the shutter mirror and the editing or production of the three-dimensional face are not described in detail to avoid unnecessary restrictions on the creation. However, the preferred embodiment of the calibration system and the adjustment method of the three-dimensional (3D) display of the present invention will be described in detail below, but in addition to these detailed descriptions, the present invention can be widely implemented in other In the embodiments, it is subject to the scope of the patents that follow. In order to make the technical content, creative purpose and the effect achieved by M394470 of this creation more complete and clear, please elaborate below, and please refer to the illustrated illustration and drawing number. Generally, the inside of a liquid crystal television (LCD TV) is formed by continuously updating a series of still pictures. Since the human eye has a residual image function, a dynamic picture is formed in a series of still pictures continuously updating. There are several types of LCD TV screen updates: from top right to bottom left, from top left to bottom right, top to bottom updates, and bottom to top updates. Generally, the LCD TV update frequency is 60hz (6 times per second), and the eye shadow is about 1/16~1/24 seconds (relative display frequency is i6hz~24hz), so there is enough time to form a dynamic picture. To display a three-dimensional picture (hereinafter 3D is represented by 3D), first, the left and <pictures must be alternately interspersed and updated, and since it is alternately interpolated and updated, the update frequency must be raised to twice the frequency of the human eye afterimage to 6〇hz~12〇hz 'or higher to 24〇u
畫Z,才能讓人眼殘影動作連續。當人眼要從3D顯示器看出3D 卷面時,需配戴一快門眼鏡,此快門眼鏡有一左快門及一右快門。 妒故3D影像之液晶電視之發射器送出一個更新左眼畫面之訊 ^時’快門眼鏡之左快門開啟同時關閉快門眼鏡之右快門,故觀 % 貝者只有左眼看到晝面。當3D影像之液晶電視之發射器送出一個 -^新右眼晝面之訊號時,快門眼鏡之左快門關閉同時開啟快門眼 ^之右快門’故觀賞者只有右眼看到畫面。經大腦融合左、右眼 面後’產生出立體的感。如果左、右快門開啟停留時間過長或 各早開啟,會產生疊影的晝面,使得3D效果變差,嚴重時甚至 法達成3D效果;如果左、右快門開啟停留時間過短或者太晚 ’則3D晝面會偏黯淡;只有精準剛好的開啟時間,能產生完 美的效果。 凡 如苐首先,睛參考第1圖,係為本創作3D顯示之調校系統示意圖。 1圖所示’ 3D顯示之調校系統包括一顯示器1〇,具有一顯示 螢幕^ 101 · ;複數個第一感應器20,係將一對第一感應器20配置在 顯示器Λτ* <矩形顯示螢幕101之對角上;而在本創作之最佳實施方 式,係/ '、仕四角落上均配置有第一感應器20; — 3D訊號發射器30, 性連接於顯示器 10上,且配置有一校準器301,其中3D訊號 發射装 u 。、35 30用以輸出一連串之3D影像之訊號,其中3D訊號發射 器30所提供之3D影像訊號係由一左眼測試畫面90與一右眼測試 晝面91交替重複顯示,同時,每一 3D影像訊號30上之一對角上, 配置有第一顏色之圖案901以及第二顏色之圖案902,其中第一顏 色之圖案901以及第二顏色之圖案902中的顏色對比色不相同(例 如:第一顏色之圖案901為深色,而第二顏色之圖案902為淺色(請 參考第3圖);一快門眼鏡測試座4〇,係配置於顯示器1〇之顯示 螢幕101之前方一距離,其具有一放置面4〇1以及一基座403,其 中放置面401位於基座403之另一側面;且在放置面401之靠近 顯示螢幕1〇1之第一端左右側邊上,各放置一左光源50及一右光 源51,而在放置面401相對於第一端之另一端(即第二端)之左右 側邊上各配置一個與左光源50及右光源51相對之一對第二感應 器’包括左第二感應器70及右第二感應器71 ;本實施例之左光源 50與右光源51之最佳發光源為發光二極體(LED),但本實施例並 不加以限制其光源類型;一快門眼鏡60 ’其上配置一接收器(未顯 示於圖中),用以接收3D訊號發射器30所發出之3D影像同步訊 號,使得快門眼鏡60可以依據3D影像同步訊號來控制快門眼鏡 60左鏡61之開(ON)與關(OFF)以及右鏡62之開(〇N)與關(〇FF), 其中,快門眼鏡60置於快門眼鏡測試座40之放置面4〇1的兩端 間,即快門眼鏡60位於左光源50、右光源51與左右相對之第二 感應器70、71之間’且快門眼鏡60之左鏡61與左光源5〇及左 第二感應器70成一直線配置,同時,快門眼鏡6〇之右鏡62與右 M394470 光源51及右第二感應器71成一直線配置。一波形顯示器8〇(例 如:示波器),其第一偵測訊號輸入端藉由導線13與一對第一感 應器20電性連接,同時其第二偵測訊號輸入端藉由導線15與左 第二感應器70及右第二感應器π電性連接。 再者’如第1圖所示’為了使快門眼鏡測試座4〇之放置面401 上的左第二感應器70及右第二感應器71在感應左光源5〇與右光 源51時,不會造成光源之間的相互干擾,故在本實施例中,係在 放置面401之接近中央附近處,設置一支撐座405,此支撐座405 具有一縱向延長之結構,故可以有效地遮住部份左光源5〇與右光 源51對左第二感應器70及右第二感應器71的干擾。很明顯地, 支撐座405是配置在左側光源5〇、右侧光源51與第二感應器70、 右第二感應器71之間。同時,也可以進一步在支撐座4〇5上形成 一凹槽部(未顯示於圖中),使得快門眼鏡6〇能夠卡固在凹槽部 中。 接著’請參考第2圖,係為本創作之複數個第一感應器另一 實施例之配置示意圖。在顯示器1〇之顯示螢幕1〇1前方配置一框 體U ’此框體11有一透明面U1與由透明面U1往前延伸之一框 邊113 ’透明面與框邊113形成一蓋體狀。透明面111大小與 顯不螢幕101相等,且藉由框邊U3框住顯示器1〇以固定住框體 11 °而複數個第一感應器20則安裝在框體11之透明面111,其配 置之位置與上述之每一 3D影像訊號上第一顏色之圖案901以及第 一顏色之圖案902相對應;例如:當每一 3D影像訊號只在一對角 上配置有第—顏色之圖案901以及第二顏色之圖案902時,此時, 即使用兩個第一感應器20與3D影像訊號上第一顏色之圖案901 以及第二顏色之圖案902相對應;當每一 3D影像訊號之四角落均 配置有第一顏色之圖案901以及第二顏色之圖案902時,則需使 11 M394470 用四個第一感應器20配置在透明面111之四角落。藉由此實施例 · 之配置,在調整另一顯示裝置時,只需將框體1丨直接卸除,再安 裝至另一顯示裝置即可,可大幅減少更換第一感應器20至另一顯 示裝置所需耗費的時間。 本創作之複數個第一感應器20可以如第1圖所示,直接配置 於顯示器10之顯示螢幕1〇1上,例如:使用黏性材料將複數個第 一感應器20黏貼於顯示螢幕101之至少一對角上並與每一 3D影 像訊號上第一顏色之圖案以及第二顏色之圖案相對應,或如第2 - 圖所示’將複數個第一感應器20黏貼於透明面ill上並與每一 3D , 影像訊號上第一顏色之圖案以及第二顏色之圖案相對應,對此實 · 施方式’本創作並不加以限制。 接著’請參考第3圖’係為本創作在進行調校時之3D影像測 試畫面示意圖。如第3圖所示,在左眼測試畫面9〇之四角落之右 上及左下配置一第一顏色之圖案9〇1,在左上及右下上配置一第二 顏色之圖案902。而在右眼測試晝面91之四角落之右上及左下配 置一第二顏之圖案色902’在左上及右下上配置一第一顏色之圖案 901。如前所述,本創作之最佳實施例是以第一顏色為一深色,第 二顏色為一淺色,藉由對比色加以區別,但本實施例並不侷限任 鲁 何顏色。當畫面更新時(如由右上至左下更新),左眼測試晝面9〇 . 之右上第一顏色之圖案901會先變成第二顏色之圖案9〇2。而更新 將完畢時,左下之第一顏色之圖案9〇1會變成第二顏色之圖案 902,此時左眼測試畫面9〇即會變成右上及左下皆為第二顏色之 圖案902之右眼測試晝面91,而左上及右下相繼變色的這段時 間,即為畫面更新所需時間。而左下變完色至下次右上要再次變 更顏色的時間’即為畫面停留時間。 請參考第4圖,係為本創作3D影像訊號更新時間軸之示意 12 M394470 圖。若以一般120hz顯示器為例,畫面更新時間約有4毫秒, 畫面停留時間約有4.3毫秒’亦即畫面更新完至下一次更新時間共 有8.3毫秒。因此,畫面如需完整呈現完美的3D效果其快門眼 鏡60之左鏡61或右鏡62之開啟時間必須愈接近4 3毫秒效果愈 好,即晝面停留時間等於左鏡61或右鏡62開啟時間(要說明一 點,因快門眼鏡60控制左鏡61或右鏡62之開啟快門速度非常之 快,因此快門開啟時間不需加入計算接著,如第4圖之時間轴 T所示,在一開始畫面更新的4毫秒期間,左鏡61與右鏡62皆 為關閉狀態’在大約3.95毫秒至4毫秒之間,左鏡61會開啟完成, 故此時只有左眼看的到畫面(即左眼測試畫面9〇),當至毫秒 時,左鏡61會關閉,然後回復成畫面更新狀態,此時,左鏡61 與右鏡62皆為關閉之狀態。當時間至12 25〜12 3毫秒之間的時 刻(即左鏡61關閉再經過3.95〜4毫秒),此時右鏡62會剛好開啟 完成,因此只有右眼看的到畫面(即右眼測試畫面91),當至16 6 毫秒時(即右鏡62開啟再經過4.3毫秒),右鏡會62關閉,又再回 復成畫面更新狀態,此時的左鏡61與右鏡62皆為關閉之狀態’ 依此循環。 在上述之3D影像訊號之更新過程中,由於左眼測試晝面9〇 與右眼测試晝面91在同一角落之位置上配置之圖形不相同,因 此,位於同一角落之第一感應器2〇所感應到的顏色對比度也不相 同,故其輸出也不相同;例如:當第一感應器2〇測得左眼測試畫 面90之第一顏色之圖案901(即為深色)時,輸出一低狀態之訊號, 而當更新為右眼測試畫面91時,此相同位置配置為第二顏色之圖 案902(即為淺色)時,則第一感應器2〇輸出一高狀態之訊號,此 過程產生第一偵測訊號;因此,第一感應器2〇會隨LCD之3D畫 面更新,將其感應出的訊號狀態經由導線13將此第一偵測訊號傳 13 M394470 送至波形顯示器80顯示;很明顯地,此苐一偵測訊號其顯示之波 形是具有高與低狀態之方波訊號。 接著,請參考第5A圖及第5B圖,係為本創作3D顯示之調 校系統之調校示意圖。首先,如第5A圖所示,於前述之LCD晝 面更新過程中,當3D晝面更新為左眼測試晝面90時,3D訊號發 射器30會將左眼測試晝面90之訊號傳送至快門眼鏡60,當快門 眼鏡60之接收器接收左眼測試畫面90之訊號時,即刻將左鏡61 開啟(此時右鏡62仍為關閉狀態)。由於本創作置於快門眼鏡60前 之左右相對之左光源50與右光源51為永照光源,且其光線對著 快門眼鏡60後方之左右相對之左第二感應器70與右第二感應器 71。以第5A圖為例,當前述之左鏡61開啟時,其左第二感應器 70會感應到前方之左光源50之光線;很明顯地,此時因右鏡62 仍為關閉狀態,故右第二感應器71無法感應到前方之右光源51 之光線。因此,當左第二感應器70從左鏡61開啟並偵測到光線 至左鏡61關閉(更新為右眼測試晝面91),這段時間便是3D影像 之左晝面停留時間,而這感應訊號便會經由左第二感應器70以導 線15將此第二偵測訊號傳送至波形顯示器80顯示,而其顯示之 波形可以是具有高與低狀態之方波訊號。而在此同時,第一感應 器20亦會將LCD之3D畫面更新之感應訊號經由導線13將第一 偵測訊號傳送波形顯示器80顯示。此時,便可藉由波形顯示器80 上所顯示之第一偵測訊號與第二偵測訊號間的波形啟始點來判斷 是否同步;即判斷快門眼鏡60之左鏡61之開啟時間是否符合顯 示器10上的4.3毫秒。而第5B圖係顯示3D晝面更新為右眼測試 晝面之示意圖,由於其過程與第5A圖之測試過程相同,故不再贅 述之。 若當波形顯示器80上所顯示之第一偵測訊號與第二偵測訊號 M394470 間的波形啟始點不同步時,即表示LCD發設器所送出之3D測試 晝面之時間點與快門眼鏡60之接收器開啟左眼之時間點之間產生 時間延遲(time lag),此時即會造成左鏡61之開啟時間還未到達4.3 毫秒時,下一更新畫面之訊號已經將左鏡61關閉,故當第一偵測 訊號與第二偵測訊號間的時間延遲愈長時,即表示左鏡61之開啟 時間愈短,因此會造成前述之3D畫面會偏黯淡且效果變差;同樣 地,如果左鏡61之開啟時間愈長時,則會產生疊影的晝面,使得 3D效果變差;只有精準剛好的開啟時間,能產生完美的3D效果。 故當本創作之調效裝置藉由波形顯示器顯示而判斷出3D晝 面停留時間有所偏差時,便經由3D訊號發射器30上之校準器301 來進行微調,以使第一偵測訊號與第二偵測訊號間的兩個訊號同 步。右鏡62調整方式亦與左鏡61相同,由波形顯示器80分析第 一偵測訊號與右第二感應器71之第二偵測訊號是否同步,再經由 校準器301調整。以上述方法調整快門眼鏡60之左鏡61與右鏡 62,可達成亮度最大、3D影像最清楚且不發生疊影之完美畫面。 在此要說明的是,校準器301為一可變電阻之調整器,可藉由此 可變電阻之阻質改變來調整3D訊號發射器30的啟始時間。 雖然本創作以前述之較佳實施例揭露如上,然其並非用以限定本 創作,任何熟習相像技藝者,在不脫離本創作之精神和範圍内, 當可作些許之更動與潤飾,因此本創作之專利保護範圍須視本說 明書所附之申請專利範圍所界定者為準。 【圖式簡單說明】 第1圖 係為本創作3D顯示之調校系統示意圖。 第2圖 係為本創作之第一感應器之配置示意圖。 第3圖 係為本創作進行調校時之3D影像之測試畫面示意圖。 15 3 M394470 第4圖 係為本創作畫面更新時間軸之示意圖。 第5A圖係為本創作3D顯示之調校系統之左鏡調校之示意圖。 第5B圖係為本創作3D顯示之調校系統之右鏡調校之示意圖。 【主要元件符號說明】 10 顯示器 101 顯示螢幕 11 框體 111 透明面 113 框邊 13 導線 15 導線 20 第一感應器 30 3D訊號發射器 300 屏幕視控裝置 301 校準器 40 快門眼鏡測試座 401 放置面 403 基座 405 支撐座 50 左光源 51 右光源 60 快門眼鏡 61 左鏡 62 右鏡 16 M394470 70 左第二感應器 71 右第二感應器 80 波形顯示器 90 左眼測試晝面 901 第一顏色之圖案 91 右眼測試晝面 902 第二顏色之圖案Painting Z, in order to make people's eyes and shadows move continuously. When the human eye wants to see the 3D roll surface from the 3D display, it is necessary to wear a shutter glasses having a left shutter and a right shutter. Therefore, the transmitter of the LCD TV of 3D image sends a message to update the left eye image. ^ When the left shutter of the shutter glasses is opened and the right shutter of the shutter glasses is closed, only the left eye sees the face. When the transmitter of the LCD TV of 3D image sends a signal of -^ new right eye, the left shutter of the shutter glasses is closed and the right shutter of the shutter eye is opened. Therefore, the viewer only sees the picture with the right eye. After the brain is fused to the left and right eyes, it produces a sense of three-dimensionality. If the left and right shutters are open for too long or open early, the overlapping faces will be generated, which will make the 3D effect worse. If it is serious, the 3D effect will be achieved even if the left and right shutters are too short or too late. 'The 3D face will be faint; only the precise opening time will produce perfect results. For example, if you first look at the first picture, it is a schematic diagram of the calibration system for creating 3D display. 1] The calibration system of the 3D display includes a display 1〇 having a display screen 101; a plurality of first sensors 20 configured to arrange a pair of first sensors 20 on the display Λτ* < rectangle Displaying the diagonal of the screen 101; in the preferred embodiment of the present invention, the first sensor 20 is disposed on the corners of the '4', and the 3D signal transmitter 30 is connected to the display 10, and A calibrator 301 is provided in which the 3D signal is transmitted. 35, 30 is used to output a series of 3D video signals, wherein the 3D video signal provided by the 3D signal transmitter 30 is repeatedly displayed by a left eye test screen 90 and a right eye test surface 91, and each 3D On one of the diagonals of the image signal 30, a pattern 901 of a first color and a pattern 902 of a second color are arranged, wherein the color contrast color in the pattern 901 of the first color and the pattern 902 of the second color are different (for example: The pattern 901 of one color is dark, and the pattern 902 of the second color is light (please refer to FIG. 3); a shutter glasses test stand 4 is disposed at a distance before the display screen 101 of the display 1〇, It has a placement surface 4〇1 and a base 403, wherein the placement surface 401 is located on the other side of the base 403; and is placed on the left and right sides of the first end of the placement surface 401 adjacent to the display screen 1〇1. a left light source 50 and a right light source 51, and one of the left and right light sources 51 and the right light source 51 are disposed on the left and right sides of the other surface (ie, the second end) of the first surface (ie, the second end). Two sensors 'including left second induction 70 and the right second sensor 71; the optimal light source of the left light source 50 and the right light source 51 of the embodiment is a light emitting diode (LED), but the embodiment does not limit the light source type; a shutter glass 60 The receiver (not shown) is configured to receive the 3D image synchronization signal sent by the 3D signal transmitter 30, so that the shutter glasses 60 can control the shutter glasses 60 according to the 3D image synchronization signal. Opening (OFF) and OFF (OFF) and opening (〇N) and closing (〇FF) of the right mirror 62, wherein the shutter glasses 60 are placed between the two ends of the placement surface 4〇1 of the shutter glasses test socket 40, that is, The shutter glasses 60 are located between the left light source 50, the right light source 51 and the left and right opposite second inductors 70, 71' and the left mirror 61 of the shutter glasses 60 is disposed in line with the left light source 5A and the left second sensor 70, while The right mirror 62 of the shutter glasses is arranged in line with the right M394470 light source 51 and the right second sensor 71. A waveform display 8 (for example, an oscilloscope) has a first detection signal input end through a wire 13 and a Electrically connecting the first sensor 20 and simultaneously transmitting the second detection signal The input end is electrically connected to the left second sensor 70 and the right second sensor π by the wire 15. Further, as shown in FIG. 1 , in order to make the shutter glasses test stand 4 〇 on the left side of the placement surface 401 When the two sensors 70 and the right second sensor 71 sense the left light source 5 〇 and the right light source 51, they do not cause mutual interference between the light sources, so in the present embodiment, near the center of the placement surface 401 A support base 405 is provided. The support base 405 has a longitudinally extending structure, so that the interference of the partial left light source 5〇 and the right light source 51 to the left second inductor 70 and the right second inductor 71 can be effectively blocked. . Obviously, the support base 405 is disposed between the left side light source 5A, the right side light source 51 and the second inductor 70, and the right second inductor 71. At the same time, a groove portion (not shown) may be further formed on the support base 4〇5 so that the shutter glasses 6〇 can be stuck in the groove portion. Next, please refer to FIG. 2, which is a schematic diagram of another embodiment of a plurality of first inductors of the present invention. A frame U' is disposed in front of the display screen 1'1 of the display 1'. The frame 11 has a transparent surface U1 and a frame edge 113 extending forward from the transparent surface U1. The transparent surface and the frame edge 113 form a cover. . The size of the transparent surface 111 is equal to that of the display screen 101, and the display frame 1 is framed by the frame edge U3 to fix the frame body 11°, and the plurality of first sensors 20 are mounted on the transparent surface 111 of the frame body 11 and configured. The position corresponds to the pattern 901 of the first color and the pattern 902 of the first color on each of the 3D image signals; for example, when the 3D image signal is disposed on only one pair of corners, the first color pattern 901 is disposed. When the pattern 902 of the second color is used, at this time, the two first sensors 20 are used to correspond to the pattern 901 of the first color and the pattern 902 of the second color on the 3D image signal; when the four corners of each 3D image signal When the pattern 901 of the first color and the pattern 902 of the second color are both disposed, the 11 M394470 is disposed at four corners of the transparent surface 111 by the four first inductors 20. With the configuration of the embodiment, when the other display device is adjusted, it is only necessary to directly remove the frame 1丨 and then mount it to another display device, which can greatly reduce the replacement of the first sensor 20 to another. The time it takes to display the device. The plurality of first sensors 20 of the present invention can be directly disposed on the display screen 1〇1 of the display 10 as shown in FIG. 1 , for example, the plurality of first sensors 20 are adhered to the display screen 101 by using a viscous material. At least one pair of corners corresponding to the pattern of the first color and the pattern of the second color on each of the 3D image signals, or as shown in FIG. 2 - the plurality of first sensors 20 are adhered to the transparent surface ill Up and corresponding to each 3D, the pattern of the first color on the image signal and the pattern of the second color, this embodiment is not limited to this creation. Then, please refer to Figure 3 for a schematic view of the 3D image test screen when the creation is adjusted. As shown in Fig. 3, a pattern 9 第一 1 of the first color is arranged on the upper right and lower left of the corners of the left eye test screen 9 ,, and a pattern 902 of the second color is arranged on the upper left and lower right. A pattern 901 of a first color is disposed on the upper left and lower right sides of the fourth corner of the right eye test face 91. As described above, the preferred embodiment of the present invention has a first color as a dark color and a second color as a light color, which is distinguished by contrast colors, but this embodiment is not limited to any color. When the picture is updated (eg, updated from top right to bottom left), the left eye test face 9〇. The pattern 901 of the first color on the upper right first becomes the pattern 9〇2 of the second color. When the update is completed, the pattern 9〇1 of the first color at the lower left will become the pattern 902 of the second color, and the left eye test screen 9〇 will become the right eye of the pattern 902 of the second color in the upper right and lower left. The time when the face 91 is tested and the upper left and lower right are successively changed is the time required for the picture to be updated. The time when the lower left is finished until the next time the upper right is to change the color again is the picture stay time. Please refer to Figure 4 for the illustration of the timeline of the 3D video signal update 12 M394470. For example, in the case of a general 120hz display, the screen update time is about 4 milliseconds, and the screen stay time is about 4.3 milliseconds, that is, the screen is updated to 8.3 milliseconds after the next update time. Therefore, if the picture needs to completely present a perfect 3D effect, the opening time of the left mirror 61 or the right mirror 62 of the shutter glasses 60 must be closer to 433 milliseconds, that is, the better the squatting time is equal to the left mirror 61 or the right mirror 62 is turned on. Time (to explain, since the shutter glasses 60 control the opening speed of the left mirror 61 or the right mirror 62 to be very fast, the shutter opening time does not need to be added to the calculation, as shown by the time axis T in Fig. 4, at the beginning During the 4 milliseconds of the screen update, both the left mirror 61 and the right mirror 62 are in the off state 'between about 3.95 milliseconds to 4 milliseconds, and the left mirror 61 is turned on, so only the left eye sees the screen (ie, the left eye test screen). 9〇), when the millisecond is reached, the left mirror 61 will be turned off, and then returned to the screen update state, at this time, the left mirror 61 and the right mirror 62 are both closed. When the time is between 12 25 and 12 3 milliseconds At the moment (ie, the left mirror 61 is turned off and then 3.95~4 milliseconds), the right mirror 62 will just be turned on, so only the right eye sees the picture (ie, the right eye test screen 91), when it is 16 6 milliseconds (ie, right) Mirror 62 is turned on and then 4.3 milliseconds), right mirror The 62 is turned off, and then returned to the screen update state. At this time, the left mirror 61 and the right mirror 62 are both in the closed state. According to this cycle, in the process of updating the above 3D video signal, the left eye test surface 9 The pattern of the right eye test surface 91 disposed at the same corner is different, so the color contrast sensed by the first sensor 2 at the same corner is different, so the output is different; For example, when the first sensor 2 detects the pattern 901 of the first color of the left eye test screen 90 (ie, is dark), it outputs a low state signal, and when updating to the right eye test screen 91, this When the same position is configured as the second color pattern 902 (ie, light color), the first sensor 2 outputs a high state signal, and the process generates a first detection signal; therefore, the first sensor 2 With the 3D picture update of the LCD, the signal state sensed by the LCD sends the first detection signal 13 M394470 to the waveform display 80 via the wire 13; obviously, the waveform of the first detection signal is displayed. High and low state square wave Next, please refer to Figure 5A and Figure 5B, which is a schematic diagram of the adjustment of the calibration system for the creation of 3D display. First, as shown in Figure 5A, during the aforementioned LCD update process, when 3D昼When the face is updated to the left eye test face 90, the 3D signal transmitter 30 transmits the signal of the left eye test face 90 to the shutter glasses 60, and when the receiver of the shutter glasses 60 receives the signal of the left eye test screen 90, immediately The left mirror 61 is turned on (the right mirror 62 is still in the closed state at this time). Since the left and right light sources 50 and 50 of the right light source 51 are placed in front of the shutter glasses 60, the light is directed to the rear of the shutter glasses 60. The left second sensor 70 and the right second sensor 71 are opposite to each other. Taking FIG. 5A as an example, when the left mirror 61 is turned on, the left second sensor 70 senses the light of the left front light source 50; obviously, since the right mirror 62 is still off, The right second sensor 71 cannot sense the light of the right right source 51. Therefore, when the left second sensor 70 is turned on from the left mirror 61 and the light is detected until the left mirror 61 is turned off (updated to the right eye test surface 91), this time is the left side of the 3D image, and The sensing signal is transmitted to the waveform display 80 via the left second sensor 70 via the wire 15, and the displayed waveform can be a square wave signal having high and low states. At the same time, the first sensor 20 also displays the first detection signal of the LCD 3D picture update signal via the wire 13 to the waveform display 80. At this time, whether the synchronization is synchronized is determined by the waveform start point between the first detection signal and the second detection signal displayed on the waveform display 80; that is, whether the opening time of the left mirror 61 of the shutter glasses 60 is determined to be consistent 4.3 milliseconds on display 10. Figure 5B shows a schematic diagram of the 3D facet update to the right eye test face. Since the process is the same as the test process of Figure 5A, it will not be described again. If the waveform starting point between the first detection signal displayed on the waveform display 80 and the second detection signal M394470 is not synchronized, it means that the time point of the 3D test surface sent by the LCD transmitter and the shutter glasses A time delay (time lag) occurs between the time points when the receiver of the 60 is turned on, and the time when the left mirror 61 is turned on has not reached 4.3 milliseconds, the signal of the next update screen has turned off the left mirror 61. Therefore, the longer the time delay between the first detection signal and the second detection signal, the shorter the opening time of the left mirror 61 is, which may cause the aforementioned 3D picture to be faint and the effect is worse; If the opening time of the left mirror 61 is longer, the overlapping surface of the mirror will be generated, which makes the 3D effect worse; only the precise opening time can produce a perfect 3D effect. Therefore, when the modulation device of the present invention determines that the 3D facet time is deviated by the waveform display, the calibrator 301 on the 3D signal transmitter 30 is fine-tuned to make the first detection signal and The two signals between the second detection signals are synchronized. The adjustment mode of the right mirror 62 is also the same as that of the left mirror 61. The waveform display 80 analyzes whether the first detection signal is synchronized with the second detection signal of the right second sensor 71, and is adjusted by the calibrator 301. By adjusting the left mirror 61 and the right mirror 62 of the shutter glasses 60 in the above manner, a perfect picture with the highest brightness and the clearest 3D image without overlapping is achieved. It should be noted that the calibrator 301 is a variable resistor adjuster, and the start time of the 3D signal transmitter 30 can be adjusted by the change of the resistance of the variable resistor. Although the present invention has been disclosed in the foregoing preferred embodiments, it is not intended to limit the present invention, and any skilled person skilled in the art can make some modifications and refinements without departing from the spirit and scope of the present invention. The scope of patent protection of the creation shall be subject to the definition of the scope of the patent application attached to this specification. [Simple description of the diagram] Figure 1 is a schematic diagram of the calibration system for creating 3D display. Figure 2 is a schematic diagram of the configuration of the first sensor of the creation. Figure 3 is a schematic diagram of the test screen of the 3D image when the creation is adjusted. 15 3 M394470 Fig. 4 is a schematic diagram of the timeline of the creation of the creation screen. Figure 5A is a schematic diagram of the left mirror adjustment of the calibration system for creating a 3D display. Figure 5B is a schematic diagram of the right mirror adjustment of the calibration system for creating 3D display. [Main component symbol description] 10 Display 101 Display screen 11 Frame 111 Transparent surface 113 Frame edge 13 Wire 15 Conductor 20 First sensor 30 3D signal transmitter 300 Screen visual device 301 Calibrator 40 Shutter glasses test stand 401 Placement surface 403 Base 405 Support base 50 Left light source 51 Right light source 60 Shutter glasses 61 Left mirror 62 Right mirror 16 M394470 70 Left second sensor 71 Right second sensor 80 Waveform display 90 Left eye test 901 901 First color pattern 91 right eye test face 902 second color pattern