TWI642295B - Optic adaptive system and implementing method thereof - Google Patents
Optic adaptive system and implementing method thereof Download PDFInfo
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Abstract
一種光學調適系統及其實施方法,其係透過網際網路資訊連結於至少一顯示裝置檢測系統,當顯示裝置檢測系統開始檢測一待檢測顯示裝置,並且將所量測到的一輸入項目數據傳送到光學調適系統,使光學調適系統基於輸入與輸出的關係計算出符合需求條件的一調適參數,並將調適參數回傳至顯示裝置檢測系統,進行顯示裝置調試作業,其中,光學調適系統經過數個顯示裝置檢測後,光學調適系統會逐步調整調適區間之範圍,使調適區間接近一實際調試範圍,進而縮短顯示裝置調試作業時間,有效提升整體效率。 An optical adjustment system and an implementation method thereof are connected to at least one display device detection system through an internet information, when the display device detection system starts detecting a to-be-detected display device, and transmits the measured input item data To the optical adjustment system, the optical adjustment system calculates an adjustment parameter that meets the demand condition based on the relationship between the input and the output, and transmits the adjustment parameter back to the display device detection system to perform the debugging operation of the display device, wherein the optical adjustment system passes through the number After the display device is detected, the optical adjustment system will gradually adjust the range of the adjustment interval, so that the adjustment interval is close to an actual debugging range, thereby shortening the debugging operation time of the display device and effectively improving the overall efficiency.
Description
一種光學調適系統,其利用所擷取的多筆顯示裝置的輸入項目數據,透過機器學習(Machine learning)逐步調整輸出的調試參數(範圍、電壓值、亮度、光學數據檢測順序),使光學調適系統可快速計算出一調適參數,縮短顯示裝置調適作業時間的光學調適系統及其實施方法。 An optical adjustment system that utilizes input item data of a plurality of display devices that are captured, and gradually adjusts output debugging parameters (range, voltage value, brightness, optical data detection order) through machine learning to make optical adjustment The system can quickly calculate an adjustment parameter and shorten the optical adjustment system of the display device to adjust the operation time and the implementation method thereof.
顯示裝置(顯示面板)於出廠前皆需進行白平衡調適,使得顯示裝置基於預設Gamma值條件下獲得最佳的顯示效果,過去顯示裝置之調適作業主要以疊代法作為面板調試的主要手法;請參閱「第1圖」,圖中所示為習知之顯示裝置檢測流程圖,如圖,其主要係應用於一顯示裝置檢測系統中,透過顯示裝置檢測系統對一待檢測顯示裝置進行檢測及調適作業,顯示裝置檢測流程包含:檢測顯示裝置步驟:將一個待檢測顯示裝置輸送至顯示裝置檢測系統,以顯示裝置檢測系統驅動待檢測顯示裝置,使待檢測顯示裝置產生光源;擷取數據步驟:顯示裝置檢測系統量測待檢測 顯示裝置的光源,並生成一筆光學檢測數據;計算調適參數步驟:顯示裝置檢測系統以該筆光學檢測數據,於預設的調適區間範圍,以疊代法逐步疊代計算出調適參數;調適顯斥裝置步驟:顯示裝置檢測系統以此調適參數對待檢測顯示裝置進行調適,使調適後的待檢測顯示裝置符合預設Gamma值;當下一個待檢測顯示裝置被輸送至顯示裝置檢測系統,所述的檢測系統會再以相同檢測區間範圍內,以疊代法逐步計算出調適參數。 The display device (display panel) needs to be white balance adjusted before leaving the factory, so that the display device obtains the best display effect based on the preset gamma value. In the past, the adjustment operation of the display device mainly used the iterative method as the main method of panel debugging. Please refer to "Figure 1", which shows a flow chart of the conventional display device detection, as shown in the figure, which is mainly applied to a display device detection system, and detects a display device to be detected through the display device detection system. And adjusting the operation, the display device detecting process comprises: detecting the display device step: conveying a to-be-detected display device to the display device detection system, and the display device detection system driving the display device to be detected, so that the display device to be detected generates a light source; Step: display device detection system measurement to be detected Displaying the light source of the device and generating a piece of optical detection data; calculating the adjustment parameter step: the display device detection system uses the optical detection data of the pen to calculate the adjustment parameter by the iterative method in the preset adjustment interval range; Repelling device step: the display device detecting system adapts the detecting display device with the adjusting parameter, so that the adjusted display device to be detected meets the preset gamma value; when the next device to be detected is sent to the display device detecting system, the The detection system will gradually calculate the adjustment parameters by the iterative method within the same detection interval.
由上述可知,由於每一顯示裝置的表現差異較大,故,須逐一調適各顯示裝置的白平衡值,然而,習知之調適過程係於固定的檢測區間範圍內進行疊代計算,因此無法縮短調適作業的時間;再者,即使工廠開設有多條生產線同時進行調適作業,各條生產線上的顯示裝置檢測系統仍各自獨立作業,此作法將造成作業成本大幅增加,是以,如何縮短調適作業時間,此乃待需解決之問題。 As can be seen from the above, since the performance difference of each display device is large, the white balance value of each display device must be adjusted one by one. However, the conventional adaptation process is performed in the fixed detection interval range for the iterative calculation, and thus cannot be shortened. In addition, even if the factory has multiple production lines and adjustment operations at the same time, the display device detection systems on each production line still operate independently. This method will result in a significant increase in operating costs, so how to shorten the adjustment operation. Time, this is a problem to be solved.
有鑑於上述的問題,本發明人係依據多年來研究顯示裝置檢測之經驗,針對顯示裝置之檢測系統、及其檢測流程進行研究及分析;緣此,本發明之主要目的在於提供一種透過收集、比對多筆調適參數,逐步調整調適區間輸出的光學調適系統及其實施方法。 In view of the above problems, the present inventors conducted research and analysis on the detection system of the display device and the detection flow thereof based on the experience of researching the display device for many years; therefore, the main object of the present invention is to provide a through-collection, The optical adjustment system and its implementation method for adjusting the output of the adaptive interval are compared step by step by adjusting multiple parameters.
為達上述的目的,本發明光學調適系統及其實施方法,光學調適系統係資訊連結於一顯示裝置檢測系統,當顯示裝置檢測系統開始檢測一待檢測顯示裝置,並且將所量測到的一輸入項目數據傳送到光學調適系統,所述的輸入項目數據可例如為各個單色色彩之色座標、灰階值、輝度值、顯示裝置種類、材料特性參數等,使光學調適系統可基於輸入與輸出的關係計算出符合需求條件的一調適參數,並將調適參數回傳至顯示裝置檢測系統,進行顯示裝置調試作業,以使顯示裝置調示完成後達到色溫調整、Gamma調整或白平衡等目的,再者,光學調適系統經過數個顯示裝置檢測後,光學調適系統會逐步調整調適區間之輸出,使調適區間接近一實際調試範圍,達到最佳化調適效果,並進而縮短顯示裝置調試作業時間、提升整體調適效率。 To achieve the above object, the optical adjustment system of the present invention and the method for implementing the same, the optical adjustment system is linked to a display device detection system, and when the display device detection system starts detecting a display device to be detected, and the measured one is measured The input item data is transmitted to the optical adjustment system, and the input item data may be, for example, color coordinates, gray scale values, luminance values, display device types, material property parameters, and the like of the respective monochrome colors, so that the optical adjustment system can be based on the input and the The output relationship calculates an adjustment parameter that meets the demand condition, and transmits the adjustment parameter back to the display device detection system to perform the display device debugging operation, so as to achieve the color temperature adjustment, the gamma adjustment or the white balance after the display device is completed. Furthermore, after the optical adjustment system is detected by several display devices, the optical adjustment system gradually adjusts the output of the adjustment interval, so that the adjustment interval is close to an actual debugging range, thereby achieving an optimal adjustment effect, and thereby shortening the debugging operation time of the display device. Improve overall adjustment efficiency.
為使 貴審查委員得以清楚了解本發明之目的、技術特徵及其實施後之功效,茲以下列說明搭配圖示進行說明,敬請參閱。 In order for your review board to have a clear understanding of the purpose, technical features and effects of the present invention, the following description will be used in conjunction with the illustrations, please refer to it.
10‧‧‧光學調適系統 10‧‧‧Optical adaptation system
101‧‧‧光學調適伺服器 101‧‧‧Optical Adaptation Server
102‧‧‧使用者操作平台 102‧‧‧User operating platform
1011‧‧‧數據處理機 1011‧‧‧Data processor
1012‧‧‧檢測條件資料庫 1012‧‧‧Check condition database
1013‧‧‧數據儲存模組 1013‧‧‧Data storage module
1014‧‧‧調適區間儲存模組 1014‧‧‧Adjustable interval storage module
1015‧‧‧調適參數儲存模組 1015‧‧‧Adjustable parameter storage module
20‧‧‧顯示裝置檢測系統 20‧‧‧Display device detection system
201‧‧‧操作裝置 201‧‧‧Operator
202‧‧‧點亮裝置 202‧‧‧Lighting device
203‧‧‧光學裝置 203‧‧‧Optical device
A1‧‧‧第一調適區間 A1‧‧‧First adjustment interval
A2‧‧‧第二調適區間 A2‧‧‧Second adaptation interval
A3‧‧‧第三調適區間 A3‧‧‧ third adjustment interval
A4‧‧‧第四調適區間 A4‧‧‧Four adjustment interval
P‧‧‧待檢測顯示裝置 P‧‧‧Display display device
S1‧‧‧輸入項目數據 S1‧‧‧Enter project data
S2‧‧‧調適參數 S2‧‧‧Adjustment parameters
Step 1‧‧‧選擇光學檢測條件步驟 Step 1‧‧‧Select optical detection condition steps
Step 2‧‧‧擷取輸入項目數據步驟 Step 2‧‧‧Drawing input project data steps
Step 3‧‧‧計算調適參數步驟 Step 3‧‧‧ Calculate the adjustment parameters
Step 3-1‧‧‧確認調適區間步驟 Step 3-1‧‧‧Confirm the adjustment interval step
Step 3-2‧‧‧於調適區間範圍內計算調適參數步驟 Step 3-2‧‧‧Steps to calculate the adjustment parameters within the adaptation interval
Step 3-3‧‧‧儲存調適參數步驟 Step 3-3‧‧‧Storage adjustment parameters
Step 3-4‧‧‧比對多筆調適參數步驟 Step 3-4‧‧‧Comparison of multiple adjustment parameters
Step 3-5‧‧‧優化調適區間步驟 Step 3-5‧‧‧Optimized adjustment interval steps
Step 4‧‧‧調整顯示裝置步驟 Step 4‧‧‧Adjusting the display device steps
第1圖,為習知之顯示裝置檢測流程圖。 Fig. 1 is a flow chart showing the detection of a conventional display device.
第2圖,為本發明之組成示意圖。 Fig. 2 is a schematic view showing the composition of the present invention.
第3圖,為本發明之組成示意圖(二)。 Figure 3 is a schematic view of the composition of the present invention (2).
第4圖,為本發明之實施流程圖(一)。 Figure 4 is a flow chart (1) of an embodiment of the present invention.
第5圖,為本發明之實施示意圖(一)。 Figure 5 is a schematic view (I) of the implementation of the present invention.
第6圖,為本發明之實施示意圖(二)。 Figure 6 is a schematic view (2) of the implementation of the present invention.
第7圖,為本發明之實施流程圖(二)。 Figure 7 is a flow chart (2) of the implementation of the present invention.
第8圖,為本發明之實施示意圖(三)。 Figure 8 is a schematic view (3) of the present invention.
第9圖,為本發明之另一實施例。 Figure 9 is another embodiment of the present invention.
請參閱「第2圖」,圖中所示為本發明之組成示意圖,如圖,本發明之光學調適系統10,包含有一光學調適伺服器101及一使用者操作平台102,所述的光學調適伺服器101具有一數據處理機1011,另包含有一檢測條件資料庫1012、一數據儲存模組1013、一調適區間儲存模組1014、及一調適參數儲存模組1015與數據處理機1011完成資訊連結;所述的數據處理機1011係可以運行光學調適系統10,其可將收集到的一輸入項目數據,以符合預設Gamma值規定計算出一調適參數,其可以為中央處理器(Central Processing Unit,CPU)、微處理控制器(Microprocessor Control Unit,MCU);所述的檢測條件資料庫1012為虛擬元件,儲存有至少一筆光學檢測條件,其中,所述的光學檢測條件為機器學習的演算法,例如,人工神經網路(artificial neural network)、決策樹(Decision tree)、感知器(Perceptron)、支援向量機(Support Vector Machine)、整合學習(AdaBoost)、聚類分析(Cluster analysis)、線性判別分 析(Linear Discriminant Analysis)、徑向基函式核(Radial basis function kernel)、最大期望演算法(Expectation-maximization algorithm)、馬爾可夫鏈(discrete-time Markov chain)、蒙特卡羅方法(Monte Carlo method)、迴歸分析(Regression Analysis)、主成分分析(principal component analysis,PCA)、偏最小二乘(partial least squares,PLS)、多變量統計建模方法(Multivariable statistical process control,MSPC)等,但凡任一種機器學習演算法,皆可實施,不以此為限,特先陳明;所述的數據儲存模組1013為虛擬元件,可供儲存至少一輸入項目數據,供數據處理機1011計算出調適參數,再者,所述的輸入項目數據可例如為各個單色色彩之色座標值、灰階值、輝度值、白平衡數值、色溫和面板特徵值其中一種、或其組合;所述的調適區間儲存模組1014供以儲存至少一調適區間之數據,所述的調適區間初始時可設定為預設的範圍,數據處理機1011可再依據多筆輸入項目數據調整其輸出(範圍、電壓值、亮度、光學數據檢測順序);所述的調適參數儲存模組1015為虛擬元件,供以儲存至少一調適參數,所述的調適參數係數據處理機1011依據輸入項目數據,於調適區間範圍內以疊代法取得,再者,調適參數係影響顯示裝置的輸出表現(例如:色溫、白平衡或Gamma等);所述的使用者操作平台102係資訊連結於光學調適伺服器101,再者,使用者操作平台102係虛擬之操作元件,提供使用者虛擬操作介面,使用者可透過一電子資 訊裝置連線至使用者操作平台102,對光學調適伺服器101進行相關操作及設定。 Please refer to FIG. 2, which is a schematic diagram of the composition of the present invention. As shown in the figure, the optical adjustment system 10 of the present invention comprises an optical adjustment server 101 and a user operation platform 102, and the optical adjustment is performed. The server 101 has a data processor 1011, and further includes a detection condition database 1012, a data storage module 1013, an adaptation interval storage module 1014, and an adaptation parameter storage module 1015 and a data processor 1011 to complete the information connection. The data processor 1011 can run the optical adaptation system 10, which can calculate an adjusted parameter according to a preset gamma value, which can be a central processing unit (Central Processing Unit). , a CPU, a Microprocessor Control Unit (MCU); the detection condition database 1012 is a virtual component, and at least one optical detection condition is stored, wherein the optical detection condition is a machine learning algorithm. For example, artificial neural network, decision tree, perceptron, support vector machine (Support) Vector Machine), integrated learning (AdaBoost), cluster analysis (Cluster analysis), linear discriminant Linear Discriminant Analysis, Radial basis function kernel, Expectation-maximization algorithm, Discrete-time Markov chain, Monte Carlo method (Monte Carlo) Method), regression analysis (regression analysis), principal component analysis (PCA), partial least squares (PLS), multivariable statistical process control (MSPC), etc. Any of the machine learning algorithms can be implemented, and is not limited thereto. The data storage module 1013 is a virtual component for storing at least one input item data for the data processor 1011 to calculate. Adjusting parameters, wherein the input item data may be, for example, one of a color coordinate value, a grayscale value, a luminance value, a white balance value, a color temperature, and a panel characteristic value of each monochrome color, or a combination thereof; The adaptive interval storage module 1014 is configured to store data of at least one adaptation interval, and the adaptation interval may be initially set to a preset range, and the data The processor 1011 can further adjust its output (range, voltage value, brightness, optical data detection order) according to the plurality of input item data; the adjustment parameter storage module 1015 is a virtual component for storing at least one adjustment parameter. The adjustment parameter data processor 1011 obtains the iterative method within the range of the adaptation interval according to the input item data, and further, the adjustment parameter affects the output performance of the display device (for example, color temperature, white balance or gamma, etc.); The user operation platform 102 is connected to the optical adaptation server 101. Further, the user operation platform 102 is a virtual operation component, and provides a virtual operation interface for the user. The device is connected to the user operating platform 102 to perform related operations and settings on the optical adaptation server 101.
請參閱「第3圖」,圖中所示為本發明之組成示意圖(二),如圖,本發明之光學調適系統10係透過網際網路資訊連接於至少一顯示裝置檢測系統20,所述的顯示裝置檢測系統20可供檢測及調適顯示裝置,其包含有一操作裝置201、一點亮裝置202及一光學裝置203,所述的操作裝置201可供使用者進行操作,且操作裝置201用以控制點亮裝置202及光學裝置203,操作裝置201係透過網際網路資訊連接至光學調適伺服器101,使操作裝置201可將輸入項目數據傳送至光學調適伺服器101、及接收自光學調適伺服器101所傳送的調適參數,並依據調適參數對顯示裝置進行調適作業;所述的點亮裝置202用以驅動顯示裝置作動;所述的光學裝置203用以量測顯示裝置的光學特性或材質特性,並進一步生成輸入項目數據,例如:單個單色色彩之色座標、灰階值、輝度值或材料特性等。 Please refer to FIG. 3, which shows a schematic diagram (2) of the present invention. As shown in the figure, the optical adjustment system 10 of the present invention is connected to at least one display device detection system 20 via internet information. The display device detecting system 20 is configured to detect and adapt the display device, and includes an operating device 201, a lighting device 202 and an optical device 203. The operating device 201 is operable by a user, and the operating device 201 is used. To control the lighting device 202 and the optical device 203, the operating device 201 is connected to the optical adaptation server 101 via the Internet information, so that the operating device 201 can transmit the input item data to the optical adaptation server 101, and receive the optical adaptation. The adjustment parameter transmitted by the server 101, and the display device is adapted according to the adjustment parameter; the lighting device 202 is used to drive the display device to operate; the optical device 203 is used to measure the optical characteristics of the display device or Material properties, and further generate input project data, such as: color coordinates of a single monochrome color, grayscale values, luminance values or material properties.
請參閱「第4圖」,圖中所示為本發明之實施流程圖(一),並請搭配「第5圖」~「第6圖」,圖中所示為本發明之實施示意圖(一)~(二),如圖,本發明之實施流程,其包含:(1)選擇光學檢測條件步驟Step 1:使用者以一電子資訊裝置係資訊連結至使用者操作平台102,完成資訊連接 後,使用者操作平台102可擷取檢測條件資料庫1012中所儲存的複數筆光學檢測條件,並顯示於使用者操作平台102上以供使用者選擇,使用者選擇完畢後,光學調適伺服器101即可使用所選定的光學檢測條件,將其設定為調適作業計算的基礎;其中,若同時有複數個使用者連線至使用者操作平台102時,光學調適伺服器101可個別記錄各個使用者所設定之光學檢測條件,並彼此分別獨立運行;(2)擷取輸入項目數據步驟Step 2:光學檢測條件選擇完畢後,使用者可以操作裝置201驅動點亮裝置202與光學裝置203,當點亮裝置202被驅動後,點亮裝置202係可驅動一待檢測顯示裝置P,另以光學裝置203量測該待檢測顯示裝置P,量測完畢後,光學裝置203可生成一輸入項目數據S1,並將該筆數據傳送至光學調適系統10;(3)計算調適參數步驟Step 3:當光學調適系統10接收到輸入項目數據S1後,光學調適系統10可以於一調適區間範圍內,以疊代法計算出一調適參數S2,將該調適參數S2傳送回操作裝置201,並儲存於光學調適系統10,其中,光學調適系統10可進一步比對最近所擷取到的至少二筆調適參數S2後,依據比對結果調整所述的輸出(範圍、電壓值、亮度、光學數據檢測順序);(4)調整顯示裝置步驟Step 4:當操作裝置201接收到調適參數S2後,操作裝置201可基於調適參數S2調整待檢測 顯示裝置P;下一待檢測顯示裝置P進行檢測時,則由擷取輸入項目數據步驟Step 2開始,無需再重新設定光學檢測條件,其餘顯示裝置之檢測流程同上,不再予以贅述,又,重複上述流程可得到最佳調適參數,進而縮短調適的時間。 Please refer to "4th figure", which shows the flow chart (1) of the present invention, and please refer to "5th figure" to "6th figure", which shows a schematic diagram of the implementation of the present invention (1) And (2), as shown in the figure, the implementation process of the present invention includes: (1) selecting an optical detection condition step Step 1: the user connects to the user operation platform 102 by using an electronic information device information to complete the information connection. After that, the user operating platform 102 can capture the plurality of optical detection conditions stored in the detection condition database 1012 and display them on the user operation platform 102 for the user to select. After the user selects, the optical adjustment server is selected. 101 can use the selected optical detection conditions to set the basis of the adjustment operation calculation; wherein, if a plurality of users are connected to the user operation platform 102 at the same time, the optical adaptation server 101 can record each use individually. The optical detection conditions set by the user are independently operated independently of each other; (2) the input item data is captured. Step 2: After the optical detection condition is selected, the user can operate the device 201 to drive the lighting device 202 and the optical device 203. After the lighting device 202 is driven, the lighting device 202 can drive a display device P to be detected, and the optical device 203 measures the display device P to be detected. After the measurement is completed, the optical device 203 can generate an input item data. S1, and transmitting the data to the optical adjustment system 10; (3) calculating the adjustment parameter step Step 3: when the optical adjustment system 10 receives the input item According to S1, the optical adjustment system 10 can calculate an adjustment parameter S2 in an adaptive manner within an adaptation interval, and transmit the adjustment parameter S2 back to the operation device 201, and store it in the optical adjustment system 10, wherein the optical adjustment system The system 10 may further compare the output (range, voltage value, brightness, optical data detection order) according to the comparison result after comparing at least two adaptation parameters S2 recently obtained; (4) adjusting the display device step Step 4: After the operation device 201 receives the adjustment parameter S2, the operation device 201 can adjust the to-be-detected based on the adjustment parameter S2. The display device P; when the next to-be-detected display device P performs the detection, the step of extracting the input item data is performed in step 2, and the optical detection condition is not required to be reset. The detection process of the other display devices is the same as above, and will not be described again. Repeat the above process to get the best adjustment parameters, which will shorten the adjustment time.
請參閱「第7圖」,圖中所示為本發明之實施流程圖(二),如圖,本發明之計算調適參數步驟Step 3更包含有:(1)確認調適區間步驟Step 3-1:光學調適系統10接收到輸入項目數據S1後,數據處理機1011會執行所選定的光學檢測條件,並且,數據處理機1011會於調適區間儲存模組1014,確認該次檢測作業的一調適區間是否有更新?若是,則數據處理機1011會選擇最新調適區間進行運算,若否,則數據處理機1011進行下一步驟;(2)於調適區間範圍內計算調適參數步驟Step 3-2:調適區間確認完成後,數據處理機1011會基於輸入項目數據S1,於調適區間範圍內計算出符合需求條件的調適參數S2,並將調適參數S2傳送至顯示裝置檢測系統20;(3)儲存調適參數步驟Step 3-3:當數據處理機1011計算出調適參數S2後,數據處理機1011會將調適參數S2儲存於調適參數儲存模組1015;(4)比對多筆調適參數步驟Step 3-4:當調適參數S2完成儲存後,數據處理機1011會將最新的調適參數S2,比對 數據儲存模組1013內最近儲存的至少二筆調適參數S2,並產生一比對結果;(5)優化調適區間步驟Step 3-5:請搭配「第8圖」,圖中所示為本發明之實施示意圖(三),如圖,數據處理機1011會依據比對結果重新調整該調適區間之輸出(範圍、電壓值、亮度、光學數據檢測順序),並且儲存於調適區間儲存模組1014,如圖中舉例:一第一調適區間A1為初始顯示裝置的調適範圍,一第二調適區間A2為第二片顯示裝置的調適範圍,一第三調適區間A3為第N-1片顯示裝置的調適範圍,一第四調適區間A4為第N片顯示裝置的調適範圍,由此圖可知,經過優化調適區間步驟Step 3-5後,第一調適區間A1係逐漸縮小範圍至第四調適區間A4,由於第四調適區間A4的疊帶範圍小於第一調適區間A1,因此,數據處理機1011可以快速計算出該顯示裝置符合需求條件的調適參數S2。 Please refer to FIG. 7 , which is a flowchart (2) of the implementation of the present invention. As shown in the figure, the step 3 of calculating the adjustment parameter of the present invention further includes: (1) confirming the adaptation interval step Step 3-1 After the optical adjustment system 10 receives the input item data S1, the data processor 1011 performs the selected optical detection condition, and the data processor 1011 adjusts the interval storage module 1014 to confirm an adjustment interval of the detection operation. Is there an update? If so, the data processor 1011 selects the latest adaptation interval for calculation. If not, the data processor 1011 performs the next step; (2) calculates the adjustment parameter within the adaptation interval. Step 3-2: After the adjustment interval is confirmed The data processor 1011 calculates the adaptation parameter S2 that meets the requirement condition within the adaptation interval based on the input item data S1, and transmits the adjustment parameter S2 to the display device detection system 20; (3) stores the adjustment parameter step Step 3- 3: After the data processor 1011 calculates the adjustment parameter S2, the data processor 1011 stores the adjustment parameter S2 in the adjustment parameter storage module 1015; (4) compares the multiple adaptation parameters step Step 3-4: when the adjustment parameter After S2 completes the storage, the data processor 1011 compares the latest adaptation parameters S2. At least two adaptation parameters S2 stored in the data storage module 1013 and generating a comparison result; (5) optimizing the adaptation interval step 3-5: please match "8th figure", which is shown in the figure The implementation diagram (3), as shown in the figure, the data processor 1011 re-adjusts the output of the adaptation interval (range, voltage value, brightness, optical data detection order) according to the comparison result, and stores it in the adaptation interval storage module 1014. For example, a first adaptation interval A1 is an adaptation range of the initial display device, a second adaptation interval A2 is an adaptation range of the second display device, and a third adaptation interval A3 is an N-1 display device. The adjustment range, a fourth adjustment interval A4 is an adaptation range of the Nth display device, and thus the figure shows that after the optimized adjustment interval step Step 3-5, the first adjustment interval A1 gradually narrows the range to the fourth adjustment interval A4. Since the stacking range of the fourth adaptive section A4 is smaller than the first adaptive section A1, the data processor 1011 can quickly calculate the adaptation parameter S2 that the display apparatus meets the demand condition.
上述實施例中,其主要係以單一顯示裝置檢測系統20為例,當複數個顯示裝置檢測系統20同時資訊連結至光學調適伺服器101時,光學調適伺服器101可分別計算出各顯示裝置檢測系統20所需之調適參數,意即,光學調適系統10可同步支援複數顯示裝置檢測系統20,其實施方式請參閱「第4圖」~「第8圖」,不再予以贅述。 In the above embodiment, the single display device detection system 20 is mainly taken as an example. When a plurality of display device detection systems 20 are simultaneously connected to the optical adaptation server 101, the optical adaptation server 101 can separately calculate each display device detection. The adjustment parameters required by the system 20, that is, the optical adjustment system 10 can synchronously support the plurality of display device detection systems 20. For the implementation of the system, please refer to "Fig. 4" to "Fig. 8", and details are not described herein.
請參閱「第9圖」,圖中所示為本發明之另一實施例,如圖,本發明之光學調適系統10,其中,所述的使用者操作平台102係可進一步建置於顯示裝置檢測系統20中,與顯示裝置檢測系統20完成資訊連結,若操作環境並不提供網際網路連線服務時,即可將操作平台102建置於顯示裝置檢測系統20中,使用者即可以操作平台102進行相關操作。 Please refer to FIG. 9 , which shows another embodiment of the present invention. As shown in the figure, the optical adjustment system 10 of the present invention, wherein the user operating platform 102 can be further built into the display device. In the detecting system 20, the information connection with the display device detecting system 20 is completed. If the operating environment does not provide the Internet connection service, the operating platform 102 can be built in the display device detecting system 20, and the user can operate. Platform 102 performs related operations.
綜上所述,本發明所稱之光學調適系統及其實施方法,其包含有一光學調適伺服器及一使用者操作平台,使用者透過使用者操作平台,可由遠端對光學調適伺服器設定一光學檢測條件,光學調適伺服器另透過網際網路資訊連結於一顯示裝置檢測系統,當顯示裝置檢測系統開始檢測一待檢測顯示裝置,並且將所量測到的一輸入項目數據傳送到光學調適伺服器後,光學調適伺服器即可由一調適區間範圍內,計算出需求條件的一調適參數,並將調適參數回傳至顯示裝置檢測系統進行調適,又,當光學調適伺服器儲存有多筆調適參數,光學調適伺服器會比對至少兩筆最新的調適參數,依據比對結果調整調適區間的輸出(範圍、電壓值、亮度、光學數據檢測順序),使調適區間接近一實際調試範圍;依此,本發明其據以實施後,確實可達到提供一種透過收集、比對多筆調適參數,逐步調整調適區間範圍的光學調適系統及其實施方法之目的。 In summary, the optical adaptation system and the implementation method thereof include an optical adjustment server and a user operation platform, and the user can set the optical adaptation server by the remote end through the user operation platform. Optical detection conditions, the optical adaptation server is further connected to a display device detection system through the Internet information, when the display device detection system starts detecting a to-be-detected display device, and transmits the measured input item data to the optical adjustment After the server, the optical adjustment server can calculate an adjustment parameter of the demand condition from an adaptation interval, and transmit the adjustment parameter back to the display device detection system for adjustment, and when the optical adjustment server stores multiple pens Adjusting the parameters, the optical adjustment server compares at least two latest adjustment parameters, and adjusts the output of the adjustment interval (range, voltage value, brightness, optical data detection order) according to the comparison result, so that the adaptation interval is close to an actual debugging range; Accordingly, the present invention can be implemented to provide a through-collection, Multi adaptation parameter for pens, gradual adjustment section adapted range adaptive optics system and method of embodiments of purposes.
唯,以上所述者,僅為本發明之較佳之實施例而已,並非用以限定本發明實施之範圍;任何熟習此技藝者,在不脫離本發明之精神與範圍下所作之均等變化與修飾,皆應涵蓋於本創作之專利範圍內。 The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention; any changes and modifications made by those skilled in the art without departing from the spirit and scope of the invention , should be covered by the scope of this creation patent.
綜上所述,本發明之功效,係具有發明之「產業可利用性」、「新穎性」與「進步性」等專利要件;申請人爰依專利法之規定,向 鈞局提起發明專利之申請。 In summary, the effects of the present invention are patents such as "industry availability," "novelty," and "progressiveness" of the invention; the applicant filed an invention patent with the bureau in accordance with the provisions of the Patent Law. Application.
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Citations (4)
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TWI316822B (en) * | 2006-08-30 | 2009-11-01 | Marketech Int Corp | |
TWI566579B (en) * | 2015-12-04 | 2017-01-11 | 瑞軒科技股份有限公司 | Detecting device for display and detecting method thereof |
TW201709189A (en) * | 2015-08-21 | 2017-03-01 | Cybernet Systems Co Ltd | White balance adjustment device and white balance adjustment method effectively adjusting the white balance and brightness of an RGB type organic EL display |
CN106686280A (en) * | 2015-11-06 | 2017-05-17 | 财团法人工业技术研究院 | Image repairing system and method thereof |
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Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
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TWI316822B (en) * | 2006-08-30 | 2009-11-01 | Marketech Int Corp | |
TW201709189A (en) * | 2015-08-21 | 2017-03-01 | Cybernet Systems Co Ltd | White balance adjustment device and white balance adjustment method effectively adjusting the white balance and brightness of an RGB type organic EL display |
CN106686280A (en) * | 2015-11-06 | 2017-05-17 | 财团法人工业技术研究院 | Image repairing system and method thereof |
TWI566579B (en) * | 2015-12-04 | 2017-01-11 | 瑞軒科技股份有限公司 | Detecting device for display and detecting method thereof |
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