M306693 八、新型說明: 【新型所屬之技術領域】 〃本創作铩有關一種雷射输入裝置之光學結構々特別濟 及一種光學輸入裝置具有分束器,使經反射後的雷射 2由分束器分別反射二道頻率相同且相交會之軸向光 並於―道轴向光束之父會處成像光干涉條紋圖樣,妹 $感測干涉條紋圖樣的變化,進一步判讀輸入裝置於工; 表面之位移方向以及位移距離資枓 曾判-於入壯里… 科達到靈敏且精確的計 項輸入I置位移之方向及距離。 【先前技術】 按’隨著科技的進步與發展,電腦已經成為人類 中所不可或缺的一部份,而輪 、/ 備,為配人電腦日斩Λ / 係電腦必備之周邊設 鍵盤等等)也在不斷更新研發以 ^如·心、 輔助並替代體積龐大的鍵盤«控性’可 路的馳,滑鼠更具有無可替代的^/。媒體以及網際網 目前市面上所販售之滑鼠 械滑鼠與光學滑鼠,機械滑氣主要^在=上可以分為機 球,利用移動滑鼠使軌__要# 部設一執跡 於滑鼠内之感測元件,進 μ執跡球帶動設 機械滑鼠之優點係技術門心异^滑鼠移動之距離,該型 軌跡球在滾動的過程中易麻Ζ貝私便且,惟其缺點則是 物帶入滑鼠内部而逐漸累:貝,且各易將桌上的灰塵及污 “斤累積,經長期使用當累積到一定程 M306693 度後即會對㈣鼠之正常運作產定之影響,導致機械 滑氡1¾使用時間增長.而精確度降低。 蠢#滑鼠的技衡原理在轸_墨壶源(通常為__藏) 將光照射到目標表面上,在一定時間内擷取俸回癒反漸光 束’靠著每秒多次的掃描擷取,經由比 移動的方向,錢定滑鼠移動了多少‘/Hu 由於光學滑鼠則係直接利用光學原理,因此並無前述 機械滑鼠易磨損、積灰塵之問題產生,但其缺點則是其結 f相對較為複雜,導致其製造成本相對較高。由於光學滑 鼠的反應速度依賴滑鼠擷取影像的精確度,除了依靠光感 測益的像素大小外,自目標表面反射的光束是否能適當地 被光感測器清晰擷取,也連帶的影響了精確度,因此,能 達到越適當的之反射光束擷取的光學滑鼠,其精確度也較 好0 目岫市場上習用的光學滑鼠,如專利證號245538號 案戶斤示的光學滑乳結構改良」,係具有一用來發射光束 之光源(導光投射元件)及光感測器(影像感測元件)所組 成。 其中该光感測器係向下正對目標表面,並斜切光束之 光反射路徑,因此當遇目標表面而反射之光束沿光反射路 徑通過時,恰可與該光感測器相切,使光感測器擷取通過 之光束,並作影像分析。當光源(導光投射元件)投射至目 標表面即會產生不同大小明暗的光影、透過光感測器(影 像感測元件)持續不斷的擷取影像,來感測滑鼠在目標表 面上移動所造成光束所照射目標表面上定點的不同,反射 M306693 光東之差異’及利用後端訊號處埋元件準確的計算出滑鼠 移動之距離與方向。 的說明中可以清管的發現諉光學滑鼠能否精確計算滑鼠 位移的距離與方向,完全與光源所產生之照明光源的投射 與工作桌面產生不同大小明暗的光影是否良好有絕對的 關係。 —然如上述構造,由於光束在自目標表面反射後,往往 會有嚴重散光現象’當光感測器在接收目標表面反射的光 ,亦會有光束耗損、不足,而導致影像分析資料不足, 無法精確的計算滑鼠位移之距離及方向,使滑鼠游標顯示 跳動、偏絲情況,導致光學滑鼠錢作錄 提昇及降低使用方便性。 士本案創作人有鑑於上述習用的光學滑鼠於實際施用 日守的缺失,且積累個人從事相關產業開發實務上多年之經 驗,精心研究,終於研發出一種雷射輸入裝置之光學結構: 【新型内容】 本創作之主要目#,旨在提供一種雷射輸入裝置之光 =、、。構利_用具束集性之雷射作為光源,並使經反射後的 雷射光束經由分束器分別反射二道頻率相同且相交會之 ^向光束’亚於二道軸向光束之交會處成像光干涉條紋圖 取,經由感測干涉條紋圖樣的變化,進一步判讀輸入裝置 面之位移方向以及位移距離㈣,達到靈敏且精 隹的计异判讀輸人裝置位移之方向及距離。 為了達到上述目的,本創作係提供一種雷射輸入裝置 M306693 之光學結構,其包含:一輸入裝置本體; 述輸ί裝置本體内,用以提供一直線投:射之:光 Α „ ./〇 : Γ ΐ 一第一介面鳴及一位於第一介面後端之第二介面,且 ,弟一介面以及該第二介面恰分別位於雷射光束之光反 射路控上,使該第一介面以及該第二介面分別反射一頻率 相同且t目交會之軸向光束;一光感測器,係位於該二轴向 光束之父g處’用以感測該一軸向光束交會所成像之光干 涉條紋圖樣。 如上述構造,當輸入裝置本體進行移動時,藉由光感 測器讀取光干涉條紋圖樣的變化,來對應判斷輸入裝置^ 體於工作表面之位移方向以及位移距離資料。 、為使能更進一步瞭解本創作之特徵及技術内容,請參 閱以下有關本創作之詳細說明與附圖,然 供參考與說明用,並非用來對本創作加以限ϋ0式僅k 【實施方式】 首先,請苓閱第一圖、第二圖、第三圖、第四圖、第 五圖以及第六圖所示,本創作係包含··一輸入裝置本體 1、一雷射光源2、一透鏡座3、一分束器4以及一光感 ’貝J ™ 5,其中,该雷射光源2係設於上述輸入裝置本體1 内,用以提供一直線投射之雷射光束a,沿一入射角度係 介於25〜45度之間之入射路徑傳遞至工作表面6上。 该分束器4係設於上述該透鏡座3中,且恰位於雷射 光束a之反射路徑上。該分束器4係呈一透明二形鏡^, 具有一第一介面41以及一位於第一介面41後端之第 M306693 =w面4 2,該第一介面41與該第二介面4 2間之夾角 係’丨於0· 1〜1〇度之間,且該第一介面4 1以及第二介面 4 2分喇:位於t射先涑级之先__路_1,使:自 6反射之反射光束b部分·該:第一介面4 p表 ,第一反射軸向光束c,且該反射光束b部分自該第一 二面4 1牙透,折射形成一第一折射軸向光束d至該第二 介面4 2,該第一折射軸向光束d於該第二介面42表面 ^射形成一第二反射軸向光束e,該第二反射軸向光束e 牙透該第介面4 1,而折射形成一第二折射軸向光束 f ,該第二折射軸向光束f恰與該第一反射軸向光束c且 相父會,且該第一反射轴向光束c與該第二折射軸向光束 "頁率相同,而於該第一反射軸向光束c與該第二折射軸 向光束f交會處成像之光干涉條紋圖樣g。 該透鏡座3係設於輸入裝置本體1内,且該透鏡座3 k位於田射光束a之入射路徑以及反射路徑上,於該透鏡 座3二侧具有一固定槽3 1,恰對應容納該雷射光源2、, ^於A透鏡座3頂端具有-凹人部3 2,恰對應該光感測 器5 ;該透鏡座3之固定槽3 i底部具有一第一透鏡3 3 恰位於雷射光束3之人射路徑上,供該雷射光束a通過。 該透鏡座3内具有—第二透鏡3 4恰位於該分束哭4鱼 該光感測器5之間,且恰使該第—介面4 i反射之該第二 反射軸向光束c以及該第二介面4 2反射之該第二斤射 轴向光束f通過。 該光感測器5係對應容設上述凹入部3 2中定位,且 該光感測器5恰位於該第一反射轴向%束c肖該第二折 9 M306693 射軸向先束;f交會處,用以感測該第一反射軸向光束0與 該第二折射軸向光束f交會所成像之光干涉條紋圖樣g。 、知止逃構趣V依第一圖第%'第玉爾以:黏 所示,由於輸人裝置本體1何’ 该固定槽3 1對應容納該雷射光源2以及該透鏡座3頂 ^具有該凹入部3 2對應設置該光感測器5,使該雷射光 源2與該光感測器5兩者相對位置固定易定位。啟動操作 時’雷射光源2所直線投射之雷射光束a,沿一入射角度 25〜45度間之入射路徑穿過該透鏡座3之第一透鏡3 3傳 遞至工作表面6,當雷射光束a遇到工作表面6的阻擋而 反射形成一反射光束b投射至位於反射路徑上該分束器 4之第一介面4 1,該反射光束b部分於該第一介面4工 表面反射形成一第一反射軸向光束c, -部分自該第-介面41穿透,折射形成 先束d投射至該第二介面4 2,該第一折射軸向光束^ 該第=介面4 2表面反射形成一第二反射軸向光束e投 =該第一介面4 1,且該第二反射軸向光束6穿透該第一 "面4 1,而折射形成一第二折射軸向光束f,嗲第二 合與該第一反射軸向光束C相交會並:別 牙,:亥,鏡座3之第二透鏡3 4,且該第—反射轴向 二=弟二折射—軸向光束"員率相同,而於該第—反 " ^與该第二折射軸向光束f交會處成像之+ ί紋^感測器5來感測讀取干涉條紋‘ g田輸入衣置本體1於工作表面6上進杆Pi 士 該光感測器5每秒多次的掃描揭取二動:樣= M306693 像,來分析比對,來判斷輸入裝置本體汀 ^ ^ ^t # ^ A 11, ,s f ^ 6 ^ 對應移動的杂向:食距'離%且測量靈敏度可細由=°。上為4π f -# ® 4 1 ^ φ 4 2 4^~' 度的範圍内調節。 用係力於H); 1-10 如上述實施例可知,本創作具有下列優點. 作採用讀取光干涉條紋圖樣g來對應判斷方 =^位,距離資料,改善傳統光學結構接收單一反射 而提曰r::工作表面6光滑而會有嚴重散光現象,進 而徒歼刼作靈敏度。 ^ ^ 2落H射滑鼠”光學結構㈣,導致製作良率低 、酋對難以提高。本創作利用分束器分別反射 =軸向光束’經由感測二道轴向光束之交會處干涉條 紋圖樣的變化來判靖# # t &、 y、 ^ M ^ ^ σ私方向以及位移距離資料;由於 、σ構間早’製作良率相對提高,同時也使產能大幅提昇。 太名二上戶J述?為本創作之較佳可行實施例,非因此侷限 新么0则巳圍’故舉凡運用本創作說明書及圖示内容 所為之纽技術變化,均包含於本創作之範圍内。 【圖式簡單說明】 第一圖係本創作之剖視示意圖。 第二圖係本創作透鏡座與分束器之立體示意圖 第三圖係本創作光源與域測器之Μ裝示意圖 第四圖係本㈣之局部剖視示意圖。 第五圖係本創作之光學運動示意圖。 第六圖係光干涉現象示意圖。 11 M306693 【主要元件符號說明】 [本創作] 顯 --* . y: . 2 —光源 3 —透鏡座 3 1 —固定槽 3 2 —凹入部 3 3 —第一透鏡 3 4 —第二透鏡 4 一分束器 4 1 一第一介面 4 2 —第二介面 5 —光感測器 6 —工作表面 a —雷射光束 b —反射光束 c —第一反射轴向光束 d —第一折射轴向光束 e —第二反射轴向光束 f 一第二折射轴向光束 g —干涉條紋圖樣M306693 VIII. New description: [New technical field] 〃本作铩 The optical structure of a laser input device, especially an optical input device with a beam splitter, so that the reflected laser 2 is split by the beam The device respectively reflects two axial beams of the same frequency and intersecting, and images the interference fringe pattern at the parent of the axial beam, and senses the change of the interference fringe pattern to further interpret the input device; The direction of displacement and the distance of the displacement have been judged - in the Zhuangli... The class achieves a sensitive and accurate calculation of the direction and distance of the I input displacement. [Prior Art] According to the advancement and development of science and technology, computers have become an indispensable part of human beings, and the wheel and/or equipment are equipped with keyboards for computers, computer keyboards, etc. Etc.) is also constantly updating the research and development to replace the bulky keyboard «controllable", the mouse has an irreplaceable ^/. The media and the Internet are currently selling the mouse-and-mouse mouse and optical mouse on the market. The mechanical slippery air can be divided into the ball on the =, using the mobile mouse to make the track __要# The sensing component in the mouse, the advantage of the mechanical ball in the mouse is the distance of the mechanical door. The distance of the mouse is easy to numb in the process of rolling. However, the shortcoming is that the object is brought into the interior of the mouse and gradually becomes tired: it is easy to accumulate dust and dirt on the table. After long-term use, it will accumulate to a certain range of M306693 degrees. The effect of the mechanical slippery 13⁄4 use time increases and the accuracy is reduced. Stupid #The technical principle of the mouse is in the 轸 _ ink pot source (usually __ hiding) to illuminate the target surface for a certain period of time撷 俸 俸 俸 俸 ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' ' The aforementioned mechanical mouse is prone to wear and dust, but its disadvantages The result is relatively complicated, which results in a relatively high manufacturing cost. Since the response speed of the optical mouse depends on the accuracy of the image captured by the mouse, the light beam reflected from the target surface is in addition to the pixel size of the light-sensing benefit. Whether it can be properly captured by the light sensor, but also affects the accuracy. Therefore, the optical mouse that can achieve the more appropriate reflected beam is better. The accuracy is also good. An optical mouse, such as the optical slider structure modified by the patent No. 245538, has a light source (light guiding projection element) for emitting a light beam and a photo sensor (image sensing element). composition. Wherein the light sensor is directed downward to the target surface and obliquely cuts the light reflection path of the light beam, so that when the reflected light beam passes through the light reflection path, it is tangent to the light sensor. The light sensor is taken through the beam and analyzed for image. When the light source (light-guiding projection element) is projected onto the target surface, light and shadow of different sizes are generated, and the image is continuously captured by the light sensor (image sensing element) to sense the movement of the mouse on the target surface. Causes the difference in the fixed point on the target surface illuminated by the beam, reflects the difference of M306693 light east and uses the buried component at the back end signal to accurately calculate the distance and direction of the mouse movement. In the description, it can be found that the optical mouse can accurately calculate the distance and direction of the displacement of the mouse, and the projection of the illumination source generated by the light source is absolutely related to whether the light and shadow of different sizes are bright and good on the working table. - However, as described above, since the light beam is reflected from the target surface, there is a serious astigmatism phenomenon. When the light sensor reflects light on the target surface, the light beam is worn out and insufficient, resulting in insufficient image analysis data. It is impossible to accurately calculate the distance and direction of the mouse displacement, so that the mouse cursor displays the beating and partial wire condition, which leads to the improvement of the optical mouse money recording and the ease of use. In view of the above-mentioned lack of practical application of the optical mouse, and the accumulation of personal experience in the relevant industry development practice, the creators of the present case finally developed an optical structure of a laser input device: Content] The main purpose of this creation is to provide a laser input device light =,,. The laser beam is used as a light source, and the reflected laser beam is respectively reflected by the beam splitter to two intersections of the same frequency and intersecting beams of light, which are adjacent to the two axial beams. The imaging light interference fringe pattern is taken, and the displacement direction and the displacement distance of the input device surface are further interpreted by sensing the change of the interference fringe pattern (4), and the direction and distance of the displacement of the input device are determined by the sensitive and precise calculation. In order to achieve the above object, the present invention provides an optical structure of a laser input device M306693, which comprises: an input device body; and a device for providing a straight line projection: a light Α „./〇: ΐ ΐ a first interface sounding and a second interface at the rear end of the first interface, and the first interface and the second interface are respectively located on the light reflection path of the laser beam, so that the first interface and the first interface The second interface respectively reflects an axial beam having the same frequency and t mesh intersection; a photo sensor is located at the parent g of the biaxial beam to sense the optical interference imaged by the axial beam intersection According to the above configuration, when the input device body moves, the change of the optical interference fringe pattern is read by the photo sensor, and the displacement direction and the displacement distance data of the input device body are determined correspondingly. To further understand the features and technical content of this creation, please refer to the following detailed description and drawings for this creation, for reference and explanation, not to limit this creation. Only k [Embodiment] First, please refer to the first diagram, the second diagram, the third diagram, the fourth diagram, the fifth diagram, and the sixth diagram. The creation system includes an input device body 1. a laser light source 2, a lens holder 3, a beam splitter 4, and a light-sensing 'Be JTM 5, wherein the laser light source 2 is disposed in the input device body 1 to provide a laser for direct projection The beam a is transmitted to the working surface 6 along an incident path having an incident angle of between 25 and 45 degrees. The beam splitter 4 is disposed in the lens holder 3 and is located just above the laser beam a. In the reflection path, the beam splitter 4 is a transparent dimorphic mirror, having a first interface 41 and a first M306693=w surface 4 2 at the rear end of the first interface 41. The first interface 41 and the first interface 41 The angle between the two interfaces of the two interfaces is between '0' and 1 to 1 degree, and the first interface 4 1 and the second interface 4 2 are separated: the first step of the t-ray is __路_1 a portion of the reflected beam b from the reflection of the first interface 4 p, the first reflection of the axial beam c, and the portion of the reflected beam b from the first two sides 4 1 Forming a first refracting axial beam d to the second interface 4 2, the first refracting axial beam d is formed on the surface of the second interface 42 to form a second reflecting axial beam e, the second reflecting axis The light beam e is permeable to the interface 4 and is refracted to form a second refracting axial beam f, the second refracting axial beam f is exactly opposite to the first reflected axial beam c, and the first reflection The axial beam c is the same as the second refracting axial beam, and the optical interference fringe pattern g is formed at the intersection of the first reflected axial beam c and the second refracting axial beam f. 3 is disposed in the input device body 1 , and the lens holder 3 k is located on the incident path and the reflection path of the field beam a, and has a fixing groove 3 1 on both sides of the lens holder 3, correspondingly accommodating the laser light source 2, ^ at the top of the A lens holder 3 has a concave man's part 3 2, which corresponds to the photo sensor 5; the bottom of the fixing groove 3 i of the lens holder 3 has a first lens 3 3 which is located just below the laser beam 3 The human beam path is for the laser beam a to pass. The lens holder 3 has a second lens 34 located between the splitting sensor 4 and the second reflecting axial beam c that reflects the first interface 4 i and the The second chirped axial beam f reflected by the second interface 42 passes. The photo sensor 5 is correspondingly positioned in the recessed portion 32, and the photo sensor 5 is located in the first reflection axis, the beam b is the second fold, and the second pin is 9 M306693. The intersection is configured to sense an optical interference fringe pattern g imaged by the first reflected axial beam 0 and the second refracted axial beam f. According to the first figure, the first 'Yuer is: sticky, because the input device body 1'' the fixed slot 3 1 correspondingly accommodates the laser light source 2 and the lens holder 3 top ^ The photo sensor 5 is disposed corresponding to the recessed portion 32, so that the relative positions of the laser light source 2 and the photo sensor 5 are fixed and easy to position. When the operation is started, the laser beam a projected by the laser light source 2 is transmitted through the first lens 3 3 of the lens holder 3 to the working surface 6 along an incident path of an incident angle of 25 to 45 degrees. The light beam a is blocked by the working surface 6 and reflected to form a reflected light beam b projected onto the first interface 4 1 of the beam splitter 4 on the reflective path. The reflected light beam b is partially reflected on the surface of the first interface 4 to form a The first reflected axial beam c, - partially penetrates from the first interface 41, and is refracted to form a first beam d projected onto the second interface 42. The first refractive axial beam is reflective from the surface of the second interface a second reflected axial beam e is cast to the first interface 4 1, and the second reflected axial beam 6 penetrates the first "face 4 1 and is refracted to form a second refractive axial beam f, The second combination intersects the first reflected axial beam C and: a tooth, a sea, a second lens 34 of the lens holder 3, and the first reflection axis 2 = the second refractive index - the axial beam " The rate of the member is the same, and the + 反^ sensor 5 is imaged at the intersection of the second-refractive axial beam f Measure the reading interference fringes' g field input clothing body 1 on the working surface 6 into the pole Pi the light sensor 5 multiple times per second scanning to extract two movements: sample = M306693 image, to analyze the comparison, come It is judged that the input device body ting ^ ^ ^t # ^ A 11, , sf ^ 6 ^ corresponds to the moving miscellaneous direction: the food distance 'from % and the measurement sensitivity can be finely determined by = °. The above is adjusted within the range of 4π f -# ® 4 1 ^ φ 4 2 4^~' degrees. Using the force of H); 1-10 As can be seen from the above embodiment, the present invention has the following advantages. The read light interference fringe pattern g is used to correspond to the judgment square = distance, and the distance data is improved to improve the conventional optical structure to receive a single reflection. Tips r: The working surface 6 is smooth and there will be severe astigmatism, which will make it sensitive. ^ ^ 2 drop H-shot mouse "optical structure (four), resulting in low production yield, the Emirates is difficult to improve. This creation uses the beam splitter to separately reflect = axial beam 'via the interference fringe at the intersection of the two axial beams The change of the pattern comes to judge Jing ## t &, y, ^ M ^ ^ σ private direction and displacement distance data; due to the relatively improved yield of σ inter-structure, the production capacity is also greatly improved. The description of the household is a better and feasible embodiment of the creation, and therefore it is not limited to the new 0. The technical changes that are made by using this creation manual and the contents of the illustration are included in the scope of this creation. The first diagram is a schematic cross-sectional view of the creation. The second diagram is a three-dimensional diagram of the lens holder and the beam splitter. The third diagram is the fourth diagram of the installation light source and the domain detector. A schematic diagram of a partial cross-section of this (4). The fifth diagram is a schematic diagram of the optical motion of the present creation. The sixth diagram is a schematic diagram of the optical interference phenomenon. 11 M306693 [Description of the main components] [This creation] Display--*. y: . 2 — Light source 3 - lens holder 3 1 Fixing groove 3 2 - recessed portion 3 3 - first lens 3 4 - second lens 4 - beam splitter 4 1 - first interface 4 2 - second interface 5 - light sensor 6 - working surface a - laser Beam b - reflected beam c - first reflected axial beam d - first refractive axial beam e - second reflected axial beam f - second refractive axial beam g - interference fringe pattern