機械手機器人外文翻譯-平面串聯(lián)機械手的運動合成【中文3500字】【中英文WORD】
機械手機器人外文翻譯-平面串聯(lián)機械手的運動合成【中文3500字】【中英文WORD】,中文3500字,中英文WORD,機械手,機器人,外文,翻譯,平面,串聯(lián),運動,合成,中文,3500,中英文,WORD
譯文標題平面串聯(lián)機械手的運動合成【中文3500字】原文標題 Planar Serial Manipulator Motion Synthesis作 者Yanhui Wei譯 名魏艷輝國 籍China原文出處Journal of Harbin Institute of Technology ( New Series) ,Vol22,No2,2015譯文:摘要:本文論述了平面串聯(lián)機器人手的運動合成問題,快速工作空間的解決方案和障礙物回避路徑規(guī)劃方法,它提出了一種一般形式的運動學反解,不依賴于機器人本身的自由度,通過確定目標向量方向的最大和最小工作空間邊界和確定的工作空間極坐標形式的表達方法,最后,根據(jù)平面軌跡規(guī)劃的障礙躲避問題,解決了安全避障的凹凸形式的運動學反解的方法,仿真結果驗證了所提方法的可行性和通用性。 關鍵詞:平面串聯(lián)機器人 運動學反解 工作空間 軌跡規(guī)劃 矢量投影1引言串聯(lián)機械手的平面問題,這一特征點的機器人是可以在兩維平面運動的最后一個系列。運動控制是很容易實現(xiàn)的,其中A型機械手每個接頭大范圍的運動。相當經(jīng)典的串聯(lián)機械手由安切洛蒂來配置。例如,PUMA機器人增加了第一個旋轉接頭和第三個關節(jié)的基礎上的平面結構,滿足要求的三維空間機器人的位置,通過正交布局,達到要求空間工作點的位置。先進的平面串聯(lián)機械手已經(jīng)應用在一些特殊情況下,如水型機器人臂。對于空間機器人的運動學分析,將機器人的配置分為多個平面的配置形式??芍貥嫏C器人通過一個模塊可以自由組合的復雜機器人的配置和地址的運動學分析,動力學分析和軌跡規(guī)劃問題。為了解決自動重構機器人運動學逆解、魏等人。1提出配置平面的概念。在這個概念中,一個三維的機器人配置被分解成一個二維平面結構,以簡化運動學反解問題,實現(xiàn)自動和快速的解決方案的目標。一般情況下,分析的解決方法是很難獲得多參數(shù)、非線性、強耦合的解決方案,并參與到6R機器人運動學反解的代數(shù)方程中2。人們用半解析方法和解決空間NR機器人運動學反解問題的一般方法。已經(jīng)進行了一個運動分析與任何形式的平面結構,從而成為一個可重構機器人系列,是機器人運動分析的關鍵問題之一。本文以矢量投影法為研究重點,對平面串聯(lián)機器人的運動學反解和工作空間的軌跡規(guī)劃進行了研究。本研究的目的是獲得一個簡單的和快速的方法和一般的運動學反解求解的可重構機器人軌跡規(guī)劃,并提供一個參考的空間形式的串聯(lián)機械手。2自動運動學解2.1平面串聯(lián)機器人平面串聯(lián)機器人主要由旋轉接頭、平移關節(jié)和連桿??紤]到連桿不是一個單一的連接形式,當機器人運動模型建立與基本運動單元的旋轉關節(jié),運動的變換矩陣是是轉動關節(jié)運動;H是相鄰的旋轉接頭中心連接桿的長度,其值的變化時,它包括移動節(jié)點一般的平面機械手是串聯(lián)的形式顯示在圖1結束點的姿態(tài)矩陣是:當圖1總平面形狀的串聯(lián)機械手運動模型2.2平面串聯(lián)機械臂的自動求解方法這種方法不包含相當大的平移關節(jié)在一個共同的平面串聯(lián)機械手的構象,但符合空間位置要求或空間冗余任務,機器人關節(jié)的過度運動會降低整體控制過程中的性能和剛度特性。如圖1所示,平面串聯(lián)機械手的運動學反解可以分為兩個部分,即姿勢和位置的要求。具有冗余形式平面串聯(lián)機器人(三自由度以上),他們的姿勢的要求是第N1接頭部分必須保證N接頭運動范圍的條件下。結束姿勢要求可以通過最后一個旋轉接頭來實現(xiàn)的,其位置的要求可以通過組合第一N1接頭實現(xiàn)。對于平面串聯(lián)機器人的自由度小于或等于3,它的三個關節(jié)都需要滿足的姿勢崗位要求,它可以解析求解應用式(2)。我們利用向量投影法求解平面機器人的各種表單自動滿足以下約束:在P是結束向量的范數(shù);AI是矢量P用聯(lián)合杠桿臂的投影之間的比例和關節(jié)臂??紤]向量投影的方向,AI表示如下:是關節(jié)臂和目標點矢量之間的夾角圖2,P點目標點。如果聯(lián)合N固定長度的HN,聯(lián)合體育中心的空間位置是可以計算出來的。因此,整個計算是一個組合的前n1接頭后,接頭的N1配合中心聯(lián)合N圖中的結束,沒有一個固定的長度,移動節(jié)點的存在,利用最短的長度。聯(lián)合我的關節(jié)n + 1的杠桿臂之間是一個最大長度的狀態(tài),確保吉+ 1約長度最大,中心節(jié)點圖n計算,這是初步jn。圖2運動學求解過程自動計算被闡明如下:(1)在關節(jié)運動的情況下,最大限度的投影量。找到點(ji + 1)與+ 1與jn,如圖所示,ji + 1與,ji + 1 jn相比;如果ji + 1 jnji + 1,自動計算;如果ji + 1 jnji + 1,進行下一步。(2)在關節(jié)運動的情況下,逆投影量的范圍。找到最大點(Ji + 1)與+ 1與jn,如圖所示。J+ 1與J+ 1 jn相比;如果J+ 1 jnJ,+ 1,自動計算,關節(jié)運動在允許范圍的情況下,J+ 1 jn符合要求;否則,進行下一步。(3)+ 1關節(jié)調整到N1關節(jié)運動使J+ 1的長度是最短的。J+ 1與J+ 1 jn相比;如果j+ 1 jnJ+ 1,J+ 1的長度是根據(jù)位置的要求;如果J+ 1 jnJ+ 1,逆投影量最大值點J+ 1jn, + 1節(jié)自動計算。從第一關節(jié)開始,一個固定的周期可以滿足要求,在機器人運動學逆解。3自動解算的工作區(qū)機器人的工作空間,可以顯示機器人的工作范圍,是評價機器人的重要指標,然而,平面機器人的工作空間與機器人的工作空間是不同的。組成關節(jié)的運動范圍也不同。因此,我們獲得的工作是復雜的,會形成一個復雜的區(qū)域,這是由三,如圖3所示。這一特征使工作空間的解決方案很難獲得。圖3工作區(qū)采用多域為解決機器人工作空間主要包括分析、圖形的方法和數(shù)值方法4。在分析方法中,工作空間的邊界是由多個信封決定。然而,這種方法是復雜的,普遍應用于機器人的關節(jié)。圖解法求解邊界工作空間,我們可以得到各種相交的線或相交的表面。這種方法是有效的但也是由自由度的數(shù)目有限,當節(jié)點的數(shù)量是很大的,我們應該通過組6處理。數(shù)值計算方法是基于極值理論和優(yōu)化方法來計算機器人工作空間的邊界曲面的特征點,這是用來構成邊界曲線和形狀的邊界表面。代表結果的搜索方法,迭代法和蒙特卡羅79。為了計算串聯(lián)機器人定姿態(tài)工作空間,提出了一種基于二進制逼近原理的快速搜索方法基于上述方法,每一種方法的目的是利用該區(qū)域的自動求解工作區(qū)的邊界的確定,如圖3所示,以方便快速評價工作區(qū)的平面串聯(lián)機械手和快速匹配的配置平面的可重構機器人,我們通常會給平面矢量來解決這個位置,機器人可以實現(xiàn)對矢量。在本文中,我們使用了一種方法的基礎上的工作空間矢量的空間矢量的情況下,在這個向量的工作空間邊界迅速確定。4軌跡規(guī)劃方法軌跡規(guī)劃的目標是規(guī)劃理想的任務和關節(jié)空間的運動軌跡,使機器人運動速度快,精度高,運動點效率高,軌跡跟蹤精度高,滿足路徑、障礙和運動學約束。避障是軌跡規(guī)劃的一個關鍵問題。通常采用的方法是規(guī)劃機器人空間軌跡的終點會議空間避障要求,使用機器人的運動學反解求解各空間點的每個關節(jié)的價值。調整速度和平移關節(jié)加速度使機器人能達到更好的運動效果。實現(xiàn)避障任務更好,許多研究已經(jīng)簡化了壁壘概述由包絡圓。參考文獻12,阻擋接近一點,以最小的點與杠桿臂之間的距離作為避障的基礎,該方法擴展了障礙物的空間,減少了實際工作環(huán)境中的實際機器人的工作空間機器人的可操作性。使用新的雙向快速探索隨機樹算法對復雜空間躲避障礙物的軌跡規(guī)劃。這些算法不需要運動學反解計算方法,但我們可以通過擴展樹方法實現(xiàn)空間避障任務。perumaal等人提出一種自動軌跡規(guī)劃確定平滑,為中存在的障礙,一個五自由度機械手抓放操作的最小時間和無碰撞軌跡。該計劃是能夠處理的軌跡與不通過點和痕跡的光滑,無碰撞,近段時間最優(yōu)軌跡,不僅為機器人的端部執(zhí)行器,但也為它的鏈接確保無碰撞軌跡。capisani等人。提出一個簡單而有效的路徑規(guī)劃策略,目標是代表機器人的配置空間的障礙,表示允許獲得一個有效的和準確的軌跡規(guī)劃和跟蹤,以及一個專用的碰撞檢測規(guī)則的機器人與障礙物之間。第2節(jié)描述機器人運動學求解方法。當空間障礙存在,其空間軌跡規(guī)劃。干擾與障礙的發(fā)生,如圖4所示。圖4平面障礙配置運動反解回避問題我們繼續(xù)使用2節(jié)的仿真實例,其中機器人從初始點移動到目標點,圖8中的區(qū)域1由實際障礙形成的,考慮機器人的尺寸和安全距離,我們展開1區(qū)的距離,形成安全的避障區(qū)2,根據(jù)運動學反解在軌跡規(guī)劃過程中,機器人的結構形式表現(xiàn)出明顯的干擾,從而平衡運動學反解的自動解和避障問題。5結論1)利用矢量投影法和關節(jié)約束,求解平面串聯(lián)機械臂的運動學問題。仿真結果表明,該方法避免了傳統(tǒng)的分析方法,它依賴于機器人的配置和自由度的形式,以及解決速度和精度的問題時,使用數(shù)值方法,這種方法也實用和通用。2)在矢量方向上提出一個工作范圍,作為平面機器人的工作空間表達式。此方法使用一個搜索的方法來解決工作區(qū)范圍迅速的方向上的設置矢量角。這種方法也自動和快速。此外,該方法是將三維空間機器人分解為二維平面機器人的基礎。3)通過對平面串聯(lián)機械手的運動學反解求解方法的改進,實現(xiàn)了軌跡規(guī)劃平面機器人工作空間的障礙。仿真結果表明,該方法是通用的和實際的障礙與凸形式。原文:Planar Serial Manipulator Motion SynthesisYanhui Wei* ,Han Han,Zepeng Wang,Xin Liu and Guangchun Li( College of Automation,Harbin Engineering University,Harbin 150001,China)Abstract: This paper deals with the universal serial manipulator on the inverse kinematics problem of planetype,the fast working space solution method,and the obstacle avoidance path planning methodWith the vectorprojection as the main constraint condition of the target,it proposes a general form of the inverse kinematics solution which does not depend on the robot configuration of freedom degreeBy identifying the target vectordirection maximum and minimum workspace boundary and determining the destination vector by thick search on the workspace boundary method,an expressing method of the polar coordinate form of work space is then introduced Finally,according to the form of plane trajectory planning for obstacle avoidance problem,the method of solving the inverse kinematics solution of the concave and convex forms of the safe obstacle avoidance area is improvedThe simulation results verify that the proposed method has feasibility and generalityKeywords: planar serial manipulators; inverse kinematics; workspace; trajectory planning; vector projection1 IntroductionPlanar serial manipulators refer to the feature in which a robot can point in a two-dimensional plane movement at the end of a series Planar serial robot motion control is easy to implement,in which a robot forms a single,large range of movement of each joint Considerable classic serial robot configuration has evolved For example,PUMA robot increases the first rotary joints to the second and third joints based on planar configuration and satisfies the requirement of a three-dimensional space robot position by orthogonal layout to request the position of space operating point Planar serial manipulators have been advanced in some special circumstances,such as under water-type robot armFor the space robot kinematics analysis,the robot configuration can be divided into multiple planar configuration forms econfigurable robot through a module can free the combination of complex robot configuration and address the kinematics analysis, dynamics analysis,and trajectory planning problemsTo solve the inverse kinematics solution of an automatically reconfigurable robot, Wei et al1 proposed the concept of configuration plane In this concept, a three-dimensional robot configuration isdecomposed into a two-dimensional plane configuration to simplify the inverse kinematics problem and achieve the goal of an automatic and fast solution Generally,the analytic solutions are difficult to obtain due to the multi-parameters, nonlinearity and coupling of the solutions,and the algebra equations involved in the inverse kinematics of 6 serial manipulators2 Wei et al3 used a semi-analytic method and a generalmethod to solve the spatial n robot inverse kinematics problem A motion analysis has been conducted with any form of planar configuration,which becomes a reconfigurable robot series and is one of the key problems of the robot motion analysisIn this paper,the inverse kinematics of planar serial manipulators and the workspace and trajectory planning are studied,with the vector projection method as the focus This study aims to obtain a simple and fast method and a general inverse kinematics solution for the reconfigurable robot trajectory planning and to provide a reference for space in the form of serial manipulators2 Automatic Kinematics Solution2. 1 General Form of Planar Serial ManipulatorsPlanar serial manipulators are mainly composed of rotational joints,translational joint,and a connecting rodConsidering that the connecting rod is not in the form of a single connection,when a robot motion model is established,with the rotational joint of the basic movement unit,the motion transformation matrix iswhere is the rotational joint exercise; h is the length of the connecting rod of two adjacent rotational joint centers,whose value varies when it includes mobilejointsThe general form of planar serial manipulators is shown in Fig1 The end point of the pose matrix is: WhereFig 1 General form of the planar serial manipulator motion model22 Automatic Solving Method of Planar Serial ManipulatorThis method does not contain considerable ranslational joint in a common conformation of planar serial manipulator but meets the space position requirements or space redundant tasks The excessive movement of the robot joints will reduce the performance and stiffness characteristics in the overall controlling processAs shown in Fig 1,the inverse kinematics of planar serial manipulator can be divided into two parts, i e,the posture and position requirements For the planar serial robot with a redundant form ( more than three degrees of freedom) ,their posture requirements are under the conditions that the first n 1 joint part must guarantee the range of n jointsmotion The end posture requirements can be achieved through the last one rotating joints,and its location requirements can be implemented by combining the first n 1 joints For the planar serial robot whose degree of freedom is less than or equal to 3,its three joints all need to meet the posture and position requirements and it can be analytically solved using Eq ( 2) We use the vector projection method to solve the various forms of planar serial robot automatically,which satisfies the following constraints:where p is the norm of the end vector; ai is the ratio between the projection of ith joint lever arm on the vector p and the joint lever arm Considering thedirection of vector projection, ai is expressed as follows: where i is the angle between ith joint lever arm and the target point vectorIn Fig2,P point is the target point If the length hn of the joint n is fixed,the spatial location of the joints sports center can be calculated Therefore,the entire calculation is after a combination of the former N 1 joint,and the ends of the joint n 1 coincide with the center joint n in the figure Without a fixed length,mobile joints exist,which utilize the shortest length The joint I to the joint n + 1 between the lever arm is in a state of maximum length,ensuring that the length of ji+1 jn is maximum The center of the joints with the picture n is calculated,which is the tentative for jn Fig2 Kinematics solving processThe automatic calculation is elucidated as follows:1) In the case of joint movement i range,the projection quantity maximumPoint ( ji+1) of ji ji+1 is found in ji jn,as shown in Fig2 The length of ji+1 jn is compared with that of ji+1 jn; if ji+1 jn ji+1 jn,i + 1 joint automatic calculation is conducted; if ji+1 jn ji+1 jn,the next step is performed;2) In the case of joint movement i range,the inverse projection quantityMaximum point ( ji+1) of ji ji+1 is found in ji jn,as shown in Fig2 The length of ji+1 jn is compared with that of ji+1 jn ; if ji+1 jn ji+1 jn,the automaticcalculation is conducted at the end of I joint In the case of joint movement I range,ji+1 jn is found to meet the requirements; otherwise, the next step is performed; 3) I + 1 joint is adjusted to n 1 joint exercise to make the length of ji+1 jn be the shortest The length of ji+1 jn is compared with that of ji+1 jn ; if ji+1 jn ji+1 jn,the length of ji+1 jn is adjusted to meet the position requirements; if ji+1 jn ji+1 jn,the inverse projection quantity maximum point of ji ji+1 is found inji jn and I + 1 joint automatic calculation is conductedStarting from the first joint,a constant cycle can meet the requirements at the end of the robot kinematics inverse solutions3 Automatic Solution of the WorkspaceThe workspace of the robot,which can show the operating range that the robot can achieve, is an important indicator for evaluating robots However,the workspace of planar robot differs because the number of composition joint and the range of motion also differThus,the workspace we obtain is complex and will form a complex region, which is made of multidomains,as shown in Fig3 This feature makes the solution of the workspace difficult to obtainFig3 Workspace made of multi-domainsThe method for solving the robot workspace mainly includes analytical, graphical, and numerical methods4 In the analytical method,the boundary of workspace is determined by multiple envelopesHowever,this method is complicated and is generally applied to the robots with less than three joints5 The graphical method is used to solve the boundary of workspace We can obtain various intersecting lines or intersecting surfaces This method is effective but is also limited by the number of degrees of freedomWhen the number of joints is large,we should handle it by group6 The numerical method is based on extreme value theory and optimization methods to calculate the feature points on the boundary surfaces of robotsworkspace,which are used to constitute the boundary curves and form the boundary surface The representative results are the search method,iterative method,and Monte Carlo79 In order to compute the constant-orientation workspace of serial robots,a fast search method based on the binary approximating principle is proposed10 Based on the above methods,each method aims to utilize the area formed by the workspace The problem of automatically solving the workspace is the determination of the boundary of the workspace As shown in Fig3, to facilitate the rapid evaluationworkspace of planar serial manipulator and the fast matching configuration plane of reconfigurable robots,we usually give plane vector to solve the position that the robot can achieve on the vector In this paper,we use a method based on the workspace expression of planar serial manipulator in the polar form,ie,in the condition in which the space vector is known,the workspace boundaries on this vector angle is rapidly determined4 Trajectory Planning MethodThe objective of trajectory planning is to plan ideal task and joint space trajectories,make the robot motion fast,accurate and stable with high movement point efficiency and high trajectory tracking accuracy,and satisfy the path, obstacle, and kinematicsconstraints The obstacle avoidance is a key problem in the trajectory planning The usual approach used is planning the robot end-point space trajectory,meeting the space avoiding obstacle requirements,and using robot inverse kinematics to solve each joint value ateach space point Adjusting the speed and acceleration of the translational joint allows the robot to achieve better motion effects To achieve the obstacle avoidance task better,many studies have simplified the barriers outline by enveloping circle11 In ef 12 ,the barrier approximates a point and takes the minimum distance between the point and the lever arm as the basis of obstacle avoidance This method expands the obstacle space,reduces the actual robot working space in the actual working environment, and limits the robots workability Xie et al13 used new bidirectional rapidly exploring random tree algorithms for complex spatial obstacle avoidance trajectory planning These algorithms do not require the inverse kinematics calculation method,but we can achieve the spatialobstacle avoidance task by expanding the tree method Duguleana14 proposes a new approach for solving the problem of obstacle avoidance during manipulation tasks performed by redundant manipulators In which q-learning is used together with neural networks in order to plan and execute arm movements at each time instant Perumaal et al15 proposed an automated trajectory planner to determine a smooth,minimumtime and collision-free trajectory for the pick-and-place operations of a 5-DOF robotic manipulator in the presence of an obstacle The proposed planner is ableto handle the trajectory with and without via-point and traces the smooth, collision-free, near-time-optimal trajectory The collision-free trajectory is ensured not only for the robots end-effector but also for its links Capisani et al16 proposed a simple but effective path planning strategy The goal is to represent the obstacles in the robot configuration space The representation allows obtaining an efficient and accurate trajectory planning and tracking And a dedicated collision checking rule between the manipulator and obstacles is also proposed Section 2 describes the method for solving the robot kinematics When space obstacles exist,their spatial trajectory is planned Interference will occur with the obstacle,as shown in Fig4Fig.4 Planar obstacle configuration inverse movement solving the avoidance problemWe continue to use the simulation example of Section 2,in which the robot moves from the initial point D to the target point P The area 1 in Fig4 is formed by the actual obstacle Considering the robot links dimension and safe distance,we expand zone 1in k distance,which forms the secure avoiding obstacle zone 2 According to the inverse kinematics solution during the trajectory planning,the final form of the robot configuration shows noticeable interference How to balance the inverse kinematics automatic solution and the obstacle avoidance is to be solved5 Conclusions1) Using the constraints of the vector projection method and joints,the kinematics problem of the planar serial manipulator is solved The simulation results show that this method avoids the traditional analytical method which relies on the forms of robot configurations and the degrees of freedom,as well as the problem of solving speed and precision when using numerical methods This method is also practical and versatile2) A working range is proposed in the direction of the vector as the workspace expression of planar robotThis method uses a searching way to solve the workspace range rapidly in the direction of the setting vector angle This method is also automatic and fastFurthermore,this method is the foundation of the research in decomposing a three-dimensional space robot into a two-dimensional planar robot3 ) Through the inverse kinematics solution method of planar serial manipulator with improved forms, the trajectory plan is achieved when the workspace of a planar robot presents obstacles The simulation results show that the method is versatile and practical to the barrier with a convex form指 導 教 師 評 語 外文翻譯成績:指導教師簽字: 年 月 日注:1. 指導教師對譯文進行評閱時應注意以下幾個方面:翻譯的外文文獻與畢業(yè)設計(論文)的主題是否高度相關,并作為外文參考文獻列入畢業(yè)設計(論文)的參考文獻;翻譯的外文文獻字數(shù)是否達到規(guī)定數(shù)量(3 000字以上);譯文語言是否準確、通順、具有參考價值。2. 外文原文應以附件的方式置于譯文之后。第 14 頁
收藏
編號:233075381
類型:共享資源
大?。?span id="aqem4j9" class="font-tahoma">66.71KB
格式:RAR
上傳時間:2023-10-02
8.8
積分
- 關 鍵 詞:
-
中文3500字
中英文WORD
機械手
機器人
外文
翻譯
平面
串聯(lián)
運動
合成
中文
3500
中英文
WORD
- 資源描述:
-
機械手機器人外文翻譯-平面串聯(lián)機械手的運動合成【中文3500字】【中英文WORD】,中文3500字,中英文WORD,機械手,機器人,外文,翻譯,平面,串聯(lián),運動,合成,中文,3500,中英文,WORD
展開閱讀全文
- 溫馨提示:
1: 本站所有資源如無特殊說明,都需要本地電腦安裝OFFICE2007和PDF閱讀器。圖紙軟件為CAD,CAXA,PROE,UG,SolidWorks等.壓縮文件請下載最新的WinRAR軟件解壓。
2: 本站的文檔不包含任何第三方提供的附件圖紙等,如果需要附件,請聯(lián)系上傳者。文件的所有權益歸上傳用戶所有。
3.本站RAR壓縮包中若帶圖紙,網(wǎng)頁內容里面會有圖紙預覽,若沒有圖紙預覽就沒有圖紙。
4. 未經(jīng)權益所有人同意不得將文件中的內容挪作商業(yè)或盈利用途。
5. 裝配圖網(wǎng)僅提供信息存儲空間,僅對用戶上傳內容的表現(xiàn)方式做保護處理,對用戶上傳分享的文檔內容本身不做任何修改或編輯,并不能對任何下載內容負責。
6. 下載文件中如有侵權或不適當內容,請與我們聯(lián)系,我們立即糾正。
7. 本站不保證下載資源的準確性、安全性和完整性, 同時也不承擔用戶因使用這些下載資源對自己和他人造成任何形式的傷害或損失。
裝配圖網(wǎng)所有資源均是用戶自行上傳分享,僅供網(wǎng)友學習交流,未經(jīng)上傳用戶書面授權,請勿作他用。