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PROPERTIES OF THE JACOBIAN

PROPERTIES OF THE JACOBIAN. θ 2. L 2. L 1. Link 2. y. Link 1. θ 1. x. Link 0. The Jacobian plays an important role in the analysis, design and control of robotic systems. The Jacobian can be expressed by its two coulmns. Then the velocity relation is given as follows.

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PROPERTIES OF THE JACOBIAN

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  1. PROPERTIES OF THE JACOBIAN θ2 L2 L1 Link 2 y Link 1 θ1 x Link 0

  2. The Jacobian plays an important role in the analysis, design and control of robotic systems. The Jacobian can be expressed by its two coulmns Then the velocity relation is given as follows The first term on the right-hand side accounts for the end-effecter velocity induced by the first joint only, while the second term represents the velocity resulting from the second joint motion only. The resultant end-effecter velocity is given by the vectorial sum of the two. Each vector of the Jacobian matrix represents the end-effecter velocity generated by the corresponding joint moving at a unit velocity when all other joints are immobilized.

  3. J1 θ2 L2 J2 L1 Link 2 y E Link 1 θ1 x Link 0 Figure illustrates the column vectors J1 and J2 of the 2 dof robot arm in the two dimensional space. Vector J2, given by the second column of the Jacobian matrix, points in the direction perpendicular to link 2. Note, however, that vector J1 is not perpendicular to link 1 but is perpendicular to line OE, the line from joint 1 to the endpoint E.

  4. J1 represents the endpoint velocity induced by joint 1 when joint 2 is immobilized. In other words, links 1 and 2 are rigidly connected, becoming a single rigid body of link length OE, and J1 is the tip velocity of the link OE. In general, each column vector of the Jacobian represents the end-effecter velocity and angular velocity generated by the individual joint velocity while all other joints are immobilized. Let be the end-effecter velocity and angular velocity, or the end-effecter velocity for short, and Ji be the i-th column of the Jacobian. The end-effecter velocity is given by a linear combination of the Jacobian column vectors weighted by the individual joint velocities. where n is the number of active joints. The geometric interpretation of the column vectors is that J1 is the end-effecter velocity and angular velocity when all the joints other than joint i are immobilized and only the i-th joint is moving at a unit velocity.

  5. Remember that the end-effecter velocity is given by the linear combination of the Jacobian column vectors J1 and J2. Therefore, the resultant end-effecter velocity varies depending on the direction and magnitude of the Jacobian column vectors J1 and J2spanning the two dimensional space. If the two vectors point in different directions, the whole two-dimensional space is covered with the linear combination of the two vectors. That is, the end-effecter can be moved in an arbitrary direction with an arbitrary velocity. On the other hand, the two Jacobian column vectors are aligned, the end-effecter cannot be moved in an arbitrary direction. This may happen for particular arm postures where the two links are fully contracted or extended. These arm configurations are referred to as singular configurations. Accordingly, the Jacobian matrix becomes singular at these positions. Using the determinant of a matrix, this condition is expressed as

  6. Non-Singular J1 J1 y J2 θ2=θ1+180° J2 Singular θ2 J2 θ1 Singular θ1 θ1 x J1 The vectors J1 and J2 points to same direction if θ1=θ2 and if θ2=180+θ1

  7. Non-Singular J1 J1 y J2 θ2=θ1+180° J2 Singular θ2 J2 θ1 Singular θ1 θ1 x J1 Robot manipulator is singular at its workspace boundaries.

  8. {A} ZA AP YA XA TRANSFORMATIONS Description of a position: Once a coordinate system is established we can locate any point in the universe with a 3x1 position vector. Because we will often define many coordinate systems in addition to the universe coordinate system, vectors must be tagged with information identifying which coordinate system they are defined within. The position vectors are written with a leading superscript indicating the coordinate system to which they are referenced, for example, AP. This means that the components of AP have numerical values which indicate distances along the axes of {A}. Each of these distances along an axis can be thought of as the result of projecting the vector onto the corresponding axis.

  9. End effecter {B} {A} ZB Description of an orientation: Often it is necessary not only to represent a point in space, but also to describe the orientation of a body in space. For example, if vector AP locates the point directly between the finger tips of a manipulator hand, the complete location of the hand is still not specified until its orientation is also given. Assuming that the manipulator has a sufficient number of joints the hand could be oriented arbitrarily while keeping the finger tips at the same position in space. In order to describe the orientation of a body we will attach a coordinate system to the body and then give a description of this coordinate system relative to the reference system. In the figure given below, coordinate system {B} has been attached to the body in a known way. A description of {B} relative to {A} now suffices to give the orientation of the body. AP

  10. Thus, positions of points are described with vectors and orientations of bodies are described with an attached coordinate system. One want to describe the body-attached coordinate system, {B}, is to write the unit vectors of its three principal axes in terms of the coordinate system {A}. We denote the unit vectors giving the principle directions of coordinate system {B} as XB, YB, and ZB. When written in terms of coordinate system {A} they are called AXB, AYB, and AZB. It will be convenient if we stack these three unit vectors together as the columns of a 3x3 matrix, in the order AXB, AYB, AZB. We will call this matrix a rotation matrix, and because this particular rotation matrix describes {B} relative to {A}, we name it with the notation ARB.

  11. Description of a frame: The information needed to completely specify the whereabouts of the manipulator hand (end-effecter) is a position and an orientation. The point on the body whose position we describe could be choosen arbitrarily, however: For convenience, the point whose position we will describe is choosen as the origin of the body-attached frame. The situation of a position and an orientation pair arises so often in robotics that we define an entity called a frame which is a set of four vectors giving position and orientation information. For example, in the figure given two slides before, one vector locates the finger tip position and three more describe its orientation. Equivalently the description of a frame can be thought of as a position vector and a rotation matrix. Note that a frame is a coordinate system, where in addition to the orientation we give a position vector which locates its origin relative to some other imbedding frame. For example, frame {B} is described by ARB and APBorg , where APBorg is the vector which locates the origin of the frame {B}:

  12. ZB {B} ZA XB BP APBorg {A} AP YB YA XA MAPPING INVOLVING GENERAL FRAMES: Very often we know the description of a vector with respect to some frame, {B}, and we would like to know its description with respect to another frame {A}. Here the origin of frame {B} is not coincident with that of frame {A} but has a general vector offset. The vector that locates {B}’s origin is called APBorg. Also {B} is rotated with respect to {A} as described by ARB. Given BP, we wish to compute AP as in the figure. Above equation describes a general transformation mapping of a vector from its description in one frame to a description in a second frame.

  13. The form of the above equation is not as appealing as the conceptual form, That is, we would like to think of a mapping from one frame to another as an operator in matrix form. This aids in writing compact equations as well as beaing conceptually clear. In order to write the mapping equations in compact form, we define 4x4 matrix operator, and use 4x1 position cevtors, so that above equation has the structure. That is, A “1” is added as the last element of the 4x1 vectors. A row “[0 0 0 1]” is added as the last row of the 4x4 matrix. The 4x4 matrix is called a Homegeneous transform. It can be regarded purely as a construction used to cast the rotation and translation of the general transform into a single matrix form.

  14. YB P YA AP BP XB APBorg XA Example: Figure shows a frame {B} which is rotated relative to frame {A} about Z by 30 degrees, and translated 10 units in XA, and 5 units in YA. Find AP where BP=[3.0 7.0 0.0]T. Given:

  15. P {C} ZC YC CP {B} ZB AP {A} YB ZA ZC XB YA XA Compound frames: each is known relative to perevious COMPOUND TRANSFORMATIONS: In the figure , we have CP and wish to find AP. Frame {C} is known relative to frame {B}, and frame {B} is known relative to frame {A}. We can transform CP into BP as And then transform BP into AP as Combining these equations

  16. Inverting a Transform: Rotation matrix is orthogonal, thus If ATB transforms the frame {A} into frame {B}, the inverse transform can be written as

  17. Example: A frame {B} which is rotated relative to frame {A} about Z by 30 degrees, and translated 4 units in XA, and 3 units in YA. Thus we have a description pf ATB. Find BTA.

  18. Example: Find AP for given CP. yA CP 40 30 30 APy yB yC 30 50 30 30 xC xB 40 xA APx MATLAB CODE clc clear teta1=30*pi/180; rot1=[cos(teta1),-sin(teta1),0 sin(teta1),cos(teta1),0 0,0,1] p1=[40;30;0]; T1=[rot1,p1]; %Trans. matrix B A T1=[T1;[0,0,0,1]]; teta2=40*pi/180; rot2=[cos(teta2),-sin(teta2),0 sin(teta2),cos(teta2),0 0,0,1] p2=[50;30;0]; T2=[rot2,p2]; %Trans. matrix C B T2=[T2;[0,0,0,1]]; CP=[30;30;0;1] T=T1*T2 AP=T*CP CP=inv(T)*AP Result:

  19. *** Sketch via SolidWorks ***

  20. zi θi+1 Zi-1 xi Zi-2 θi θi-1 Link i xi-1 Link i-1 Robot Kinematics: A Matrices For given values of the joint variables, it is important to be able to specify the locations of the links with respect to each other. This is accomplished by using the manipulator kinematic equations. We may associate with each link i a coordinate frame (xi, yi, zi) fixed to that link. A standard and consistent paradigm for so doing is the Denavit-Hartenberg (D-H) representation. The frame attached to link 0 (the base of the manipulator) is called the base frame or inertial frame. The relation between coordinate frame i-1 and coordinate frame i is given by the transformation matrix.

  21. αi Denavit-Hartenberg Frame Assignment The link parameters αi, the twist of the link i and ai the length of link i. The joint parameters are the joint angle θi and the joint offset di.

  22. A commonly used convention for selecting frames of reference in robotic applications is the Denavit-Hartenberg, or D-H convention. In this convention, each homogenous transformation Ai is represented as a product of four basic transformation.

  23. The A matrix Ai is a function of anly a single variable, namely the joint variable θi or di, since all the other parameters in Ai, are fixed for a specific joint. The A matrix is a homegeneous transformation matrix of the form where Ri is a rotation matrix an pi is a translation vector. Thus if ir is a point described with respect to the coordinate frame link i, the same point has coordinates i-1r with respect to the frame of link i-1 given by

  24. Arm T Matrix: To obtain the coordinates of a point in terms of the base (i.e., link 0) frame, we may use the matrices Then, given the coordinates ir of a point expressed in the frame attached to link i, the coordinates of the same point in the base frame are given by We call Ti a kinematic chain of transformations. We define the arm T matrix as with n the number of links in the manipulator. Then, if nr are the coordinates of a point referred to the last link, the base coordinates of the point are

  25. x2 y2 a2 θ2 a1 z2 y1 θ2 θ1 x1 y0 Arm schematic θ1 z1 x0 z0 D-H coordinate frames Example: Two-link planar RR arm (Planar Elbow Manipulator) a2 a1

  26. The arm T matrix is given by c12 -s12 This represents the kinematic solution, which converts the joint variable coordinates (θ1, θ2) into the base-frame Cartesian coordinates of the end of the arm. The origin O2 of frame 2 in terms of base coordinates is located at

  27. A1= A2= T=A1*A2= a1=1 m, a2=0.5 m, θ1=30°, θ2=60°

  28. Example: Three-Link Cylindirical Manipulator Link Parameters d1

  29. SCARA MANIPULATOR: a2 a1 d4

  30. The forward kinematic equations are given by

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