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ME 4135 Differential Motion and the Robot Jacobian

ME 4135 Differential Motion and the Robot Jacobian. Slide Series 6 R. R. Lindeke, Ph.D. Lets develop the differential Operator – bringing calculus to Robots. The Differential Operator is a way to account for “Tiny Motions” ( T)

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ME 4135 Differential Motion and the Robot Jacobian

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  1. ME 4135Differential Motion and the Robot Jacobian Slide Series 6 R. R. Lindeke, Ph.D.

  2. Lets develop the differential Operator – bringing calculus to Robots • The Differential Operator is a way to account for “Tiny Motions” (T) • It can be used to study movement of the End Frame over a short time intervals (t) • It is a way to track and explain motion for different points of view

  3. Considering motion: • We can define a General Rotation of a vector K: • By a general matrix defined as:

  4. These Rotation are given as: • But lets remember for our purposes that this angle is very small (a ‘tiny rotation’) in radians • If the angle is small we can have use some simplifications: Cos small  1 Sin small  small

  5. Substituting the Small angle Approximation: Similarly for Y and Z:

  6. Simplifying the Rotation Matrices(form their product): Note here: we have neglected higher order products of the  terms!

  7. What about Small (general) Translations? • We define it as a matrix: • General ‘Tiny Motion’ is then (including both Rot. and Translation):

  8. So using this idea: • Let’s define a motion which is due to a robot’s joint(s) moving during a small time interval: • T+T = {Rot(K,d)*Trans(dx,dy,dz)}T • Consider Here: T is the original end frame pose • Substituting for the matrices:

  9. Solving for the differential motion (T)

  10. Factoring T (on the RHS)

  11. Further Simplifying: We will call this matrix the del operator: 

  12. Thus, the Change in POSE (T or dT) is: • dT (T) = T • Where:  = {[Trans(dx,dy,dz)*Rot(K,d)] – I} • Thus we see that this  operator is analogous to the derivative operator d( )/dx but now taken with respect to HTM’s!

  13. Lets look into an application: • Given: • Subject it to 2 simultaneous movements: • Along X0 (dx) by .0002 units (/unit time) • About Z0 a Rotation of 0.001rad (/unit time)

  14. Graphically: Here: Rinit = (32 + 52) .5 = 5.831 units init = Atan2(3,5) = 1.0304 rad R 

  15. Where is the Frame n after one time step? • Considering Position: • Effect of “Translation”: • X=3.0002 and Y = 5.000 • New Rf = (3.00022 + 5.02).5 = 5.83105 u • Effect of Rotation • fin = 1.0304 + 0.001 = 1.0314 rad • Therefore: Xf = Cos(fin) * Rf = 2.99505 • And: Yf = Sin(fin) * Rf = 5.00309

  16. Where is the Frame n after one time step? • Considering Orientation:

  17. After 1 time step, Exact Pose is:

  18. Lets Approximate it using this  operator • Tnew = Tinit + dT = Tinit + Tinit – the 1st law of differential calculus • Where:

  19. Thus, Tnew is Approximately:

  20. Comparing: • “Exact”: • Approximate: Realistically these are all but equal but using the ‘del’ approximation, but finding it was much easier!

  21. We can (might!) use the ‘del’ approach to move a robot in space: • Take a starting POSE (Torig) and a starting motion set (deltas in rotation and translation as function of unit times) • Form  operator for motion • Compute dT (Torig) • Form Tnew = Torig + dT • Repeat as time moves forward over n time steps

  22. Taking Motion W.R.T. other Spaces (another use for this del operator idea) • Original Model (the motion we seek is defined in an inertial space): • dT = T (1) • However, if the motion is taken w.r.t. another (non-inertia) space: • dT = TT (2) • Here T implies motion w.r.t. itself – a moving frame – but could be motion w.r.t. any other non-inertia space (robot or camera, etc.) • Consider as well: the pose change (motion that is happening) itself (dT) is independent of point of view so, by equating (1) and (2) we can isolate T • T = (T)-1T

  23. Solving for the specific Terms in T • Positional Change Vector w.r.t. (any) Tspace: • Angular effects wrt Tspace: d, n, o & a vectors are extracts from the T Matrix dp is the translation vector in   is the rotational effects in 

  24. Subbing into a ‘del’ Form:

  25. An Application of this issue: TRpart TCamPart TWCR If the Part is moving along a conveyor and we “measure” its motion in the Camera Frame (let the camera measure it at various times) and we would need to pick the part with the robot, we must track wrt to the robot, so we need part motion “del” in the robot’s space.

  26. This is a Motion “Mapping” Issue: • Pa R WC Ca PaPa R  C Pa • Pa R WC Ca Pa • Knowns: • C • Robot in WC • Camera in WC • And of course Part in Camera (But we don’t need it for now!)

  27. Lets Isolate the “Middle” • R WC CaR  C • R WC Ca • To solve for R we make progress from “R to R” directly (R) and “The long way around”:

  28. Rewriting into a Standard Form: • It can be shown for 2 Matrices (A & B): • A-1*B = (B-1*A)-1 (1) • Or B-1*A = (A-1*B)-1 (2) • If, on the previous page we consider: • TWCCam as “A” and TWCR as “B”, • and define the form: (TwcCam)-1*TWCR as “T” • Then, Using the theorem (from matrix math) stated as (2) above “T”-1 is: (TWCR)-1* TWCCam

  29. Continuing: • Rewriting, we find that R = “T”-1(Cam) “T” • R is now shown in the “standard form” for non-inertial space motion • the terms: d, n, o & a vectors come from our ‘complex T’ matrix • the dp and  vectors can be extracted from the Cam • These term are required to define motion in the robot space • Of course the “T” is really: (TwcCam)-1*TWCRhere! • Its from this “T” product that we extract n, o, a, d vectors

  30. R is given by simplifying: • 1st: (TwcCam)-1*TWCR = “T” • Then these Scalars: WHERE: d, n, o & a vectors are extracts from the “T” Matrix above dp is the ‘translation’ vector in Cam  is the vector of ‘rotational effects’ in Cam

  31. Lets Examine the Jacobian Ideas • Fundamentally:

  32. In This Model, Ddot & Dq,dot are: We state, then, that the Jacobian is a mapping tool that relates Cartesian Velocities (of the n frame) to the movement of the individual Robot Joints

  33. Lets build one from ‘1st Principles’ – Here is a Spherical Arm: R Lets start with only linear motion ---- equations are straight forward!  

  34. Writing the Position Models: • Z = R*Sin() • X = R*Cos()*Cos() • Y = R*Cos()*Sin() To find velocity, differentiate these as seen here:

  35. Writing it as a Matrix: This is the Jacobian; It is built as the Matrix of partial joint contributions (coefficients of the velocity equations) to Velocity of the End Frame

  36. Here we could develop an Inverse Jacobian: It was formed by taking the partial derivatives of the IKS equations

  37. The process we just did is limited to finding Linear Velocity!… and We need both linear and angular velocities for full functioned robots! • We can approach the problem by separations as we did in the General case of Inverse Kinematics – • Here we separate Velocity (Linear from Rotational), not Joints (Arms from Wrists) • Generally speaking, in the Jacobian we will obtain one Column for each Joint and 6 rows for a full velocity effect • We say the Jacobian is a 6 by n (6xn) matrix

  38. Separation Leads to: • A Cartesian Velocity Term V0n: • An Angular Velocity Term 0n: Each of these “Ji’s” are 3 Row by n Columned Matrices

  39. Building the “Sub-Jacobians”: • We follow 3 stipulations: • Velocities can only be added if they are defined in the same space – as we know from dynamics • Motion of the end effector (n frame) is taken w.r.t. the base space (0 frame) • Linear Velocity effects are physically separable from angular velocity effects • To address the problem we will consider moving a single joint at a time (using DH separation ideas!)

  40. Lets start with the Angular Velocity (!) • Considering any joint i, its Axis of motion is: Zi-1 (Z in Frame i-1) • The (modeling) effect of a joint is to drive the very next frame (frame i) • If Joint i is revolute: • here k(i-1) is the Zi-1 direction (by definition) • This model is applied to each of the joints (revolute) in the machine (as it rotates the next frame, all subsequent fames, move similarly!) • But if the Joint is Prismatic, it has no angular effect on its “controlled” frame and thus no rotoation from it on all subsequent frames

  41. Developing the (base) J • We need to add up each of the joint effects • Thus we need to “normalize” them to base space to do the sum • DH methods allow us to do this! • Since Zi-1 is the active direction in a Frame of the model, we really need only to extract the 3rd column of the product of A1 * …*Ai-1 to have a definition of Zi-1 in base space. Then, this Ai’s products 3rd column is the effect of Joint i as defined in the (common) base space (note, the ‘qdot’ term is the rate of rotation of the given joint)

  42. So the Angular Velocity then is: Note Zi-1 for Jointi – per DH algorithm! As stated previously, Zi-1 is the 3rd col. of A1*…Ai-1 (rows 1,2 & 3). And we will have a term in the sum for each joint

  43. Going Back to the Spherical Device: Notice: 3 columns since we have 3 joints! Here, Z1 depends on the Frame Skeleton drawn!

  44. Building the Linear Jacobian • It too will depend on the motion associated with Zi-1 • It too will require that we normalize each joints linear motion contribution to the base space • We will find that revolute and prismatic joints will make functionally different contributions to the solution (as if we would think otherwise!) • Prismatic joints are “Easy,” Revolutes are not!

  45. Building the Linear Jacobian

  46. Building the Linear Jacobian – for Prismatic Joints When a prismatic jointi moves, all subsequent links move (linearly) at the same rate and in the same direction

  47. Building the Linear Jacobian – Prismatic Joints • Therefore, for each prismatic joint of a machine, the contribution to the Jacobian (after normalizing) is: • Zi-1 which is the 3rd column of the matrix given by: A0 * … * Ai-1 • This is as expected based on the model on the previous slide (and our “move only one and then normalize it” method)

  48. Building the Linear Jacobian for Revolute Joints • This is a dicer problem, • but then, remembering the idea of prismatic joints on angular velocity … • But no that won’t work here – just because its a rotation, and it changes orientation of the end – revolute motion also does have a linear contribution effect to the motion of the end • This is a “levering effect” which moves the origin of the n-frame as we saw when discussing the del-operator on the -R structure. • We must compute and account for this effect and then normalize it too.

  49. Building the Linear Jacobian – Revolute Joints Using this model we would expect that a rotation i would ‘lever the end’ by an amount that is equivalent (in direction) to the CROSS product of the ‘driver’ vector and the ‘connector’ vector and with a magnitude equal to Joint velocity

  50. Building the Linear Jacobian – Revolute Joints This is the directional resultant (DR) vector given by: Zi-1 X di-1n [with Magnitude equal to joint speed!] Note the “Green” Vector is equal to the ‘red’ DR vector!

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