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MECH572A Introduction To Robotics

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Title: MECH572A Introduction To Robotics


1
MECH572AIntroduction To Robotics
  • Lecture 8

2
Review
  • Robot Kinematics
  • Geometric Analysis
  • Differential analysis
  • Forward (direct) vs. Inverse Kinematics
    problem
  • Inverse Kinematics Problem (IKP)
  • - Problem description Known QEE and pEE,
    Seek ?1, ?n
  • - Possibility of Analytical (closed form)
    solution depends on the architecture of the
    manipulator
  • - 6-R Decoupled manipulator (e.g., PUMA)
  • Position problem position of C
    (wrist centre)
  • Orientation problem EE orientation

3
Review
  • IKP 6-R Decoupled Manipulator
  • Solution process
    overview

Arm (position)
Wrist (orientation)
?1, ?2, ?3
?4, ?5, ?6
Eliminate ?2
Special geometry in wrist axis
Elimination
Equ's in ?1, ?3
Eliminate ?1
?1 ? 0
Quadratic equ in ?4 (?4)
Quartic equ in ?3 (?3)
Radical ? 0
?4
?3
Solution
?5
?2 ? 0
?1
?6
?2
Max Number of Solution 4
Max Number of Solution 2
4
Manipulator Kinematics
  • Velocity (Differential) Analysis

5
Manipulator Kinematics
  • Velocity Analysis
  • Angular velocity of EE
  • Position of EE

6
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • Define
  • Let

Position vector from Oi to P
Recall twist
7
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • Jacobian matrix
  • ith column (revolute joints)

Linear transformation between joint rates and
Cartesian rates (EE)
The Plücker array of ith axis w.r.t point P of EE
8
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • Prismatic joint
  • The ith column of Jacobian matrix

9
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • For 6 joint manipulator, J is a 6?6 square
    matrix
  • Solve equations using Gauss-elimination (LU
    decomposition) algorithm

Compute y (Forward substitution)
Compute (Backward substitution)
10
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • Transformation of Jacobian matrix
  • In general, Jacobian can be defined wrt
    different points. For decoupled manipulators
  • Recall twist transformation

Wrist Centre
Point P at EE
Two point A and B on EE
Property
11
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • The Jacobian matrix of decoupled Manipulator
    has special form
  • Partition arm and wrist rates

Arm rate
Wrist rate
12
Manipulator Kinematics
  • Velocity Analysis (cont'd)
  • Decoupled Manipulator solve 2 systems of
    three equations and three unknowns

13
Manipulator Kinematics
  • Application Example MSS/Canadarm2
  • Operating and control overview

Display Control Panel
Hand Controllers
Commands
Telemetry
Robotic Work Station (RWS)
MSS
14
Manipulator Kinematics
  • Application Example (cont'd)
  • Kinematic aspects of Canadarm2 control modes
  • 1. Human-in-the-loop modes (commanding the
    arm via hand controllers)
  • a) Manual Augmented Mode (MAM)
  • Description Control the manipulator
    by commanding EE rate
  • Kinematics IKP rate problem
  • b) Single Joint Rate Mode (SJRM)
  • Description Control the manipulator by
    commanding a single joint
  • Kinematics DKP rate problem

15
Manipulator Kinematics
  • Application Example (cont'd)
  • Kinematic aspects of Canadarm2 control modes
    (Cont'd)
  • 2. Automatic Modes
  • a) Joint Modes
  • Operator Commanded/Pre-Stored Joint Auto
    Modes (OJAM PJAM)
  • Description Execute joints movements to
    a pre-set joint positions
  • Kinematics DKP position/orientation
    problem
  • b) EE Modes (POR ltPoint Of Resolutiongt Mode)
  • Operator Commanded/Pre-Stored POR Auto
    Modes (OPAM PPAM)
  • Description Execute manipulator movements
    to a pre-set EE position/orientation
  • Kinematics IKP position/orientation
    problem

16
Manipulator Kinematics
  • Singularity Analysis Decoupled Manipulators
  • Observe the Jacobian Matrix
  • - If neither J12 nor J21 is singular, IKP
    problem is solvable
  • - Singularities of sub-Jacobian can be
    analyzed separately for decoupled manipulators
  • a) Singularity of J21
  • - Singularity of J21 depends on the
    relative orientation of the first three
    column vectors
  • - ?1 does not change relative
    orientation (viewpoint only)

17
Manipulator Kinematics
  • Singularity Analysis (cont'd)
  • General concept

L1
Locus of L One sheet hyperboloid surface
L2
L3
L
18
Manipulator Kinematics
  • Singularity Analysis (cont'd)
  • In summary Let L1, L2 and L3 represent e1,
    e2 and e3, respectively, if wrist centre C fall
    on the surface of hyperboloid, singularity
    occurs.
  • Example PUMA Robot
  • Case 1
  • C lies in the plane determined by
  • intersecting e1 and e2
  • e1? r1 and e2 ? r2 are coplanar
  • Velocity of C along the direction
  • perpendicular to e3? r3 and n12
  • (L direction) can not be produced
  • L intersects with e1at I, with
  • e2 and e3 at ?

19
Manipulator Kinematics
  • Singularity Analysis (cont'd)
  • Case 2
  • e2 and e3 are parallel
  • r2 and r3 lie in the same
  • plane
  • e2? r2 and e3? r3 are
  • coplanar
  • Velocity of C in the plane
  • determined by e2 and e3
  • normal to e1? r1 (L direction)
  • can not be produced

20
Manipulator Kinematics
  • Singularity Analysis (cont'd)
  • Geometric representation of singularity
  • Singularity lies in the line that
    represents nullspace of
  • no mapping
    between and
  • The range of J21 is perpendicular to the
    nullspace of
  • Wrist singularity J12 is singular
  • e4, e5 and e6 are coplanar
  • e.g.,

21
Manipulator Kinematics
  • Acceleration Analysis
  • Rate relationship
  • Differentiate wrt time
  • Solving equation using LU decomposition

Compute z (forward substitution)
Compute (Backward substitution)
22
Manipulator Kinematics
  • Acceleration Analysis (cont'd)
  • Computing the Jacobian rate
  • Recall
  • Differentiate

23
Manipulator Kinematics
  • Acceleration Analysis (contd)
  • Computing the Jacobian rate (cont'd)
  • where

24
Static Analysis
  • Mapping between joint torques and EE wrench
  • Joint torques
  • Wrench acting at EE
  • Power at EE
  • Power at joints

25
Static Analysis
  • Mapping between joint torques and EE wrench
    (cont'd)
  • Power conservation condition
  • Mapping EE wrench in Cartesian space to
    joint torques in joint space.

Recall
26
Static Analysis
  • Mapping between joint torques and EE wrench
    (cont'd)
  • 6-R Decoupled Manipulator
  • Solve the static problem for decoupled arm

Arm torques
Wrist torques
27
Manipulator Kinematics
  • Interpretation Jacobian Matrix
  • Mapping from n-D joint space to 6-D Cartesian
    space
  • The range of J (Column space) represents all
    possible EE twist that can be produced by the
    manipulator
  • If t lies in the range of J, then there exist a
    that produces t at EE
  • The nullspace of J transpose represent all
    singularities

28
Assignment 3
  • Problems 4.4, 4.7, 4.19
  • Due in two weeks
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