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Gripping Parts at Concave Vertices

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Title: Gripping Parts at Concave Vertices


1
Gripping Parts at Concave Vertices
  • K. Gopal Gopalakrishnan
  • Ken Goldberg
  • U.C. Berkeley

2
Outline
  • Inspiration
  • Related Work
  • 2D v-grips
  • 3D v-grips
  • Conclusion

3
Inspiration
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Parts position and orientation are fixed.
8
Advantages
  • Inexpensive
  • Lightweight
  • Small footprint
  • Self-Aligning
  • Multiple grips

9
Outline
  • Inspiration
  • Related Work
  • 2D v-grips
  • 3D v-grips
  • Conclusion

10
Basics of Grasping
  • Summaries of results in grasping
  • Mason, 2001
  • Bicchi, Kumar, 2000
  • Rigorous definitions of Form and Force Closure
  • Rimon, Burdick, 1996
  • Mason, 2001

Mason, 2001
11
Orders of Form-Closure
  • First second order form-closure
  • Rimon, Burdick, 1995
  • For first order form-closure, n(n1)/21 contacts
    are necessary and sufficient
  • Realeaux, 1963
  • Somoff, 1900
  • Mishra, Schwarz, Sharir, 1987
  • Markenscoff, 1990

12
Other Related Work
Caging Grasps Rimon, Blake, 1999 Efficient
Computation of Nguyen regions Van der Stappen,
Wentink, Overmars, 1999 Multi-DOF Grips for
Robotic Fixtureless Assembly Plut, Bone, 1996
1997
13
Outline
  • Inspiration
  • Related Work
  • 2D v-grips
  • 3D v-grips
  • Conclusion

14
2D v-grips

Expanding.
Contracting.
15
2D Problem Definition
  • We first analyze two-dimensional parts on the
    horizontal plane.
  • Assumptions
  • Rigid Part.
  • No out-of-plane rotation.
  • Polygonal perimeter and Polygonal holes.
  • Frictionless contacts.
  • Zero Jaw radii.

16
2D Problem Definition
  • Let va and vb be two concave vertices.
  • We call the unordered pair ltva, vbgt a v-grip if
    jaws placed at these vertices will provide
    frictionless form-closure of the part.

va
vb
17
2D Problem Definition
Input Vertices of polygons representing the
parts boundary and/or holes, in
counter-clockwise order, and jaw radius. Output
A list (possibly empty) of all v-grips sorted by
quality measure.
18
2D Algorithm
Step1 We list all concave vertices. Step2 At
these vertices, we draw normals to the edges
through the jaws center. Step3 We label the
4 regions as shown
Theorem Both jaws lie strictly in the others
Region I means it is an expanding v-grip or Both
jaws lie in the others Region IV, at least one
strictly, means it is a contracting v-grip
19
Conditions for V-grip
Configurations like this are also
contracting v-grips
20
The Distance Function s(s1,s2)
  • Represents the distance between any 2 points
    on the parts perimeter.
  • The points are represented by an arclength
    parameter s.
  • Blake, Taylor, 1993 Rimon, Blake, 1998

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Proving the Theorem
The proof lies in proving the equivalence of
these 4 statements For any pair of concave
vertices ltv1,v2gt,
  • A v1 and v2 both lie strictly in the others
    region I.
  • B s(v1,s2) and s(s1,v2) are local maxima at
    s(v1,v2).
  • C s(v1,v2) is a strict local maximum of
    s(s1,s2).
  • D The grasp at v1,v2 is an expanding v-grip.

And similarly for contracting grasps (with region
IV and minima)
25
Proof Sketch
  • A ? B The shortest distance from a point to a
    line is along the perpendicular.
  • B ? C

26
Proof Sketch (Contd.)
  • C ? D Worst case analysis.
  • Any motion results in a collision.
  • D ? C Assume form-closure but not C.
  • Case I Contracting v-grip.
  • Form-Closure at non-extremum
  • Slide part along constant s contour.

27
2D Algorithm
Thus, If 2 vertices lie in region I of each other
(A is true), an expanding v-grip is achieved (D
is true). We enumerate all pairs of Concave
vertices and apply theorems 1 and 2 for each pair
to check for v-grips to generate an unranked list
of v-grips.
28
Ranking Grips
  • Based on sensitivity to small disturbances.
  • Relax the jaws slightly. (Change the distance
    between them.)
  • Consider maximum error in orientation due to this.

29
Ranking Grips
  • Maximum change in orientation occurs with one jaw
    at a vertex.
  • The metric is given by dq/dl.
  • Using sine rule and neglecting 2nd order terms,
  • dq/dl tan(f)/l

30
Ranking Grips Example
D
C
A
B
Metric evaluates grasp AC as better than BD
31
Computational Complexity
  • O(n) to identify k concave vertices.
  • O(k2) to list v-grips and evaluate metrics.
  • O(k2 log k) to sort list.
  • Total O(n k2 log k) for 0 radius

32
Jaws with non-zero radii
  • Jaw has a radius r
  • The part is transformed with a Minkowsky
    addition, offsetting the polygons with a disk of
    radius r.
  • Apply 2D algorithm to transformed part.
  • O(n log n) time required.

33
Outline
  • Inspiration
  • Related Work
  • 2D v-grips
  • 3D v-grips
  • Conclusion

34
3D v-grips
Initial orientation
Final orientation after v-grip
35
3D v-grips
Initial orientation
Final orientation after v-grip
36
3D Problem Definition
  • In 3D, v-grips can be achieved with a pair of
    frictionless vertical cylinders and a planar
    work-surface.
  • Assumptions
  • Rigid part
  • Part is defined by a polyhedron.
  • Frictionless contacts
  • Jaws have zero radii.

37
3D Problem Definition
  • 3D v-grip
  • Start from a stable initial orientation.
  • Close jaws monotonically.
  • Deterministic Quasi-static process.
  • Final configuration is a 3D v-grip if only
    vertical translation is possible.

Input A CAD model of the part and the position
of its center of mass. Output A list (possibly
empty) of all 3D v-grips.
38
3D Algorithm
  • We describe a numerical algorithm for computing
    all 3D v-grips.
  • The grasp occurs in 2 phases
  • Rotation in plane
  • Rotation out of plane
  • We find part trajectory during the second phase.

We describe the algorithm for contracting v-grips
39
Phase I
A candidate 2D v-grip occurs at end of phase
I This is because a minimum height of COM occurs
at minimum jaw distance
40
Phase II
All configurations in Phase II are candidate 2D
v-grips.
41
3D Algorithm
  • Enumerate starting positions.
  • Identify 2D v-grips of projections.
  • Compute Phase II trajectory
  • Incrementally close jaws.
  • Find local minimum of COM height among candidate
    2D v-grips.
  • Check termination criteria.

42
3D Algorithm Termination.
  1. 3D v-grip.
  • 3D equilibrium grip.
  • Part can move but Gripper cannot close.
  • The part falls away.
  • All termination conditions checked in
    wrench-space.

43
Example Gear Shaft
Orthogonal views
44
Gear Shaft
We assume that the gear is a cylinder (no teeth)
to allow gripping.
This part is symmetric about the axis (one
redundant degree of freedom). Search is thus
reduced to 0 dimensions!
45
Gear Shaft Solution
Part Orientation
Shaft Trajectory
46
3D Example without Symmetry
Orthogonal views
47
3D Example Part Trajectory
48
Outline
  • Inspiration
  • Related work
  • 2D v-grips
  • 3D v-grips
  • Conclusion

49
Conclusions 2D
  • Fast algorithm to find all 2D v-grips
  • Quality Metric that is fast to compute and is
    consistent with intuition in most cases.
  • Extended to non-zero jaw radii.
  • Implemented in Java applet available online.

50
Conclusions 3D
  • 3D algorithm determines all 3D v-grips.
  • The algorithm reduces a 6D search to a 1D search.
  • Critical part parameters for Design for Mfg

51
http//alpha.ieor.berkeley.edu/v-grips
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