It is known in literature that a wheeled mobile robot (WMR), with fixed length axle, will undergo slip when it negotiates an uneven terrain. However, motion without slip is desired in WMR’s, since slip at the wheel-ground contact may result in significant wastage of energy and may lead to a larger burden on sensor based navigation algorithms. To avoid slip, the use of a variable length axle (VLA) has been proposed in the literature and the kinematics of the vehicle has been solved depicting no-slip motion. However, the dynamic issues have not been addressed adequately and it is not clear if the VLA concept will work when gravity and inertial loads are taken into account. To achieve slip-free motion on uneven terrain, we have proposed a three-wheeled WMR architecture with torus shaped wheels, and the two rear wheels having lateral tilt capability. The direct and inverse kinematics problem of this WMR has been solved earlier and it was shown by simulation that such a WMR can travel on uneven terrain without slip. In this paper, we derive a set of 27 ordinary differential equations (ODE’s) which form the dynamic model of the three-wheeled WMR. The dynamic equations of motion have been derived symbolically using a Lagrangian approach and computer algebra. The holonomic and nonholonomic constraints of constant length and no-slip, respectively, are taken into account in the model. Simulation results clearly show that the three-wheeled WMR can achieve no-slip motion even when dynamic effects are taken into consideration.

Issue Section:
Technical Papers
Keywords:
mobile robots, robot dynamics, mechanical contact, axles, wheels, differential equations, sensors
Topics:
Equations of motion, Mobile robots, Simulation, Wheels, Vehicles
1.
Waldron
,
K. J.
, 1995, “
Terrain Adaptive Vehicles
,”
J. Mech. Des.
1050-0472,
117B
, pp.
107
112
.
2.
Alexander
,
J. C.
,
Maddocks
,
J. H.
, 1989, “
On the kinematics of wheeled mobile robots
,”
Int. J. Robot. Res.
0278-3649,
8
, pp.
15
27
.
Crossref
Search ADS
 
3.
Muir
,
P. F.
, and
Neuman
,
C. P.
, 1987, “
Kinematic modeling of wheeled mobile robots
,”
J. Rob. Syst.
0741-2223,
4
, pp.
281
329
.
Crossref
Search ADS
 
4.
Bickler
,
D. B.
, 1998, “
Roving over Mars
,”
Mech. Eng. (Am. Soc. Mech. Eng.)
0025-6501,
120
, pp.
74
77
.
5.
Sreenivasan
,
S. V.
, and
Waldron
,
K. J.
, 1996, “
Displacement analysis of an actively articulated wheeled vehicle configuration with extension to motion planning on uneven terrain
,”
J. Mech. Des.
1050-0472,
118
, pp.
312
317
.
Crossref
Search ADS
 
6.
Wilcox
,
B. H.
, and
Gennery
,
D. B.
, 1987, “
A Mars rover for the 1990’s
,”
J. Br. Interplanet. Soc.
0007-084X,
40
, pp.
484
488
.
7.
Choi
,
B. J.
,
Sreenivasan
,
S. V.
, and
Davis
,
P. W.
, 1999, “
Two wheels connected by an unactuated variable length axle on uneven ground: Kinematic modeling and experiments
,”
ASME J. Mech. Des.
1050-0472,
121
, pp.
235
240
.
Crossref
Search ADS
 
8.
Davis
,
P. W.
,
Sreenivasan
,
S. V.
, and
Choi
,
B. J.
, 1997, “
Kinematics of two wheels joined by a variable-length axle on uneven terrain
,”
Proceedings of the ASME DETC’97
, Paper No. DETC97∕DAC-3857.
9.
Sreenivasan
,
S. V.
, and
Nanua
,
P.
, 1996, “
Kinematic Geometry of Wheeled Vehicle systems
,”
24th ASME Mechanisms Conference, Irvine, CA
, 96-DETC-MECH-1137.
10.
Choi
,
B. J.
, and
Sreenivasan
,
S. V.
, 1999 “
Gross motion characteristics of articulated robots with pure rolling capability on smooth uneven surfaces
,”
IEEE Trans. Rob. Autom.
1042-296X,
15
, pp.
340
343
.
Crossref
Search ADS
 
11.
Mackle
,
G.
,
Schirle
,
T.
, 2002, “
Active Tire Tilt Control—Das Neue Fahrwerkkonzept Des F400 Carving
,” “
11th Aachen colloquium on Vehicle and Engine Technology, RWTH
,” Vol.
1
.
12.
Harty
,
D.
, 2003, “
Brand-by-Wire—A Possiblity
SAE International Congress and Exhibition
, Paper No 2003-01-0097, Detroit, MI, March 2003.
13.
Zachrison
,
A.
,
Rösth
,
M.
,
Andersson
,
J.
, and
Werndin
,
R.
, 2003, “
EVOLVE a vehicle based test platform for active rear axle camber and steering control
,”
SAE International Congress and Exhibition
, Paper No. 2003-01-0581, Detroit.
14.
Chakraborty
,
N.
, and
Ghosal
,
A.
, 2003, “
Kinematics of wheeled mobile robots with toroidal wheels on uneven terrain
,”
Proceedings of ASME Design Engineering Technical Conference
, Paper No. DETC2003∕DAC-48846, Vol.
2B
, pp.
1331
1341
.
15.
Chakraborty
,
N.
, 2003, “
Modeling of Wheeled Mobile Robots on Uneven Terrain
,” M.Sc. thesis, ME Department, Indian Institute of Science, Bangalore, India.
16.
Farritor
,
S.
,
Hacot
,
H.
, and
Dubowsky
,
S.
, 1998, “
Physics-based planning for planetary Exploration
,”
Proceedings of the IEEE ICRA 1998, Leuven, Belgium
, pp.
278
283
.
17.
Haug
,
E. J.
, 1989,
Computer Aided Kinematics and Dynamics of Mechanical Systems
,
Allyn and Bacon
, Vol.
1
.
18.
Montana
,
D. J.
, 1988, “
The kinematics of contact and grasp
,”
Int. J. Robot. Res.
0278-3649,
7
, pp.
17
32
.
Crossref
Search ADS
 
19.
Wolfram
,
S.
, 1999,
The Mathematica Book
, 4th ed.,
Cambridge University Press
, Cambridge.
20.
ADAMS Users Guide
,
MSC Software
, USA.
21.
MATLAB Users Manual
,
Mathwork Inc.
, 1992.
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