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Tire Modeling Lateral and Longitudinal Tire Forces GurkanErdogan, PhD April 27, 2009
Tire ModelingLateral and Longitudinal Tire Forces
Gurkan Erdogan, PhD
April 27, 2009
Why Tires are important
for Vehicle Control Systems?
• Tires generate the forces that drive and maneuver the vehicle.
• The knowledge of magnitude, direction and limit of the tire
forces are essential and valuable for vehicle control systems.forces are essential and valuable for vehicle control systems.
• However, the estimation of these variables in all driving
conditions and in real-time is a very challenging task.
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Horizontal Tire Forces
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How tire force is generated?
• Tire forces are generated inside the contact patch, in
other words between the tire and the ground.
• Tire forces are a combination of two factors: • Tire forces are a combination of two factors:
– Friction/sliding in the contact patch, and
– Elastic deformations/slipping of the tire.
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Background – Friction Forces
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Background – Friction Forces
• Stribeck Effect
– Stribeck (1902) observed that the friction force is decreasing
continuously with increasing velocities for low velocities.
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Background – Elastic Force
xkF ×=( )εσ ×= E
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Background – Friction/Elastic Forces
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Classification of Tire Mathematical Models
• Based on how you attack the problem…
from experimental
data only
using similarity
methods
through simple
physical model
through complex
physical model
empirical theoretical
• Based on which time behavior you can capture…
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Steady State
Models
Dynamic (Transient)
Models
Tire Modelsthrough simple physical models
• There are four main players in tire modeling through simple physical models
1. Tread deflection (with and w/o)
2. Carcass/belt deflection (with and w/o)
3. Distribution of contact pressure (symmetric and asymmetric dist.)
4. Tire-road friction properties (variable friction)
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Tire Modelsthrough simple physical models
• Brush Model– BM (Rigid Carcass)
– BM + Linear Carcass Defection
– BM + Parabolic Carcass Defection
– BM + Asymmetric Carcass Deflection– BM + Asymmetric Carcass Deflection
• String Model– Stretched String (No Tread Element)
– BM + Stretched String
• Beam Model
Ideally:
Some Concepts - Instantaneous Center of Rotation
Reality:
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ωωωωw
Some Concepts – Effective Radius
tr
t
arV
eff
weffeff
φ
ω
=
==
Rstat
Rw
a
φ
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t
φa
reff =
weffstat RrR <<
Slip Ratio: ( )weffx
xweff
xrV
Vr
ω
ωσ
,max
−=
Brush Model – Pure Longitudinal Slipthrough simple physical models
Longitudinal Tire Deformation
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xweffo VrV −= ω
0=gV
Remember…
BM – Pure Longitudinal Slip
Brush Model – Pure Side Slipthrough simple physical models
weffr ω
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Vθδα −=Slip Angle:
Brush Model – Pure Side Slipthrough simple physical models
• Uniform Normal Force Distribution
weffr ω
Fz
( ) ∫−
==a
a
zzz dxqFa
Fxp
2
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weffr ω
• Uniform Normal Force Distribution
Brush Model – Pure Side Slipthrough simple physical models
( )( )
( ) ( )zz
py
zzy
FFM
ac
FFF
µµ
αµ
µtan8
32
'
2
2
−=
−=Lateral Tire Force :
Tire Moment:
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( )( )
( )( )
( )bs
z
py
py
z
py
zz
xF
ac
ac
F
ac
FM
αµ
αµ
αµ
tan2
tan48tan8 23
'
=
−=
Friction Coefficient :
Tire Moment:
( ) 21
tan
1
222
max
−=−=α
µµµµ
ac
F
a
FF
xyFF
py
zzz
bsbzy
• Parabolic Normal Force Distribution
weffr ω
Fz
Brush Model – Pure Side Slipthrough simple physical models
( ) ( )∫−
=
−=
a
a
zz dxxpF
a
xa
a
Fxp
2
22
4
3
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weffr ω
Brush Model – Pure Side Slipthrough simple physical models
• Parabolic Normal Force Distribution
αθδ =− V
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• Parabolic Normal Force Distribution
– Small Slip Angle (as αααα����0, tan(αααα)���� αααα)
( ) ( )( )α
αxa
xay
−=
−= tan
ycq pyy =
Brush Model – Pure Side Slipthrough simple physical models
( )
y
py
a
a
py
a
a
yz
Fa
aac
dxxxac
dxxqM
3
32 2
=
−=
−=
=
∫
∫
−
−
α
α( )
α
α
α
αF
py
a
a
py
a
a
yy
C
ac
dxxac
dxqF
=
=
−=
=
∫
∫
−
−
22
( )αxa −=
Brush Model – Pure Side Slipthrough simple physical models
• Parabolic Normal Force Distribution
– Large Slip Angles
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( )( )
( )( )
( )( )
+−=
slslsl
zy FFαα
αα
αα
µ2
2
tan
tan
3
1
tan
tan1
tan
tan3
( )slz
py
F
acαµ tan
3
2 2
=
Lateral Tire Force :
Friction Coefficient :
( )( )
( )( )
( )( )
( )( )
}|tan
tan|)
tan
tan(3|
tan
tan|31{
tan
tan 32'
slslslsl
zz aFMαα
αα
αα
αα
µ −+−−=Tire Moment (Lateral):
• Theoretical Slips
( )
( )
−=+
−=
=
−=−
=+
−=−
=
=
driveV
V
brakeV
V
driveV
V
V
VV
brakeV
V
V
VV
sy
x
sy
y
sxxr
x
sx
x
xr
x
κα
α
σ
κκ
κ
σ
1
tan
tan
1
Brush Model – Combined Slipthrough simple physical models
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−=+
−==+
driveV
driveVV
rrr κκ 11
weffr rV ω= ( )
( )
22
yx
y
x
xav
xau
σσσ
σ
σ
+=
−=
−=
+−=
2
2
3
113
mmm
zFFσσ
σσ
σσ
µTire Force :
}331{3
3
2
2'
mmmm
zz aFMσσ
σσ
σσ
σσ
µ −+−−=Tire Moment:
Brush Model – Combined Slipthrough simple physical models
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m
z
p
F
acσµ
3
2 2
=Friction Coefficient :
mmmm
Friction Circle:
• Dugoff’s Model
_
_
yliny
xlinx
CF
CF
=
=
σ
σ
α
κ
Brush Model – Combined Slipthrough simple physical models
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( )( )
2
_
2
_
2
_
2
_2
_
2
_
_
_2
_
2
_
_
2
2
2,
2
1
1,
2
linylinx
z
linyy
linxxzlinylinx
linyy
linxxzlinylinx
yliny
FF
F
FF
FFFFFif
FF
FFFFFif
CF
+=
−×=
−×=>+
×=
×=≤+
=
µ
λ
λλλλµ
µ
σα
String Modelthrough simple physical models
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• The steady state tire models are handy when we have constant linear and angular velocities.
• Experimental data used to validate the slip/force curves are obtained using specialized equipment that allows independent linear and angular velocity modulation so as to cover the whole slip range.
Dynamic (Transient) Tire Modelsthrough simple physical models
• This steady-state point of view is rarely true in reality, especially when the vehicle goes through continuous successive phases between acceleration and braking.
• Dynamic models capture the transient behavior of the tire-road contact forces under time-varying velocity conditions.– Bliman
– Kinematic TM
– Dahl TM
– LuGre TM
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Dynamic Models – Relaxation Length
• Relaxation length
– is related to the distance needed by the tire to reach a the steady state situation after a step change in slip.
– is the distance needed to build up the steady state tire forces.
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( )veFz
FF
coulomb
o
F
x
coulombo
frictionndeformatio
sgn1
−=
=
−σ
σ zF
vvz
coulomb
oσ−=&
Dynamic Models – Dahl Modelsthrough simple physical models
The Dahl model is essentially Coulomb friction with a lag.
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( )
( )vv
ze
vvez
dt
dF
dt
dF
coulomb
o
coulomb
o
F
x
F
x
frictionndeformatio
sgn
sgn
&
&
=
=
=
−
−
σ
σ
Derivation
( )vFz
zF
vv
zz
o
coulombss
ss
coulomb
o
ss
sgn
0
0
σ
σ
=
−=
⇒=&
Steady State:
( ) ( )
( ) ( ) ( )veFvfzz
orveFz
FF
vg
x
coulombo
vg
x
coulombo
frictionndeformatio
o
o
sgn1
,sgn1
1
−=++
−=
=
−
−
σ
σ
σσ
σ
&
Dynamic Models –LuGre Modelsthrough simple physical models
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( )z
vg
vvz
oσ−=&
( ) ( )( ) vvf
eFFFvg stribeckvv
coulombstaticcoulomb
2σ
α
=
−+= −
Tire Modelsfrom experimental data only
• Pacejka TM
• Burckhardt TM
• Kiencke and Daiss TM
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TIREBLACK BOX
Create
TIRE
DEFORMATION
Measure
TIRE FORCE
( )SlipfForce =
Pacejka Tire Model (Magic Formula)from experimental data only
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References
• Vehicle Dynamics and Control, 2005, R. Rajamani
• Tire and Vehicle Dynamics, 2005, H.B. Pacejka
• Contact Mechanics, 1987, K.L. Johnson
• Vehicle Dynamics: Theory and Application, 2009, R. N. Jazar
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THANKS …
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