simulating balance recovery responses to trips based on biomechanical principles takaaki shiratori...
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![Page 1: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/1.jpg)
Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles
Takaaki Shiratori1,2
Rakié Cham3
Brooke Coley3
Jessica K. Hodgins1,2
31 2
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Physical Simulation for Human Characters
Steady-state behaviors.
Reactive responses required.
Yin et al., 2007 Muico et al., 2009
1 http://lh6.ggpht.com/_UAku2WOHdSE/SlP6lTodsMI/AAAAAAAADOU/BFQRfrvySDM/
Interaction
1
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Clear obstacle.
Reactive Response to Trips
Collision with obstacle. Recover balance.Obstacle
Motion capture data Simulation
Biomechanical Principles
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Synthesize reactive responses.
Prior Work
Kudoh et al., 2002 Zordan et al., 2002
Simulation-based method
Ye et al., 2008
Biomechanics-based method
Not applicable to tripping.
Not for human characters.
Macchietto et al., 2009Komura et al., 2004
Trip and slip for bipedal robots.
Boone et al., 1997
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Strategies
Clearancewith tripped leg
Clearance withnon-tripped leg
Flight phase ordouble support
Flight phase ordouble support
Touchdown
Touchdown
Push-offreaction
Push-offreaction
Strategy selection
Collision in late swing
(40-75% of entire swing)
Collision in early swing(5-50% of entire swing)
Elevating strategy
Lowering strategy
[Eng et al. 1994, Schillings et al. 2000, Pijnappels et al. 2004, 2005]
Leg swap
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Ground reaction force vector passes anteriorly to the COM.
Push-off Reaction
[Pijnappels et al. 2005]
Reduce forward angular velocity.
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Increase moment of inertia to reduce angular acceleration.
Arm ipsilateral to tripped legmoves in sideward direction.
Arm contralateral to tripped legmoves in forward direction.
Protect head/chest.
Arm Motions
[Roos et al. 2008, Pijnappels et al. 2008]
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Subjects must not know when/where tripping occurs.
Capturing Tripping Motion
Trip machine
Harness
Semi-rigid shoe
Trip slide
Look here
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Elev.-DS Elev.-FL Lower.-DS Lower.-FL
# subjects 4 3 4 3
Speed [m/s](SD)
1.15(0.146)
1.44(0.0751)
0.942(0.191)
1.44(0.232)
Motion Capture Dataset
(DS: double support FL: flight phase)
Elevating Lowering
Faster walking speeds tend to lead to Flight Phase.
Elev.-DS Elev.-FL Lower.-DS Lower.-FL
# subjects 4 3 4 3
Speed [m/s](SD)
1.15(0.146)
1.44(0.0751)
0.942(0.191)
1.44(0.232)
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Human Model
Create a 3D skin model from ~400 optical markers. Calculate mass and moment of inertia from volume.
[Park and Hodgins 2006]
42 DOFsin total
96 contact pointsper foot.
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Finite state machine with Proportional Derivative (PD) servo.
Controller Overview
Yes
Collision PassiveReaction Clearance FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?Strategy?
COM startsfalling.
Tripped legtouches ground.
Elevating
Lowering
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Controller for Tripping Reactions
ElevatingYes
Collision PassiveReaction Clearance FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Lowering
Flight phase?Strategy?
COM startsfalling.
Tripped legtouches ground.
Baseline walkingPlayback of motion capture data.
SimulationInitialized with tripping forces just before trip occurs.
Simulation initialization
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Controller for Tripping Reactions
Yes
Collision PassiveReaction Clearance FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?Strategy?
COM startsfalling.
Tripped legtouches ground.
Observed tripping forces. Vertical: sine function Fore-aft: Gaussian function[Pijnappels, et al., 2004]
100
50
0
-50
-100
-150
-2000 0.020.040.060.080.10
Force [N]
Time [sec]
Fore-aft (x)Vertical (z)
x
z
Elevating
Lowering
Simulation initialization
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Controller for Tripping Reactions
Yes
Collision Clearance FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Support legControl attitude of upper body.
Swing leg Moving forward like walking.Target angles: motion capture data of walking.
PassiveReaction
Elevating
Lowering
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Knee torque
Controller for Tripping Reactions
Yes
Collision Clearance FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
PassiveReaction
Muscle activities
start.
Elevating
Vastus lateralis
Rectus femoris Transit: touch sensor brain muscle
Muscle recruitment (40 msec)
[Schillings et al. 2000][Pijnappels et al. 2005]
[Ralston et al. 1976]
Lowering
Support knee
0: tripping instant
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Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Elevatingstrategy?
COM startsfalling.
Tripped legtouches ground.
PassiveReaction
Muscle activities
start.Strategy?
Clearance
Support legPush-off reaction: Extend all joints.Compensation torque to ankle for COM.
)( zdzcc vvk
Elevating
Lowering
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Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Elevatingstrategy?
COM startsfalling.
Tripped legtouches ground.
Muscle activities
start.Strategy?
Clearance
Swing legClear the obstacle.Target angles:motion capture data.
Motion capture Simulation
Elevating
Lowering
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Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
Flight phase?
Flight
Leading legExtended for touchdown.Target angles:motion capture data.
Trailing legStart flexion. Motion capture Simulation
Elevating
Lowering
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Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance Flight
Leading legcontactsground.
Single SupportAfter Trip
Leading legControl attitude of upper body.
Trailing legMove forward for the next step.
Elevating
Lowering
![Page 20: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/20.jpg)
Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
Flight phase?
COM startsfalling.
Leading legExtended for the next stepTarget angles:motion capture data.
Trailing legControl attitude of upper body.Keep extension. Motion capture Simulation
Elevating
Lowering
![Page 21: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/21.jpg)
Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
Leading legcontactsground.
DoubleSupport
Leading legControl attitude of upper body and extend knee.
Trailing legControl attitude of upper body .Plantar-flex ankle for the next step.
Elevating
Lowering
![Page 22: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/22.jpg)
Controller for Elevating Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
DoubleSupport
Trailing leg leaves ground.
Single SupportAfter Trip
Leading legControl attitude of upper body.
Trailing legMove forward for the next step.
Elevating
Lowering
![Page 23: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/23.jpg)
Controller for Lowering Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Flight phase?
PassiveReaction
Elevatingstrategy?
COM startsfalling.
Tripped legtouches ground.
PassiveReaction
Muscle activities
start.Strategy?
Clearance
Leg SwapLeg Swap
Swing leg (tripped)Extended for touchdown immediately.
Elevating
Lowering
![Page 24: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/24.jpg)
Controller for Lowering Strategy
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
Leg Swap
Swing leg (tripped)Extended for touchdown immediately.
Support leg (non-tripped)Leaves ground after swing leg touchdown.Clear the obstacle.
Tripped legtouches ground.
Leg Swap
Clearance
Elevating
Lowering
![Page 25: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/25.jpg)
Start reaction.Timing: 100 msec
Target angles:motion capture data.
Control of Arm Motion
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
Clearance
Leg Swap
Clearance
Motion capture Simulation
[Pijnappels et al. 2008]
Elevating
Lowering
![Page 26: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/26.jpg)
Control of Arm Motion
Yes
Collision FlightSingle Support
After Trip
DoubleSupportFall
Muscle activities
start.
Leading legcontactsground.
Leading legcontactsground.
Trailing leg leaves ground.
No
Leg Swap
Flight phase?
PassiveReaction
Strategy?
COM startsfalling.
Tripped legtouches ground.
ClearanceSingle Support
After Trip
Back to motion in normal walking.
Motion capture(walking)
Simulation
Elevating
Lowering
![Page 27: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/27.jpg)
Elevating strategy with double support.Input walking speed: 1.0 m/s
Simulation Result
Elevating Lowering
DS FL DS FL
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Elevating strategy with flight phase.Input walking speed: 1.4 m/s
Simulation Result
Elevating Lowering
DS FL DS FL
![Page 29: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/29.jpg)
Lowering strategy with double support.Input walking speed: 0.75 m/s
Simulation Result
Elevating Lowering
DS FL DS FL
![Page 30: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/30.jpg)
Lowering strategy with flight phase.Input walking speed: 1.1 m/s
Simulation Result
Elevating Lowering
DS FL DS FL
![Page 31: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/31.jpg)
Elevating strategy with flight phase.
Comparison with Motion Capture Data
-100
-80
-60
-40
-20
0
20
-0.5 0 0.5 1.0
Pitch [deg]
Time [sec]-20
0
20
40
60
80
100
120
-0.5 0 0.5 1.0
Pitch [deg]
Time [sec]
Hip Knee
: tripping instant : simulation result : motion capture data
![Page 32: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/32.jpg)
Elevating strategy with flight phase.
Comparison with Motion Capture Data
Foot trajectory Pelvis-10-5 0 5
10 15 20 25 30 35 40 45
-0.5 0 0.5 1.0
Pitch [deg]
Time [sec]0
0.1
0.2
0.3
0.4
0.5
0 0.5 1.0
Height [m]
Length [m]
: tripping instant : simulation result : motion capture data
![Page 33: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/33.jpg)
Root mean square errors Unit: [deg/frame] (frame rate = 120 Hz)
Quantitative Comparison
![Page 34: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/34.jpg)
Recovery with multiple steps.
Discussion
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Better contact model Many force plates. Larger marker set for feet. More precise model of tripping forces.
Discussion
Push-off reaction Tripping forces.
![Page 36: Simulating Balance Recovery Responses to Trips Based on Biomechanical Principles Takaaki Shiratori 1,2 Rakié Cham 3 Brooke Coley 3 Jessica K. Hodgins 1,2](https://reader035.vdocuments.site/reader035/viewer/2022081520/56649f0a5503460f94c1e29d/html5/thumbnails/36.jpg)
Controllers for strategies of balance recovery responses to trips.
GraphicsIntegrate walking controllers.Other reactive responses.
Biomechanics applicationAnswer “what if” questions.Improve training and rehabilitation systems.
Summary
1 2
3
2 http://www.yamakai.org/profiles/marriott.html 1 http://www.youtube.com/watch?v=LVStmLCoH30
3 http://www.treadmilladviser.com/landice-l7-rehabilitation-treadmill.html
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Adam Bargteil for help with calculating mass and moment of inertia.
Moshe Mahler for rendering animation. Justin Macey for the human model. Subjects for participation in the experiments.
NSF -0540865 Quality of Life Technology Engineering Research Center
F31 AG025684-03 NIH Ruth L. Kirschstein Award Autodesk for Maya donation.
Acknowledgements