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Compliance in Robot Legs

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Title: Compliance in Robot Legs


1
Compliance in Robot Legs
  • Jonathan Hurst

2
(No Transcript)
3
Outline
  • Introduction
  • What is the long-term goal of this work?
  • What is the intent of this presentation?
  • Background, motivation
  • Running Spring Loaded Inverted Pendulum (SLIP)
  • Why are real springs important?
  • Future work
  • Current Research
  • Hardware!
  • Simulation and Control (in collaboration with
    Joel Chestnutt)
  • Future work

4
Introduction
  • The long-term goal is to build a bipedal robot
    that can walk, run, jump, hop on one foot up
    stairs, recover from a stumble, and generally
    behave in a dynamically stable manner
  • The goal of this presentation is to convince the
    listener of the following
  • Series compliance is essential for a successful
    running robot
  • Physically varying the stiffness of this series
    compliance is useful

5
Running
  • Animals
  • Compliant elements in limbs, used for energy
    storage
  • Energy consumption is lower than work output
  • The motion of the center of mass of a running
    animal is similar to that of a pogo stick, and is
    common to all animals Blickhan and Full, 93

6
Running
  • Running is loosely defined
  • Aerial phase
  • Energy transfer
  • The Spring Loaded Inverted Pendulum (SLIP) model
    Schwind and Koditschek, 97 closely approximates
    the motion of a running animals center of mass
  • Assumes no leg dynamics at all during flight
  • Assumes lossless, steady state, cyclical running
    gait
  • Assumes point mass ballistic dynamics for mass

Ideal, lossless model
7
SLIP
  • Control inputs
  • Leg Touchdown Angle, q
  • Leg Stiffness, K
  • Spring rest position, X
  • Gait parameters at steady state schwind, kod,
    97
  • Leg Ground Stiffness
  • Leg Length at the bottom of stance phase
  • Leg angular velocity at the bottom of stance
  • OR
  • Stride Length
  • Hopping Height
  • Leg Ground Stiffness

8
SLIP Observations of Animals
  • Animals maintain a relatively constant stride
    length, and change leg stiffness for these
    reasons
  • Changing ground stiffness
  • Different speeds within a gait
  • Changing gravity or payload
  • Ground stiffness changes are a bigger problem for
    bigger animalsFerris and Farley, 97

9
SLIP stiffness adjustment vs. mass
  • From experimental observations, leg stiffness
    scales with animal body massFarley, Glasheen,
    McMahon, 93
  • Springs in series add as inverses
  • Ground stiffness changes significantly for
    different terrain types
  • The lower the leg stiffness, the less global
    stiffness is affected by changing ground stiffness

10
SLIP
  • Observations of animal behavior gives us hints,
    not proofs
  • Do we really need a physical spring, or is
    spring-like behavior achievable without one?
  • Springs are needed for energetic reasons
  • Springs are needed for power output reasons
  • Springs are needed for bandwidth reasons

11
Energetics
  • Energy consumption should be minimized when
    designing and building a running robot
  • Tether-free
  • Large payload capacity
  • Long battery life
  • Natural dynamics affect energy consumption
  • Mimicking the control model (SLIP) with the
    systems natural dynamics is a good idea. So
    far, every running robot has used physical series
    springs.

12
Energetics CMU Bowleg
  • 70 spring restitution
  • Mass distribution
  • 0.8 spring
  • 5 batteries
  • 20 entire mechanism
  • 80 ballast
  • Used a spring hanging from the ceiling to
    simulate operation in 0.35G
  • Tensioned leg spring during flight
  • If a slightly larger motor replaced some ballast
    weight, the Bowleg could hop in 1G, but not
    without the spring

13
Energetics ARL Monopod
  • The most energy-efficient legged robot
  • Running speed of 4.5 km/h
  • Total power expenditure of 48W
  • 10.5 Joules of energy exerted by leg motor in
    each hop, for 135J of mechanical work

14
Energetics
  • A 4kg robot hopping 0.5m high yields a flight
    phase of 0.632 seconds
  • Assume stance and flight are symmetrical
  • Constant force of 40N
  • Work output of 20J
  • Power output of 32W
  • Robot with series spring and 70 restitution
  • Constant force of 40N
  • Work output of 6J by the motor, 14J by the spring
  • Power output of 3.8W by the motor, 28.8W by the
    spring
  • Violating the assumption of constant force spring
    only enhances the difference, favoring the
    series-spring method

15
Power Considerations
16
Bandwidth Considerations
  • Reflected rotor inertia dominates the natural
    dynamics
  • Inertia is proportional to the square of the gear
    reduction
  • Given the following values
  • Gear reduction 16 rev/m
  • Rotor inertia 0.00134 kg-m2
  • Reflected inertia of the motor is equivalent to
    leg mass of 13.5 kg
  • Kinetic energy in leg momentum is lost as an
    inelastic collision with the ground (a
    high-frequency input)
  • For a 30kg robot, much of the energy will be
    lost in an inelastic collision, and cannot be
    recovered through the electric motor

17
Summary of the facts so far
  • Animals have leg compliance
  • SLIP
  • Stride Length
  • Hopping Height
  • Leg Ground Stiffness
  • Animals physically vary leg stiffness
  • Series springs are important
  • Bandwidth
  • Power
  • Energy

18
Further Research
  • I think variable stiffness is important for a
    human-scale legged robot
  • The extent to which physically variable stiffness
    is important should be calculable
  • Cant make the stride length longer
  • Cant lower hopping height
  • Stiffness is the only thing left!

19
Current Research
  • Actuator with physically variable compliance
  • 2-DOF device, 1-DOF actuator
  • Motor 1 spring set point
  • Motor 2 cable tensionspring stiffness

20
Mechanism Design
  • Cable drive
  • Lightweight about 3 kg
  • Fiberglass springs for high energy density
  • Spiral pulleys impart nonlinearity to spring
    function
  • Electric motors allow for precise control
  • Very low friction on the leg side of the
    springs

21
Mechanical Model
22
Motor Position
time
Leg Position
time
23
Control
24
Control
25
Performance
  • We created a plot of
  • comparative max force
  • against frequency.
  • Peak spring force is measured on two models
  • The dynamic simulation, with physically realistic
    spring adjustment limits and the controller on M1
  • An idealized simulation, with no spring
    adjustment limits and M1 held stationary
  • X2 is forced to a sine function, cycling from 1
    to 100 Hz
  • If the Bode plot for the dynamic simulation were
    divided by the Bode plot for the idealized
    simulation, this would be the result.

26
Frequency-Magnitude plots
27
Frequency-Magnitude Plots
  • Physical adjustment is limited to 10 kN/m
  • Two discrepancies are apparent
  • 0.78 is the difference between fkx, described by
    the software controller, and the polynomial fit
    of our physical spring function
  • 0.6 is the difference between the peak forces of
    the natural dynamics of the two systems

28
System validation
  • We built a simulation of a runner with the full
    dynamic model of the actuator built in so its
    almost a SLIP
  • Raibert-style controller commands leg angle,
    energy insertion for a SLIP

29
Future Work
  • Show analytically how bandwidth is affected by
    the various parameters and situations of the
    actuator
  • Calculate the required range of variable
    stiffness, and rate of change
  • Put a hip on this thing, make it hop
  • Research and implement controllers for hopping
    height, stride length, speed on a step-to-step
    basis
  • Working with a team, build and control a running
    biped that can hop on one foot up stairs

30
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