HART Lab — Elizabeth Sonder
UC Berkeley · HART Lab · 2016

Soft Robotic
Actuators

Fluidic elastomer actuators and body-worn harness design for an assistive exoskeleton targeting elbow actuation assistance.

By Elizabeth Sonder, Human-Assistive Robotic Technologies Lab
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HART Lab — Human-Assistive Robotic Technologies, UC Berkeley

The HART Lab develops cyberphysical systems that interact with and assist the human body. Elizabeth Sonder contributed to the lab’s assistive devices project, designing fluidic elastomer actuators (FEAs) for elbow actuation assistance and the soft body harness that secured the device to the user.

UC Berkeley Assistive Devices Soft Robotics
Overview

What is a Fluidic Elastomer Actuator?

A fluidic elastomer actuator (FEA) is a soft robotic component made from silicone rubber chambers reinforced with inextensible fibers along their length. When pressurized with air, the restricted walls force the actuator to deflect in a controlled direction — bending rather than expanding uniformly.

For elbow assistance, this bending motion maps naturally onto the arc of the joint. The actuator is compliant against the body, conforming to the user’s anatomy rather than imposing a rigid exoskeleton structure. Elizabeth Sonder designed and fabricated the FEA unit for elbow actuation assistance and the soft harness worn on the body to secure and position it.

Actuator typeFluidic Elastomer Actuator (FEA)
MaterialSilicone rubber chambers, silk fiber reinforcement
MechanismInflation-driven bending via constrained elongation
Target jointElbow (flexion assistance)
Operating pressure60 psi (inflated state)
HarnessCustom soft body harness, worn on upper body
Harness materialSoft textile construction
ContextHART Lab assistive devices project, UC Berkeley
RoleFEA fabrication, harness design and construction
Actuator Design

FEA Construction

The actuator is built as a series of silicone rubber air chambers arranged along a central spine. Silk fibers wound along the length of each chamber prevent axial expansion, channeling all pneumatic force into a lateral bending deflection. The resulting motion closely follows the arc of the human elbow, making it suitable for wearable assistive applications.

Bare silicone chambers — top view
// Bare Silicone Chambers
Top and side view of the cast silicon chamber structure prior to fiber wrapping and fabric enclosure.
Bare silicone chambers — side view
// Chamber Profile
The leaf-shaped profile distributes pressure across the chamber array evenly, minimizing stress concentrations at the tips.
FEA uninflated, wrapped in fabric
// Uninflated
FEA encased in fabric sheath, uninflated. The actuator lies flat and compliant against the arm.
FEA inflated at 60psi
// Inflated at 60 psi
At 60 psi the constrained chambers drive the actuator into a tight curl, producing the elbow flexion force.
Two-part silicone molding process
// Molding Process
Two-part silicone rubber (Part A + Part B, mixed 50/50) measured into medicine cups before casting. The mold form is visible in the foreground.
Working Principle

Controlled Deflection via Fiber Constraint

Silicon rubber chambers restricted along the length of the chamber with silk fibers forces deflection in a controlled direction upon inflation.

— HART Lab, Soft Robotic Actuators presentation. Ref: Onal & Rus, “A Modular Approach to Soft Robots,” IEEE RAS/EMBS BioRob, 2012.
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// Pneumatic Actuation

Air pressure inflates the silicone chambers. Without constraint, they would expand radially. The fiber wrapping redirects this energy into bending.

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// Fiber Reinforcement

Silk fibers wound along the chamber length prevent axial elongation, acting as an inextensible constraint that converts internal pressure into a pure bending moment.

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// Body Compliance

The silicone construction is soft and compliant at rest, conforming to the user’s arm geometry without rigid contact points or pressure concentrations.

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// Joint-Specific Design

This unit was designed specifically for elbow flexion assistance, with chamber geometry and fiber angle tuned for the elbow’s range of motion and torque requirements.

Body Interface

Soft Harness Design

An actuator is only as effective as its coupling to the body. Elizabeth Sonder designed and constructed the soft textile harness that secures the FEA to the user’s upper body and positions it correctly relative to the elbow joint. The harness distributes reaction forces across the torso and upper arm, preventing the actuator from migrating during use while remaining comfortable and adjustable for different body sizes.

Harness worn on body, rear view
// Worn Configuration
Rear view of the harness worn by Elizabeth Sonder, showing the metal strut frame, pneumatic tubing routing, and soft textile body contact points.
Harness on mannequin
// Mannequin Display
The harness displayed on a torso mannequin at Maker Faire, showing the full upper-body frame structure and actuator mounting points.

// Design Considerations

The harness is a hybrid soft-rigid construction: a textile body layer distributes pressure across the torso and shoulders for comfort, while a metal strut frame provides the structural stiffness needed to anchor the pneumatic actuators against the reaction forces generated during inflation. Pneumatic tubing runs from a supply along the frame to the FEA positioned at the elbow.

Wearable assistive devices must balance compliance with the body surface against the structural rigidity needed to transmit actuation forces to the target joint. A harness that flexes too much under load allows the actuator to migrate, reducing assist effectiveness. The strut-and-textile approach addresses this directly: soft where it contacts skin, rigid where it carries load.

Research Context

Assistive Devices at HART Lab

The HART Lab’s assistive devices work sits within a broader research program on individualized human models for cyberphysical interactions, led by Professor Ruzena Bajcsy. The pipeline moves from measurement (kinematics and dynamics captured via 3D vision systems) through prescription (customized assistance profiles) to intervention — the physical actuation system that Elizabeth contributed to.

01 // MEASURE

Kinematics & Dynamics

3D vision (MS Kinect) captures individualized upper-limb motion and reachable workspace.

02 // PRESCRIBE

Customise Assistance

Patient-specific models determine the optimal stiffness and assist profile for the target joint.

03 // INTERVENE

Optimise Actuation

FEAs deliver variable-stiffness pneumatic assistance tuned to the individual’s needs.

Skills Demonstrated

What This Work Shows

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// Soft Robotics Fabrication

Design and fabrication of fluidic elastomer actuators from silicone rubber, including chamber molding, fiber reinforcement winding, and pressure testing.

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// Wearable Device Design

Custom soft harness construction for body-worn assistive devices. Force transfer, fit, and comfort considerations for upper-body wearables.

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// Human-Centered Engineering

Designing hardware that interfaces directly with the human body, accounting for anatomical variation, comfort, and the biomechanics of the target joint.

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// Research Lab Contribution

Hardware contribution to a UC Berkeley research program on individualized cyberphysical assistive systems, under Professor Ruzena Bajcsy.