Matthew Tesch scite author profile

Abstract-The design of a hyper-redundant serial-linkage snake robot is the focus of this paper. The snake, which consists of many fully enclosed actuators, incorporates a modular architecture. In our design, which we call the Unified Snake, we consider size, weight, power, and speed tradeoffs. Each module includes a motor and gear train, an SMA wire actuated bistable brake, custom electronics featuring several different sensors, and a custom intermodule connector. In addition to describing the Unified Snake modules, we also discuss the specialized head and tail modules on the robot and the software that coordinates the motion.

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Expensive multiobjective optimization for robotics

Tesch¹,

Schneider²,

Choset³

2013

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Expensive multiobjective optimization for robotics with consideration of heteroscedastic noise

Ariizumi

Tesch

Choset

et al. 2014

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Context Identification for Efficient Multiple-Model State Estimation of Systems With Cyclical Intermittent Dynamics

2011

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Using response surfaces and expected improvement to optimize snake robot gait parameters

Tesch

Schneider

Choset

2011

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Abstract-Several categories of optimization problems suffer from expensive objective function evaluation, driving the need for smart selection of subsequent experiments. One such category of problems involves physical robotic systems, which often require significant time, effort, and monetary expenditure in order to run tests. To assist in the selection of the next experiment, there has been a focus on the idea of response surfaces in recent years. These surfaces interpolate the existing data and provide a measure of confidence in their error, serving as a low-fidelity surrogate function that can be used to more intelligently choose the next experiment. In this paper, we robustly implement a previous algorithm based on the response surface methodology with an expected improvement criteria. We apply this technique to optimize open-loop gait parameters for snake robots, and demonstrate improved locomotive capabilities.

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Snakes on an inclined plane: Learning an adaptive sidewinding motion for changing slopes

Gong

Tesch

Rollinson

et al. 2014

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Multiobjective Optimization Based on Expensive Robotic Experiments under Heteroscedastic Noise

et al. 2017

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Matthew Tesch

Parameterized and Scripted Gaits for Modular Snake Robots

Design and architecture of the unified modular snake robot

Expensive multiobjective optimization for robotics

Expensive multiobjective optimization for robotics with consideration of heteroscedastic noise

Context Identification for Efficient Multiple-Model State Estimation of Systems With Cyclical Intermittent Dynamics

Using response surfaces and expected improvement to optimize snake robot gait parameters

Snakes on an inclined plane: Learning an adaptive sidewinding motion for changing slopes

Multiobjective Optimization Based on Expensive Robotic Experiments under Heteroscedastic Noise

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