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    Chapter 23 — Biomimetic Robots

    Kyu-Jin Cho and Robert Wood

    Biomimetic robot designs attempt to translate biological principles into engineered systems, replacing more classical engineering solutions in order to achieve a function observed in the natural system. This chapter will focus on mechanism design for bio-inspired robots that replicate key principles from nature with novel engineering solutions. The challenges of biomimetic design include developing a deep understanding of the relevant natural system and translating this understanding into engineering design rules. This often entails the development of novel fabrication and actuation to realize the biomimetic design.

    This chapter consists of four sections. In Sect. 23.1, we will define what biomimetic design entails, and contrast biomimetic robots with bio-inspired robots. In Sect. 23.2, we will discuss the fundamental components for developing a biomimetic robot. In Sect. 23.3, we will review detailed biomimetic designs that have been developed for canonical robot locomotion behaviors including flapping-wing flight, jumping, crawling, wall climbing, and swimming. In Sect. 23.4, we will discuss the enabling technologies for these biomimetic designs including material and fabrication.

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    Pop-up fabrication of the Harvard Monolithic Bee (Mobee)

    Author  Robert J. Wood

    Video ID : 398

    The Harvard Monolithic Bee is a millimeter-scale flapping winged robotic insect produced using printed-circuit MEMS (PC-MEMS) techniques. This video describes the manufacturing process, including pop-up book inspired assembly. This work was funded by the NSF, the Wyss Institute, and the ASEE. Music: D-Song by Bonobo.

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    Controlled flight of a biologically-inspired, insect-scale robot

    Author  Robert J. Wood

    Video ID : 399

    The Harvard Microrobotics Lab has demonstrated the first controlled flight of an insect-sized, flapping-wing robot. This video shows the 80 mg, piezoelectrically actuated robot achieving hovering flight and performing a simple lateral maneuver. Power and control signals are provided via wire tether. This work was funded by the NSF and the Wyss Institute.

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    RHex the parkour robot

    Author  Uluc Saranli, Martin Buehler, Daniel E. Koditschek

    Video ID : 400

    RHex is an all-terrain walking robot that could conceivably one day climb over rubble in a rescue mission or cross the desert with environmental sensors strapped to its back. The name is pronounced "Rex" like the over-excited puppy it resembles when it is bounding over the ground; RHex is short for "robot hexapod", a name that stems from its six springy legs.

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    Mini-Whegs™

    Author  Jeremy M. Morrey, Bram Lambrecht, Andrew D. Horchler, Roy E. Ritzmann, Roger D. Quinn

    Video ID : 401

    The video describes a new biologically inspired robot series called Mini-Whegs™. These 8-9 cm long robots can run at sustained speeds of over 10 body lengths per second and navigate in challenging terrain.

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    Robot dragonfly DelFly Explorer flies autonomously

    Author  Christophe De Wagter, Sjoerd Tijmons, Bart D.W. Remes, Guido C.H.E. de Croon

    Video ID : 402

    The DelFly Explorer is the first flapping-wing micro air vehicle that is able to fly with complete autonomy in unknown environments. Weighing just 20 g, it is equipped with a 4 g onboard, stereo-vision system. The DelFly Explorer can perform an autonomous take-off, maintain its height, and avoid obstacles for as long as its battery lasts (~9 min). All sensing and processing is performed onboard, so no human or offboard computer is in the loop.

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    Stanford Sprawl and iSprawl

    Author  Sangbae Kim, Jonathan E. Clark, Mark R. Cutkosky

    Video ID : 403

    The "Sprawl" family of hand-sized hexapedal robots is composed of prototypes designed to test ideas about locomotion dynamics, leg design and leg arrangement and to identify areas that can be improved by shape deposition manufacturing.

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    DASH: Resilient high-speed 16 g hexapedal robot

    Author  Paul Birkmeyer, Kevin C. Peterson, Ronald S. Fearing

    Video ID : 405

    DASH (dynamic autonomous sprawled hexapod) is a resilient high-speed 16 g hexapedal robot. Developed by P. Birkmeyer and R.S. Fearing, Biomimetic Millisystems Laboratory, University of California, Berkeley. Video presented at IEEE/IROS, St. Louis (2009).

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    HAMR3: An autonomous 1.7 g ambulatory robot

    Author  Andrew T. Baisch, Christian Heimlich, Michael Karpelson, Robert J. Wood

    Video ID : 406

    The successor to HAMR2, HAMR3 is a cockroach-inspired robot developed at the Harvard Microrobotics Lab by Andrew Baisch, Christian Heimlich, Michael Karpelson and Robert J. Wood. This version of the robot includes fully-integrated, onboard power electronics.

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    Undulatory gaits in a centipede millirobot

    Author  Katie L. Hoffman, Robert J. Wood

    Video ID : 407

    This video shows performances of several gait patterns which are specified by leg-cycle frequency and phase difference between legs on each side in a centipede-inspired multi-legged robot.

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    VelociRoACH

    Author  Duncan W. Haldane, Kevin C. Peterson, Fernando L. Garcia Bermudez, Ronald S. Fearing

    Video ID : 408

    UC Berkeley's miniature robot VelociRoACH. It is the latest version of the RoACH series which can run at extremely higher speeds relative to previous versions.

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