AFAM: An Articulated Four Axes Microrobot for Nanoscale Applications

This paper presents a microassembled robot called the Articulated Four Axes Microrobot (AFAM). Target application areas include micro and nano part manipulation and probing. The robot consists of a cantilever actuated along four axes: in-place X, Y and YAW ; out-of-plane pitch. The microrobot size s...

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Bibliographic Details
Published inIEEE transactions on automation science and engineering Vol. 10; no. 2; pp. 276 - 284
Main Authors Murthy, Rakesh, Stephanou, Harry E., Popa, Dan O.
Format Journal Article
LanguageEnglish
Published New York IEEE 01.04.2013
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Actuators
Assembly
Automation
Fabrication
Finite element analysis
Force
Joints
Microassembly
Microbots
microelectromechanical systems (MEMS)
microrobot
Nanoscale devices
Prototypes
Reliability
Robots
Simulation
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Summary:This paper presents a microassembled robot called the Articulated Four Axes Microrobot (AFAM). Target application areas include micro and nano part manipulation and probing. The robot consists of a cantilever actuated along four axes: in-place X, Y and YAW ; out-of-plane pitch. The microrobot size spans a total volume of 3~{\rm mm}\times 1.5~{\rm mm}\times 1~{\rm mm} ( XYZ ), and operates within a workspace envelope of 50~\mu{\rm m}\times 50~\mu{\rm m}\times 75~\mu{\rm m} ( XYZ ). This is by far the largest operating envelope of any micropositioner with nonplanar dexterity. As a result it can be classified as a new type of three-dimensional microrobot and a candidate for miniaturizing top-down assembly systems to dimensions under 1~{\rm cm}^{3} . A key feature in this design is a cable-like microwire that transforms in-plane actuator displacement into out-of-plane pitch and yaw motion (via flexure joints). Finite-element analysis simulation followed by microfabrication and assembly processes developed to prototype the designs are described. The microrobot is designed to carry an AFM tip as the end effector and accomplish nanoindentation on a polymer surface. The tip attachment technique and nanoindentation experiments have also been described in this paper. Open loop precision has been characterized using a laser interferometer which measured an average resolution of 50 nm along XYZ , repeatability of 100 nm and accuracy of 500 nm. Experiments to determine microrobot reliability are also presented.
ISSN:1545-5955
1558-3783
DOI:10.1109/TASE.2012.2217740