Mechanical Computing Systems Using Only Links and Rotary Joints

Author:

Merkle Ralph C.1,Freitas Robert A.1,Hogg Tad1,Moore Thomas E.2,Moses Matthew S.3,Ryley James4

Affiliation:

1. Institute for Molecular Manufacturing, Palo Alto, CA 94301 e-mail:

2. Independent Consultant, White Lake, MI 48383 e-mail:

3. Independent Consultant, Lafayette, CO 80026 e-mail:

4. Independent Consultant, Los Angeles, CA 90241 e-mail:

Abstract

A new model for mechanical computing is demonstrated that requires only two basic parts, links, and rotary joints. These basic parts are combined into two main higher level structures, locks, and balances, and suffice to create all necessary combinatorial and sequential logic required for a Turing-complete computational system. While working systems have yet to be implemented using this new approach, the mechanical simplicity of the systems described may lend themselves better to, e.g., microfabrication, than previous mechanical computing designs. Additionally, simulations indicate that if molecular-scale implementations could be realized, they would be far more energy-efficient than conventional electronic computers.

Publisher

ASME International

Subject

Mechanical Engineering

Reference40 articles.

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3. Mechanical Computing in Microelectromechanical Systems (MEMS),2003

4. Mechanical Computing Redux: Relays for Integrated Circuit Applications;Proc. IEEE,2010

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