Title :
Asynchronous embryonics
Author :
Jackson, Alexander H. ; Tyrrell, Andrew M.
Author_Institution :
Dept. of Electron., York Univ., UK
Abstract :
As embryonic arrays take inspiration from nature they display biological properties, namely complex structure and fault-tolerance. However, they have yet to take advantage of a further biological feature at a fundamental level; asynchronous operation. In addition to the benefits normally associated with asynchronous digital design, such as intrinsic power management, two areas in which embryonic arrays could benefit are scalability and reliability. This paper gives an overview of embryonic systems and a pertinent asynchronous methodology, that of macromodules. It is shown that a macromodule approach allows the implementation of asynchronous circuits on Xilinx Virtex FPGAs using only the standard design tools. A preliminary VHDL simulation illustrates the operation of an asynchronous embryonic array. Although mentioned, little detail of the reconfiguration scheme is given for brevity. This simulation brings truly asynchronous embryonic circuits a step closer
Keywords :
asynchronous circuits; asynchronous sequential logic; fault tolerant computing; logic CAD; reconfigurable architectures; VHDL simulation; Xilinx Virtex FPGAs; asynchronous circuits; asynchronous digital design; asynchronous embryonic array; asynchronous operation; complex structure; embryonic arrays; fault-tolerance; macromodule approach; power management; reconfiguration scheme; reliability; scalability; Asynchronous circuits; Circuit simulation; Displays; Embryo; Energy management; Fault tolerance; Field programmable gate arrays; Power system management; Power system reliability; Scalability;
Conference_Titel :
Evolvable Hardware, 2001. Proceedings. The Third NASA/DoD Workshop on
Conference_Location :
Long Beach, CA
Print_ISBN :
0-7695-1180-5
DOI :
10.1109/EH.2001.937963
