n-bit Data Parallel Spin Wave Logic Gate

Abdulqader Mahmoud1,a, Frederic Vanderveken2,d, Florin Ciubotaru2,e, Christoph Adelmann2,f, Sorin Cotofana1,b and Said Hamdioui1,c

1Computer Engineering Laboratory, Delft University of Technology, Delft, Netherlands
aA.N.N.Mahmoud@tudelft.nl
bFlorin.Ciubotaru@imec.be
cChristoph.Adelmann@imec.be
2Logic Technologies, IMEC, Leuven, Belgium
dS.D.Cotofana@tudelft.nl
eS.Hamdioui@tudelft.nl
fFrederic.Vanderveken@imec.be

ABSTRACT

Due to their very nature, Spin Waves (SWs) created in the same waveguide, but with different frequencies, can coexist while selectively interacting with their own species only. The absence of inter-frequency interferences isolates input data sets encoded in SWs with different frequencies and creates the premises for simultaneous data parallel SW based processing without hardware replication or delay overhead. In this paper we leverage this SW property by introducing a novel computation paradigm, which allows for the parallel processing of n-bit input data vectors on the same basic SW based logic gate. Subsequently, to demonstrate the proposed concept, we present 8-bit parallel 3-input Majority gate implementation and validate it by means of Object Oriented MicroMagnetic Framework (OOMMF) simulations. To evaluate the potential benefit of our proposal we compare the 8-bit data parallel gate with equivalent scalar SW gate based implementation. Our evaluation indicates that 8-bit data 3-input Majority gate implementation requires 4:16x less area than the scalar SW gate based equivalent counterpart while preserving the same delay and energy consumption figures.

Keywords: Spin-waves, Spin-wave Computing, Logic Gate, Multi-frequency, Data Parallelism, Energy, Delay, Area.



Full Text (PDF)