Open Access Open Access  Restricted Access Subscription Access

Parallel Bijective Processing of Regular Nano Systolic Grids via Carbon Field Emission Controlled - Switching


Affiliations
1 Electrical Engineering Department, Philadelphia University, Jordan, Jordan
2 Department of Physics, Mu'tah University, Al-Karak, Jordan
3 German Association for International Cooperation (GIZ), Germany
4 Electrical Engineering Department, Philadelphia University, Jordan
 

New implementations for parallel processing applications using reversible systolic networks and the corresponding nano and field-emission controlled-switching components is introduced. The extensions of implementations to many-valued field-emission systolic networks using the introduced reversible systolic architectures are also presented. The developed implementations are performed in the reversible domain to perform the required parallel computing. The introduced systolic systems utilize recent findings in field emission and nano applications to implement the function of the basic reversible systolic network using nano controlled-switching. This includes many-valued systolic computing via carbon nanotubes and carbon field-emission techniques. The presented realization of reversible circuits can be important for several reasons including the reduction of power consumption, which is an important specification for the system design in several future and emerging technologies, and also achieving high performance realizations. The introduced implementations for non-classical systolic computation are new and interesting for the design within modern technologies that require optimal design specifications of high speed, minimum power and minimum size, which includes applications in adiabatic low-power signal processing.

Keywords

Carbon Nanotubes and Nanotips, Controlled Switching, Field Emission, Reversibility, Systolic Grids.
User
Notifications
Font Size

Abstract Views: 381

PDF Views: 158




  • Parallel Bijective Processing of Regular Nano Systolic Grids via Carbon Field Emission Controlled - Switching

Abstract Views: 381  |  PDF Views: 158

Authors

A. N. Al-Rabadi
Electrical Engineering Department, Philadelphia University, Jordan, Jordan
M. S. Mousa
Department of Physics, Mu'tah University, Al-Karak, Jordan
R. F. Al-Rabadi
German Association for International Cooperation (GIZ), Germany
S. Alnawasreh
Department of Physics, Mu'tah University, Al-Karak, Jordan
B. Altrabsheh
Electrical Engineering Department, Philadelphia University, Jordan
M. A. Madanat
Department of Physics, Mu'tah University, Al-Karak, Jordan

Abstract


New implementations for parallel processing applications using reversible systolic networks and the corresponding nano and field-emission controlled-switching components is introduced. The extensions of implementations to many-valued field-emission systolic networks using the introduced reversible systolic architectures are also presented. The developed implementations are performed in the reversible domain to perform the required parallel computing. The introduced systolic systems utilize recent findings in field emission and nano applications to implement the function of the basic reversible systolic network using nano controlled-switching. This includes many-valued systolic computing via carbon nanotubes and carbon field-emission techniques. The presented realization of reversible circuits can be important for several reasons including the reduction of power consumption, which is an important specification for the system design in several future and emerging technologies, and also achieving high performance realizations. The introduced implementations for non-classical systolic computation are new and interesting for the design within modern technologies that require optimal design specifications of high speed, minimum power and minimum size, which includes applications in adiabatic low-power signal processing.

Keywords


Carbon Nanotubes and Nanotips, Controlled Switching, Field Emission, Reversibility, Systolic Grids.