Process Scalability of Pulse-Based Circuits for Analog Image Convolution

Process Scalability of Pulse-Based Circuits for Analog Image Convolution

This paper studies the process scalability of pulse-mode CMOS circuits for analog 2-D convolution in computer vision systems. A simple, scalable architecture for an integrate and fire neuron is presented for implementing weighted addition of pulse-frequency modulated (PFM) signals. Sources of error...

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Veröffentlicht in:IEEE transactions on circuits and systems. I, Regular papers Regular papers, 2018-09, Vol.65 (9), p.2929-2938
Hauptverfasser: D'Angelo, Robert, Xiaocong Du, Salthouse, Christopher D., Hollosi, Brent, Freifeld, Geremy, Uy, Wes, Haiyao Huang, Nhut Tran, Chery, Armand, Jae-Sun Seo, Yu Cao, Poppe, Dorothy C., Sonkusale, Sameer R.
Format: Artikel
Sprache:eng
Schlagworte:
Analog circuits
Analog computers
Analytical models
Capacitors
CMOS
Computational modeling
Computer architecture
Computer simulation
Computer vision
Convolution
Integrated circuit modeling
neuromorphic circuits
Neurons
spiking neurons
Time-mode circuits
Vision systems
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Zusammenfassung:This paper studies the process scalability of pulse-mode CMOS circuits for analog 2-D convolution in computer vision systems. A simple, scalable architecture for an integrate and fire neuron is presented for implementing weighted addition of pulse-frequency modulated (PFM) signals. Sources of error are discussed and modeled in a detailed behavioral simulation and compared with equivalent transistor-level simulations. Next, the design of a 180-nm PFM chip with programmable weights is presented, and full image convolutions are demonstrated with the analog hardware. Preliminary chip measurements for a 45-nm implementation are also included to demonstrate process scalability. Design considerations for porting this architecture to nanometer processes, including FinFET technologies, are then discussed. This paper concludes with a simulation study on scaling down to 10 nm using a predictive technology model.
ISSN:1549-8328
1558-0806
DOI:10.1109/TCSI.2018.2821691