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Analog circuits and systems research and education can benefit from the flexibility provided by large-scale Field Programmable Analog Arrays (FPAAs). This paper presents the hardware and software infrastructure supporting the use of a family of floating-gate based FPAAs being developed at Georgia Tech. This infrastructure is compact and portable and provides the user with a comprehensive set of tools...
Analog circuits and systems research and education can benefit from the flexibility provided by large-scale Field Programmable Analog Arrays (FPAAs). This demonstration will present visitors with the hardware and software infrastructure supporting the use of a family of floating-gate based FPAAs being developed at Georgia Tech. A picture of the programming and control hardware that will be demonstrated...
The RASP 2.8 is a very powerful reconfigurable analog computing platform with thirty-two computational analog blocks (CABs). Each CAB has a wide variety of sub-circuits ranging in granularity from multipliers and programmable offset wide linear range Gm blocks to NMOS and PMOS transistors. The programmable interconnects and circuit elements in the CAB are implemented using floating gate transistors...
This paper presents our programmable floating-gate dendrite model based upon our transistor channel models. We are developing a flexible, low-power, real-time computational engine for studying, understanding, and implementing neural computation. Here we present a systematic study of the dynamics seen in this silicon model, emphasizing the connection to conventional neurobiological modeling of dendrites...
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