Your search keyword '"Kim, Jeeson"' showing total 2 results

1. Hardware-Efficient Emulation of Leaky Integrate-and-Fire Model Using Template-Scaling-Based Exponential Function Approximation.

Author

Kim, Jeeson, Kornijcuk, Vladmir, Ye, Changmin, and Jeong, Doo Seok

Subjects

*EXPONENTIAL functions, *GATE array circuits, *MEMBRANE potential, *REACTIVE power, *APPROXIMATION algorithms

Abstract

We present a method to emulate a leaky integrate-and-fire (LIF) model in a field-programmable gate array (FPGA) in a hardware-efficient manner. The simplified spike-response model (SRM0) is chosen as an LIF model. For the hardware-efficient implementation of SRM0, we adopt the template-scaling-based exponential function approximation (TS-EFA). This method allows high precision and low latency exponential function approximations with the efficient use of hardware resources. We subsequently propose an algorithm for SRM0, which leverages the advantage of TS-EFA. An implementation of 512 neurons conforming to SRM0 in an FPGA highlights (i) high precision of SRM0 emulation (mean squared error of membrane potential approximation: $4\times 10^{-12} - 1\times 10^{-10}$), (ii) low latency (eight clock cycles), and (iii) high efficiency in hardware usage (only 125b memory per neuron). [ABSTRACT FROM AUTHOR]

Published

2021

2. Nano-Intrinsic True Random Number Generation: A Device to Data Study.

Author

Kim, Jeeson, Nili, Hussein, Truong, Nhan Duy, Ahmed, Taimur, Yang, Jiawei, Jeong, Doo Seok, Sriram, Sharath, Ranasinghe, Damith C., Ippolito, Samuel, Chun, Hosung, and Kavehei, Omid

Subjects

*RANDOM numbers, *RANDOM number generators, *MACHINE learning, *FIELD-effect transistors, *RANDOM noise theory

Abstract

We present a circuit technique to extract true random numbers from carrier capture and emission in oxide traps in the emerging redox-based resistive memory (ReRAM). This phenomenon that appears as small changes in current magnitude passing through the device is known as random telegraph noise (RTN) and is increasingly becoming a source of reliability issues in nanometer-scale devices. We demonstrate a circuit that exploits TRN suitable for a true random number generator (TRNG) in security applications, where the system is secure from different adversarial attacks, including side-channel monitoring and machine learning analysis. We experimentally characterize RTN in ReRAMs and extract its dependency to temperature, voltage, and area. We introduce an RTN harvesting circuit to mitigate sensitivities to temperature fluctuations, injected supply noise, and power signal monitoring. We reduced bias and imbalance in data due to high-speed sampling via von Neumann whitening. The circuit is compared to conventional non-differential readout approach. Our approach shows a 7.26 times improvement in autocorrelation and significant resilience against the injected supply noise. We also demonstrate the TRNG’s quality and robustness using statistical tests and machine learning attacks. The output of the generator satisfies statistical tests for randomness and is immune to modeling attacks based on the machine learning methods. [ABSTRACT FROM AUTHOR]

Published

2019