Energy-Reliability Limits in Nanoscale Feedforward Neural Networks and Formulas

Abstract: Due to energy-efficiency requirements, computational systems are now being implemented using noisy nanoscale semiconductor devices whose reliability depends on energy consumed. We study circuit-level energy-reliability limits for deep feedforward neural networks (multilayer perceptrons) built using such devices, and en route also establish the same limits for formulas (boolean tree-structured circuits). To obtain energy lower bounds, we extend Pippenger's mutual information propagation technique for characteri… Show more

“…In this work, we investigate this key issue in the context of in-memory computing, by first aiming to predict the effect of noisy memristor values onto the final DNN computation. The physical substrate of memristors and their computational and noise properties make the mathematical problem quite different from the above works [6]- [9].…”

“…It is shown in [6] that noise can sometimes help in the inference performance of neural networks by getting them unstuck from local minima. Several works in the literature also investigate the robustness of DNNs to undesired noise [7]- [9], though without considering the in-memory computation framework. As a key issue, the DNN robustness is strongly related to the power consumption of its electrical circuit implementation [9].…”

“…Several works in the literature also investigate the robustness of DNNs to undesired noise [7]- [9], though without considering the in-memory computation framework. As a key issue, the DNN robustness is strongly related to the power consumption of its electrical circuit implementation [9]. In this work, we investigate this key issue in the context of in-memory computing, by first aiming to predict the effect of noisy memristor values onto the final DNN computation.…”

Power-Efficient Deep Neural Networks with Noisy Memristor Implementation

“…In this work, we investigate this key issue in the context of in-memory computing, by first aiming to predict the effect of noisy memristor values onto the final DNN computation. The physical substrate of memristors and their computational and noise properties make the mathematical problem quite different from the above works [6]- [9].…”

“…It is shown in [6] that noise can sometimes help in the inference performance of neural networks by getting them unstuck from local minima. Several works in the literature also investigate the robustness of DNNs to undesired noise [7]- [9], though without considering the in-memory computation framework. As a key issue, the DNN robustness is strongly related to the power consumption of its electrical circuit implementation [9].…”

“…Several works in the literature also investigate the robustness of DNNs to undesired noise [7]- [9], though without considering the in-memory computation framework. As a key issue, the DNN robustness is strongly related to the power consumption of its electrical circuit implementation [9]. In this work, we investigate this key issue in the context of in-memory computing, by first aiming to predict the effect of noisy memristor values onto the final DNN computation.…”

Power-Efficient Deep Neural Networks with Noisy Memristor Implementation