Understanding the bit-width precision is critical in compact representation of a Deep Neural Network (DNN) model with minimal degradation in the inference accuracy. While DNNs are resilient to small errors and noise as pointed out by many prior sources, there is a need to develop a generic mathematical framework for evaluating a given DNN’s sensitivity to input bit-width precision. In this work, we derive a bit-width precision estimator which incorporates the sensitivity of DNN inference accuracy to round-off errors, noise, or other perturbations in inputs. We use the tools of numerical linear algebra, particularly stability analysis, to establish the general bounds that can be imposed on the precision. Random perturbations and ‘worst-case’...
Despite having high accuracy, neural nets have been shown to be susceptible to adversarial examples,...
Recent successes of deep learning have been achieved at the expense of a very high computational and...
Due to limited size, cost and power, embedded devices do not offer the same computational throughput...
Understanding the bit-width precision is critical in compact representation of a Deep Neural Network...
The acclaimed successes of neural networks often overshadow their tremendous complexity. We focus on...
International audienceDeep Neural Networks (DNN) represent a performance-hungry application. Floatin...
The resurgence of machine learning in various applications and it's inherent compute-intensive natur...
Although Deep Neural Networks (DNNs) have shown incredible performance in perceptive and control tas...
We present any-precision deep neural networks (DNNs), which are trained with a new method that allow...
Recently, there has been a push to perform deep learning (DL) computations on the edge rather than t...
Deep neural networks (DNNs) have been shown to tolerate “brain damage”: cumulative changes to the ne...
Deep neural networks (DNNs) are being incorporated in resource-constrained IoT devices, which typica...
The pervasiveness of deep neural networks (DNNs) in edge devices enforces new requirements on inform...
Deep learning research has recently witnessed an impressively fast-paced progress in a wide range of...
Despite superior accuracy on most vision recognition tasks, deep neural networks are susceptible to ...
Despite having high accuracy, neural nets have been shown to be susceptible to adversarial examples,...
Recent successes of deep learning have been achieved at the expense of a very high computational and...
Due to limited size, cost and power, embedded devices do not offer the same computational throughput...
Understanding the bit-width precision is critical in compact representation of a Deep Neural Network...
The acclaimed successes of neural networks often overshadow their tremendous complexity. We focus on...
International audienceDeep Neural Networks (DNN) represent a performance-hungry application. Floatin...
The resurgence of machine learning in various applications and it's inherent compute-intensive natur...
Although Deep Neural Networks (DNNs) have shown incredible performance in perceptive and control tas...
We present any-precision deep neural networks (DNNs), which are trained with a new method that allow...
Recently, there has been a push to perform deep learning (DL) computations on the edge rather than t...
Deep neural networks (DNNs) have been shown to tolerate “brain damage”: cumulative changes to the ne...
Deep neural networks (DNNs) are being incorporated in resource-constrained IoT devices, which typica...
The pervasiveness of deep neural networks (DNNs) in edge devices enforces new requirements on inform...
Deep learning research has recently witnessed an impressively fast-paced progress in a wide range of...
Despite superior accuracy on most vision recognition tasks, deep neural networks are susceptible to ...
Despite having high accuracy, neural nets have been shown to be susceptible to adversarial examples,...
Recent successes of deep learning have been achieved at the expense of a very high computational and...
Due to limited size, cost and power, embedded devices do not offer the same computational throughput...