Your search keyword '"W., Romaszkan"' showing total 2 results

1. GEO: Generation and Execution Optimized Stochastic Computing Accelerator for Neural Networks

Author

W. Romaszkan, Tianmu Li, Puneet Gupta, and Sudhakar Pamarti

Subjects

Acceleration, Stochastic computing, Artificial neural network, Coupling (computer programming), Computer science, Binary number, Throughput (business), Lower energy, Efficient energy use, Computational science

Abstract

Stochastic computing (SC) has seen a renaissance in recent years as a means for machine learning acceleration due to its compact arithmetic and approximation properties. Still, SC accuracy remains an issue, with prior works either not fully utilizing the computational density or suffering from significant accuracy losses. In this work, we propose GEO - Generation and Execution Optimized Stochastic Computing Accelerator for Neural Networks, which optimizes stream generation and execution components of SC, and bridges the accuracy gap between stochastic computing and fixed-point neural networks. It improves accuracy by coupling controlled stream sharing with training and balancing OR and binary accumulations. GEO further optimizes the SC execution through progressive shadow buffering and architectural optimizations. GEO can improve accuracy compared to state-of-the-art SC by 2.2-4.0% points while being up to 4.4X faster and 5.3X more energy efficient. GEO eliminates the accuracy gap between SC and fixed-point architectures while delivering up to 5.6X higher throughput and 2.6X lower energy.

Published

2021

2. ACOUSTIC: Accelerating Convolutional Neural Networks through Or-Unipolar Skipped Stochastic Computing

Author

Sudhakar Pamarti, Tianmu Li, W. Romaszkan, Puneet Gupta, and Tristan Melton

Subjects

010302 applied physics, Hardware architecture, Stochastic computing, Artificial neural network, Computer science, Inference, 02 engineering and technology, 01 natural sciences, Convolutional neural network, Power budget, 020202 computer hardware & architecture, Neuromorphic engineering, Computer engineering, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Efficient energy use

Abstract

As privacy and latency requirements force a move towards edge Machine Learning inference, resource constrained devices are struggling to cope with large and computationally complex models. For Convolutional Neural Networks, those limitations can be overcome by taking advantage of enormous data reuse opportunities and amenability to reduced precision. To do that however, a level of compute density unattainable for conventional binary arithmetic is required. Stochastic Computing can deliver such density, but it has not lived up to its full potential because of multiple underlying precision issues. We present ACOUSTIC: Accelerating Convolutions through Or-Unipolar Skipped sTochastIc Computing, an accelerator framework that enables fully stochastic, high-density CNN inference. Leveraging split-unipolar representation, OR-based accumulation and novel computation-skipping approach, ACOUSTIC delivers server-class parallelism within a mobile area and power budget - a 12mm2 accelerator can be as much as 38.7x more energy efficient and 72.5x faster than conventional fixed-point accelerators. It can also be up to 79.6x more energy efficient than state-of-the-art stochastic accelerators. At the lower-end ACOUSTIC achieves 8x-120X inference throughput improvement with similar energy and area when compared to recent mixed-signal/neuromorphic accelerators.

Published

2020