SynergicLearning: Neural Network-Based Feature Extraction for Highly-Accurate Hyperdimensional Learning

Machine learning models differ in terms of accuracy, computational/memory complexity, training time, and adaptability among other characteristics. For example, neural networks (NNs) are well-known for their high accuracy due to the quality of their automatic feature extraction while brain-inspired h...

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Vydáno v:Digest of technical papers - IEEE/ACM International Conference on Computer-Aided Design s. 1 - 9
Hlavní autoři: Nazemi, Mahdi, Esmaili, Amirhossein, Fayyazi, Arash, Pedram, Massoud
Médium: Konferenční příspěvek
Jazyk:angličtina
Vydáno: Association on Computer Machinery 02.11.2020
Témata:
adaptability
Adaptation models
arbitrary NN
Artificial neural networks
automatic feature extraction
brain-inspired hyperdimensional learning models
classification components
computational efficiency
Computational modeling
Data models
end-to-end hardware realization
feature extraction
feature extractor
HD computing framework
HD learning models
high-performance HD
highly-accurate hyperdimensional learning
hybrid machine learning model
hybrid model
Hyperdimensional Learning
learning (artificial intelligence)
machine learning models
neural nets
neural network-based feature extraction
neural networks
On-line Learning
online learning
Parallel Processing
parameterized hardware implementation
synergic machine learning model
synergic models
Training
Training data
training time
ISSN:1558-2434
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Popis
Shrnutí:Machine learning models differ in terms of accuracy, computational/memory complexity, training time, and adaptability among other characteristics. For example, neural networks (NNs) are well-known for their high accuracy due to the quality of their automatic feature extraction while brain-inspired hyperdimensional (HD) learning models are famous for their quick training, computational efficiency, and adaptability. This work presents a hybrid, synergic machine learning model that excels at all the said characteristics and is suitable for incremental, on-line learning on a chip. The proposed model comprises an NN and a classifier. The NN acts as a feature extractor and is specifically trained to work well with the classifier that employs the HD computing framework. This work also presents a parameterized hardware implementation of the said feature extraction and classification components while introducing a compiler that maps any arbitrary NN and/or classifier to the aforementioned hardware. The proposed hybrid machine learning model has the same level of accuracy (i.e. ±1%) as NNs while achieving at least 10% improvement in accuracy compared to HD learning models. Additionally, the end-to-end hardware realization of the hybrid model improves power efficiency by 1.60x compared to state-of-the-art, high-performance HD learning implementations while improving latency by 2.13x. These results have profound implications for the application of such synergic models in challenging cognitive tasks.
ISSN:1558-2434
DOI:10.1145/3400302.3415696