Comparative study of variational quantum circuit and quantum backpropagation multilayer perceptron for COVID-19 outbreak predictions

• URL: http://arxiv.org/abs/2008.07617v2
• Date: Wed, 19 Aug 2020 11:21:59 GMT
• Title: Comparative study of variational quantum circuit and quantum backpropagation multilayer perceptron for COVID-19 outbreak predictions
• Authors: Pranav Kairon and Siddhartha Bhattacharyya
• Abstract summary: We present a comparative analysis of continuous variable quantum neural networks (Variational circuits) and quantum backpropagating multi layer perceptron (QBMLP) We provide a statistical comparison between two models, both of which perform better than the classical artificial neural networks.
• Score: 7.481372595714034
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: There are numerous models of quantum neural networks that have been applied to variegated problems such as image classification, pattern recognition etc.Quantum inspired algorithms have been relevant for quite awhile. More recently, in the NISQ era, hybrid quantum classical models have shown promising results. Multi-feature regression is common problem in classical machine learning. Hence we present a comparative analysis of continuous variable quantum neural networks (Variational circuits) and quantum backpropagating multi layer perceptron (QBMLP). We have chosen the contemporary problem of predicting rise in COVID-19 cases in India and USA. We provide a statistical comparison between two models , both of which perform better than the classical artificial neural networks.

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