Your search keyword '"Date, Prasanna"' showing total 5 results

1. A Classical-Quantum Hybrid Approach for Unsupervised Probabilistic Machine Learning

Author

Date, Prasanna, Schuman, Catherine, Patton, Robert, Potok, Thomas, Kacprzyk, Janusz, Series Editor, Arai, Kohei, editor, and Bhatia, Rahul, editor

Published

2020

2. Quantum discriminator for binary classification.

Author

Date, Prasanna and Smith, Wyatt

Subjects

*QUANTUM computers, *MACHINE learning, *QUBITS

Abstract

Quantum computers have the unique ability to operate relatively quickly in high-dimensional spaces—this is sought to give them a competitive advantage over classical computers. In this work, we propose a novel quantum machine learning model called the Quantum Discriminator, which leverages the ability of quantum computers to operate in the high-dimensional spaces. The quantum discriminator is trained using a quantum-classical hybrid algorithm in O (N log N) time, and inferencing is performed on a universal quantum computer in O (N) time. The quantum discriminator takes as input the binary features extracted from a given datum along with a prediction qubit, and outputs the predicted label. We analyze its performance on the Iris and Bars and Stripes data sets, and show that it can attain 99% accuracy in simulation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Adiabatic quantum linear regression.

Author

Date, Prasanna and Potok, Thomas

Subjects

*QUANTUM computing, *PROBLEM solving, *QUANTUM computers, *COMPUTER performance, *MACHINE learning, *PYTHON programming language, *REGRESSION analysis

Abstract

A major challenge in machine learning is the computational expense of training these models. Model training can be viewed as a form of optimization used to fit a machine learning model to a set of data, which can take up significant amount of time on classical computers. Adiabatic quantum computers have been shown to excel at solving optimization problems, and therefore, we believe, present a promising alternative to improve machine learning training times. In this paper, we present an adiabatic quantum computing approach for training a linear regression model. In order to do this, we formulate the regression problem as a quadratic unconstrained binary optimization (QUBO) problem. We analyze our quantum approach theoretically, test it on the D-Wave adiabatic quantum computer and compare its performance to a classical approach that uses the Scikit-learn library in Python. Our analysis shows that the quantum approach attains up to 2.8 × speedup over the classical approach on larger datasets, and performs at par with the classical approach on the regression error metric. The quantum approach used the D-Wave 2000Q adiabatic quantum computer, whereas the classical approach used a desktop workstation with an 8-core Intel i9 processor. As such, the results obtained in this work must be interpreted within the context of the specific hardware and software implementations of these machines. [ABSTRACT FROM AUTHOR]

Published

2021

4. Balanced k-means clustering on an adiabatic quantum computer.

Author

Arthur, Davis and Date, Prasanna

Subjects

*K-means clustering, *MACHINE learning, *QUANTUM computing, *PROOF of concept, *COMPUTER training, *QUANTUM computers

Abstract

Adiabatic quantum computers are a promising platform for efficiently solving challenging optimization problems. Therefore, many are interested in using these computers to train computationally expensive machine learning models. We present a quantum approach to solving the balanced k-means clustering training problem on the D-Wave 2000Q adiabatic quantum computer. In order to do this, we formulate the training problem as a quadratic unconstrained binary optimization (QUBO) problem. Unlike existing classical algorithms, our QUBO formulation targets the global solution to the balanced k-means model. We test our approach on a number of small problems and observe that despite the theoretical benefits of the QUBO formulation, the clustering solution obtained by a modern quantum computer is usually inferior to the solution obtained by the best classical clustering algorithms. Nevertheless, the solutions provided by the quantum computer do exhibit some promising characteristics. We also perform a scalability study to estimate the run time of our approach on large problems using future quantum hardware. As a final proof of concept, we used the quantum approach to cluster random subsets of the Iris benchmark data set. [ABSTRACT FROM AUTHOR]

Published

2021

5. QUBO formulations for training machine learning models.

Author

Date, Prasanna, Arthur, Davis, and Pusey-Nazzaro, Lauren

Subjects

*MACHINE learning, *DEEP learning, *QUANTUM computers, *SUPPORT vector machines, *REGRESSION analysis

Abstract

Training machine learning models on classical computers is usually a time and compute intensive process. With Moore's law nearing its inevitable end and an ever-increasing demand for large-scale data analysis using machine learning, we must leverage non-conventional computing paradigms like quantum computing to train machine learning models efficiently. Adiabatic quantum computers can approximately solve NP-hard problems, such as the quadratic unconstrained binary optimization (QUBO), faster than classical computers. Since many machine learning problems are also NP-hard, we believe adiabatic quantum computers might be instrumental in training machine learning models efficiently in the post Moore's law era. In order to solve problems on adiabatic quantum computers, they must be formulated as QUBO problems, which is very challenging. In this paper, we formulate the training problems of three machine learning models—linear regression, support vector machine (SVM) and balanced k-means clustering—as QUBO problems, making them conducive to be trained on adiabatic quantum computers. We also analyze the computational complexities of our formulations and compare them to corresponding state-of-the-art classical approaches. We show that the time and space complexities of our formulations are better (in case of SVM and balanced k-means clustering) or equivalent (in case of linear regression) to their classical counterparts. [ABSTRACT FROM AUTHOR]

Published

2021