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Quantum computing offers a faster way to train machine learning models. This study reformulates linear regression, SVM, and k-means clustering for adiabatic quantum computers, showing improved or equivalent computational efficiency.

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Area of Science:

  • Quantum Computing
  • Machine Learning
  • Computational Complexity

Background:

  • Classical machine learning training is computationally intensive.
  • Moore's Law limitations necessitate novel computing approaches.
  • Quantum computing, particularly adiabatic quantum computing, shows promise for complex problem-solving.

Purpose of the Study:

  • To reformulate machine learning training problems for adiabatic quantum computers.
  • To explore the potential of quantum computing in addressing the computational demands of machine learning.
  • To analyze and compare the computational complexity of quantum-enhanced machine learning algorithms with classical methods.

Main Methods:

  • Formulation of linear regression, support vector machine (SVM), and balanced k-means clustering training as Quadratic Unconstrained Binary Optimization (QUBO) problems.
  • Analysis of the computational time and space complexities of the proposed QUBO formulations.
  • Comparison of the quantum formulations' complexities against state-of-the-art classical algorithms.

Main Results:

  • Successfully formulated training for linear regression, SVM, and balanced k-means as QUBO problems.
  • Demonstrated that the proposed quantum formulations offer better or equivalent time and space complexities compared to classical approaches for SVM, balanced k-means, and linear regression, respectively.
  • Established the feasibility of using adiabatic quantum computers for efficient machine learning model training.

Conclusions:

  • Adiabatic quantum computers can efficiently train machine learning models by leveraging QUBO formulations.
  • Quantum computing presents a viable path for machine learning in the post-Moore's Law era.
  • The proposed QUBO formulations pave the way for practical quantum machine learning applications.