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Embedding Quantum machine learning Leverage (statistics) Computer science Quantum Quantum circuit Algorithm Hilbert space Quantum algorithm Quantum computer Quantum information Theoretical computer science Quantum error correction Topology (electrical circuits) Mathematics Artificial intelligence Pure mathematics Quantum mechanics Physics Combinatorics

Seth Lloyd , Maria Schuld , Aroosa Ijaz , Josh Izaac , Nathan Killoran ·

YOU? · · 2020 · Open Access · · DOI: https://doi.org/10.48550/arxiv.2001.03622 · OA: W2998932335

Quantum classifiers are trainable quantum circuits used as machine learning models. The first part of the circuit implements a quantum feature map that encodes classical inputs into quantum states, embedding the data in a high-dimensional Hilbert space; the second part of the circuit executes a quantum measurement interpreted as the output of the model. Usually, the measurement is trained to distinguish quantum-embedded data. We propose to instead train the first part of the circuit -- the embedding -- with the objective of maximally separating data classes in Hilbert space, a strategy we call quantum metric learning. As a result, the measurement minimizing a linear classification loss is already known and depends on the metric used: for embeddings separating data using the l1 or trace distance, this is the Helstrom measurement, while for the l2 or Hilbert-Schmidt distance, it is a simple overlap measurement. This approach provides a powerful analytic framework for quantum machine learning and eliminates a major component in current models, freeing up more precious resources to best leverage the capabilities of near-term quantum information processors.