Large scale structure-aware pronoun resolution using quantum natural language processing

Abstract

Natural language consists of words, sentences, and larger units. Guided by grammatical structure, words compose with each other to form sentences. Similarly, guided by discourse structure, sentences compose with each other to form dialogues and documents. Classical machine learning algorithms have achieved significant success in learning the meanings of words. When it comes to meanings of sentences and discourse units, they however fall short of being compositional. The DisCoCat model of meaning, introduced by Clark, Coecke, and Sadrzadeh in 2010, provides a solution—at the sentence level—using higher-order tensors, the learning of which has been a challenge. A recent initiative known as Quantum Natural Language Processing (QNLP) introduces a translation between the DisCoCat tensors and Variational Quantum Circuits (VQC). This offers the potential of learning these higher-order tensors more efficiently when the circuits are executed on quantum computers. In previous work, we lifted the DisCoCat framework from the sentence level to the discourse level using a Fock space semantics. In this paper, we extend the DisCoCat-VQC translation to this semantics and experiment with it in a discourse task. We develop a massive dataset with 16,400 entries inspired by a major coreference resolution task, known as the Winograd Schema Challenge, proposed as a test of machine intelligence. Noisy and noiseless simulations were executed on IBMQ software, and the parameters of the discourse VQCs were learnt. The model converged to 77.5% accuracy, surpassing a Bag-of-Words model that neglects any structure. It also outperformed 2 out of 3 state-of-the-art classical coreference resolution architectures. These findings highlight the significant potential of quantum machine learning in advancing discourse analysis and structured natural language processing.