Quantum Algorithms for solving Hard Constrained Optimisation Problems
It addresses optimization challenges in domains such as social work scheduling and warehouse robotics, but appears incremental as it builds on existing quantum computing frameworks.
The thesis tackles hard constrained optimization problems like scheduling and robotics by developing quantum algorithms, including a new paradigm called quantum Case-Based Reasoning (qCBR) and an algorithm called EVA that speeds up variational quantum eigensolver (VQE) execution times.
The thesis deals with Quantum Algorithms for solving Hard Constrained Optimization Problems. It shows how quantum computers can solve difficult everyday problems such as finding the best schedule for social workers or the path of a robot picking and batching in a warehouse. The path to the solution has led to the definition of a new artificial intelligence paradigm with quantum computing, quantum Case-Based Reasoning (qCBR) and to a proof of concept to integrate the capacity of quantum computing within mobile robotics using a Raspberry Pi 4 as a processor (qRobot), capable of operating with leading technology players such as IBMQ, Amazon Braket (D-Wave) and Pennylane. To improve the execution time of variational algorithms in this NISQ era and the next, we have proposed EVA: a quantum Exponential Value Approximation algorithm that speeds up the VQE, and that is, to date, the flagship of the quantum computation. To improve the execution time of variational algorithms in this NISQ era and the next, we have proposed EVA: a quantum Exponential Value Approximation algorithm that speeds up the VQE, and that is, to date, the flagship of the quantum computation.