QAISim: A Toolkit for Modeling and Simulation of AI in Quantum Cloud Computing Environments
- URL: http://arxiv.org/abs/2512.17918v1
- Date: Mon, 01 Dec 2025 16:14:25 GMT
- Title: QAISim: A Toolkit for Modeling and Simulation of AI in Quantum Cloud Computing Environments
- Authors: Irwindeep Singh, Sukhpal Singh Gill, Jinzhao Sun, Jan Mol,
- Abstract summary: We propose a python-based toolkit called QAISim for the simulation and modeling of Quantum Artificial Intelligence (QAI) models.<n>We have simulated policy gradient and Deep Q-Learning algorithms for reinforcement learning.
- Score: 0.9155342779211822
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Quantum computing offers new ways to explore the theory of computation via the laws of quantum mechanics. Due to the rising demand for quantum computing resources, there is growing interest in developing cloud-based quantum resource sharing platforms that enable researchers to test and execute their algorithms on real quantum hardware. These cloud-based systems face a fundamental challenge in efficiently allocating quantum hardware resources to fulfill the growing computational demand of modern Internet of Things (IoT) applications. So far, attempts have been made in order to make efficient resource allocation, ranging from heuristic-based solutions to machine learning. In this work, we employ quantum reinforcement learning based on parameterized quantum circuits to address the resource allocation problem to support large IoT networks. We propose a python-based toolkit called QAISim for the simulation and modeling of Quantum Artificial Intelligence (QAI) models for designing resource management policies in quantum cloud environments. We have simulated policy gradient and Deep Q-Learning algorithms for reinforcement learning. QAISim exhibits a substantial reduction in model complexity compared to its classical counterparts with fewer trainable variables.
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