Enhancing Future Link Prediction in Quantum Computing Semantic Networks through LLM-Initiated Node Features
- URL: http://arxiv.org/abs/2410.04251v1
- Date: Sat, 5 Oct 2024 18:16:07 GMT
- Title: Enhancing Future Link Prediction in Quantum Computing Semantic Networks through LLM-Initiated Node Features
- Authors: Gilchan Park, Paul Baity, Byung-Jun Yoon, Adolfy Hoisie,
- Abstract summary: This study proposes initializing node features using LLMs to enhance node representations for link prediction tasks in graph neural networks.
Our method, evaluated using various link prediction models on a quantum computing semantic network, demonstrated efficacy compared to traditional node embedding techniques.
- Score: 2.137420847424282
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Quantum computing is rapidly evolving in both physics and computer science, offering the potential to solve complex problems and accelerate computational processes. The development of quantum chips necessitates understanding the correlations among diverse experimental conditions. Semantic networks built on scientific literature, representing meaningful relationships between concepts, have been used across various domains to identify knowledge gaps and novel concept combinations. Neural network-based approaches have shown promise in link prediction within these networks. This study proposes initializing node features using LLMs to enhance node representations for link prediction tasks in graph neural networks. LLMs can provide rich descriptions, reducing the need for manual feature creation and lowering costs. Our method, evaluated using various link prediction models on a quantum computing semantic network, demonstrated efficacy compared to traditional node embedding techniques.
Related papers
- CTRQNets & LQNets: Continuous Time Recurrent and Liquid Quantum Neural Networks [76.53016529061821]
Liquid Quantum Neural Network (LQNet) and Continuous Time Recurrent Quantum Neural Network (CTRQNet) developed.
LQNet and CTRQNet achieve accuracy increases as high as 40% on CIFAR 10 through binary classification.
arXiv Detail & Related papers (2024-08-28T00:56:03Z) - Parallel Proportional Fusion of Spiking Quantum Neural Network for Optimizing Image Classification [10.069224006497162]
We introduce a novel architecture termed Parallel Proportional Fusion of Quantum and Spiking Neural Networks (PPF-QSNN)
The proposed PPF-QSNN outperforms both the existing spiking neural network and the serial quantum neural network across metrics such as accuracy, loss, and robustness.
This study lays the groundwork for the advancement and application of quantum advantage in artificial intelligent computations.
arXiv Detail & Related papers (2024-04-01T10:35:35Z) - Enhancing the expressivity of quantum neural networks with residual
connections [0.0]
We propose a quantum circuit-based algorithm to implement quantum residual neural networks (QResNets)
Our work lays the foundation for a complete quantum implementation of the classical residual neural networks.
arXiv Detail & Related papers (2024-01-29T04:00:51Z) - ShadowNet for Data-Centric Quantum System Learning [188.683909185536]
We propose a data-centric learning paradigm combining the strength of neural-network protocols and classical shadows.
Capitalizing on the generalization power of neural networks, this paradigm can be trained offline and excel at predicting previously unseen systems.
We present the instantiation of our paradigm in quantum state tomography and direct fidelity estimation tasks and conduct numerical analysis up to 60 qubits.
arXiv Detail & Related papers (2023-08-22T09:11:53Z) - QuanGCN: Noise-Adaptive Training for Robust Quantum Graph Convolutional
Networks [124.7972093110732]
We propose quantum graph convolutional networks (QuanGCN), which learns the local message passing among nodes with the sequence of crossing-gate quantum operations.
To mitigate the inherent noises from modern quantum devices, we apply sparse constraint to sparsify the nodes' connections.
Our QuanGCN is functionally comparable or even superior than the classical algorithms on several benchmark graph datasets.
arXiv Detail & Related papers (2022-11-09T21:43:16Z) - DQC$^2$O: Distributed Quantum Computing for Collaborative Optimization
in Future Networks [54.03701670739067]
We propose an adaptive distributed quantum computing approach to manage quantum computers and quantum channels for solving optimization tasks in future networks.
Based on the proposed approach, we discuss the potential applications for collaborative optimization in future networks, such as smart grid management, IoT cooperation, and UAV trajectory planning.
arXiv Detail & Related papers (2022-09-16T02:44:52Z) - QDCNN: Quantum Dilated Convolutional Neural Network [1.52292571922932]
We propose a novel hybrid quantum-classical algorithm called quantum dilated convolutional neural networks (QDCNNs)
Our method extends the concept of dilated convolution, which has been widely applied in modern deep learning algorithms, to the context of hybrid neural networks.
The proposed QDCNNs are able to capture larger context during the quantum convolution process while reducing the computational cost.
arXiv Detail & Related papers (2021-10-29T10:24:34Z) - A Quantum Convolutional Neural Network for Image Classification [7.745213180689952]
We propose a novel neural network model named Quantum Convolutional Neural Network (QCNN)
QCNN is based on implementable quantum circuits and has a similar structure as classical convolutional neural networks.
Numerical simulation results on the MNIST dataset demonstrate the effectiveness of our model.
arXiv Detail & Related papers (2021-07-08T06:47:34Z) - The Computational and Latency Advantage of Quantum Communication
Networks [70.01340727637825]
This article summarises the current status of classical communication networks.
It identifies some critical open research challenges that can only be solved by leveraging quantum technologies.
arXiv Detail & Related papers (2021-06-07T06:31:02Z) - The Hintons in your Neural Network: a Quantum Field Theory View of Deep
Learning [84.33745072274942]
We show how to represent linear and non-linear layers as unitary quantum gates, and interpret the fundamental excitations of the quantum model as particles.
On top of opening a new perspective and techniques for studying neural networks, the quantum formulation is well suited for optical quantum computing.
arXiv Detail & Related papers (2021-03-08T17:24:29Z) - Variational learning for quantum artificial neural networks [0.0]
We first review a series of recent works describing the implementation of artificial neurons and feed-forward neural networks on quantum processors.
We then present an original realization of efficient individual quantum nodes based on variational unsampling protocols.
While keeping full compatibility with the overall memory-efficient feed-forward architecture, our constructions effectively reduce the quantum circuit depth required to determine the activation probability of single neurons.
arXiv Detail & Related papers (2021-03-03T16:10:15Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.