Relation-aware graph structure embedding (RaGSE) is promising for predicting multi-relational drug-drug interactions (DDIs). Most existing methods based on RaGSE commence by constructing a multi-relational DDI graph. ...
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Relation-aware graph structure embedding (RaGSE) is promising for predicting multi-relational drug-drug interactions (DDIs). Most existing methods based on RaGSE commence by constructing a multi-relational DDI graph. They then learn the RaGSEs for drugs by aggregating their neighbor's features under different relations. Nevertheless, new drugs lack neighbors in the DDI graph. This limitation hinders the ability of these methods to effectively learn RaGSEs for new drugs, resulting in suboptimal performance when evaluating DDIs that involve new drugs. To alleviate this issue, we propose a novel DDI prediction method based on relation-aware graph structure embedding with co-contrastive learning, RaGSECo. The proposed RaGSECo constructs two heterogeneous graphs: a multi-relational DDI graph and a multi-attribute drug-drug similarity (DDS) graph. The two graphs are used respectively for learning and propagating the RaGSEs of drugs, aiming to ensure all drugs, including new ones, can possess effective RaGSEs. Additionally, we present a novel co-contrastive learning module to learn feature representations for drug pairs (DPs). This module learns DP representations from two distinct views (interaction and similarity views) and encourages these views to supervise each other collaboratively to obtain more discriminative DP representations. We evaluate the effectiveness of our RaGSECo on three different tasks using two real datasets. Experimental outcomes unequivocally indicate that our RaGSECo surpasses several state-of-the-art methods in performance.
A significant demand rises for energy-efficient deep neural networks to support power-limited embedding devices with successful deep learning applications in IoT and edge computing *** accurate energy prediction appro...
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A significant demand rises for energy-efficient deep neural networks to support power-limited embedding devices with successful deep learning applications in IoT and edge computing *** accurate energy prediction approach is critical to provide measurement and lead optimization ***,the current energy prediction approaches lack accuracy and generalization ability due to the lack of research on the neural network structure and the excessive reliance on customized training *** paper presents a novel energy prediction model,*** treats neural networks as directed graphs and applies a bi-directional graph neural network training on a randomly generated dataset to extract structural features for energy *** has advantages over linear approaches because the bi-directional graph neural network collects structural features from each layer's parents and *** results show that NeurstrucEnergy establishes state-of-the-art results with mean absolute percentage error of 2.60%.We also evaluate NeurstrucEnergy in a randomly generated dataset,achieving the mean absolute percentage error of 4.83%over 10 typical convolutional neural networks in recent years and 7 efficient convolutional neural networks created by neural architecture *** code is available at https://***/NEUSoftGreenAI/***.
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