Dynamic Neural Network Architecture Design for Predicting Remaining Useful Life of Dynamic Processes

Simani, Silvio; Lam, Ying-Fai; Farsoni, Saverio; Castaldi, Paolo

doi:10.47852/bonviewjdsis3202967

Cited by 10 publications

(2 citation statements)

References 45 publications

(63 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The design of ANN structures has been one of the most popular research topics in artificial intelligence in the past decade [48]. Past research has been done [1] on the use of ANNs for estimating PV panel model parameters according to variations in temperature and radiation.…”

Section: Ann-based Model Parameter Range Classifier (Mprc)mentioning

confidence: 99%

PV Panel Model Parameter Estimation by Using Particle Swarm Optimization and Artificial Neural Network

Lo,

Chung,

Hsung

et al. 2024

Sensors

View full text Add to dashboard Cite

Photovoltaic (PV) panels are one of the popular green energy resources and PV panel parameter estimations are one of the popular research topics in PV panel technology. The PV panel parameters could be used for PV panel health monitoring and fault diagnosis. Recently, a PV panel parameters estimation method based in neural network and numerical current predictor methods has been developed. However, in order to further improve the estimation accuracies, a new approach of PV panel parameter estimation is proposed in this paper. The output current and voltage dynamic responses of a PV panel are measured, and the time series of the I–V vectors will be used as input to an artificial neural network (ANN)-based PV model parameter range classifier (MPRC). The MPRC is trained using an I–V dataset with large variations in PV model parameters. The results of MPRC are used to preset the initial particles’ population for a particle swarm optimization (PSO) algorithm. The PSO algorithm is used to estimate the PV panel parameters and the results could be used for PV panel health monitoring and the derivation of maximum power point tracking (MMPT). Simulations results based on an experimental I–V dataset and an I–V dataset generated by simulation show that the proposed algorithms can achieve up to 3.5% accuracy and the speed of convergence was significantly improved as compared to a purely PSO approach.

show abstract

Section: Ann-based Model Parameter Range Classifier (Mprc)mentioning

confidence: 99%

PV Panel Model Parameter Estimation by Using Particle Swarm Optimization and Artificial Neural Network

Lo,

Chung,

Hsung

et al. 2024

Sensors

View full text Add to dashboard Cite

show abstract

“…As the load carried by the superstructure increases, the design parameters of the grouped helical anchor, such as embedment depth, anchor plate diameter, anchor plate quantity, and foundation shape, must be adjusted correspondingly. Machine learning, artificial intelligence, and artificial neural network (ANN) algorithms are expected to develop a more accurate and reliable tool for determining the load-bearing capacity (LBC) of helical anchors [22][23][24][25]. Such models can be specifically established to provide quick and precise predictions of the LBC under various loading conditions, including axial, lateral, and inclined loads [26,27].…”

Section: Introductionmentioning

confidence: 99%

Field Experimental Study on the Uplift and Lateral Capacity of Deep Helical Anchors and Grouped Helical Anchors in Clays

Yuan,

Hao,

Ding

et al. 2024

Buildings

View full text Add to dashboard Cite

This research aims to investigate the bearing capability of deep helical anchors and grouped helical anchors under uplift or lateral loads using field experiments. Grouped helical anchors may serve as a viable alternative to traditional deep foundations, offering increased resistance against uplift and lateral forces. The study of group effect primarily focuses on vertically installed helical anchors, with few data available on various configurations of grouped helical anchors. This research includes a total of 12 single-helix anchors, 4 double-helix anchors, and 4 grouped helical anchors, with anchor plate diameters of 400 mm and maximum embedment depths of 7.4 m. There are two configurations of grouped helical anchors, each with different platforms. This article studies the effect of some factors, including the embedment depth, the number of anchor plates, the spacing between anchor shafts, the selection of failure criteria, and the group effect. The primary findings indicate that adding the anchor plates to single-helix anchors without extending the shaft length does not increase uplift or lateral capacity. In this soil condition, the group efficiency of double-helix anchors is higher than 1. By comparing the group efficiency and economy of the G1 and G2 grouped helical anchors, it is highly recommended to use the G2 configuration. The data obtained from this work may also serve as a valuable tool for validating numerical models used to analyze interactions among grouped helical anchors.

show abstract

Multi-objective optimization enabling CFRP energy-efficient milling based on deep reinforcement learning

Zhang,

Yan

et al. 2024

Appl Intell

View full text Add to dashboard Cite

Dynamic Neural Network Architecture Design for Predicting Remaining Useful Life of Dynamic Processes

Cited by 10 publications

References 45 publications

PV Panel Model Parameter Estimation by Using Particle Swarm Optimization and Artificial Neural Network

PV Panel Model Parameter Estimation by Using Particle Swarm Optimization and Artificial Neural Network

Field Experimental Study on the Uplift and Lateral Capacity of Deep Helical Anchors and Grouped Helical Anchors in Clays

Multi-objective optimization enabling CFRP energy-efficient milling based on deep reinforcement learning

Contact Info

Product

Resources

About