Finite-Element Neural Network-Based Solving 3-D Differential Equations in MFL

Xu, Chao; Wang, Changlong; Ji, Fengzhu; Yuan, Xichao

doi:10.1109/tmag.2012.2207732

Cited by 44 publications

(31 citation statements)

References 23 publications

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“…A number of regularization functionals classes is proposed by different authors [9,[25][26][27][28]. The Tikhonov regularization is extensively used in [9].…”

Section: Proposition 1 Let N Be a Compact Set In The Metric Space Fmentioning

confidence: 99%

Modeling of complex dynamic systems using differential neural networks with the incorporation of a priori knowledge

Bellamine

Almansoori

Elkamel

2015

Applied Mathematics and Computation

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“…A number of regularization functionals classes is proposed by different authors [9,[25][26][27][28]. The Tikhonov regularization is extensively used in [9].…”

Section: Proposition 1 Let N Be a Compact Set In The Metric Space Fmentioning

confidence: 99%

Modeling of complex dynamic systems using differential neural networks with the incorporation of a priori knowledge

Bellamine

Almansoori

Elkamel

2015

Applied Mathematics and Computation

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“…A physical model is usually employed as the forward model which mainly involve three classes: heuristic models (e.g., artificial neural network [6,7]), analytical models (e.g., dipole model [8,9]), and numerical models (e.g., finite element method [10,11]). Compared with numerical models and analytical models, the heuristic models are faster but less accurate.…”

Section: Introductionmentioning

confidence: 99%

“…An inversing procedure is often regarded as solving an optimization problem, and many optimization algorithms have been applied to the inversing techniques, such as gradient descent algorithm [6,7] and genetic algorithm (GA) [12,13]. It's proved that the efficiency of the iterative approach applied to solve optimization problem determines the computing time and solution accuracy of inversing technique.…”

Section: Introductionmentioning

confidence: 99%

Defect Profile Estimation from Magnetic Flux Leakage Signal via Efficient Managing Particle Swarm Optimization

Han

Jia-dong

Wang

et al. 2014

Sensors

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In this paper, efficient managing particle swarm optimization (EMPSO) for high dimension problem is proposed to estimate defect profile from magnetic flux leakage (MFL) signal. In the proposed EMPSO, in order to strengthen exchange of information among particles, particle pair model was built. For more efficient searching when facing different landscapes of problems, velocity updating scheme including three velocity updating models was also proposed. In addition, for more chances to search optimum solution out, automatic particle selection for re-initialization was implemented. The optimization results of six benchmark functions show EMPSO performs well when optimizing 100-D problems. The defect simulation results demonstrate that the inversing technique based on EMPSO outperforms the one based on self-learning particle swarm optimizer (SLPSO), and the estimated profiles are still close to the desired profiles with the presence of low noise in MFL signal. The results estimated from real MFL signal by EMPSO-based inversing technique also indicate that the algorithm is capable of providing an accurate solution of the defect profile with real signal. Both the simulation results and experiment results show the computing time of the EMPSO-based inversing technique is reduced by 20%–30% than that of the SLPSO-based inversing technique.

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“…This is true not only for coiled tubing inspection, but also for inspection of other metal structures, such as pipelines, storage tanks, aircrafts, etc. The task remains challenging in quantitatively predicting the topology and severity of detected defects, as described in C. Breidenthal et al 10 , Ravan et al 11 , Rostamabad et al 12 , Amineh et al 13,14 , Priewald et al 15 , Xu et al 16 , McJunkin et al 17 , among others. Because of the intrinsic complexity, much of the defect characterization work still heavily depends on individual prove ups upon detection.…”

Section: Introductionmentioning

confidence: 99%

Steel Coiled Tubing Defect Evaluation Using Magnetic Flux Leakage Signals

Liu

Minerbo

Zheng

2014

Day 2 Wed, March 26, 2014

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Mechanical defects, such as manufacturing imperfections, grinding marks, corrosion pits, slip marks, kinking, gouges, etc, whether occurred in the factory or in the field, can be readily found on CT strings. Extensive studies have demonstrated the detrimental effects of mechanical defects, over the integrity of the coiled tubing, both in the lab and in the field. Researchers in the field have been proposing theoretical models for the severity assessment of mechanical defects, particularly as it relates to the remaining fatigue life. For such models, the defect sizing is usually a prerequisite. In order to improve coiled tubing pipe management, it is important to assess the size of a defect, and its severity.MFL (magnetic flux leakage) based devices are volumetric and non-contact technology that is now commercially available for inspection and monitoring of CT strings. These devices have been demonstrated to be sufficiently sensitive in identifying mechanical defects. However, defect characterization and evaluation based on the devices' MFL signals is rarely seen. To fully utilize these MFL based inspection devices for coiled tubing pipe management, it is important to establish correlation between the MFL inspection signals and the geometry and severity of the underlying mechanical defects.The current work developed a three dimensional Finite Element Analysis (FEA) model to calculate magnetic flux leakage for mechanical defects on steel coiled tubing. The fidelity of the FEA model was verified against analytical and experimental results over a series of benchmark defects. By using the analytical and FEA models, parametric studies were performed to evaluate how the MFL signals are affected by various factors. The results were used to identify defect geometry features based on MFL signals. Physical limits behind these results were identified and analyzed. Ways to overcome such limits were proposed. Further, a novel approach was presented and validated to reconstruct three-dimensional MFL field based on a single MFL component measurement. The benefit of using multiple MFL components was demonstrated for defect characterization.

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Finite-Element Neural Network-Based Solving 3-D Differential Equations in MFL

Cited by 44 publications

References 23 publications

Modeling of complex dynamic systems using differential neural networks with the incorporation of a priori knowledge

Modeling of complex dynamic systems using differential neural networks with the incorporation of a priori knowledge

Defect Profile Estimation from Magnetic Flux Leakage Signal via Efficient Managing Particle Swarm Optimization

Steel Coiled Tubing Defect Evaluation Using Magnetic Flux Leakage Signals

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