2022
DOI: 10.3390/s22155610
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Review of Neural Network Modeling of Shape Memory Alloys

Abstract: Shape memory materials are smart materials that stand out because of several remarkable properties, including their shape memory effect. Shape memory alloys (SMAs) are largely used members of this family and have been innovatively employed in various fields, such as sensors, actuators, robotics, aerospace, civil engineering, and medicine. Many conventional, unconventional, experimental, and numerical methods have been used to study the properties of SMAs, their models, and their different applications. These m… Show more

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Cited by 25 publications
(13 citation statements)
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References 105 publications
(126 reference statements)
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“…Shape memory alloys (SMAs) belong to this family because of their two remarkable characteristics, namely, shape memory effect (SME) and superelastic effect (SE), and have been innovatively employed in various fields, such as sensors, actuators, robotics, aerospace, civil engineering, and medicine. [22] The shape memory and superelastic effects are originated from the thermoelastic martensitic transformation (MT), which is nothing but the ability of shape memory alloys (SMAs) to undergo reversible martensitic phase transformations on application of heating or cooling within specific temperature ranges. [23].…”
Section: Overview On Shape Memory Alloysmentioning
confidence: 99%
“…Shape memory alloys (SMAs) belong to this family because of their two remarkable characteristics, namely, shape memory effect (SME) and superelastic effect (SE), and have been innovatively employed in various fields, such as sensors, actuators, robotics, aerospace, civil engineering, and medicine. [22] The shape memory and superelastic effects are originated from the thermoelastic martensitic transformation (MT), which is nothing but the ability of shape memory alloys (SMAs) to undergo reversible martensitic phase transformations on application of heating or cooling within specific temperature ranges. [23].…”
Section: Overview On Shape Memory Alloysmentioning
confidence: 99%
“…The intrinsic structure model of SMAC considering continuous time variation was studied to reveal the time-varying properties of SMAC for the problems of time variation of SMA composite properties and fatigue [ 35 ]. A neural network-based intrinsic structure relationship for SMAC was investigated in the presence of SMA response stresses [ 36 ]. In addition, a three-dimensional thermodynamic intrinsic structure model applicable to arbitrarily shaped objects was investigated for the variation of composite structure shapes and can be downscaled to achieve an accurate description of structures such as wires, rods, beams, and shells [ 37 ].…”
Section: Introductionmentioning
confidence: 99%
“…Analyzing materials and composites uses various methods such as multiple linear regression, support vector machines, artificial neural networks, and least squares methods for different purposes. These techniques have been utilized to predict screw pull-out strengths and flexural modulus values of particleboards [ 17 , 18 ], to classify alloys based on their shapes [ 19 ], to predict sound absorption coefficients of sandwich-structured materials [ 20 ], to detect protozoa in wastewater [ 21 ], to model the strength of lightweight foam concrete [ 22 ], and to determine the processing parameters for drilling glass-laminated aluminum-reinforced epoxy composites [ 23 ]. However, no studies on machine learning related to xanthan-gum-based foam materials exist.…”
Section: Introductionmentioning
confidence: 99%
“…Within the materials and composites domain, diverse methodologies, including multiple linear regression, support vector machines, artificial neural networks, and least squares methods, have been carried out for various purposes. These techniques have provided successful outcomes in predicting screw pull-out strengths and flexural modulus values of particleboards [ 17 , 18 ], classifying alloys based on their shapes [ 19 ], forecasting sound absorption coefficients of sandwich-structured materials [ 20 ], detecting protozoa in wastewater [ 21 ], modeling the strength of lightweight foam concrete [ 22 ], determining processing parameters for drilling glass-laminated aluminum-reinforced epoxy composites [ 23 ], estimating performance in different applications [ 24 ] and organic photovoltaic design [ 25 ]. Additionally, in the context of predicting material properties and minimizing both material waste and cost losses, machine learning methods provide considerable advantages.…”
Section: Introductionmentioning
confidence: 99%