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Faraj R., Mikułowski G., Wiszowaty R., Study on the state-dependent path-tracking for smart pneumatic shock-absorber, SMART MATERIALS AND STRUCTURES, 29, 11, 115008-1-25, 2020 | |
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Pieczyska E.A., Staszczak M., Maj M., Kowalczyk-Gajewska K., Golasiński K., Cristea M., Tobushi H., Hayashi S., Investigation of thermomechanical couplings, strain localization and shape memory properties in a shape memory polymer subjected to loading at various strain rates, SMART MATERIALS AND STRUCTURES, 25, 8, 085002-1-15, 2016 | |
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Faraj R., Holnicki-Szulc J., Knap L., Seńko J., Adaptive inertial shock-absorber, SMART MATERIALS AND STRUCTURES, 25, 035031-1-9, 2016 | |
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Pieczyska E.A., Maj M., Kowalczyk-Gajewska K., Staszczak M., Gradys A., Majewski M., Cristea M., Tobushi H., Hayashi S., Thermomechanical properties of polyurethane shape memory polymer–experiment and modelling, SMART MATERIALS AND STRUCTURES, 24, 045043-1-16, 2015 | |
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Szmidt T., Zalewski R., Inertially excited beam vibrations damped by Vacuum Packed Particles, SMART MATERIALS AND STRUCTURES, 10, 105026-1-9, 2014 | |
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Dunić V., Pieczyska E.A., Tobushi H., Staszczak M., Slavković R., Experimental and numerical thermo-mechanical analysis of shape memory alloy subjected to tension with various stress and strain rates, SMART MATERIALS AND STRUCTURES, 23, 055026-1-11, 2014 | |
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Mikułowski G., Wiszowaty R., Holnicki-Szulc J., Characterization of a piezoelectric valve for an adaptive pneumatic shock absorber, SMART MATERIALS AND STRUCTURES, 22, 12, 125011-1-12, 2013 | |
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Hou J., Jankowski Ł., Ou J., An online substructure identification method for local structural health monitoring, SMART MATERIALS AND STRUCTURES, 22, 9, 095017-1-11, 2013 | |
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Pieczyska E.A., Tobushi H., Kulasiński K., Development of transformation bands in TiNi SMA for various stress and strain rates studied by a fast and sensitive infrared camera, SMART MATERIALS AND STRUCTURES, 22, 3, 035007-1-8, 2013 | |
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Orłowska A., Kołakowski P., Holnicki-Szulc J., Detecting delamination zones in composites by embedded electrical grid and thermographic methods, SMART MATERIALS AND STRUCTURES, 20, 10, 105009-1-9, 2011 | |
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Kołakowski P., Szelążek J., Sekuła K., Świercz A., Mizerski K., Gutkiewicz P., Structural health monitoring of a railway truss bridge using vibration-based and ultrasonic methods, SMART MATERIALS AND STRUCTURES, 20, 3, 1-17, 2011 | |
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Batifol C., Zieliński T.G., Ichchou M., Galland M.A., A finite-element study of a piezoelectric/poroelastic sound package concept, SMART MATERIALS AND STRUCTURES, 16, 1, 168-177, 2007 | |
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Holnicki-Szulc J., Pawłowski P., Wikło M., High-performance impact absorbing materials—the concept, design tools and applications., SMART MATERIALS AND STRUCTURES, 12(3), 461-467, 2003 | |
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Popławski B., Mikułowski G., Pisarski D., Wiszowaty R., Jankowski Ł., Optimum actuator placement for damping of vibrations using the prestress-accumulation release control approach, SMART STRUCTURES AND SYSTEMS, 24, 1, 27-35, 2019 | |
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Zawidzki M., Jankowski Ł., Optimization of modular Truss-Z by minimum-mass design under equivalent stress constraint, SMART STRUCTURES AND SYSTEMS, 21, 6, 715-725, 2018 | |