Publications

Please contact the authors if you would like to receive a reprint of any of our articles. Your interest in our research is highly appreciated. We are more than happy to send you electronic files of any of the papers. 

2016

1Mlyniec, A. and Korta, J. and Uhl, T., "Structurally based constitutive model of epoxy adhesives incorporating the influence of post-curing and thermolysis", Composites Part B: Engineering, 86 , 160--167, 2016 Link BIB
@article{Mlyniec2016a,
author = {Mlyniec, A. and Korta, J. and Uhl, T.},
doi = {10.1016/j.compositesb.2015.09.062},
issn = {13598368},
journal = {Composites Part B: Engineering},
pages = {160--167},
title = {{Structurally based constitutive model of epoxy adhesives incorporating the influence of post-curing and thermolysis}},
url = {http://linkinghub.elsevier.com/retrieve/pii/S1359836815006265},
volume = {86},
year = {2016},
abstract = {Performance of the adhesively joined composite structures frequently depends on their stiffness since excessive deformation can alter their functionality. In this article, we present the structurally based constitutive model which takes into account the influence of the post-curing as well as thermolysis process on stiffness of epoxy adhesives. We propose the chemomechanical model considering the autocatalytic post-curing process and thermolysis, which dominates in the first phase of the degradation process at elevated temperatures. The proposed model employs reaction kinetics of curing and ther- molysis of epoxy, statistical mechanics as well as non-linear large strain constitutive material model which incorporates influence of chemical reactions. Presented model is calibrated to the results of experimental investigations probing the influence of the aging cycles according to the SAE/USCAR standard on stiffness of the epoxy adhesives. The material model is validated by comparison with results of single lap shear tests after HumidityeTemperature aging in class I and V.We achieve 98.3\% compliance for investigated aging cycles. Proposed model takes into account not only aging effects but elevated temperatures as well. Thus it can be used for prediction of the mechanical behavior of heavy loaded epoxy adhesive joints working in engine compartment. The consistency of the experimental results with model predictions, proves that our chemomechanical model constitutes a useful tool for the prediction of the durability and lifetime of adhesively joined structures.},
publisher = {Elsevier Ltd}
}
2Jacek Urbanek and Tomasz Barszcz and Adam Jablonski, "Application of angular–temporal spectrum to exploratory analysis of generalized angular–temporal deterministic signals", Applied Acoustics, 109 , 27 - 36, 2016 Link BIB
@article{Urbanek201627,
author = {Jacek Urbanek and Tomasz Barszcz and Adam Jablonski},
doi = {http://dx.doi.org/10.1016/j.apacoust.2016.03.004},
issn = {0003-682X},
journal = {Applied Acoustics},
keywords = {Angular–temporal spectrum},
number = {},
pages = {27 - 36},
title = {{Application of angular–temporal spectrum to exploratory analysis of generalized angular–temporal deterministic signals}},
url = {http://www.sciencedirect.com/science/article/pii/S0003682X16300378},
volume = {109},
year = {2016},
abstract = {Abstract Vibration-based condition monitoring of rotary machinery develops toward application for highly non-stationary operational conditions, mainly rotational speed and load. If speed and load vary during the acquisition of vibration signal, both, instantaneous amplitudes and instantaneous frequencies of signal components vary accordingly. This scenario causes a strong demand for novel signal processing approach suitable for analysis of such processes. In this paper, angular–temporal spectrum is introduced as a novel and practical solution for analysis of such signals. The tool is based on well-established principles of angular–temporal determinism, and allows for representation of energy of analyzed signal on bi-frequency plane related to angular and temporal properties of the signal. Additionally, proposed approach includes amplitude normalization technique in order to give more interpretable measures of amplitude related to varying speed and load. The paper gives overall description of the proposed tool as well as its intuitive explanation from the perspective of signal generation mechanism. The outcome of the angular–temporal spectrum is presented using generated signal, vibration signal measured on lab test-rig operating with damaged bearing during run-up process, and finally on industrial data from a wind turbine.},
note = {}
}
3Mlyniec, Andrzej and Ekiert, Martyna and Morawska-Chochol, Anna and Uhl, Tadeusz, "Influence of density and environmental factors on decomposition kinetics of amorphous polylactide - Reactive molecular dynamics studies", Journal of Molecular Graphics and Modelling, 67 , 54--61, 2016 Link BIB
@article{Mlyniec2016b,
author = {Mlyniec, Andrzej and Ekiert, Martyna and Morawska-Chochol, Anna and Uhl, Tadeusz},
doi = {10.1016/j.jmgm.2016.04.010},
issn = {10933263},
journal = {Journal of Molecular Graphics and Modelling},
pages = {54--61},
title = {{Influence of density and environmental factors on decomposition kinetics of amorphous polylactide - Reactive molecular dynamics studies}},
url = {http://dx.doi.org/10.1016/j.jmgm.2016.04.010},
volume = {67},
year = {2016},
publisher = {Elsevier Inc.}
}

2015

1Mlyniec, Andrzej and Mazur, Lukasz and Tomaszewski A, Krzysztof and Uhl, Tadeusz, "Viscoelasticity and failure of collagen nanofibrils: 3D Coarse-Grained simulation studies", Soft Materials, 13 1, 47--58, 2015 Link BIB
@article{Mlyniec2015a,
author = {Mlyniec, Andrzej and Mazur, Lukasz and Tomaszewski A, Krzysztof and Uhl, Tadeusz},
doi = {10.1080/1539445X.2015.1009549},
journal = {Soft Materials},
number = {1},
pages = {47--58},
title = {{Viscoelasticity and failure of collagen nanofibrils: 3D Coarse-Grained simulation studies}},
url = {http://www.tandfonline.com/doi/abs/10.1080/1539445X.2015.1009549},
volume = {13},
year = {2015},
abstract = {In this manuscript, we investigate the influence of loading rate and fibril length on viscoelastic and failure behavior of collagen nanofibrils. The computational experiments were performed using three-dimensional shape-based Coarse-Grained models of collagen nanofibrils, with parameters derived from atomistic simulations. The atomistic computational tensile and shear experiments were performed using Molecular Dynamics and extended AMBER force field for aqueous and non-aqueous environments. The Coarse-Grained interactions were defined by both intermolecular and intramolecular potentials which describe non-bonded and bonded interactions respectively. Computational studies revealed that the hydrogen bond network impacts both viscoelastic behavior and failure of collagen nanofibrils. Greater fibril length results in brittle cracking while higher loading rates result in ductile behavior, due to the unwinding and sliding of the fibril. The proposed Coarse-Grained model can be used in further studies incorporating the effects of ageing, such as collagen degradation and glycation.}
}
2Mlyniec, A. and Tomaszewski, K.A. and Spiesz, E.M. and Uhl, T., "Molecular-based nonlinear viscoelastic chemomechanical model incorporating thermal denaturation kinetics of collagen fibrous biomaterials", Polymer Degradation and Stability, 119 , 87--95, 2015 Link BIB
@article{Mlyniec2015b,
author = {Mlyniec, A. and Tomaszewski, K.A. and Spiesz, E.M. and Uhl, T.},
doi = {10.1016/j.polymdegradstab.2015.05.005},
issn = {01413910},
journal = {Polymer Degradation and Stability},
keywords = {chemomechanical model,collagen denaturation,collagen microfibrils},
pages = {87--95},
title = {{Molecular-based nonlinear viscoelastic chemomechanical model incorporating thermal denaturation kinetics of collagen fibrous biomaterials}},
url = {http://linkinghub.elsevier.com/retrieve/pii/S0141391015001731},
volume = {119},
year = {2015},
publisher = {Elsevier Ltd}
}
3Korta, Jakub and Mlyniec, Andrzej and Uhl, Tadeusz, "Experimental and numerical study on the effect of humidity-temperature cycling on structural multi-material adhesive joints", Composites Part B: Engineering, 79 , 621--630, 2015 Link BIB
@article{Korta2015,
author = {Korta, Jakub and Mlyniec, Andrzej and Uhl, Tadeusz},
doi = {10.1016/j.compositesb.2015.05.020},
journal = {Composites Part B: Engineering},
keywords = {adhesion,environmental degradation,joining,joints,mechanical,multi-material,testing},
pages = {621--630},
title = {{Experimental and numerical study on the effect of humidity-temperature cycling on structural multi-material adhesive joints}},
url = {http://linkinghub.elsevier.com/retrieve/pii/S1359836815003248},
volume = {79},
year = {2015},
abstract = {The following paper describes investigations on the impact of harsh environment on shear and tensile strength of multi-material adhesive joints. The samples were made from carbon fiber – epoxy composites, aluminum and two types of advanced steels: abrasion resistant and high-strength. In order to assess the suitability of structural bonding for this sort of applications, it was decided to test two different epoxy-based adhesives, designed for moderate and elevated operating temperatures. The harmful conditions were simulated by means of humidity-temperature cycling tests, according to the SAE standard. The obtained results revealed that even moderately harsh humidity-temperature loads can cause debonding of the joints, even if no external forces are applied. In order to gain insight into this phenomenon, a series of finite element analyses was performed, simulating the exposure of the samples to the chosen environmental conditions. Based on these studies, the temperature expansion coefficient was identified as the crucial factor for the performance of the joints made from dissimilar materials. The results of the described experiments, confirmed by numerical calculations, constitute a guideline for multi-material structural design, supporting this constantly growing branch of modern engineering with a relevant input.},
publisher = {Elsevier Ltd}
}

2014

1Mlyniec, A. and Korta, J. and Kudelski, R. and Uhl, T., "The influence of the laminate thickness, stacking sequence and thermal aging on the static and dynamic behavior of carbon/epoxy composites", Compos. Struct., 118 , 208--216, 2014 Link BIB
@article{Mlyniec2014c,
author = {Mlyniec, A. and Korta, J. and Kudelski, R. and Uhl, T.},
doi = {10.1016/j.compstruct.2014.07.047},
issn = {02638223},
journal = {Compos. Struct.},
keywords = {Damping factors,Durability,Environmental degradation,Polymer-matrix composites,Thermal aging,Vibration},
month = aug,
pages = {208--216},
title = {{The influence of the laminate thickness, stacking sequence and thermal aging on the static and dynamic behavior of carbon/epoxy composites}},
url = {http://www.sciencedirect.com/science/article/pii/S0263822314003705},
volume = {118},
year = {2014},
abstract = {In this work, we investigate the influence of laminate thickness, stacking sequence and thermal aging on the damping behavior of carbon/epoxy laminates. The dynamic behavior of quasi-isotropic and unidirectional laminates of different thickness, are measured by means of Laser Doppler Vibrometry and Dynamic Mechanical Analysis. Obtained results before and after aging at 175°C for 250 and 500h, are compared with static strength properties. The Laser Doppler Vibrometry measurements of the modal damping factors, show general increasing tendency for the unidirectional composites after aging, but decreasing tendency for quasi-isotropic plates. The DMA damping measurements reveal an increase of the damping in longitudinal direction after aging, but a decrease in transverse direction. Comparison of results of dynamic measurements with static properties, confirm that mechanism of damping in composite structures depends mainly on stacking sequence. Moreover, modal damping of unidirectional composites depends mainly on the properties of the fiber–matrix interface, while damping of the quasi-isotropic laminates is affected by long-term properties of the matrix. Thus, to ensure long term damping performance of the carbon/epoxy components subjected to vibrations, one should take into account the stability of the matrix and fiber–matrix interfaces and also the alignment of the reinforcing fibers.}
}
2Mlyniec, A. and Morawska-Chochol, A. and Kloch, K. and Uhl, T., "Phenomenological and chemomechanical modeling of the thermomechanical stability of liquid silicone rubbers", Polym. Degrad. Stab., 99 , 290--297, 2014 Link BIB
@article{Mlyniec2014a,
author = {Mlyniec, A. and Morawska-Chochol, A. and Kloch, K. and Uhl, T.},
issn = {01413910},
journal = {Polym. Degrad. Stab.},
month = jan,
pages = {290--297},
title = {{Phenomenological and chemomechanical modeling of the thermomechanical stability of liquid silicone rubbers}},
url = {http://www.sciencedirect.com/science/article/pii/S0141391013003546},
volume = {99},
year = {2014},
abstract = {In this article, we present the constitutive models taking into account the stability of liquid silicone rubber's. We propose the phenomenological large strain viscoelastic material model and the enhanced chemomechanical model. The phenomenological model is calibrated to the experimental investigations probing the thermomechanical behavior of liquid silicone rubber's, while the chemomechanical model uses kinetic theory, to calculate the changes of mechanical properties in time. The proposed chemomechanical model employs: chemical reaction kinetics, statistical mechanics and microstructural based Bergström-Boyce material model. Viscoelastic material property changes resulting from e.g. the variation of crosslink density are computed using the Arrhenius equation. The material model is validated by comparison with results of compression tests of specimens aged in 125 and 175 °C non-loaded and under stress of 0.48 MPa. We achieve 96\% compliance for investigated temperature and pressure range. The good agreement with the experimental data, demonstrates that chemomechanical modeling framework provides a useful tool for the prediction of the stability of liquid silicone rubbers and the lifetime of vibration isolators.}
}
3Mlyniec, A and Ambrozinski, L and Packo, P and Bednarz, J and Staszewski, WJ and Uhl, T, "Adaptive de-icing system – numerical simulations and laboratory experimental validation", Int. J. Appl. Electromagn. Mech., DOI: 10.3233/JAE-140091, 2014 Link BIB
@article{Mlyniec2014b,
author = {Mlyniec, A and Ambrozinski, L and Packo, P and Bednarz, J and Staszewski, WJ and Uhl, T},
doi = {10.3233/JAE-140091},
journal = {Int. J. Appl. Electromagn. Mech.},
title = {{Adaptive de-icing system – numerical simulations and laboratory experimental validation}},
url = {http://iospress.metapress.com/content/512n705w1r7pt572/},
year = {2014}
}
4Broda, D. and Staszewski, W.J. and Martowicz, A. and Uhl, T. and Silberschmidt, V.V., "Modelling of nonlinear crack-wave interactions for damage detection based on ultrasound ", Journal of Sound and Vibration, 333 4, 1097, 2014 Link BIB
@Article{Broda2014,
author = {Broda, D. and Staszewski, W.J. and Martowicz, A. and Uhl, T. and Silberschmidt, V.V.},
journal = {Journal of Sound and Vibration},
number = {4},
pages = {1097},
title = {{Modelling of nonlinear crack-wave interactions for damage detection based on ultrasound }},
url = {http://www.sciencedirect.com/science/article/pii/S0022460X13007876},
volume = {333},
year = {2014},
timestamp = {2014.10.16}
}
5Ambrozinski, L. and Magda, P. and Stepinski, T. and Uhl, T. and Dragan, K., "A method for compensation of the temperature effect disturbing Lamb waves propagation", AIP Conference Proceedings, 1581 1, 1157-1164, 2014 Link BIB
@ARTICLE{Ambrozinski2014,
author = {Ambrozinski, L. and Magda, P. and Stepinski, T. and Uhl, T. and Dragan, K.},
doi = {http://dx.doi.org/10.1063/1.4864951},
journal = {AIP Conference Proceedings},
number = {1},
pages = {1157-1164},
title = {{A method for compensation of the temperature effect disturbing Lamb waves propagation}},
url = {http://scitation.aip.org/content/aip/proceeding/aipcp/10.1063/1.4864951},
volume = {1581},
year = {2014},
timestamp = {2015.02.13},
__markedentry = {[Lukasz:]}
}
6Ambrozinski, L. and Stepinski, T. and Uhl, T., "2D aperture synthesis for Lamb wave imaging using coarrays", , DOI: , 2014 BIB
@INPROCEEDINGS{Ambrozinski2014a,
author = {Ambrozinski, L. and Stepinski, T. and Uhl, T.},
title = {{2D aperture synthesis for Lamb wave imaging using coarrays}},
year = {2014},
booktitle = {Proc. SPIE 9064, Health Monitoring of Structural and Biological Systems 2014, 90642A},
timestamp = {2014.04.13},
__markedentry = {[Lukasz:]}
}
7Ambrozinski, L. and Stepinski, T. and Uhl, T., "Efficient Tool for Designing 2D Phased Arrays in Lamb Waves Imaging of Isotropic Structures", Journal of Intelligent Material Systems and Structures, DOI: , 2014 BIB
@ARTICLE{Ambrozinski2014b,
author = {Ambrozinski, L. and Stepinski, T. and Uhl, T.},
journal = {Journal of Intelligent Material Systems and Structures},
title = {{Efficient Tool for Designing 2D Phased Arrays in Lamb Waves Imaging of Isotropic Structures}},
volume = {in press},
year = {2014},
timestamp = {2014.08.21}
}
8Dworakowski, Z. and Ambrozinski, L. and Packo, P and Dragan, K. and Stepinski, T., "Application of ANNs for compounding multiple damage indices in Lamb wave based damage detection", Structural Control and Health Monitoring, DOI: , 2014 BIB
@ARTICLE{Dworakowski2014,
author = {Dworakowski, Z. and Ambrozinski, L. and Packo, P and Dragan, K. and Stepinski, T.},
journal = {Structural Control and Health Monitoring},
title = {{Application of ANNs for compounding multiple damage indices in Lamb wave based damage detection}},
volume = {accepted},
year = {2014},
timestamp = {2014.04.07},
__markedentry = {[Lukasz:]}
}
9Dworakowski, Z. and Ambrozinski, L. and Packo, P. and Dragan, K. and Stepinski, T., "Application of artificial neural networks for compounding multiple damage indices in lamb-wave-based damage detection", Structural Control and Health Monitoring, DOI: , 2014 Link BIB
@ARTICLE{Dworakowski2014a,
author = {Dworakowski, Z. and Ambrozinski, L. and Packo, P. and Dragan, K. and Stepinski, T.},
journal = {Structural Control and Health Monitoring},
title = {{Application of artificial neural networks for compounding multiple damage indices in lamb-wave-based damage detection}},
url = {http://www.scopus.com/inward/record.url?eid=2-s2.0-84897351965&partnerID=40&md5=b101ae941d0b768cc7902c44451418db},
volume = {in press},
year = {2014},
timestamp = {2015.02.13},
note = {cited By (since 1996)0; Article in Press},
document_type = {Article in Press},
source = {Scopus}
}

2013

1Manka, M. and Rosiek, M. and Martowicz, A. and Stepinski, T. and Uhl, T., "Lamb wave transducers made of piezoelectric macro-fiber composite", Structural Control & Health Monitoring, 20 8, 1138, 2013 Link BIB
@Article{Manka2013,
author = {Manka, M. and Rosiek, M. and Martowicz, A. and Stepinski, T. and Uhl, T.},
journal = {Structural Control & Health Monitoring},
number = {8},
pages = {1138},
title = {{Lamb wave transducers made of piezoelectric macro-fiber composite}},
url = {http://onlinelibrary.wiley.com/doi/10.1002/stc.1523/pdf},
volume = {20},
year = {2013},
timestamp = {2014.10.16}
}
2Lukasz Ambrozinski, "Advanced Structural Damage Detection: From Theory to Engineering Applications", , DOI: , 2013 BIB
@INBOOK{Ambrozinski2013a,
author = {Lukasz Ambrozinski},
pages = {177-210},
title = {{Advanced Structural Damage Detection: From Theory to Engineering Applications}},
year = {2013},
publisher = {Wiley},
chapter = {Beamforming of guided waves},
editor = {T. Stepinski and T. Uhl and W.J. Staszewski},
timestamp = {2013.05.24}
}
3Ambrozinski, L. and Magda, P. and Dragan, K. and Stepinski, T. and Uhl, T., "Temperature compensation based on Hilbert transform and instantaneous phase for Lamb waves-based SHM systems of aircraft structures", , DOI: , 2013 BIB
@INPROCEEDINGS{ambrozinski2013d,
author = {Ambrozinski, L. and Magda, P. and Dragan, K. and Stepinski, T. and Uhl, T.},
title = {{Temperature compensation based on Hilbert transform and instantaneous phase for Lamb waves-based SHM systems of aircraft structures}},
year = {2013},
booktitle = {Structural health monitoring 2013: a roadmap to intelligent structures : proceedings of the 9th International workshop on Structural Health Monitoring},
timestamp = {2014.01.31},
__markedentry = {[Lukasz:]}
}
4Dworakowski, Z. and Ambrozinski, L. and Packo, P. Dragan, K. and Stepinski, K. and Uhl, T., "Application of Artificial Neural Networks for Damage Indices Classification with the Use of Lamb Waves for the Aerospace Structures", Key Engineering Materials, 588 , 12-21, 2013 BIB
@ARTICLE{Dworakowski2013,
author = {Dworakowski, Z. and Ambrozinski, L. and Packo, P. Dragan, K. and Stepinski, K. and Uhl, T.},
journal = {Key Engineering Materials},
pages = {12-21},
title = {{Application of Artificial Neural Networks for Damage Indices Classification with the Use of Lamb Waves for the Aerospace Structures}},
volume = {588},
year = {2013},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}
5Galina, A. and Packo, P. and Ambrozinski, L., "Advanced Structural Damage Detection: From Theory to Engineering Applications", , DOI: , 2013 BIB
@INBOOK{Galina2013,
author = {Galina, A. and Packo, P. and Ambrozinski, L.},
pages = {71-72},
title = {{Advanced Structural Damage Detection: From Theory to Engineering Applications}},
year = {2013},
publisher = {Wiley},
chapter = {Model assisted probability of detection in structural health monitoring},
editor = {T. Stepinski and T. Uhl and W.J. Staszewski},
timestamp = {2013.05.24},
__markedentry = {[Lukasz:]}
}
6Manka, M. and Ambrozinski, L. and Uhl, T., "Computer-aided prototyping of interdigital transducers for the structural health monitoring of planar structures", Mechanics and Control, 32(2) , 69-76, 2013 BIB
@ARTICLE{Manka2013b,
author = {Manka, M. and Ambrozinski, L. and Uhl, T.},
journal = {Mechanics and Control},
pages = {69-76},
title = {{Computer-aided prototyping of interdigital transducers for the structural health monitoring of planar structures}},
volume = {32(2)},
year = {2013},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}
7Manka, M. and Martowicz, A. and Rosiek, M. and Ambrozinski, L. and Uhl, T., "Numerical modelling and experimental verification of the interdigital transducers for Lamb wave generation", , DOI: , 2013 BIB
@INPROCEEDINGS{Manka2013d,
author = {Manka, M. and Martowicz, A. and Rosiek, M. and Ambrozinski, L. and Uhl, T.},
title = {{Numerical modelling and experimental verification of the interdigital transducers for Lamb wave generation}},
year = {2013},
booktitle = {Mechatronic Systems and Materials: the 9th international conference},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}
8Manka, M. and Rosiek, M. and Martowicz, A. and Ambrozinski, L. and Uhl, T. and Stepinski, T., "Novel method for simulation of Lamb wave propagation generated by an interdigital transducer", , DOI: , 2013 BIB
@INPROCEEDINGS{Manka2013c,
author = {Manka, M. and Rosiek, M. and Martowicz, A. and Ambrozinski, L. and Uhl, T. and Stepinski, T.},
title = {{Novel method for simulation of Lamb wave propagation generated by an interdigital transducer}},
year = {2013},
booktitle = {Structural health monitoring 2013: a roadmap to intelligent structures: proceedings of the 9th International workshop on Structural Health Monitoring},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}
9P. Packo and L. Pieczonka and L. Ambrozinski and T. Uhl and W.J. Staszewski, "Elastic constants identification for laminated composites based on Lamb waves propagation", , DOI: , 2013 BIB
@CONFERENCE{Packo2013,
author = {P. Packo and L. Pieczonka and L. Ambrozinski and T. Uhl and W.J. Staszewski},
month = september 13-15,
title = {{Elastic constants identification for laminated composites based on Lamb waves propagation}},
volume = {2},
year = {2013},
publisher = {DEStech Publications, Inc., cop.},
booktitle = {Structural health monitoring 2013: condition-based maintenance and intelligent structures : proceedings of the 9th international workshop on Structural health monitoring},
editor = {Fu-Kuo Chang},
timestamp = {2011.10.05}
}
10Stepinski, T. and Ambrozinski, L. and Uhl, T., "Beamforming of Lamb waves using 2D arrays: a comparative study", , DOI: , 2013 BIB
@INPROCEEDINGS{Stepinski2013a,
author = {Stepinski, T. and Ambrozinski, L. and Uhl, T.},
month = september 13-15,
title = {{Beamforming of Lamb waves using 2D arrays: a comparative study}},
volume = {2},
year = {2013},
publisher = {DEStech Publications, Inc., cop.},
booktitle = {Structural health monitoring 2013: a roadmap to intelligent structures : proceedings of the 9th International workshop on Structural Health Monitoring},
editor = {Fu-Kuo Chang},
timestamp = {2011.10.05},
__markedentry = {[Lukasz:]}
}
11Stepinski, T and Ambrozinski, L. and Uhl, T., "Designing 2D arrays for SHM of planar structures: a review", , DOI: , 2013 BIB
@INPROCEEDINGS{Stepinski2013b,
author = {Stepinski, T and Ambrozinski, L. and Uhl, T.},
title = {{Designing 2D arrays for SHM of planar structures: a review}},
year = {2013},
booktitle = {Proc. SPIE: Nondestructive characterization for composite materials, aerospace engineering, civil infrastructure, and homeland security},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}

2012

1Martowicz, A. and Uhl, T., "Reliability- and performance-based robust design optimization of MEMS structures considering technological uncertainties", Mechanical Systems and Signal Processing, 32 , 44-58, 2012 Link BIB
@Article{Martowicz2012,
author = {Martowicz, A. and Uhl, T.},
journal = {Mechanical Systems and Signal Processing},
pages = {44-58},
title = {{Reliability- and performance-based robust design optimization of MEMS structures considering technological uncertainties}},
url = {http://www.sciencedirect.com/science/article/pii/S0888327012001847/pdfft?md5=a59e41e406d7861aa8d99a8d9278580c&pid=1-s2.0-S0888327012001847-main.pdf},
volume = {32},
year = {2012},
timestamp = {2014.10.16}
}
2Lukasz Ambrozinski and Tadeusz Stepinski and Pawel Packo and Tadeusz Uhl, "Self-focusing Lamb waves based on the decomposition of the time-reversal operator using time-frequency representation", Mechanical Systems and Signal Processing, 27 , 337 - 349, 2012 Link BIB
@ARTICLE{ambrozinski2012337,
author = {Lukasz Ambrozinski and Tadeusz Stepinski and Pawel Packo and Tadeusz Uhl},
doi = {10.1016/j.ymssp.2011.09.019},
issn = {0888-3270},
journal = {Mechanical Systems and Signal Processing},
keywords = {Lamb waves},
pages = {337 - 349},
title = {{Self-focusing Lamb waves based on the decomposition of the time-reversal operator using time-frequency representation}},
url = {http://www.sciencedirect.com/science/article/pii/S0888327011003876},
volume = {27},
year = {2012},
timestamp = {2015.02.13},
__markedentry = {[Lukasz:]}
}
3Ambrozinski, Lukasz and Stepinski, Tadeusz and Uhl, Tadeusz, "Experimental comparison of 2D arrays topologies for SHM of planar structures", , DOI: , 2012 BIB
@CONFERENCE{ambroz_spie_2012,
author = {Ambrozinski, Lukasz and Stepinski, Tadeusz and Uhl, Tadeusz},
title = {{Experimental comparison of 2D arrays topologies for SHM of planar structures}},
year = {2012},
booktitle = {Proc. of SPIE: Nondestructive characterization for composite materials, aerospace engineering, civil infrastructure, and homeland security},
timestamp = {2012.04.04},
__markedentry = {[Lukasz:]}
}
4Ambrozinski, L. and Stepinski, T. and Uhl, T., "Design of 2D Phased Array for Monitoring Isotropic Plate-Like Structures Using Lamb Waves", , DOI: , 2012 BIB
@INPROCEEDINGS{AmbrozinskiEWSHM2012,
author = {Ambrozinski, L. and Stepinski, T. and Uhl, T.},
title = {{Design of 2D Phased Array for Monitoring Isotropic Plate-Like Structures Using Lamb Waves}},
year = {2012},
booktitle = {Structural health monitoring, Proceedings of the sixth European workshop},
timestamp = {2012.10.28},
__markedentry = {[Lukasz:]}
}
5Ambrozinski, L. and Stepinski, T. and Uhl, T. and Ochonski, J. and Klepka, A., "Development of Lamb Waves-Based SHM Systems", Key Engineering Materials, 518 , 87-94, 2012 BIB
@ARTICLE{Ambrozinski2012,
author = {Ambrozinski, L. and Stepinski, T. and Uhl, T. and Ochonski, J. and Klepka, A.},
journal = {Key Engineering Materials},
pages = {87-94},
title = {{Development of Lamb Waves-Based SHM Systems}},
volume = {518},
year = {2012},
timestamp = {2012.10.28},
__markedentry = {[Lukasz:]}
}
6Dragan, K. and Dziendczikowski, M. and Uhl, T. and Ambrozinski, L., "Damage detection in the aircrafts structure with the use of integrated sensors - SYMOST project", , DOI: , 2012 BIB
@INPROCEEDINGS{Dragan2012,
author = {Dragan, K. and Dziendczikowski, M. and Uhl, T. and Ambrozinski, L.},
title = {{Damage detection in the aircrafts structure with the use of integrated sensors - SYMOST project}},
year = {2012},
booktitle = {Structural health monitoring 2012: proceedings of the sixth European workshop},
timestamp = {2013.01.18},
__markedentry = {[Lukasz:]}
}

2011

1Mlyniec, A. and Uhl, T., "Modelling and testing of ageing of short fibre reinforced polymer composites", Proc. Inst. Mech. Eng. Part C J. Mech. Eng. Sci., 226 1, 16--31, 2011 Link BIB
@article{Mlyniec2011,
author = {Mlyniec, A. and Uhl, T.},
doi = {10.1177/0954406211411552},
issn = {0954-4062},
journal = {Proc. Inst. Mech. Eng. Part C J. Mech. Eng. Sci.},
month = sep,
number = {1},
pages = {16--31},
title = {{Modelling and testing of ageing of short fibre reinforced polymer composites}},
url = {http://pic.sagepub.com/content/226/1/16.abstract},
volume = {226},
year = {2011},
publisher = {SAGE Publications},
language = {en}
}
2Martowicz, A. and Uhl, T., "Assessment of variation of natural frequencies of FE model based on the application of alpha-cut strategy and genetic algorithms", Finite Elements in Analysis and Design, 47 1, 63, 2011 Link BIB
@Article{Martowicz2011,
author = {Martowicz, A. and Uhl, T.},
journal = {Finite Elements in Analysis and Design},
number = {1},
pages = {63},
title = {{Assessment of variation of natural frequencies of FE model based on the application of alpha-cut strategy and genetic algorithms}},
url = {http://www.sciencedirect.com/science/article/pii/S0168874X10001162/pdfft?md5=8170aa3fa67567e835ac94e336c6a5d6&pid=1-s2.0-S0168874X10001162-main.pdf},
volume = {47},
year = {2011},
timestamp = {2014.10.16}
}
3Gallina, A. and Martowicz, A. and Uhl, T., "Robustness analysis of a car windscreen using response surface techniques", Finite Elements in Analysis and Design, 47 1, 46, 2011 Link BIB
@Article{Gallina2011,
author = {Gallina, A. and Martowicz, A. and Uhl, T.},
journal = {Finite Elements in Analysis and Design},
number = {1},
pages = {46},
title = {{Robustness analysis of a car windscreen using response surface techniques}},
url = {http://www.sciencedirect.com/science/article/pii/S0168874X10001186/pdfft?md5=d3970729a709b4ccf28d9d458676aa8a&pid=1-s2.0-S0168874X10001186-main.pdf},
volume = {47},
year = {2011},
timestamp = {2014.10.16}
}
4Ambrozinski, Lukasz and Stepinski, Tadeusz and Uhl, Tadeusz, "Self Focusing of 2D Arrays for SHM of Plate-Like Structures Using Time Reversal Operator", , DOI: , 2011 BIB
@CONFERENCE{Ambrozinski2011,
author = {Ambrozinski, Lukasz and Stepinski, Tadeusz and Uhl, Tadeusz},
month = September 13 - 15,
pages = {1119 - 1127},
title = {{Self Focusing of 2D Arrays for SHM of Plate-Like Structures Using Time Reversal Operator}},
year = {2011},
publisher = {DEStech Publications, Inc., cop},
booktitle = {Structural health monitoring 2011: condition-based maintenance and intelligent structures: proceedings of the 8th international workshop on Structural health monitoring},
editor = {Fu-Kuo Chang},
timestamp = {2011.09.21},
__markedentry = {[Lukasz:]},
address = {Stanford, USA}
}
5Gallina, A. and Packo, P. and Ambrozinski, L. and Uhl, T. and Staszewski, W.J., "Model assisted probability of detection evaluation of a health monitoring system by using CUDA technology", , DOI: , 2011 BIB
@CONFERENCE{galina:2011,
author = {Gallina, A. and Packo, P. and Ambrozinski, L. and Uhl, T. and Staszewski, W.J.},
month = september 13-15,
title = {{Model assisted probability of detection evaluation of a health monitoring system by using CUDA technology}},
volume = {2},
year = {2011},
publisher = {DEStech Publications, Inc., cop.},
booktitle = {Structural health monitoring 2011: condition-based maintenance and intelligent structures: proceedings of the 8th international workshop on Structural health monitoring},
editor = {Fu-Kuo Chang},
timestamp = {2011.10.05},
__markedentry = {[Lukasz:]}
}
6Ochonski, J. and Ambrozinski, L. and Klepka, A. and Uhl, T., "Selected problems of modal analysis of mechanical systems", , DOI: , 2011 BIB
@INBOOK{Ochonski2011_2,
author = {Ochonski, J. and Ambrozinski, L. and Klepka, A. and Uhl, T.},
pages = {73-80},
title = {{Selected problems of modal analysis of mechanical systems}},
year = {2011},
publisher = {Department of Robotics and Mechatronics, University of Science and Technology AGH},
chapter = {Influence of array parameters on beamforming in SHM applications},
editor = {Uhl, T.},
timestamp = {2014.03.31},
__markedentry = {[Lukasz:]}
}
7Packo, Pawel and Ambrozinski, Lukasz and Uhl, Tadeusz, "Structure damage modelling for guided waves-based SHM systems testing", , DOI: , 2011 Link BIB
@CONFERENCE{packo2011,
author = {Packo, Pawel and Ambrozinski, Lukasz and Uhl, Tadeusz},
month = April 19-21,
pages = {1061-1066},
title = {{Structure damage modelling for guided waves-based SHM systems testing}},
url = {http://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=05775618},
year = {2011},
booktitle = {ICMSAO},
timestamp = {2011.10.05}
}

2010

1Andrzej Klepka and Lukasz Ambrozinski, "Selection of piezoceramic sensor parameters for damage detection and localization system", DIAGNOSTYKA, 4(56) , 17-22, 2010 BIB
@ARTICLE{Klepka:2010,
author = {Andrzej Klepka and Lukasz Ambrozinski},
journal = {DIAGNOSTYKA},
pages = {17-22},
title = {{Selection of piezoceramic sensor parameters for damage detection and localization system}},
volume = {4(56)},
year = {2010},
timestamp = {2011.01.18},
__markedentry = {[Lukasz:]}
}
2Janusz Ochonski and Lukasz Ambrozinski and Andrzej Klepka and Tadeusz Uhl and Tadeusz Stepinski, "Choosing an appopriate sensor for the designed SHM system based on Lamb waves propagation", , DOI: , 2010 BIB
@CONFERENCE{ochonski:2010,
author = {Janusz Ochonski and Lukasz Ambrozinski and Andrzej Klepka and Tadeusz Uhl and Tadeusz Stepinski},
month = October 18-20,
pages = {1-8},
title = {{Choosing an appopriate sensor for the designed SHM system based on Lamb waves propagation}},
year = {2010},
booktitle = {11th IMEKO TC 10 workshop on Smart diagnostics of structures},
timestamp = {2011.10.05},
__markedentry = {[Lukasz:]},
address = {Krakow}
}

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