Publikationer av Anders Rosén
Refereegranskade
Artiklar
[1]
[2]
E. Begovic et al., "Experimental modelling of local structure responses for high-speed planing craft in waves," Ocean Engineering, vol. 216, 2020.
[3]
C. Wielgosz et al., "Experimental modelling of spray deflection influence on planing craft performance in calm water and waves," Journal of Engineering for the Maritime Environment (Part M), vol. 234, no. 2, s. 399-408, 2020.
[4]
A. Rosén et al., "Numerical modelling of structure responses for high-speed planing craft in waves," Ocean Engineering, vol. 217, 2020.
[5]
T. Manderbacka et al., "An overview of the current research on stability of ships and ocean vehicles : The STAB2018 perspective," Ocean Engineering, vol. 186, 2019.
[6]
C.-J. Söder, A. Rosén och M. Huss, "Ikeda Revisited," Journal of Marine Science and Technology, vol. 24, no. 1, s. 306-316, 2019.
[7]
A.-K. Högfeldt et al., "Mutual Capacity Building through North-South Collaboration Using Challenge-Driven Education," Sustainability, vol. 11, no. 24, 2019.
[8]
L. Olin et al., "Numerical modelling of spray sheet deflection on planing hulls," Journal of Engineering for the Maritime Environment (Part M), vol. 231, no. 4, s. 811-817, 2017.
[9]
M. Burman et al., "Comparative Life Cycle Assessment of the hull of a high-speed craft," Journal of Engineering for the Maritime Environment (Part M), vol. 230, no. 2, s. 378-387, 2016.
[10]
I. Bačkalov et al., "Improvement of ship stability and safety in intact condition through operational measures : Challenges and opportunities," Ocean Engineering, vol. 120, s. 353-361, 2016.
[11]
M. Razola et al., "On high-speed craft acceleration statistics," Ocean Engineering, vol. 114, s. 115-133, 2016.
[12]
I. Bačkalov et al., "Ship stability, dynamics and safety : Status and perspectives from a review of recent STAB conferences and ISSW events," Ocean Engineering, vol. 116, s. 312-349, 2016.
[13]
L. Skoglund et al., "A comparative study of deterministic and ensemble weather forecasts for weather routing," Journal of Marine Science and Technology, vol. 20, no. 3, s. 429-441, 2015.
[14]
M. Razola, A. Rosén och K. Garme, "Allen and Jones revisited," Ocean Engineering, vol. 89, s. 119-133, 2014.
[15]
M. Razola, A. Rosén och K. Garme, "Experimental Evaluation of Slamming Pressure Models Used in Structural Design of High-Speed Craft," International Shipbuilding Progress, vol. 61, no. 1-2, s. 17-39, 2014.
[16]
K. Garme et al., "Rough water performance of lightweight high-speed craft," Journal of Engineering for the Maritime Environment (Part M), vol. 228, no. 3, s. 293-301, 2014.
[17]
M. Razola et al., "Towards simulation-based structural design of high-speed craft," Transactions - Society of Naval Architects and Marine Engineers, vol. 122, s. 479-492, 2014.
[18]
M. Razola, J. Kuttenkeuler och A. Rosén, "Adressing localized assault loads in composite craft design," Transactions of the Royal Institution of Naval Architects Part B: International Journal of Small Craft Technology, vol. 154, no. Part B2, s. B87-B93, 2013.
[19]
I. Stenius et al., "Experimental hydroelastic characterization of slamming loaded marine panels," Ocean Engineering, vol. 74, s. 1-15, 2013.
[20]
C.-J. Söder et al., "Parametric roll mitigation using rudder control," Journal of Marine Science and Technology, vol. 18, no. 3, s. 395-403, 2013.
[21]
C.-J. Söder, A. Rosén och M. Palmqvist, "Motion-based monitoring of racking stresses in ro-ro ships," Ships and Offshore Structures, vol. 7, no. 4, s. 389-398, 2012.
[22]
I. Stenius, A. Rosén och J. Kuttenkeuler, "Hydroelastic interaction in panel-water impacts of high-speed craft," Ocean Engineering, vol. 38, no. 2-3, s. 371-381, 2011.
[23]
I. Stenius, A. Rosén och J. Kuttenkeuler, "On Structural Design of Energy Efficient Small High-Speed Craft," Marine Structures, vol. 24, no. 1, s. 43-59, 2011.
[24]
I. Stenius, A. Rosén och J. Kuttenkeuler, "Explicit FE-modelling of hydroelasticity in panel-water impacts," International Shipbuilding Progress, vol. 54, no. 2-3, s. 111-127, 2007.
[25]
I. Stenius, A. Rosén och J. Kuttenkeuler, "Explicit FE-modelling of fluid-structure interaction in hull-water impacts," International Shipbuilding Progress, vol. 53, no. 2, s. 103-121, 2006.
[26]
A. Rosén, "Impact Pressure Distribution Reconstruction from Discrete Point Measurements," International Shipbuilding Progress, vol. 52, no. 1, s. 91-107, 2005.
[27]
A. Rosén och K. Garme, "Model Experiment Addressing the Impact Pressure Distribution on Planing Craft in Waves," International Journal of Small Craft Technology, vol. 146, 2004.
[28]
K. Garme och A. Rosén, "Time-domain simulations and full-scale trials on planing craft in waves," International Shipbuilding Progress, vol. 50, no. 3, s. 177-208, 2003.
Konferensbidrag
[29]
A. Rosén, E. Liedholm Johnson och J. Jaldén, "Evaluating and Enhancing the Status of Sustainability in Engineering Education," i Proceedings of the 19th International CDIO Conference, 2023, s. 29-42.
[30]
A.-K. Peters och A. Rosén, "Learning about the role of educational developers and researchers for sustainability at a technical university," i ECER - European Conference on Educational Research, 2023.
[31]
P. Pantzos et al., "Engineering Students’ Motivation For Learning Inchallenge-Driven Project Courses: A Qualitative Pilot Study," i SEFI 2022. 50th Annual Conference of The European Society for Engineering Education 19-22 September, Barcelona, Spain : Towards a new future in engineering education, new scenarios that European alliances of tech universities open up, 2022.
[32]
M. Magnell et al., "Integrating Gender Equality, Diversity, and Equal Conditions, in Engineering Education," i Proceedings of the 18 th International CDIO Conference, hosted by Reykjavik University, Reykjavik Iceland, June13-15, 2022., 2022.
[33]
M. Zu et al., "Specifying Seakeeping Criteria for Efficient Task Performance," i Proceedings 15th International Symposium on Practical Design of Ships and Other Floating Structures PRADS 2022, 2022.
[34]
J. Malmqvist et al., "THE CDIO SYLLABUS 3.0 : AN UPDATED STATEMENT OF GOALS," i 18th CDIO International Conference, CDIO 2022 : Proceedings, 2022, s. 18-36.
[35]
J. Malmqvist et al., "The CDIO Syllabus 3.0 - An Updated Statement of Goals," i Proceedings of the 18th International CDIO Conference, hosted by Reykjavik University, Reykjavik Iceland, June13-15, 2022., 2022.
[36]
A. Rosén et al., "Transformation-Driving Education: Perspectives Emerging in a Dialogue between Teachers with Experiences from Challenge-Driven Education," i Frontiers in education (FIE 2022), 2022.
[37]
A. Rosén et al., "Experiences from Applying the CDIO Standard for Sustainable Development in Institution-Wide Program Evaluations," i Proceedings 17th International CDIO Conference, CDIO 2021, 2021.
[38]
J. Hedvall et al., "Perspectives on Challenge-Driven Engineering Education for a Sustainable Future," i 10th Engineering Education for Sustainable Development Conference (EESD2021), 2021, s. 184-191.
[39]
J. Malmqvist, K. Edström och A. Rosén, "CDIO Standards 3.0 – Updates to the Core CDIO Standards," i 16th International CDIO Conference, CDIO 2020Virtual, Online, 8-10 June 2020, 2020, s. 60-76.
[40]
J. R. G. Souppez et al., "Comparative Assessment of Rule-Based Design on the Pressures and Resulting Scantlings of High Speed Powercrafts," i Proceedings of the 12th symposium on high speed marine vehicles (HSMV 2020), 2020, s. 263-275.
[41]
J. Malmqvist et al., "Optional CDIO Standards : Sustainable development, Simulation-based mathematics, Engineering entrepreneurship, Internationalisation & mobility," i 16th International CDIO Conference, CDIO 2020 - Proceedings, 2020, s. 48-59.
[42]
J. Malmqvist et al., "Optional CDIO Standards: Sustainable Development, Simulation-Based Mathematics, Engineering Entrepreneurship, Internationalisation & Mobility," i 16th International CDIO Conference, 2020, s. 48-59.
[43]
A. Rosén et al., "Mapping the CDIO Syllabus to the UNESCO key competencies for sustainability," i Proceedings of the 15th International CDIO Conference, 2019.
[44]
J. Malmqvist et al., "Towards CDIO Standards 3.0," i Proceedings of the 15th International CDIO Conference, 2019.
[45]
H. Liwång och A. Rosén, "A framework for investigating the potential for operational measures in relation to intact stability," i Proceedings of the 13th International conference on stability of ships and ocean vehicles (STAB 2018), 2018, s. 488-499.
[46]
N. Themelis och A. Rosén, "An Overview of the Current Research on Stability of Ships and Ocean Vehicles," i 13th International Conference on the Stability of Ships and Ocean Vehicles (STAB2018), 2018.
[47]
A. Rosén et al., "Connecting North and South through Challenge Driven Education," i Proceedings of the 14th International CDIO Conference, 2018.
[48]
C. Wielgosz et al., "Experimental validation of numerical drag prediction of novel spray deflector design," i Marine Design XIII, 2018, s. 491-497.
[49]
C.-J. Söder och A. Rosén, "A framework for holistic roll damping prediction," i Proceedings of the 15th International Ship Stability Workshop, 13-15 June 2016, Stockholm, Sweden, 2016.
[50]
C.-J. Söder, E. Ovegård och A. Rosén, "On Aerodynamic Roll Damping," i Proceedings of the 12th International Conference on the Stability of Ships and Ocean Vehicles, 14-19 June 2015, Glasgow, UK., 2015.
[51]
I. Backalov et al., "Ship Stability & Safety in Intact Condition through Operational Measures," i 12TH INTERNATIONAL CONFERENCE ON THE STABILITY OF SHIPS AND OCEAN VEHICLES (STAB2015), 2015, s. 159-172.
[52]
I. Backalov et al., "Ship Stability, Dynamics and Safety : Status and Perspectives," i 12TH INTERNATIONAL CONFERENCE ON THE STABILITY OF SHIPS AND OCEAN VEHICLES (STAB2015), 2015, s. 99-141.
[53]
C.-J. Söder et al., "Assessment of Ship Roll Damping through Full-Scale and Model-Scale Experiments and Semi-Empirical Methods," i 11th International Conference on the Stability of Ships and Ocean Vehicles, 2012.
[54]
E. Ovegård et al., "Operational Guidance with Respect to Pure Loss of Stability and Parametric Rolling," i Proceedings of the 11th International Conference on the Stability of Ships and Ocean Vehicles (STAB2012), 2012.
[55]
A. Rosén et al., "3+2≠5 eller Programmål för ingenjörsutbildningar i ljuset av Bolognareformen," i 3:e Utvecklingskonferensen för Sveriges ingenjörsutbildningar, 2011, s. 47-52.
[56]
I. Stenius et al., "Hydroelastic Effects in Slamming Loaded Panels," i 11th International Conference on Fast Sea Transportation, FAST 2011 - Proceedings, 2011, s. 644-652.
[57]
M. A. Battley et al., "Effects of Panel Stiffness on Slamming Responses of Composite Hull Panels," i 17th International Conference on Composite Materials, ICCM17, 2009, s. 1-11.
[58]
A. Rosén, K. Garme och J. Kuttenkeuler, "Full-Scale Design Evaluation of the Visby Class Corvette," i 9th International Conference on Fast Sea Transportation, FAST'07, 2007, s. 593-598.
Kapitel i böcker
[59]
C.-J. Söder et al., "Assessment of ship roll damping through full scale and model scale experiments and semi-empirical methods," i Contemporary Ideas on Ship Stability, Belenky V. L. red., : Springer, 2019, s. 177-190.
[60]
A. Rosén, M. Huss och M. Palmquist, "Experience from Parametric Rolling of Ships," i Parametric Resonance in Dynamical Systems, Fossen T. I., Nijmeijer H. red., : Springer, 2012, s. 147-165.
Icke refereegranskade
Konferensbidrag
[61]
L. Gumaelius, A. Rosén och M. de Vries, "How to assess key competencies for sustainability in engineering education," i PBL 2021 International Conference, Transforming PBL through Hybrid Learning Models – Timely Challenges and Answers in a (Post)-Pandemic Perspective and Beyond, 2021, s. 390-394.
[62]
A. Rosén, H. Havtun och H. Lennholm, "Framework for bottom-up integration of sustainable development in engineering educations," i Symposium “Accelerating the Implementation of Sustainable Development in the Curriculum”, Stockholm, Sweden, 10th-11th September, 2019, 2019.
[63]
A. Rosén et al., "High-speed craft dynamics in waves: challenges and opportunities related to the current safety philosophy," i 16th International Ship Stability Workshop (ISSW 2017), Belgrade, Serbia, 2017., 2017.
[64]
L. Skoglund, J. Kuttenkeuler och A. Rosén, "Evaluating Weather Routing Decisions Using Ensemble Weather Forecasts," i International Conference on Design & Operation of Container Ships, 2014, s. 61-66.
[65]
M. Razola et al., "Towards Simulation-Based Design of High-Speed Craft," i 4th Chesapeake Powerboat Symposium, 2014.
[66]
A. Rosén et al., "On the influence of sea state idealizations and wave directionality in dynamic stability assessments," i Proceedings of the 13th International Ship Stability Workshop, Brest 23-26 September, 2013.
[67]
M. Razola et al., "On Structural Design of High-Speed Planing Craft with Respect to Slamming," i 8th International Conference on High-Speed Marine Vehicles, 2012.
[68]
A. Rosén och M. Razola, "Fluid-Structure Interaction for High-Speed Composite Craft," i Proceedings of the Review of the US Office of Naval Research Solid Mechanics Program, 2011.
[69]
K. Garme, A. Rosén och J. Kuttenkeuler, "In Detail Investigation of Planing Pressure," i Proceedings of the HYDRALAB III Joint User Meeting, 2010.
[70]
M. Burman, A. Rosén och D. Zenkert, "Spectrum Slam Fatigue Loading of Sandwich Materials for Marine Structures," i Ninth International Conference on Sandwich Structures (ICSS-9) in Pasadena, California, 14-16 June 2010, 2010.
[71]
I. Stenius och A. Rosén, "FE-Modelling of Hydrodynamic Hull-Water Impact Loads," i Proceedings of The 6th European LS-DYNA Users' Conference, 2007.
[72]
I. Stenius och A. Rosén, "Explicit FE Analysis of Hull-Water Impacts," i 8th International Conference on Fast Sea Transportation. St.Petersburg, Russia, 2005.
[73]
K. Garme och A. Rosén, "Direct Calculations in the Design of HSC," i Proceedings 6th International Conference on Fast Sea Transportation, 2001.
[74]
A. Rosén, "Impact Pressure Analysis on High-Speed Craft in Waves through FE-analysis on Measurement Data," i 8th International Symposium on Practical Design of Ships, 2001, s. 629-635.
[75]
K. Garme och A. Rosén, "Experimental Pressure Investigation on a High-Speed Craft in Waves," i Proceedings International Conference on Hydrodynamics of High-Speed Craft, 2000.
Kapitel i böcker
[76]
M. Magnell och A. Rosén, "Projektbaserad undervisning," i Ämnesintegrerad undervisning inom professionsutbildningar, Maria Christidis & Nikolaos Christidis red., 1. uppl. : Gleerups Utbildning AB, 2023, s. 125-147.
Avhandlingar
[77]
A. Rosén, "Loads and responses for planing craft in waves," Doktorsavhandling Stockholm : Farkost och flyg, Trita-AVE, 2004:47, 2004.
Rapporter
[78]
H. Hermansson-Järvenpää och A. Rosén, "KTH:s hållbarhetsmål för utbildning - Uppföljning av målperioden 2016-2020," , 2021.
[79]
K. Garme et al., "In Detail Investigation of Planing Pressure," , NTNU/Marintek Ocean Basin, NTNU_Marintek_530512, EC contract no. 022441, Report NyIII-NTNU-11, 2011.
[80]
[81]
A. Rosén, P. Delin och M. Palmquist, "Comments on and Evaluation of the Level 1 Vulnerability Criteria for Parametric Roll and Pure Loss of Stability," , Report for the Swedish Transport Agency and the International Maritime Organization, IMO SLF 53/INF.10/ANNEX 10, 2010.
[82]
A. Rosén et al., "Programmål inom den nya utbildningsstrukturen på KTH," Stockholm : KTH Royal Institute of Technology, 2010.
[83]
A. Rosén et al., "Sample Calculations on the Level 2 Vulnerability Criteria for Parametric Roll," , Report to the Swedish Transport Agency and the International Maritime Organization, IMO SLF 53/INF.8, 2010.
Proceedings (redaktörskap)
[84]
"Proceedings of the 15th International Ship Stability Workshop (ISSW 2016)," Stockholm, Sweden, KTH Royal Institute of Technology, 2016.
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2024-12-22 03:05:33