References
- 1. Cooper K.P., Jones H.N., Meger R.A. (2007), Analysis of railgun barrel material, IEEE Transactions on Magnetics, 43(1), 120-125.
- 2. Domin J., Kluszczynski K. (2013), Hybrid pneumatic-electro-magnetic launcher - general concept, mathematical model and results of simulation, Przegląd Elektrotechniczny, 89(12), 21-25.
- 3. Gieras J. F., Piech Z. J., Tomczuk B. (2011), Linear synchronous motors, CRC Press, Taylor & Francis Group.
- 4. Gosiewski Z., Klosowski P. (2008), Support of work of electro-magnetic gun by using permanent magnets, Bulletin of the Military University of Technology, 57(3), 87-95.
- 5. Hogan J.D., Spray J.G., Rogers R.J., Vincent G., Schneider M., (2013), Dynamic fragmentation of planetary materials: ejecta length quantification and semi-analytical modelling, International Journal of Impact Enginee-ring, 62, 219–228.
- 6. Hundertmark S., Schneider M., Simicic D., Vincent G., (2013), Experiments to increase the used energy with the PEGASUS railgun installation, http://arxiv.org/pdf/1402.6094v1.pdf.
- 7. Kluszczynski K., Domin J. (2015), Two module electromagnetic launcher with pneumatic assist: modelling, computer simulations and laboratory investigations, COMPEL (The International Journal for Computation and Mathematics in Electrical and Electronic Engineering), 34(3), 691-709.
- 8. McNab I.R., Beach F.C. (2007), Naval railguns, IEEE Transactions on Magnetics, 43(1), 463-468.
- 9. Piekielny P. (2015), The measurement stand for the testing of the electrodynamic accelerator parameters, Zeszyty Naukowe Politechniki Opolskiej, 71, 53-54.
- 10. Piskur P. (2010), Multiparameter optimization of construction and control of an electromagnetic launcher for application in linear drive of machining tool, Ph.D. theses, Koszalin University of Technology, Department of Mechatronics, Nanotechnology and Vacuum Technology, Koszalin, Poland. (in polish)
- 11. Poniaev S.A., Bobashev S.V., Zhukov R.O., Sedov A.I., Izotov S.N., Kulakov S.L., Smirnova M.N., (2015), Small-size railgun of mm-size solid bodies for hypervelocity material testing, Acta Astronautica, 109, 162-165.
- 12. Tang L., He J., Chen L., Xia S., Feng D., Li J., Yan P., (2015), Study of some influencing factors of armature current distribution at current ramp-up stage in railgun, IEEE Transactions on Plasma Science, 43(5), 1585-1591.
- 13. Tumanski S. (2011), Handbook of Magnetic Measurements, CRC Press.
- 14. Waindok A., Mazur G. (2011), Mutual inductances in a mathematical model of the three-stage reluctance accelerator, 3rd International Students Conference on Electrodynamics and Mechatronics (SCE III), Opole, Poland, 115-118.
- 15. Waindok A., Piekielny P. (2013), Analysis of selected constructions of the electrodynamic accelerator, International Symposium on Electrodynamic and Mechatronic Systems (SELM), Zawiercie, Poland, 51-52.
- 16. Wild B., Schuppler C., Alouahabi F., Schneider M., Hoffman R. (2014), The influence of the rail material on the multishot performance of the Rapid Fire Railgun (RAFIRA), 17th International Symposium on Electromagnetic Launch Technology (EML), La Jolla, CA, USA.
- 17. Zimon J., Tomczuk B., Wajnert D. (2012), Field-circuit modeling of AMB system for various speeds of the rotor, Journal of Vibroengineering, 14(1), 165-170.