References
- [1] Lifshitz, J. M., 1988, „Compressive Fatique and Static Properties of a Unidirectional Graphite/ Epoxy Composite” Journal of Composites Technology and Research, 10 (3), pp. 100–106.
- [2] Chatys, R., Darska, J. and Opala, M., 2005, “The Effect of the Technological Parameters on the Quality of Composite Materials Produced with the RTM Method.”, International Conference ”Terotechnology’2005”, Kielce, September 28-30, 2005., ”Mechanika”, nr. 83, pp. 21–28.
- [3] Chatys, R., 2009, „Mechanical Properties of Polymer Composites Produced by Resin Injection Molding for Applications Under Increased Demands for Quality and Repeatability”, Journal Ultrasound, 64(2), pp. 35–38.
- [4] Topoliński, T. and Weiner, W., 1995, „Programowane badania zmęczeniowe ogniw przenośnika na tle wyników badań eksploatacyjnych” (Programmable the study fatigue the conveyor links on the background of the results of operational research - available in Polish), VI Konferencja nt. „Nowe kierunki modyfikacji i zastosowań tworzyw sztucznych” (6th Conference on “New directions of modifications and uses of plastics”), Poznań, 10-13.05.1995 pp. 137–142.
- [5] Szala, J., 2007, „Podstawowe problemy konstruowania złożonych obiektów ze względu na zmęczeniowe pękanie” (Basic problems of constructing complex objects due to fatigue cracking - available in Polish), XXIII Sympozjon Podstaw Konstrukcji Maszyn (23rd Symposium on Machine Design Basics), Przemyśl, 17-21 September 2007, Ed. by PRz, Rzeszów.
- [6] Reifsnider, K. L. and Stinchcomb, W. W., 2005, A Critical-Element Model of the Residual Strength and Life of Fatigue-Loaded Composite Coupons”, Composite Materials: Fatigue and Fracture, ASTM STP 907. pp. 298–313.
- [7] Yang, J. N., Jones, S. L., Yang, S. H. and Meskini, A., 1990, „A Stiffness Degradation Model for Graphite/Epoxy Laminates”, J, of Composites Materials, 24(3), pp. 753–763.
- [8] Broutman, L. J. and Sahu, S., 1972, „A New Theory to Predict Cumulative Fatigue Damage in Fiberglass Reinforced Plastics”, Composite Materials: Testing and Design, 2nd Conference American Society for Testing and Materials, Philadelphia, ASTM STP, 497, pp. 170–188.
- [9] Rotem, A., 1986, „Fatigue and Residual Strength of Composite Laminates”, Engineering Fracture Mechanics, 25(6), pp. 819–827.
- [10] Paramonov, Yu. M., Kleinhof, M. A. and Paramonova, A. Yu., 2006,”Markov Model of Connection Between the Distribution of Static Strength and Fatigue Life of a Fibrous Composite”, Mechanics of Composite Materials, 42(5), pp. 615–630.
- [11] Paramonov, Yu. and Andersons, J., 2007, „A family of weakest link models for fibre strength distribution”, Composites: Part A38, pp. 1227–1233.
- [12] Kemeny, J. G and Snell, J. L., 1966, „ Finite Marcov Chains”, Princeton: N.J. Van Nostrand.
- [13] Chatys, R., Paramonova, A. Yu. and Kleinhofs, M. A., 2011, „Analysis of Residual Strength after Fatigue in Fibrous Composite using Markov Chains Model”, Monography: “Selected Problems of Modeling and Control in Mechanics”, Edited by Stanisław Adamczak and Leszek Radziszewski, Kielce, 2011, pp. 166–178.
- [14] Paramonov, J., Chatys, R., Anderson, J. and Kleinhofs, M., 2012, „Markov Model of Fatigue of a Composite Material with Poisson Process of Defect Initiation”, Mechanics of Composite Materials,. 48(2), pp. 211–228.
- [15] Paramonov, Yu., Chatys, R., Andersons, J. and Kleinhofs, M., 2011, „Poisson process of defect initiation in fatigue of a composite material”, International Conferences „RelStat’2011”, 20-21.10.2011, Riga Latvia, pp. 1–12 (CD).
- [16] Iosifescu, M., 1988, „Skończone procesy Markowa i ich zastosowanie” (Finished Markov processes and their application - available in Polish), Ed. by PWN, Warsaw, Poland.
- [17] Fleming, W. H. and Soner, H. M., 1993, „Controlled Markov processes and viscosity solutions” Springer Verlag, New York.
- [18] White, D. J., 1992,”Markov decision processes”, Chichester: John Wiley.
- [19] Found, M. S and Quaresimin, M., 2003, „Two–stage fatigue loading of woven carbon fiber reinforced laminates”, Fatigue Fract. Eng. Mater. Struct. 26, pp. 17–26.
- [20] ASTM D638 - Standard Test Method for Tensile Properties of Plastics.