References
- Al Aridhee, J., Łysiak, G. (2015). Stress relaxation characteristics of wheat kernels at different moisture. Acta Scientarum Polonorum, Technica Agraria, 14(3-4), 3-10.
- ASAE 368.4. Compression Test of Food Materials of Convex Shape. (2006). St. Joseph, MI (USA): American Society of Agricultural and Biological Engineers, (ASABE), 554-556.
- Bargale, P.C., Irudayaraj, J. (1995). Mechanical strength and rheological behavior of barley kernels. Internaional Journal of Food Science and Technology, 30(5), 609-623.
- Buňka, F., Pachlová, V., Pernická, L., Burešová, I., Kráčmar, S., Lošák, T. (2013). The dependence of Peleg's coefficients on selected conditions of a relaxation test in model samples of edam cheese. Journal of Texture Studies, 44(3), 187-195.
- Dell Inc. Dell Statistica (data analysis software system). Version 13. software.dell.com, 2016.
- Faridi, H., Faubion, J.M. (2012). Dough rheology and baked product texture. Springer Science & Business Media.
- Filipčev, B.V. (2014) Texture and stress relaxation of spelt–amaranth composite breads. Food and Feed Research, 41(1), 1-9.
- Gunasekaran, S., Ak, M.M. (2000). Dynamic oscillatory shear testing of foods-selected applications. Trends in Food Science and Technology, 11(3), 115-127.
- Guo, L., Wang, D., Tabil, L.G., Wang, G. (2016). Compression and relaxation properties of selected biomass for briquetting. Biosystems Engineering, 148, 101-110.
- Guo, Z., Castell-Perez, M.E., Moreira, R.G. (1999). Characterization of masa and low–moisture corn tortilla using stress relaxation methods. Journal of Texture Studies, 30(2), 197-215.
- Hatcher, D.W., Bellido, G.G., Dexter, J.E., Anderson, M.J., Fu, B.X. (2008). Investigation of uniaxial stress relaxation parameters to characterize the texture of yellow alkaline noodles made from durum and common wheats. Journal of Texture Studies, 39(6), 695-708.
- Herak, D., Kabutey, A., Choteborsky, R., Petru, M., Sigalingging, R. (2015). Mathematical models describing the relaxation behaviour of Jatropha curcas L. bulk seeds under axial compression. Bio-systems Engineering, 131, 77-83.
- Karaman, S., Yilmaz, M.T., Toker, O.S., Dogan, M. (2016). Stress relaxation/creep compliance behaviour of kashar cheese: Scanning electron microscopy observations. International Journal of Dairy Technology, 69(2), 254-261.
- Karim, A.A., Norziah, M.H., Seow, C.C. (2000). Methods for the study of starch retrogradation. Food Chemistry, 71(1), 9-36.
- Khazaei, J., Mann, D. (2004). Effects of temperature and loading characteristics on mechanical and stress–relaxation behavior of sea buckthorn berries. Part 2. Puncture Tests. Agricultural Engineering International: CIGR Journal.
- Khazaei, J., Mann, D. (2005). Effects of moisture content and number of loadings on force relaxation behavior of chickpea kernels. International Agrophysics, 19(4), 305-313.
- Lewicki, P. (2004). Water as the determinant of food engineering properties. A review. Journal of Food Engineering, 61(4), 483-495.
- Lewicki, P., Łukaszuk, A. (2000). Changes of rheological properties of apple tissue undergoing convective drying. Drying Technology, 18(3), 707-722.
- Lewicki, P., Spiess, W.E. (1995). Rheological properties of raisins: Part I. Compression test. Journal of Food Engineering, 24(3), 321-338.
- Łysiak, G. (2007). Influence in of moisture on rheological characteristics of the kernel of wheat. Acta Agrophysica, 9(1), 91-97.
- Mandala, I., Karabela, D., Kostaropoulos A. (2007). Physical properties of breads containing hydrocolloids stored at low temperature. I. Effect of chilling. Food Hydrocolloids, 21(8), 1397-1406.
- Ozturk, O.K., Takhar, P.S. (2017). Stress relaxation behavior of oat flakes. Journal of Cereal Science, 77, 84-89.
- Peleg, M. (1980). Linearization of relaxation and creep curves of solid biological materials. Journal of Rheology, 24(4), 451-463.
- Peleg, M., Normand, M.D. (1983). Comparison of two methods for stress relaxation data presentation of solid foods. Rheologica Acta, 22(1), 108-113.
- Shelef, L., Bousso, D. (1964). A new instrument for measuring relaxation in flour dough. Rheologica Acta, 3(3), 168-172.
- Shiau, S.Y., Chang, Y.H. (2013). Instrumental textural and rheological properties of raw, dried, and cooked noodles with transglutaminase. International Journal of Food Properties, 16(7), 1429-1441.
- Shiau, S.Y., Wu, T.T., Liu, Y.L. (2012). Effect of the amount and particle size of wheat fiber on textural and rheological properties of raw, dried and cooked noodles. Journal of Food Quality, 35(3), 207-216.
- Singh, H., Rockall, A., Martin, C.R., Chung, O.K., Lookhart, G.L. (2006). The analysis of stress relaxation data of some viscoelastic foods using a texture analyzer. Journal of Texture Studies, 37(4), 383-392.
- Sozer, N., Dalgic, A. C. (2007). Modelling of rheological characteristics of various spaghetti types. European Food Research and Technology, 225(2), 183-190.
- Sozer, N., Kaya, A., Dalgic, A.C. (2008). The effect of resistant starch addition on viscoelastic properties of cooked spaghetti. Journal of Texture Studies, 39(1), 1-16.
- Wu, M.Y., Chang, Y.H., Shiau, S.Y., Chen, C.C. (2012). Rheology of fiber–enriched steamed bread: stress relaxation and texture profile analysis. Journal of Food and Drug Analysis, 20(1), 133-142.