| [1] |
Aborhey, S.; Williamson, D., State and parameter estimation of microbial growth processes, Automatica, 14, 493 (1978) · Zbl 0425.93034 |
| [2] |
(Armiger, W. B., Computer applications in fermentation technology. Computer applications in fermentation technology, Biotechnology and Bioengineering Symposium No. 9 (1979), John Wiley: John Wiley New York) |
| [3] |
Beck, B.; Young, P., Systematic identification of DO-BOD model structure, (Env. Eng. Div. Proc. ASCE, 102 (1976)), 909 |
| [4] |
Busby, J. B.; Andrews, J. F., Dynamic modelling and control strategies for the activated sludge process, Journal WPCF, 47, 1055 (1975) |
| [5] |
Curds, C. R., Computer simulations of microbial population dynamics in the activated sludge process, Water Res., 5, 1049 (1971) |
| [6] |
Fredrickson, A. G.; Ramakrishna, D.; Tsuchiya, H. M., Statistics and dynamics of procaryotic cell population, Math. Biosci., 1, 327 (1967) · Zbl 0152.18901 |
| [7] |
Halme, A., Computer control of the Pekilo protein process, (Biotechnology and Bioengineering Symposium, No. 9 (1979), John Wiley: John Wiley New York), 369 |
| [8] |
Halme, A.; Holmberg, A., Application of control engineering to fermentation processes, (Niemi, A., A Link Between Science and Applications of Automatic Control (1979), Pergamon Press: Pergamon Press Oxford), 291 |
| [9] |
Holmberg, A.; Sievänen, R.; Carlberg, G., Fermentation of Bacillus thuringiensis for exotoxin production—process analysis study, Biotech. Bioengng, 22, 1707 (1980) |
| [10] |
Holmberg, A.; Selkäinaho, J.; Pallasvuo, O.; Halme, A., Microprocessor based estimation and control of the activated sludge wastewater treatment process—experimental testing at the Suomenoja research plant 10.6.-2.7.1980, (Report Series B59 (1980), Helsinki University of Technology, Systems Theory Laboratory) |
| [11] |
Hämäläinen, R. P.; Halme, A.; Gyllenberg, A., A control model for activated sludge wastewater treatment process, (Proc. 6th IFAC World Congress. Proc. 6th IFAC World Congress, paper 61.6 (1975), The Instrument Society of America: The Instrument Society of America Pittsburgh) |
| [12] |
Monod, J., (Recherches sur la Croissance des Cultures Bactériennes (1942), Hermann: Hermann Paris) |
| [13] |
Nihtilä, M.; Virkkunen, J., Practical identifiability of growth and substrate consumption models, Biotech. Bioengng, 19, 1831 (1977) |
| [14] |
Pirt, S. J., Principles of Microbe and Cell Cultivation (1975), John Wiley: John Wiley New York |
| [15] |
Pohjanpalo, H., System identifiability based on the power series expansion of the solution, Math. Biosci., 41, 21 (1978) · Zbl 0393.92008 |
| [16] |
Randolph, A. D.; Larson, M. A., (Theory of Particulate Processes—Analysis and Techniques of Continuous Crystallization (1971), Academic Press: Academic Press New York) |
| [17] |
Ranta, J., Some controllability aspects of microbial growth processes based on the biomass age distribution, (Preprints of IFAC 8th World Congress. Preprints of IFAC 8th World Congress, Kyoto (1981), Pergamon Press: Pergamon Press Oxford) |
| [18] |
Ranta, J.; Kaitala, V.; Halme, A., Modeling and simulation of bacterial population age distribution in the activated sludge process, (Proc. IFAC Workshop on Systems Analysis Application to Complex Programs, IFAC Series (1977), Pergamon Press: Pergamon Press Oxford) · Zbl 0401.92005 |
| [19] |
Svrcek, W. Y.; Elliot, R. F.; Zajic, J. E., The extended Kalman filter applied to a continuous culture model, Biotech. Bioengng, 16, 827 (1974) |
| [20] |
Tong, D. D.M.; Metzler, C. M., Mathematical properties of compartment models with Michaelis-Menten type elimination, Math. Biosci., 48, 293 (1980) · Zbl 0431.92015 |
| [21] |
Tsuchiya, H. M.; Fredrickson, A. G.; Aris, P., Dynamics of microbial cell populations, Advan. Chem. Engng, 6, 125 (1966) |
