Stability Analysis and Controller Design of Further Development of MIMOS II for Space Applications with Focus on the Extended Lyapunov Method: Part I
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Stability Analysis and Controller Design of Further Development of MIMOS II for Space Applications with Focus on the Extended Lyapunov Method: Part I

Authors: Mohammad Beyki, Justus Pawlak, Robert Patzke, Franz Renz

Abstract:

In the context of planetary exploration, the MIMOS II (miniaturized M¨ossbauer spectrometer) serves as a proven and reliable measuring instrument. The transmission behaviour of the electronics in the M¨ossbauer spectroscopy is further developed and optimized. For this purpose, the overall electronics is split into three parts. This elaboration deals exclusively with the first part of the signal chain for the evaluation of photons in experiments with gamma radiation. Parallel to the analysis of the electronics, an additional method for analysing the stability of linear and non-linear systems is presented: The extended method of Lyapunov’s stability criteria. The design helps to weigh advantages and disadvantages against other simulated circuits in order to optimize the MIMOS II for the terestric and extraterestric measurment. Finally, after stability analysis, the controller design according to Ackermann is performed, achieving the best possible optimization of the output variable through a skillful pole assignment.

Keywords: Controller design for MIMOS II, stability analysis, M¨ossbauer spectroscopy, electronic signal amplifier, light processing technology, photocurrent, transimpedance amplifier, extended Lyapunov method.

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References:


[1] M. Blumers, B. Bernhardt, P. Lechner, G. Klingelh¨ofer, C. dUston, H. Soltau, L. Str¨uder, R. Eckerhardt, J. Br¨uckner, H. Henkel, J.G. Lopez, J. Maul, ’The miniaturised M¨ossbauer spectrometer MIMOS II A: Increased sensitivity and new capability for element alanalysis’, Nuclear Instruments and Methods in Physics Research A 624 (2010) 277281. journalhomepage: www.elsevier.com/locate/nima, 2010
[2] G. Klingelh¨ofer, B. Fegley, R.V. Morris, E. Kankeleit, P. Held, E. Evlanov, O. Priloutskii, Planetary and Space Science, 44, 11, 1277-1288 (1996).
[3] M. Beyki, J. Pawlak, R. Patzke, F. Renz, ’Simulation of the electronic part of M¨ossbauer spectroscopy’, OHJG 2023, Okayama, Japan, DOI: https://doi.org/10.25968/opus-2459 .
[4] M. Beyki, J. Pawlak, R. Patzke, F. Renz, ’Simulative Development of the Electronic Component of M¨ossbauer Spectroscopy with a Focus on the Controllability of a 2nd Order Transimpedance Amplifier’, Lux Junior 2023, Ilmenau, Germany, DOI: 10.22032/dbt.55787, https://www.tu-ilmenau.de/fileadmin/Bereiche/MB/lichttechnik/Lux junior/2023/Beyki Lux junior 2023.pdf
[5] X. Ramus, ’Transimpedance Considerations for High-Speed Amplifiers’, Texas Instruments: Application Report SBOA122 November 2009, https: //www.ti.com/lit/an/sboa122/sboa122.pdf.
[6] R. Patzke, ’Schnelle und rauscharme Photonenmessung mit pin-Fotodioden’, Hochschule Hannover – University of Applied Sciences and Arts, Fachgebiet Integrierte Schaltungen und Eingebettete Systeme (IES), DOI: https://doi.org/10.25968/opus-2315, 31/July/2022.
[7] O. F¨ollinger, U. Konigorski, B. Lohmann, G. Roppenecker, A. Tr¨achtler, ’Regelungstechnik: Einf¨uhrung in die Methoden und ihre Anwendung’, 13th edition, VDE VERLAG GMBH 2022, p. 168 - 188.
[8] M. Beyki, R. Kutzner, U. Lindemann, ’Systemtheorie & Optimale Regelung – Teil V Zustandsregelung’, 1st edition, Hochschule Hannover – University of Applied Sciences and Arts, DOI: https://doi.org/10.25968/opus-2442 .
[9] J. Adamy, ’Systemdynamik und Regelungstechnik II – Teil II: Nichtlineare Systeme’, Shaker Verlag, Aachen, 2005, chapt. 4.5.
[10] H. Unbehauen, ’Regelungstechnik II – Zustandsregelungen, digitale und nichtlineare Regelsysteme’, 9th edition, Vieweg Verlag, Wiesbaden, 2007, p. 222-236.