Selected ETH Polymer Physics publications

All All Article Preprint Proc Report Thesis Book Book Review Patent Review Project All latest All 2024 All 2023 All 2022 All 2021 All 2020 All 2019 All 2018 All 2017 All 2016 All 2015 All 2014 All 2013 All 2012 All 2011 All 2010 All 2009 All 2008 All 2007 All 2006 All 2005 All 2004 All 2003 All 2002 All 2001 All 2000 All 1999 All 1998 All 1997 All 2025 by default year impact cited downloads downloads/a submission author title journal classical default bibitems bibtex Hcitations newcommand twiki (&y=year) citations per author impact per author bibtex e-collection

abstracts hide pdf's show images matching keyword & author

1 selected entry has been cited at least 34 times (SCI, 04-05-2024)

Article	R. Schlickeiser, M. Kröger Analytical solution of the SIR-model for the temporal evolution of epidemics. Part B. Semi-time case J. Phys. A: Math. Theor. 54 (2021) 175601
The earlier analytical analysis (part A) of the susceptible.infectious.recovered (SIR) epidemics model for a constant ratio k of infection to recovery rates is extended here to the semi-time case which is particularly appropriate for modeling the temporal evolution of later (than the first) pandemic waves when a greater population fraction from the first wave has been infected. In the semi-time case the SIR model does not describe the quantities in the past; instead they only hold for times later than the initial time t = 0 of the newly occurring wave. Simple exact and approximative expressions are derived for the final and maximum values of the infected, susceptible and recovered/removed population fractions as well the daily rate and cumulative number of new infections. It is demonstrated that two types of temporal evolution of the daily rate of new infections j(.) occur depending on the values of k and the initial value of the infected fraction I(0) = .: in the decay case for k . 1 . 2. the daily rate monotonically decreases at all positive times from its initial maximum value j(0) = .(1 . .). Alternatively, in the peak case for k < 1 . 2. the daily rate attains a maximum at a finite positive time. By comparing the approximated analytical solutions for j(.) and J(.) with the exact ones obtained by numerical integration, it is shown that the analytical approximations are accurate within at most only 2.5 percent. It is found that the initial fraction of infected persons sensitively influences the late time dependence of the epidemics, the maximum daily rate and its peak time. Such dependencies do not exist in the earlier investigated all-time case. for LaTeX users @article{RSchlickeiser2021-54,  author = {R. Schlickeiser and M. Kr\"oger},  title = {Analytical solution of the SIR-model for the temporal evolution of epidemics. Part B. Semi-time case},  journal = {J. Phys. A: Math. Theor.},  volume = {54},  pages = {175601},  year = {2021} } \bibitem{RSchlickeiser2021-54} R. Schlickeiser, M. Kr\"oger, Analytical solution of the SIR-model for the temporal evolution of epidemics. Part B. Semi-time case, J. Phys. A: Math. Theor. {\bf 54} (2021) 175601. RSchlickeiser2021-54 R. Schlickeiser, M. Kr\"oger Analytical solution of the SIR-model for the temporal evolution of epidemics. Part B. Semi-time case J. Phys. A: Math. Theor.,54,2021,175601

---

© 07 May 2024 mk@mat.ethz.ch      1 out of 813 entries requested [H-factor to-date: > 0]