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Stochastic approach to study control strategies of Covid-19 pandemic in India

Published online by Cambridge University Press:  28 August 2020

Athokpam Langlen Chanu
Affiliation:
School of Computational & Integrative Sciences, Jawaharlal Nehru University, New Delhi110067, India
R. K. Brojen Singh*
Affiliation:
School of Computational & Integrative Sciences, Jawaharlal Nehru University, New Delhi110067, India
*
Author for correspondence: R. K. Brojen Singh, E-mail: brojen@jnu.ac.in
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Abstract

India is one of the severely affected countries by the Covid-19 pandemic at present. Within the stochastic framework of the SEQIR model, we studied publicly available data of the Covid-19 patients in India and analysed possible impacts of quarantine and social distancing as controlling strategies for the pandemic. Our stochastic simulation results clearly show that proper quarantine and social distancing should be maintained right from the start of the pandemic and continued until its end for effective control. This calls for a more disciplined social lifestyle in the future. However, only social distancing and quarantine of the exposed population are found not sufficient enough to end the pandemic in India. Therefore, implementation of other stringent policies like complete lockdown as well as increased testing of susceptible populations is necessary. The demographic stochasticity, which is quite visible in the system dynamics, has a critical role in regulating and controlling the pandemic.

Information

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press
Figure 0

Fig. 1. The schematic diagram of the SEQIR model (adapted from the reference [17]).

Figure 1

Table 1. Rate constant values taken from [17]

Figure 2

Table 2. Initial values taken from [17]

Figure 3

Fig. 2. The upper panels (a–d) represent the simulation results of Infected Population I(t) vs. time, t (in days) for India using the Stochastic Simulation Algorithm (SSA). (a and b) I(t) vs. t for India for different values of the system size V. As V increases, I(t) decreases. (c) I(t) vs. t for India for different values of transmission rate α at V = 0.7. I(t) increases with increase in α. (d) I(t) vs. t for India for different values of quarantine rate β2 at V = 1.0. I(t) decreases with increase in β2. The lower panels (e–g) represent the simulation results of Infected Population I(t) vs. time t (in days) for Uttar Pradesh using the SSA. (e) I(t) vs. t for Uttar Pradesh for different values of V. As V increases, I(t) decreases. (f and g) I(t) vs. t for Uttar Pradesh for different values of quarantine rates β2 at two values of system size V = 1.0 and V = 100.0, respectively. In both (f) and (g), I(t) decreases with increase in β2.

Figure 4

Fig. 3. The upper panels (a–c) show simulation results of Infected Population I(t) vs. time t (in days) for Delhi using the Stochastic Simulation Algorithm (SSA). (a) I(t) vs. t of Delhi for different values of the system size V. As V increases, I(t) decreases. (b and c) I(t) vs. t of Delhi for different values of quarantine rate β2 at two different volumes V = 1.0 and V = 5.0, respectively. In both (b) and (c), I(t) decreases with increase in β2. Again, (d–f) show simulation results of Infected Population I(t) vs. time t (in days) for Kerala using SSA. (d) I(t) vs. t of Kerala for different values of V. As V increases, I(t) decreases. (e and f) I(t) vs. t of Kerala for different values of quarantine rate β2 at two different volumes V = 1.0 and V = 5.0, respectively. In both (e) and (f), I(t) decreases with increase in β2.

Figure 5

Fig. 4. The upper panels (a–c) show simulation results of Infected Population I(t) vs. time t (in days) for Maharashtra using Stochastic Simulation Algorithm. (a) I(t) vs. t of Maharashtra for different values of system size V. I(t) decreases with increase in V. (b and c) I(t) vs. t of Maharashtra for different values of quarantine rate β2 at two different volumes V = 1.0 and V = 5.0, respectively. In both (b) and (c), I(t) decreases with increase in β2. Again, (d–f) show simulation results of Infected Population I(t) vs. time t (in days) for West Bengal using the SSA. (d) I(t) vs. t of West Bengal for different values of V. I(t) decreases with increase in V. (e and f) I(t) vs. t of West Bengal for different values of β2 at two different volumes V = 1.0 and V = 5.0, respectively. In both (e) and (f), I(t) decreases with increase in β2.

Figure 6

Fig. 5. Left panel: Simulation results of I(t) vs. time t (in days) using Stochastic Simulation Algorithm for five Indian states, namely Maharashtra, Delhi, Kerala, Uttar Pradesh and West Bengal at a fixed system size V = 1000. Right panel: Heat Maps for (a) India, (b) Uttar Pradesh, (c) Delhi, (d) Kerala, (e) Maharashtra and (f) West Bengal to study the variation of the infected population I w.r.t the transmission rate α and quarantine rate β2. Stochastic fluctuations in I are clearly visible.