Stochastic Models for the Inference of Life Evolution


SMILE is an interdisciplinary research group gathering probabilists, statisticians, bio-informaticians and biologists.
SMILE is affiliated to the Stochastics and Biology group of LPSM (Lab of Probability, Statistics and Modeling) at Sorbonne Université (ex Université Pierre et Marie Curie Paris 06).
SMILE is hosted within the CIRB (Center for Interdisciplinary Research in Biology) at Collège de France.
SMILE is supported by Collège de France and CNRS.
Visit also our homepage at CIRB.

Recent contributions of the SMILE group related to SARS-Cov2 and COVID-19.


SMILE is hosted at Collège de France in the Latin Quarter of Paris. To reach us, go to 11 place Marcelin Berthelot (stations Luxembourg or Saint-Michel on RER B).
Our working spaces are rooms 107, 121 and 122 on first floor of building B1 (ask us for the code). Building B1 is facing you upon exiting the traversing hall behind Champollion's statue.


You can reach us by email (amaury.lambert - at - or (smile - at -

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A mathematical assessment of the efficiency of quarantining and contact tracing in curbing the COVID-19 epidemic

In our model of the COVID-19 epidemic, infected individuals can be of four types, according whether they are asymptomatic (\$$A\$$) or symptomatic (\$$I\$$), and use a contact tracing mobile phone app (\$$Y\$$) or not (\$$N\$$). We denote by \$$f\$$ the fraction of \$$A\$$'s, by \$$y\$$ the fraction of \$$Y\$$'s and by \$$R_0\$$ the average number of secondary infections from a random infected individual. We investigate the effect of non-digital interventions (voluntary isolation upon symptom onset, quarantining private contacts) and of digital interventions (contact tracing thanks to the app), depending on the willingness to quarantine, parameterized by four cooperating probabilities. For a given `effective' \$$R_0\$$ obtained with non-digital interventions, we use non-negative matrix theory and stopping line techniques to characterize mathematically the minimal fraction \$$y_0\$$ of app users needed to curb the epidemic. We show that under a wide range of scenarios, the threshold \$$y_0\$$ as a function of \$$R_0\$$ rises steeply from 0 at \$$R_0=1\$$ to prohibitively large values (of the order of 60-70\% up) whenever the effective \$$R_0\$$ is above 1.3. Our results show that moderate rates of adoption of a contact tracing app can reduce \$$R_0\$$ but are by no means sufficient to reduce it below 1 unless it is already very close to 1 thanks to non-digital interventions.

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