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Literature DB >> 25113590

Bayesian tracking of emerging epidemics using ensemble optimal statistical interpolation.

Loren Cobb¹, Ashok Krishnamurthy², Jan Mandel¹, Jonathan D Beezley³.

Abstract

We present a preliminary test of the Ensemble Optimal Statistical Interpolation (EnOSI) method for the statistical tracking of an emerging epidemic, with a comparison to its popular relative for Bayesian data assimilation, the Ensemble Kalman Filter (EnKF). The spatial data for this test was generated by a spatial susceptible-infectious-removed (S-I-R) epidemic model of an airborne infectious disease. Both tracking methods in this test employed Poisson rather than Gaussian noise, so as to handle epidemic data more accurately. The EnOSI and EnKF tracking methods worked well on the main body of the simulated spatial epidemic, but the EnOSI was able to detect and track a distant secondary focus of infection that the EnKF missed entirely.

Entities: Chemical Disease Species

Keywords: Bayesian statistical tracking; Data assimilation; Emerging epidemics; Ensemble Kalman filter; Optimal statistical interpolation; Spatial S-I-R epidemic model

Mesh：

Year: 2014 PMID： 25113590 PMCID： PMC4143132 DOI： 10.1016/j.sste.2014.06.004

Source DB: PubMed Journal: Spat Spatiotemporal Epidemiol ISSN： 1877-5845

9 in total

1. Data driven computing by the morphing fast Fourier transform ensemble Kalman filter in epidemic spread simulations.

Authors: Jan Mandel; Jonathan D Beezley; Loren Cobb; Ashok Krishnamurthy
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2. Variational data assimilation with epidemic models.

Authors: C J Rhodes; T D Hollingsworth
Journal: J Theor Biol Date: 2009-03-04 Impact factor: 2.691

3. The role of population heterogeneity and human mobility in the spread of pandemic influenza.

Authors: Stefano Merler; Marco Ajelli
Journal: Proc Biol Sci Date: 2009-10-28 Impact factor: 5.349

4. Using the Kalman filter and dynamic models to assess the changing HIV/AIDS epidemic.

Authors: B Cazelles; N P Chau
Journal: Math Biosci Date: 1997-03 Impact factor: 2.144

5. ON THE CONVERGENCE OF THE ENSEMBLE KALMAN FILTER.

Authors: Jan Mandel; Loren Cobb; Jonathan D Beezley
Journal: Appl Math (Prague) Date: 2011-12 Impact factor: 0.881

6. Reconstruction of the seasonally varying contact rate for measles.

Authors: M Kalivianakis; S L Mous; J Grasman
Journal: Math Biosci Date: 1994-12 Impact factor: 2.144

7. Modeling the spatial spread of infectious diseases: the GLobal Epidemic and Mobility computational model.

Authors: Duygu Balcan; Bruno Gonçalves; Hao Hu; José J Ramasco; Vittoria Colizza; Alessandro Vespignani
Journal: J Comput Sci Date: 2010-08-01

8. Real time bayesian estimation of the epidemic potential of emerging infectious diseases.

Authors: Luís M A Bettencourt; Ruy M Ribeiro
Journal: PLoS One Date: 2008-05-14 Impact factor: 3.240

9. Real-time influenza forecasts during the 2012-2013 season.

Authors: Jeffrey Shaman; Alicia Karspeck; Wan Yang; James Tamerius; Marc Lipsitch
Journal: Nat Commun Date: 2013 Impact factor: 14.919

9 in total

5 in total

4. Integration of a Kalman filter in the geographically weighted regression for modeling the transmission of hand, foot and mouth disease.

Authors: Bisong Hu; Wenqing Qiu; Chengdong Xu; Jinfeng Wang
Journal: BMC Public Health Date: 2020-04-10 Impact factor: 3.295

5. Identifying the measurements required to estimate rates of COVID-19 transmission, infection, and detection, using variational data assimilation.

Authors: Eve Armstrong; Manuela Runge; Jaline Gerardin
Journal: Infect Dis Model Date: 2020-11-02