Iterated filtering algorithms are a tool for maximum likelihood inference on partially observed dynamical systems. Stochastic perturbations to the unknown parameters are used to explore the parameter space. Applying sequential Monte Carlo (the particle filter) to this extended model results in the selection of the parameter values that are more consistent with the data. Appropriately constructed procedures, iterating with successively diminished perturbations, converge to the maximum likelihood estimate.[1][2][3] Iterated filtering methods have so far been used most extensively to study infectious disease transmission dynamics. Case studies include cholera,[4][5] Ebola virus,[6] influenza,[7][8][9][10] malaria,[11][12][13] HIV,[14] pertussis,[15][16] poliovirus[17] and measles.[5][18] Other areas which have been proposed to be suitable for these methods include ecological dynamics[19][20] and finance.[21][22]

The perturbations to the parameter space play several different roles. Firstly, they smooth out the likelihood surface, enabling the algorithm to overcome small-scale features of the likelihood during early stages of the global search. Secondly, Monte Carlo variation allows the search to escape from local minima. Thirdly, the iterated filtering update uses the perturbed parameter values to construct an approximation to the derivative of the log likelihood even though this quantity is not typically available in closed form. Fourthly, the parameter perturbations help to overcome numerical difficulties that can arise during sequential Monte Carlo.

Overview

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The data are a time series   collected at times  . The dynamic system is modeled by a Markov process   which is generated by a function   in the sense that

 

where   is a vector of unknown parameters and   is some random quantity that is drawn independently each time   is evaluated. An initial condition   at some time   is specified by an initialization function,  . A measurement density   completes the specification of a partially observed Markov process. We present a basic iterated filtering algorithm (IF1)[1][2] followed by an iterated filtering algorithm implementing an iterated, perturbed Bayes map (IF2).[3][23]

Procedure: Iterated filtering (IF1)

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Input: A partially observed Markov model specified as above; Monte Carlo sample size  ; number of iterations  ; cooling parameters   and  ; covariance matrix  ; initial parameter vector  
for   to  
draw   for  
set   for  
set  
for   to  
draw   for  
set   for  
set   for  
draw   such that  
set   and   for  
set   to the sample mean of  , where the vector   has components  
set   to the sample variance of  
set  
Output: Maximum likelihood estimate  

Variations

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  1. For IF1, parameters which enter the model only in the specification of the initial condition,  , warrant some special algorithmic attention since information about them in the data may be concentrated in a small part of the time series.[1]
  2. Theoretically, any distribution with the requisite mean and variance could be used in place of the normal distribution. It is standard to use the normal distribution and to reparameterise to remove constraints on the possible values of the parameters.
  3. Modifications to the IF1 algorithm have been proposed to give superior asymptotic performance.[24][25]

Procedure: Iterated filtering (IF2)

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Input: A partially observed Markov model specified as above; Monte Carlo sample size  ; number of iterations  ; cooling parameter  ; covariance matrix  ; initial parameter vectors  
for   to  
set   for  
set   for  
for   to  
draw   for  
set   for  
set   for  
draw   such that  
set   and   for  
set   for  
Output: Parameter vectors approximating the maximum likelihood estimate,  

Software

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"pomp: statistical inference for partially-observed Markov processes" : R package.

References

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  1. ^ a b c Ionides, E. L.; Breto, C.; King, A. A. (2006). "Inference for nonlinear dynamical systems". Proceedings of the National Academy of Sciences of the USA. 103 (49): 18438–18443. Bibcode:2006PNAS..10318438I. doi:10.1073/pnas.0603181103. PMC 3020138. PMID 17121996.
  2. ^ a b Ionides, E. L.; Bhadra, A.; Atchade, Y.; King, A. A. (2011). "Iterated filtering". Annals of Statistics. 39 (3): 1776–1802. arXiv:0902.0347. doi:10.1214/11-AOS886. S2CID 6527480.
  3. ^ a b Ionides, E. L.; Nguyen, D.; Atchadé, Y.; Stoev, S.; King, A. A. (2015). "Inference for dynamic and latent variable models via iterated, perturbed Bayes maps". Proceedings of the National Academy of Sciences of the USA. 112 (3): 719–724. Bibcode:2015PNAS..112..719I. doi:10.1073/pnas.1410597112. PMC 4311819. PMID 25568084.
  4. ^ King, A. A.; Ionides, E. L.; Pascual, M.; Bouma, M. J. (2008). "Inapparent infections and cholera dynamics" (PDF). Nature. 454 (7206): 877–880. Bibcode:2008Natur.454..877K. doi:10.1038/nature07084. hdl:2027.42/62519. PMID 18704085. S2CID 4408759. Archived from the original on 2021-08-28. Retrieved 2024-05-23.
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  6. ^ King AA, Domenech de Celles M, Magpantay FM, Rohani P (2015). "Avoidable errors in the modelling of outbreaks of emerging pathogens, with special reference to Ebola". Proceedings of the Royal Society B. 282 (1806): 20150347. doi:10.1098/rspb.2015.0347. PMC 4426634. PMID 25833863.
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  13. ^ Roy, M.; Bouma, M. J.; Ionides, E. L.; Dhiman, R. C.; Pascual, M. (2013). "The potential elimination of Plasmodium vivax malaria by relapse treatment: Insights from a transmission model and surveillance data from NW India". PLOS Neglected Tropical Diseases. 7 (1): e1979. doi:10.1371/journal.pntd.0001979. PMC 3542148. PMID 23326611.
  14. ^ Zhou, J.; Han, L.; Liu, S. (2013). "Nonlinear mixed-effects state space models with applications to HIV dynamics". Statistics and Probability Letters. 83 (5): 1448–1456. doi:10.1016/j.spl.2013.01.032.
  15. ^ Lavine, J.; Rohani, P. (2012). "Resolving pertussis immunity and vaccine effectiveness using incidence time series". Expert Review of Vaccines. 11 (11): 1319–1329. doi:10.1586/ERV.12.109. PMC 3595187. PMID 23249232.
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  18. ^ He, D.; Ionides, E. L.; King, A. A. (2010). "Plug-and-play inference for disease dynamics: measles in large and small towns as a case study". Journal of the Royal Society Interface. 7 (43): 271–283. doi:10.1098/rsif.2009.0151. PMC 2842609. PMID 19535416.
  19. ^ Ionides, E. L.. (2011). "Discussion on "Feature Matching in Time Series Modeling" by Y. Xia and H. Tong". Statistical Science. 26: 49–52. arXiv:1201.1376. doi:10.1214/11-STS345C. S2CID 88511724.
  20. ^ Blackwood, J. C.; Streicker, D. G.; Altizer, S.; Rohani, P. (2013). "Resolving the roles of immunity, pathogenesis, and immigration for rabies persistence in vampire bat". Proceedings of the National Academy of Sciences of the USA. 110 (51): 20837––20842. Bibcode:2013PNAS..11020837B. doi:10.1073/pnas.1308817110. PMC 3870737. PMID 24297874.
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  22. ^ Breto, C. (2014). "On idiosyncratic stochasticity of financial leverage effects". Statistics and Probability Letters. 91: 20–26. arXiv:1312.5496. doi:10.1016/j.spl.2014.04.003. S2CID 122694545.
  23. ^ Lindstrom, E.; Ionides, E. L.; Frydendall, J.; Madsen, H. (2012). "Efficient Iterated Filtering". System Identification. 45 (16): 1785–1790. doi:10.3182/20120711-3-BE-2027.00300.
  24. ^ Lindstrom, E. (2013). "Tuned iterated filtering". Statistics and Probability Letters. 83 (9): 2077–2080. doi:10.1016/j.spl.2013.05.019.
  25. ^ Doucet, A.; Jacob, P. E.; Rubenthaler, S. (2013). "Derivative-Free Estimation of the Score Vector and Observed Information Matrix with Application to State-Space Models". arXiv:1304.5768 [stat.ME].