Autologistic Model of Spatial Pattern of Phytophthora Epidemic in Bell Pepper: Effects of Soil Variables on Disease Presence

The autologistic model is a flexible model for predicting presence or absence of disease in an agricultural field, based on soil variables, while taking spatial correlation into account. In the autologistic model, the log odds of disease in a particular quadrat are modeled as a linear combination of disease presence or absence in neighboring quadrats and the soil variables. Neighboring quadrats can be defined as adjacent quadrats within a row, quadrats in adjacent rows, quadrats two rows away, and so forth. The regression coefficients give estimates of the increase in odds of disease if neighbors within a row or in adjacent rows show disease symptoms; thus, we obtain information about the degree of spread in different directions. The coefficients for the soil variables give estimates of the increase in odds of disease as soil water content or pathogen population density increase. In this problem, the soil variables may also be highly correlated over quadrats, and disease incidence in within-row neighbors may be highly correlated with disease incidence in adjacent-row neighbors. This collinearity makes estimation and interpretation of the parameters of the autologistic model more difficult. We discuss fitting the autologistic model and tools for evaluating the aptness of the model.

[1]  Sylvia Richardson,et al.  Markov Chain Monte Carlo in Practice , 1997 .

[2]  P. Diggle,et al.  Analysis of Longitudinal Data , 2003 .

[3]  P. de Reffye,et al.  Analysis and Mapping of the Spatial Spread of African Cassava Mosaic Virus Using Geostatistics and the Kriging Technique , 1989 .

[4]  J. Besag Statistical Analysis of Non-Lattice Data , 1975 .

[5]  J. Pierrat,et al.  Modélisation spatio-temporelle d'une épidémie par un processus de Gibbs : estimation et tests , 1992 .

[6]  C. Geyer Markov Chain Monte Carlo Maximum Likelihood , 1991 .

[7]  J. Ristaino,et al.  Spatial and temporal dynamics of Phytophthora epidemics in commercial bell pepper fields , 1993 .

[8]  P S Albert,et al.  A generalized estimating equations approach for spatially correlated binary data: applications to the analysis of neuroimaging data. , 1995, Biometrics.

[9]  J. Ristaino,et al.  Spatial dynamics of disease symptom expression during Phytophthora epidemics in bell pepper , 1994 .

[10]  D. Hosmer,et al.  Applied Logistic Regression , 1991 .

[11]  J. Plank CHAPTER 7 – Analysis of Epidemics , 1960 .

[12]  S. Chakraborty,et al.  A stochastic model for anthracnose development in Stylosanthes scabra , 1992 .

[13]  A. Agresti,et al.  Categorical Data Analysis , 1991, International Encyclopedia of Statistical Science.

[14]  D. K. Pickard Asymptotic inference for an Ising lattice , 1976 .

[15]  L. Madden,et al.  Analysis of epidemics using spatio-temporal autocorrelation , 1988 .

[16]  J. Besag Nearest‐Neighbour Systems and the Auto‐Logistic Model for Binary Data , 1972 .

[17]  J. Besag Spatial Interaction and the Statistical Analysis of Lattice Systems , 1974 .

[18]  D. J. Strauss,et al.  The Many Faces of Logistic Regression , 1992 .

[19]  Noel A Cressie,et al.  Statistics for Spatial Data. , 1992 .

[20]  D. K. Pickard Asymptotic inference for an Ising lattice III. Non-zero field and ferromagnetic states , 1979 .

[21]  Marcia L. Gumpertz,et al.  Geostatistical analysis of Phytophthora epidemic development in commercial bell pepper fields , 1995 .