tpfit_me: Maximum Entropy Method for One-dimensional Model Parameters...
In spMC: Continuous-Lag Spatial Markov Chains
tpfit_me R Documentation
Maximum Entropy Method for One-dimensional Model Parameters Estimation
Description
The function estimates the model parameters of a 1-D continuous lag spatial Markov chain by the use of the maximum entropy method. Transition rates matrix along a user defined direction and proportions of categories are computed.
Usage
tpfit_me(data, coords, direction, tolerance = pi/8,
max.it = 9000, mle = "avg")
Arguments
data
a categorical data vector of length n.
coords
an n \times d matrix where each row denotes the d-D coordinates of data locations.
direction
a d-D numerical vector (or versor) which represents the chosen direction.
tolerance
a numerical value for the tolerance angle (in radians). It is pi/8 by default.
max.it
a numerical value which denotes the maximum number of iterations to perform during the optimization phase. It is 9000 by default.
mle
a character value to pass to the function mlen. It is "avg" by default.
Details
A 1-D continuous-lag spatial Markov chain is probabilistic model which involves a transition rate matrix R computed for the direction \phi. It defines the transition probability \Pr(Z(s + h) = z_k | Z(s) = z_j) through the entry t_{jk} of the following matrix
T = \mbox{expm} (h R),
where h is a positive lag value.
To calculate entries of the transition rate matrix, we need to maximize the entropy of the transition probabilities of embedded occurrences along a given direction \phi. The entropy is defined as
e = - \sum_{k}^K \sum_{j \neq k}^K \tau_{jk, \phi} \log \tau_{jk, \phi},
where \tau_{jk, \phi} are transition probabilities of embedded occurrences. It is maximized by the use of the iterative proportion fitting method.
When some entries of the matrix R are not identifiable, it is suggested to vary the tolerance coefficient or to set the input argument mle to "mlk".
Value
An object of the class tpfit is returned. The function print.tpfit is used to print the fitted model. The object is a list with the following components:
coefficients
the transition rates matrix computed for the user defined direction.
prop
a vector containing the proportions of each observed category.
tolerance
a numerical value which denotes the tolerance angle (in radians).
Author(s)
Luca Sartore drwolf85@gmail.com
References
Carle, S. F., Fogg, G. E. (1997) Modelling Spatial Variability with One and Multidimensional Continuous-Lag Markov Chains. Mathematical Geology, 29(7), 891-918.
See Also
predict.tpfit, print.tpfit, multi_tpfit_me
Examples
data(ACM)
# Estimate the parameters of a
# one-dimensional MC model
tpfit_me(ACM$MAT5, ACM[, 1:3], c(0,0,1))
spMC documentation built on May 3, 2023, 9:13 a.m.
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| tpfit_me | R Documentation |
Maximum Entropy Method for One-dimensional Model Parameters Estimation
Description
The function estimates the model parameters of a 1-D continuous lag spatial Markov chain by the use of the maximum entropy method. Transition rates matrix along a user defined direction and proportions of categories are computed.
Usage
tpfit_me(data, coords, direction, tolerance = pi/8,
max.it = 9000, mle = "avg")Arguments
data |
a categorical data vector of length |
coords |
an |
direction |
a |
tolerance |
a numerical value for the tolerance angle (in radians). It is |
max.it |
a numerical value which denotes the maximum number of iterations to perform during the optimization phase. It is |
mle |
a character value to pass to the function |
Details
A 1-D continuous-lag spatial Markov chain is probabilistic model which involves a transition rate matrix R computed for the direction \phi. It defines the transition probability \Pr(Z(s + h) = z_k | Z(s) = z_j) through the entry t_{jk} of the following matrix
T = \mbox{expm} (h R),
where h is a positive lag value.
To calculate entries of the transition rate matrix, we need to maximize the entropy of the transition probabilities of embedded occurrences along a given direction \phi. The entropy is defined as
e = - \sum_{k}^K \sum_{j \neq k}^K \tau_{jk, \phi} \log \tau_{jk, \phi},
where \tau_{jk, \phi} are transition probabilities of embedded occurrences. It is maximized by the use of the iterative proportion fitting method.
When some entries of the matrix R are not identifiable, it is suggested to vary the tolerance coefficient or to set the input argument mle to "mlk".
Value
An object of the class tpfit is returned. The function print.tpfit is used to print the fitted model. The object is a list with the following components:
coefficients |
the transition rates matrix computed for the user defined direction. |
prop |
a vector containing the proportions of each observed category. |
tolerance |
a numerical value which denotes the tolerance angle (in radians). |
Author(s)
Luca Sartore drwolf85@gmail.com
References
Carle, S. F., Fogg, G. E. (1997) Modelling Spatial Variability with One and Multidimensional Continuous-Lag Markov Chains. Mathematical Geology, 29(7), 891-918.
See Also
predict.tpfit, print.tpfit, multi_tpfit_me
Examples
data(ACM)
# Estimate the parameters of a
# one-dimensional MC model
tpfit_me(ACM$MAT5, ACM[, 1:3], c(0,0,1))
R Package Documentation
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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