bayes.mean: Parameter estimates based on non-informative Bayes
In rotations: Working with Rotation Data
bayes.mean R Documentation
Parameter estimates based on non-informative Bayes
Description
Use non-informative Bayes to estimate the central orientation and concentration parameter of a sample of rotations.
Usage
bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000)
## S3 method for class 'SO3'
bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000)
## S3 method for class 'Q4'
bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000)
Arguments
x
n-by-p matrix where each row corresponds to a random rotation in matrix (p=9) or quaternion (p=4) form.
type
Angular distribution assumed on R. Options are Cayley, Fisher or Mises
S0
initial estimate of central orientation
kappa0
initial estimate of concentration parameter
tuneS
central orientation tuning parameter, concentration of proposal distribution
tuneK
concentration tuning parameter, standard deviation of proposal distribution
burn_in
number of draws to use as burn-in
m
number of draws to keep from posterior distribution
Details
The procedures detailed in bingham2009b and bingham2010 are implemented to obtain
draws from the posterior distribution for the central orientation and concentration parameters for
a sample of 3D rotations. A uniform prior on SO(3) is used for the central orientation and the
Jeffreys prior determined by type is used for the concentration parameter.
bingham2009b bingham2010
Value
list of
-
Shat Mode of the posterior distribution for the central orientation S
-
kappa Mean of the posterior distribution for the concentration kappa
See Also
mean.SO3, median.SO3
Examples
Rs <- ruars(20, rvmises, kappa = 10)
Shat <- mean(Rs) #Estimate the central orientation using the projected mean
rotdist.sum(Rs, Shat, p = 2) #The projected mean minimizes the sum of squared Euclidean
rot.dist(Shat) #distances, compute the minimized sum and estimator bias
#Estimate the central orientation using the posterior mode (not run due to time constraints)
#Compare it to the projected mean in terms of the squared Euclidean distance and bias
ests <- bayes.mean(Rs, type = "Mises", S0 = mean(Rs), kappa0 = 10, tuneS = 5000,
tuneK = 1, burn_in = 1000, m = 5000)
Shat2 <- ests$Shat #The posterior mode is the 'Shat' object
rotdist.sum(Rs, Shat2, p = 2) #Compute sum of squared Euclidean distances
rot.dist(Shat2) #Bayes estimator bias
rotations documentation built on June 25, 2022, 1:06 a.m.
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| bayes.mean | R Documentation |
Parameter estimates based on non-informative Bayes
Description
Use non-informative Bayes to estimate the central orientation and concentration parameter of a sample of rotations.
Usage
bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000) ## S3 method for class 'SO3' bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000) ## S3 method for class 'Q4' bayes.mean(x, type, S0, kappa0, tuneS, tuneK, burn_in, m = 5000)
Arguments
x |
n-by-p matrix where each row corresponds to a random rotation in matrix (p=9) or quaternion (p=4) form. |
type |
Angular distribution assumed on R. Options are |
S0 |
initial estimate of central orientation |
kappa0 |
initial estimate of concentration parameter |
tuneS |
central orientation tuning parameter, concentration of proposal distribution |
tuneK |
concentration tuning parameter, standard deviation of proposal distribution |
burn_in |
number of draws to use as burn-in |
m |
number of draws to keep from posterior distribution |
Details
The procedures detailed in bingham2009b and bingham2010 are implemented to obtain
draws from the posterior distribution for the central orientation and concentration parameters for
a sample of 3D rotations. A uniform prior on SO(3) is used for the central orientation and the
Jeffreys prior determined by type is used for the concentration parameter.
bingham2009b bingham2010
Value
list of
-
ShatMode of the posterior distribution for the central orientation S -
kappaMean of the posterior distribution for the concentration kappa
See Also
mean.SO3, median.SO3
Examples
Rs <- ruars(20, rvmises, kappa = 10)
Shat <- mean(Rs) #Estimate the central orientation using the projected mean
rotdist.sum(Rs, Shat, p = 2) #The projected mean minimizes the sum of squared Euclidean
rot.dist(Shat) #distances, compute the minimized sum and estimator bias
#Estimate the central orientation using the posterior mode (not run due to time constraints)
#Compare it to the projected mean in terms of the squared Euclidean distance and bias
ests <- bayes.mean(Rs, type = "Mises", S0 = mean(Rs), kappa0 = 10, tuneS = 5000,
tuneK = 1, burn_in = 1000, m = 5000)
Shat2 <- ests$Shat #The posterior mode is the 'Shat' object
rotdist.sum(Rs, Shat2, p = 2) #Compute sum of squared Euclidean distances
rot.dist(Shat2) #Bayes estimator bias
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