nfw: The Standard Distribution Functions for the 3D NFW Profile
In asgr/NFWdist: The Standard Distribution Functions for the 3D NFW Profile
Description
Usage
Arguments
Details
Value
Note
Author(s)
References
See Also
Examples
Description
Density, distribution function, quantile function and random generation for the 3D NFW profile
Usage
1
2
3
4
Arguments
x,q
Vector of quantiles. This is scaled such that x and q are equal to R/Rvir for NFW. This means the PDF is only defined between 0 and 1.
p
Vector of probabilities.
n
Number of observations. If length(n) > 1, the length is taken to be the number required.
con
The NFW profile concentration parameter, where c=Rvir/Rs.
log, log.p
Logical; if TRUE, probabilities/densities p are returned as log(p).
Details
The novel part of this package is the general solution for the CDF inversion (i.e. qnfw). As far as I can see this has not been published anywhere, and it is a useful function for populating halos in something like an HOD.
One of lamW (fastest) or gsl (easier to install) must be installed to use the qnfw and rnfw functions!. Try to install lamW first (since it is about four times faster), but if that is tricky due to Rcpp dependencies then use gsl instead.
Value
dnfw gives the density, pnfw gives the distribution function, qnfw gives the quantile function, and rnfw generates random deviates.
Note
This seems to work at least as efficiently as accept reject, but it is ultimately much more elegant code in any case.
Author(s)
Aaron Robotham
References
Robotham & Howlett, 2018, arXiv, 1805.09550
See Also
lambert_W0 (gsl) or lambertW0 (lamW).
Examples
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
#Both the PDF (dnfw) integrated up to x, and CDF at q (pnfw) should be the same:
#0.373, 0.562, 0.644, 0.712
for(con in c(1,5,10,20)){
print(integrate(dnfw, lower=0, upper=0.5, con=con)$value)
print(pnfw(0.5, con=con))
}
#The qnfw should invert the pnfw, returning the input vector (1:9)/10:
for(con in c(1,5,10,20)){
print(qnfw(p=pnfw(q=(1:9)/10,con=con), con=con))
}
#The sampling from rnfw should recreate the expected PDF from dnfw:
for(con in c(1,5,10,20)){
plot(density(rnfw(1e6,con=con), bw=0.01))
lines(seq(0,1,len=1e3), dnfw(seq(0,1,len=1e3),con=con),col='red')
legend('topright',legend=paste('con =',con))
}
asgr/NFWdist documentation built on May 7, 2019, 8:38 a.m.
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Description Usage Arguments Details Value Note Author(s) References See Also Examples
Description
Density, distribution function, quantile function and random generation for the 3D NFW profile
Usage
1 2 3 4 |
Arguments
x,q |
Vector of quantiles. This is scaled such that x and q are equal to R/Rvir for NFW. This means the PDF is only defined between 0 and 1. |
p |
Vector of probabilities. |
n |
Number of observations. If length(n) > 1, the length is taken to be the number required. |
con |
The NFW profile concentration parameter, where c=Rvir/Rs. |
log, log.p |
Logical; if TRUE, probabilities/densities p are returned as log(p). |
Details
The novel part of this package is the general solution for the CDF inversion (i.e. qnfw). As far as I can see this has not been published anywhere, and it is a useful function for populating halos in something like an HOD.
One of lamW (fastest) or gsl (easier to install) must be installed to use the qnfw and rnfw functions!. Try to install lamW first (since it is about four times faster), but if that is tricky due to Rcpp dependencies then use gsl instead.
Value
dnfw gives the density, pnfw gives the distribution function, qnfw gives the quantile function, and rnfw generates random deviates.
Note
This seems to work at least as efficiently as accept reject, but it is ultimately much more elegant code in any case.
Author(s)
Aaron Robotham
References
Robotham & Howlett, 2018, arXiv, 1805.09550
See Also
lambert_W0 (gsl) or lambertW0 (lamW).
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 | #Both the PDF (dnfw) integrated up to x, and CDF at q (pnfw) should be the same:
#0.373, 0.562, 0.644, 0.712
for(con in c(1,5,10,20)){
print(integrate(dnfw, lower=0, upper=0.5, con=con)$value)
print(pnfw(0.5, con=con))
}
#The qnfw should invert the pnfw, returning the input vector (1:9)/10:
for(con in c(1,5,10,20)){
print(qnfw(p=pnfw(q=(1:9)/10,con=con), con=con))
}
#The sampling from rnfw should recreate the expected PDF from dnfw:
for(con in c(1,5,10,20)){
plot(density(rnfw(1e6,con=con), bw=0.01))
lines(seq(0,1,len=1e3), dnfw(seq(0,1,len=1e3),con=con),col='red')
legend('topright',legend=paste('con =',con))
}
|
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