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Ray Tracing the Zonohedron Boundary and the 2-Transition Surface"
In zonohedra: Compute and Plot Zonohedra from Vector Generators
```{css, echo=FALSE}
body {
max-width: 870px; / make wider, default is 700px /
}
```r
knitr::opts_chunk$set(echo = TRUE)
old_opt = options( width=144 )
Introduction
The focus of this vignette are the two
functions raytrace() and raytrace2trans().
The former is for the boundary of the zonohedron
and the latter is for the associated 2-transition surface.
We revisit the example at the end of section 6
in Scott Burns' paper @Burns2021,
which is also illustrated in the 1nm plot from Figure 8.
His example is from colorimetry, where the boundary of the zonohedron
is the set of optimal colors
and the 2-transition surface is the set of Schrödinger colors
(both for Illuminant E).
The correspondence for the optimal colors was discovered by
Paul Centore, see @Centore2013.
Other featured functions are invertboundary(), inside() and inside2trans().
library(zonohedra)
A Ray Tracing Example
In Burns' example, the base of the ray is the center of the zonohedron $Z$:
matgen = colorimetry.genlist[["xyz1931.1nm"]] # the CIE 1931 CMFs at 1nm step
matgen = 100 * matgen / sum( matgen[2, ] ) # it is traditional to scale so the center has Y=50, recall we use Illuminant E
zono = zonohedron( matgen )
base = getcenter(zono) ; base
The vector base corresponds to Burns' vector $XYZ_{\text{50%}}$.
The direction of the ray is given by spherical angles,
which define a unit vector u:
theta = 1.478858 ; phi = 0.371322
u = c( sin(phi)*cos(theta), sin(phi)*sin(theta), cos(phi) ) ; u
Calculate the intersection of the ray with the boundary of $Z$.
df_opt = raytrace( zono, base, u ) ; df_opt
XYZ_opt = df_opt$point[1, ] ; XYZ_opt
This matches Burns' value of $XYZ_{\text{LPsoln}}$.
From Figure 8 of @Burns2021 we see that this point
(and every point in the same parallelogram)
comes from a reflectance spectrum with 4 transitions.
This can be verified by inverting:
invertboundary( zono, XYZ_opt )$transitions
Now calculate the intersection of the ray with the 2-transition surface
associated with $Z$.
df_2trans = raytrace2trans( zono, base, u ) ; df_2trans
XYZ_2trans = df_2trans$point[1, ] ; XYZ_2trans
This matches Burns' value of $XYZ_{\text{two-trans}}$ to 4 decimal places.
The transition wavelengths 629 and 575nm,
and the parallelogram coordinates 0.2246808 and 0.4459951
(these are the corresponding reflectances),
are clearly visible in Figure 8.
Now consider the distance between these 2 points
$XYZ_{\text{LPsoln}}$ and $XYZ_{\text{two-trans}}$.
The parameter tmax in both data frames is the parameter on the ray
where it intersects the boundary or the surface.
Since u is a unit vector, the difference between the parameters is this distance.
df_opt$tmax - df_2trans$tmax
This matches Burns' value of $1.29 \times 10^{-3}$,
which is very tiny especially compared to the two $XYZ$s.
What is the maximum that this distance can be over the entire $\partial Z$ ?
To get a rough estimate, a search was made over the rays
passing though the centers of all the 21900 deficient parallelograms,
and with the same basepoint as before.
The largest distance over these rays was $2.47 \times 10^{-3}$.
This distance is for the parallelogram with generators corresponding
to 592 and 608 nm; the generating 'spectrum' has 8 transitions.
The actual maximum distance between the boundary of the color solid
and the 2-transition surface is not much larger than this sampling.
This confirms Burns' statement from @Burns2021 that the distance between
these surfaces has
"... no practical impact on typical colorimetric calculations".
If the zonohedron $Z$ is called the Object Color Solid (OCS),
and the inside of the 2-transition surface is called the
Schrödinger Color Solid (SCS),
we see that the OCS is obtained by adding a very thin "skin"
on some regions of the SCS.
Inside or Outside ?
Consider the midpoint of $XYZ_{\text{LPsoln}}$ and $XYZ_{\text{two-trans}}$.
It lies on the same ray as these 2 points,
so it must be inside the zonohedron, but outside the 2-transition surface.
We can verify this easily:
XYZ_mid = (XYZ_opt + XYZ_2trans) / 2
inside( zono, XYZ_mid )
inside2trans( zono, XYZ_mid )
References
Session Information
This document was prepared
r format(Sys.Date(), "%a %b %d, %Y")
with the following configuration:
options(old_opt)
sessionInfo()
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zonohedra documentation built on Sept. 11, 2024, 5:20 p.m.
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```{css, echo=FALSE} body { max-width: 870px; / make wider, default is 700px / }
```r knitr::opts_chunk$set(echo = TRUE) old_opt = options( width=144 )
Introduction
The focus of this vignette are the two
functions raytrace() and raytrace2trans().
The former is for the boundary of the zonohedron
and the latter is for the associated 2-transition surface.
We revisit the example at the end of section 6
in Scott Burns' paper @Burns2021,
which is also illustrated in the 1nm plot from Figure 8.
His example is from colorimetry, where the boundary of the zonohedron
is the set of optimal colors
and the 2-transition surface is the set of Schrödinger colors
(both for Illuminant E).
The correspondence for the optimal colors was discovered by
Paul Centore, see @Centore2013.
Other featured functions are invertboundary(), inside() and inside2trans().
library(zonohedra)
A Ray Tracing Example
In Burns' example, the base of the ray is the center of the zonohedron $Z$:
matgen = colorimetry.genlist[["xyz1931.1nm"]] # the CIE 1931 CMFs at 1nm step matgen = 100 * matgen / sum( matgen[2, ] ) # it is traditional to scale so the center has Y=50, recall we use Illuminant E zono = zonohedron( matgen ) base = getcenter(zono) ; base
The vector base corresponds to Burns' vector $XYZ_{\text{50%}}$.
The direction of the ray is given by spherical angles,
which define a unit vector u:
theta = 1.478858 ; phi = 0.371322 u = c( sin(phi)*cos(theta), sin(phi)*sin(theta), cos(phi) ) ; u
Calculate the intersection of the ray with the boundary of $Z$.
df_opt = raytrace( zono, base, u ) ; df_opt XYZ_opt = df_opt$point[1, ] ; XYZ_opt
This matches Burns' value of $XYZ_{\text{LPsoln}}$. From Figure 8 of @Burns2021 we see that this point (and every point in the same parallelogram) comes from a reflectance spectrum with 4 transitions. This can be verified by inverting:
invertboundary( zono, XYZ_opt )$transitions
Now calculate the intersection of the ray with the 2-transition surface associated with $Z$.
df_2trans = raytrace2trans( zono, base, u ) ; df_2trans XYZ_2trans = df_2trans$point[1, ] ; XYZ_2trans
This matches Burns' value of $XYZ_{\text{two-trans}}$ to 4 decimal places. The transition wavelengths 629 and 575nm, and the parallelogram coordinates 0.2246808 and 0.4459951 (these are the corresponding reflectances), are clearly visible in Figure 8.
Now consider the distance between these 2 points
$XYZ_{\text{LPsoln}}$ and $XYZ_{\text{two-trans}}$.
The parameter tmax in both data frames is the parameter on the ray
where it intersects the boundary or the surface.
Since u is a unit vector, the difference between the parameters is this distance.
df_opt$tmax - df_2trans$tmax
This matches Burns' value of $1.29 \times 10^{-3}$, which is very tiny especially compared to the two $XYZ$s.
What is the maximum that this distance can be over the entire $\partial Z$ ? To get a rough estimate, a search was made over the rays passing though the centers of all the 21900 deficient parallelograms, and with the same basepoint as before. The largest distance over these rays was $2.47 \times 10^{-3}$. This distance is for the parallelogram with generators corresponding to 592 and 608 nm; the generating 'spectrum' has 8 transitions. The actual maximum distance between the boundary of the color solid and the 2-transition surface is not much larger than this sampling. This confirms Burns' statement from @Burns2021 that the distance between these surfaces has "... no practical impact on typical colorimetric calculations".
If the zonohedron $Z$ is called the Object Color Solid (OCS), and the inside of the 2-transition surface is called the Schrödinger Color Solid (SCS), we see that the OCS is obtained by adding a very thin "skin" on some regions of the SCS.
Inside or Outside ?
Consider the midpoint of $XYZ_{\text{LPsoln}}$ and $XYZ_{\text{two-trans}}$. It lies on the same ray as these 2 points, so it must be inside the zonohedron, but outside the 2-transition surface. We can verify this easily:
XYZ_mid = (XYZ_opt + XYZ_2trans) / 2 inside( zono, XYZ_mid ) inside2trans( zono, XYZ_mid )
References
Session Information
This document was prepared
r format(Sys.Date(), "%a %b %d, %Y")
with the following configuration:
options(old_opt) sessionInfo()
Try the zonohedra package in your browser
Any scripts or data that you put into this service are public.
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We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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