The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
Jack, zonal, Schur, and other symmetric polynomials.
library(jack)
Schur polynomials have applications in combinatorics and zonal polynomials have applications in multivariate statistics. They are particular cases of Jack polynomials, which are some multivariate symmetric polynomials. The original purpose of this package was the evaluation and the computation in symbolic form of these polynomials. Now it contains much more stuff dealing with multivariate symmetric polynomials.
In version 6.0.0, each function whose name ended with the suffix
CPP
(JackCPP
, JackPolCPP
, etc.)
has been renamed by removing this suffix, and the functions
Jack
, JackPol
, etc. have been renamed by
adding the suffix R
to their name: JackR
,
JackPolR
, etc. The reason of these changes is that a name
like Jack
is more appealing than JackCPP
and
it is more sensible to assign the more appealing names to the functions
implemented with Rcpp since they are highly more
efficient. The interest of the functions JackR
,
JackPolR
, etc. is meager.
The functions JackPol
, ZonalPol
,
ZonalQPol
and SchurPol
respectively return the
Jack polynomial, the zonal polynomial, the quaternionic zonal
polynomial, and the Schur polynomial.
Each of these polynomials is given by a positive integer, the number
of variables (the n
argument), and an integer partition
(the lambda
argument); the Jack polynomial has a parameter
in addition, the alpha
argument, a number called the
Jack parameter.
Actually there are four possible Jack polynomials for a given Jack
parameter and a given integer partition: the \(J\)-polynomial, the \(P\)-polynomial, the \(Q\)-polynomial and the \(C\)-polynomial. You can specify which one
you want with the which
argument, which is set to
"J"
by default. These four polynomials differ only by a
constant factor.
To get a Jack polynomial with JackPol
, you have to
supply the Jack parameter as a bigq
rational number or
anything coercible to a bigq
number by an application of
the as.bigq
function of the gmp package,
such as a character string representing a fraction,
e.g. "2/5"
:
<- JackPol(2, lambda = c(3, 1), alpha = "2/5")
jpol
jpol## 98/25*x^3.y + 28/5*x^2.y^2 + 98/25*x.y^3
This is a qspray
object, from the qspray
package. Here is how you can evaluate this polynomial:
evalQspray(jpol, c("2", "3/2"))
## Big Rational ('bigq') :
## [1] 1239/10
It is also possible to convert a qspray
polynomial to a
function whose evaluation is performed by the Ryacas
package:
<- as.function(jpol) jyacas
You can provide the values of the variables of this function as numbers or character strings:
jyacas(2, "3/2")
## [1] "1239/10"
You can even pass a variable name to this function:
jyacas("x", "x")
## [1] "(336*x^4)/25"
If you want to substitute a complex number to a variable, use a
character string which represents this number, with I
denoting the imaginary unit:
jyacas("2 + 2*I", "2/3 + I/4")
## [1] "Complex((-158921)/2160,101689/2160)"
It is also possible to evaluate a qspray
polynomial for
some complex values of the variables with evalQspray
. You
have to separate the real parts and the imaginary parts:
evalQspray(jpol, values_re = c("2", "2/3"), values_im = c("2", "1/4"))
## Big Rational ('bigq') object of length 2:
## [1] -158921/2160 101689/2160
If you just have to evaluate a Jack polynomial, you don’t need to
resort to a qspray
polynomial: you can use the functions
Jack
, Zonal
, ZonalQ
or
Schur
, which directly evaluate the polynomial; this is much
more efficient than computing the qspray
polynomial and
then applying evalQspray
.
Jack(c("2", "3/2"), lambda = c(3, 1), alpha = "2/5")
## Big Rational ('bigq') :
## [1] 1239/10
However, if you have to evaluate a Jack polynomial for several
values, it could be better to resort to the qspray
polynomial.
As of version 6.0.0, the package is able to compute the skew Schur
polynomials with the function SkewSchurPol
, and the general
skew Jack polynomial is available as of version 6.1.0 (function
SkewJackPol
).
As of version 6.0.0, it is possible to get a Jack polynomial with a symbolic Jack parameter in its coefficients, thanks to the symbolicQspray package.
<- JackSymPol(2, lambda = c(3, 1)) )
( J ## { [ 2*a^2 + 4*a + 2 ] } * X^3.Y + { [ 4*a + 4 ] } * X^2.Y^2 + { [ 2*a^2 + 4*a + 2 ] } * X.Y^3
This is a symbolicQspray
object, from the
symbolicQspray package.
A symbolicQspray
object corresponds to a multivariate
polynomial whose coefficients are fractions of polynomials with rational
coefficients. The variables of these fractions of polynomials can be
seen as some parameters. The Jack polynomials fit into this category:
from their definition, their coefficients are fractions of polynomials
in the Jack parameter. However you can see in the above output that for
this example, the coefficients are polynomials in the Jack
parameter (a
): there’s no fraction. Actually this fact is
always true for the Jack \(J\)-polynomials. This is an established
fact and it is not obvious (it is a consequence of the Knop & Sahi formula).
You can substitute a value to the Jack parameter with the help of the
substituteParameters
function:
<- substituteParameters(J, 5) )
( J5 ## 72*X^3.Y + 24*X^2.Y^2 + 72*X.Y^3
== JackPol(2, lambda = c(3, 1), alpha = "5")
J5 ## [1] TRUE
Note that you can change the letters used to denote the variables. By
default, the Jack parameter is denoted by a
and the
variables are denoted by X
, Y
, Z
if there are no more than three variables, otherwise they are denoted by
X1
, X2
, … Here is how to change these
symbols:
showSymbolicQsprayOption(J, "a") <- "alpha"
showSymbolicQsprayOption(J, "X") <- "x"
J## { [ 2*alpha^2 + 4*alpha + 2 ] } * x1^3.x2 + { [ 4*alpha + 4 ] } * x1^2.x2^2 + { [ 2*alpha^2 + 4*alpha + 2 ] } * x1.x2^3
If you want to have the variables denoted by x
and
y
, do:
showSymbolicQsprayOption(J, "showMonomial") <- showMonomialXYZ(c("x", "y"))
J## { [ 2*alpha^2 + 4*alpha + 2 ] } * x^3.y + { [ 4*alpha + 4 ] } * x^2.y^2 + { [ 2*alpha^2 + 4*alpha + 2 ] } * x.y^3
The skew Jack polynomials with a symbolic Jack parameter are available too, as of version 6.1.0.
The expression of a Jack polynomial in the canonical basis can be
long. Since these polynomials are symmetric, one can get a considerably
shorter expression by writing the polynomial as a linear combination of
the monomial symmetric polynomials. This is what the function
compactSymmetricQspray
does:
<- JackPol(3, lambda = c(4, 3, 1), alpha = "2") )
( J ## 3888*x^4.y^3.z + 2592*x^4.y^2.z^2 + 3888*x^4.y.z^3 + 3888*x^3.y^4.z + 4752*x^3.y^3.z^2 + 4752*x^3.y^2.z^3 + 3888*x^3.y.z^4 + 2592*x^2.y^4.z^2 + 4752*x^2.y^3.z^3 + 2592*x^2.y^2.z^4 + 3888*x.y^4.z^3 + 3888*x.y^3.z^4
compactSymmetricQspray(J) |> cat()
## 3888*M[4, 3, 1] + 2592*M[4, 2, 2] + 4752*M[3, 3, 2]
The function compactSymmetricQspray
is also applicable
to a symbolicQspray
object, like a Jack polynomial with
symbolic Jack parameter.
It is easy to figure out what is a monomial symmetric polynomial:
M[i, j, k]
is the sum of all monomials
x^p.y^q.z^r
where (p, q, r)
is a permutation
of (i, j, k)
.
The “compact expression” of a Jack polynomial with n
variables does not depend on n
if
n >= sum(lambda)
:
<- c(3, 1)
lambda <- "3"
alpha <- JackPol(4, lambda, alpha)
J4 <- JackPol(9, lambda, alpha)
J9 compactSymmetricQspray(J4) |> cat()
## 32*M[3, 1] + 16*M[2, 2] + 28*M[2, 1, 1] + 24*M[1, 1, 1, 1]
compactSymmetricQspray(J9) |> cat()
## 32*M[3, 1] + 16*M[2, 2] + 28*M[2, 1, 1] + 24*M[1, 1, 1, 1]
In fact I’m not sure the Jack polynomial makes sense when
n < sum(lambda)
.
The qspray package provides a function to compute
the Hall inner product of two symmetric polynomials, namely
HallInnerProduct
. This is the generalized Hall inner
product, the one with a parameter \(\alpha\). It is known that the Jack
polynomials with parameter \(\alpha\)
are orthogonal for the Hall inner product with parameter \(\alpha\). Let’s give a try:
<- "3"
alpha <- JackPol(4, lambda = c(3, 1), alpha, which = "P")
J1 <- JackPol(4, lambda = c(2, 2), alpha, which = "P")
J2 HallInnerProduct(J1, J2, alpha)
## Big Rational ('bigq') :
## [1] 0
HallInnerProduct(J1, J1, alpha)
## Big Rational ('bigq') :
## [1] 135/8
HallInnerProduct(J2, J2, alpha)
## Big Rational ('bigq') :
## [1] 63/5
If you set alpha=NULL
in HallInnerProduct
,
you get the Hall inner product with symbolic parameter \(\alpha\):
HallInnerProduct(J1, J1, alpha = NULL)
## 3/128*alpha^4 + 1/4*alpha^3 + 63/128*alpha^2 + 81/64*alpha
This is a qspray
object. The Hall inner product is
always polynomial in \(\alpha\).
It is also possible to get the Hall inner product of two
symbolicQspray
polynomials. Take for example a Jack
polynomial with symbolic parameter:
<- JackSymPol(4, lambda = c(3, 1), which = "P")
J showSymbolicQsprayOption(J, "a") <- "t"
HallInnerProduct(J, J, alpha = 2)
## [ 20*t^4 - 24*t^3 + 92*t^2 - 48*t + 104 ] %//% [ t^4 + 4*t^3 + 6*t^2 + 4*t + 1 ]
We use t
to display the Jack parameter and not
alpha
so that there is no confusion between the Jack
parameter and the parameter of the Hall product.
Now, what happens if we compute the symbolic Hall inner product of
this Jack polynomial with itself, that is, if we run
HallInnerProduct(J, J, alpha = NULL)
? Let’s see:
<- HallInnerProduct(J, J, alpha = NULL) )
( Hip ## { [ 6 ] %//% [ t^4 + 4*t^3 + 6*t^2 + 4*t + 1 ] } * alpha^4 + { [ 9*t^2 - 6*t + 1 ] %//% [ t^4 + 4*t^3 + 6*t^2 + 4*t + 1 ] } * alpha^3 + { [ 3*t^4 - 6*t^3 + 5*t^2 ] %//% [ t^4 + 4*t^3 + 6*t^2 + 4*t + 1 ] } * alpha^2 + { [ 4*t^4 ] %//% [ t^4 + 4*t^3 + 6*t^2 + 4*t + 1 ] } * alpha
We get the Hall inner product of the Jack polynomial with itself,
with two symbolic parameters: the Jack parameter displayed as
t
and the parameter of the Hall product displayed as
alpha
. This is a symbolicQspray
object.
Now one could be interested in the symbolic Hall inner product of the
Jack polynomial with itself for the case when the Jack parameter and the
parameter of the Hall product coincide, that is, to set
alpha=t
in the symbolicQspray
polynomial that
we named Hip
. One can get it as follows:
changeVariables(Hip, list(qlone(1)))
## [ 3*t^4 + t^3 ] %//% [ t^2 + 2*t + 1 ]
This is rather a trick. The changeVariables
function
allows to replace the variables of a symbolicQspray
polynomial with the new variables given as a list in its second
argument. The Hip
polynomial has only one variable,
alpha
, and it has one parameter, t
. This
parameter t
is the polynomial variable of the
ratioOfQsprays
coefficients of Hip
.
Technically this is a qspray
object: this is
qlone(1)
. So we provided list(qlone(1))
as the
list of new variables. This corresponds to set alpha=t
. The
usage of the changeVariables
is a bit deflected, because
qlone(1)
is not a new variable for Hip
, this
is a constant.
Just to illustrate the possibilities of the packages involved in the jack package (qspray, ratioOfQsprays, symbolicQspray), let us check that the Jack polynomials are eigenpolynomials for the Laplace-Beltrami operator on the space of homogeneous symmetric polynomials.
<- function(qspray, alpha) {
LaplaceBeltrami <- numberOfVariables(qspray)
n <- lapply(seq_len(n), function(i) {
derivatives1 derivQspray(qspray, i)
})<- lapply(seq_len(n), function(i) {
derivatives2 derivQspray(derivatives1[[i]], i)
})<- lapply(seq_len(n), qlone) # x_1, x_2, ..., x_n
x # first term
<- 0L
out1 for(i in seq_len(n)) {
<- out1 + alpha * x[[i]]^2 * derivatives2[[i]]
out1
}# second term
<- 0L
out2 for(i in seq_len(n)) {
for(j in seq_len(n)) {
if(i != j) {
<- out2 + x[[i]]^2 * derivatives1[[i]] / (x[[i]] - x[[j]])
out2
}
}
}# at this step, `out2` is a `ratioOfQsprays` object, because of the divisions
# by `x[[i]] - x[[j]]`; but actually its denominator is 1 because of some
# simplifications and then we extract its numerator to get a `qspray` object
<- getNumerator(out2)
out2 /2 + out2
out1 }
<- "3"
alpha <- JackPol(4, c(2, 2), alpha)
J collinearQsprays(
qspray1 = LaplaceBeltrami(J, alpha),
qspray2 = J
)## [1] TRUE
Many other symmetric multivariate polynomials have been introduced in version 6.1.0. Let’s see a couple of them.
The skew Jack polynomials are now available. They generalize the skew Schur polynomials. In order to specify the skew integer partition \(\lambda/\mu\), one has to provide the outer partition \(\lambda\) and the inner partition \(\mu\). The skew Schur polynomial associated to some skew partition is the skew Jack \(P\)-polynomial with Jack parameter \(\alpha=1\) associated to the same skew partition:
<- 3
n <- c(3, 3)
lambda <- c(2, 1)
mu <- SkewSchurPol(n, lambda, mu)
skewSchurPoly <- SkewJackPol(n, lambda, mu, alpha = 1, which = "P")
skewJackPoly == skewJackPoly
skewSchurPoly ## [1] TRUE
The \(t\)-Schur polynomials depend on a single parameter usually denoted by \(t\) and their coefficients are polynomials in this parameter. They yield the Schur polynomials when substituting \(t\) with \(0\):
<- 3
n <- c(2, 2)
lambda <- tSchurPol(n, lambda)
tSchurPoly substituteParameters(tSchurPoly, values = 0) == SchurPol(n, lambda)
## [1] TRUE
Similarly to the \(t\)-Schur polynomials, the Hall-Littlewood polynomials depend on a single parameter usually denoted by \(t\) and their coefficients are polynomials in this parameter. The Hall-Littlewood \(P\)-polynomials yield the Schur polynomials when substituting \(t\) with \(0\):
<- 3
n <- c(2, 2)
lambda <- HallLittlewoodPol(n, lambda, which = "P")
hlPoly substituteParameters(hlPoly, values = 0) == SchurPol(n, lambda)
## [1] TRUE
The Macdonald polynomials depend on two parameters usually denoted by \(q\) and \(t\). Their coefficients are not polynomials in \(q\) and \(t\) in general, they are ratios of polynomials in \(q\) and \(t\). These polynomials yield the Hall-Littlewood polynomials when substituting \(q\) with \(0\):
<- 3
n <- c(2, 2)
lambda <- MacdonaldPol(n, lambda)
macPoly <- HallLittlewoodPol(n, lambda)
hlPoly changeParameters(macPoly, list(0, qlone(1))) == hlPoly
## [1] TRUE
The ordinary Kostka numbers are usually denoted by \(K_{\lambda,\mu}\) where \(\lambda\) and \(\mu\) denote two integer partitions. The Kostka number \(K_{\lambda,\mu}\) is then associated to the two integer partitions \(\lambda\) and \(\mu\), and it is the coefficient of the monomial symmetric polynomial \(m_{\mu}\) in the expression of the Schur polynomial \(s_{\lambda}\) as a linear combination of monomial symmetric polynomials. It is always a non-negative integer. It is possible to compute these Kostka numbers with the jack package. They are also available in the syt package. There is more in the jack package. Since the Schur polynomials are the Jack \(P\)-polynomials with Jack parameter \(\alpha=1\), one can more generally define the Kostka-Jack number \(K_{\lambda,\mu}(\alpha)\) as the coefficient of the monomial symmetric polynomial \(m_{\mu}\) in the expression of the Jack \(P\)-polynomial \(P_{\lambda}(\alpha)\) with Jack parameter \(\alpha\) as a linear combination of monomial symmetric polynomials. The jack package allows to compute these numbers. Note that I call them “Kostka-Jack numbers” here as well as in the documentation of the package but I don’t know whether this wording is standard (probably not).
The Kostka numbers are also generalized by the Kostka-Foulkes polynomials, or \(t\)-Kostka polynomials, which are provided in the jack package. These are univariate polynomials whose variable is denoted by \(t\), and their value at \(t=1\) are the Kostka numbers. These polynomials are used in the computation of the Hall-Littlewood polynomials.
Finally, the Kostka numbers are also generalized by the Kostka-Macdonald polynomials, or \(qt\)-Kostka polynomials, also provided in the jack package. Actually these polynomials even generalize the Kostka-Foulkes polynomials. They have two variables, denoted by \(q\) and \(t\), and one obtains the Kostka-Foulkes polynomials by replacing \(q\) with \(0\). Currently the Kostka-Macdonald polynomials are not used in the jack package.
The skew generalizations are also available in the jack package: skew Kostka-Jack numbers, skew Kostka-Foulkes polynomials, and skew Kostka-Macdonald polynomials.
I.G. Macdonald. Symmetric Functions and Hall Polynomials. Oxford Mathematical Monographs. The Clarendon Press Oxford University Press, New York, second edition, 1995.
J. Demmel and P. Koev. Accurate and efficient evaluation of Schur and Jack functions. Mathematics of computations, vol. 75, n. 253, 223-229, 2005.
The symmetric functions catalog. https://www.symmetricfunctions.com/index.htm.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.