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#
# Package for interpolation methods (one- and two-dimensional)
#
# Remarks:
# None of the methods deal gracefully with missing values
#
# To do:
# Add B-splines as methods
# For spatial interpolation in two dimensions also quadrant method?
# Method for destroying a table
# Proper documentation
# Proper test cases
#
# version 0.1: initial implementation, january 2003
# version 0.2: added linear and Lagrange interpolation, straightforward
# spatial interpolation, april 2004
# version 0.3: added Neville algorithm.
# version 1.0: added cubic splines, september 2004
#
# Copyright (c) 2004 by Arjen Markus. All rights reserved.
# Copyright (c) 2004 by Kevin B. Kenny. All rights reserved.
#
# See the file "license.terms" for information on usage and redistribution
# of this file, and for a DISCLAIMER OF ALL WARRANTIES.
#
# RCS: @(#) $Id: interpolate.tcl,v 1.10 2009/10/22 18:19:52 arjenmarkus Exp $
#
#----------------------------------------------------------------------
package require Tcl 8.4
package require struct::matrix
# ::math::interpolate --
# Namespace holding the procedures and variables
#
namespace eval ::math::interpolate {
variable search_radius {}
variable inv_dist_pow 2
namespace export interp-1d-table interp-table interp-linear \
interp-lagrange
namespace export neville
}
# defineTable --
# Define a two-dimensional table of data
#
# Arguments:
# name Name of the table to be created
# cols Names of the columns (for convenience and for counting)
# values List of values to fill the table with (must be sorted
# w.r.t. first column or first column and first row)
#
# Results:
# Name of the new command
#
# Side effects:
# Creates a new command, which is used in subsequent calls
#
proc ::math::interpolate::defineTable { name cols values } {
set table ::math::interpolate::__$name
::struct::matrix $table
$table add columns [llength $cols]
$table add row
$table set row 0 $cols
set row 1
set first 0
set nocols [llength $cols]
set novals [llength $values]
while { $first < $novals } {
set last [expr {$first+$nocols-1}]
$table add row
$table set row $row [lrange $values $first $last]
incr first $nocols
incr row
}
return $table
}
# inter-1d-table --
# Interpolate in a one-dimensional table
# (first column is independent variable, all others dependent)
#
# Arguments:
# table Name of the table
# xval Value of the independent variable
#
# Results:
# List of interpolated values, including the x-variable
#
proc ::math::interpolate::interp-1d-table { table xval } {
#
# Search for the records that enclose the x-value
#
set xvalues [lrange [$table get column 0] 2 end]
foreach {row row2} [FindEnclosingEntries $xval $xvalues] break
incr row
incr row2
set prev_values [$table get row $row]
set next_values [$table get row $row2]
set xprev [lindex $prev_values 0]
set xnext [lindex $next_values 0]
if { $row == $row2 } {
return [concat $xval [lrange $prev_values 1 end]]
} else {
set wprev [expr {($xnext-$xval)/($xnext-$xprev)}]
set wnext [expr {1.0-$wprev}]
set results {}
foreach vprev $prev_values vnext $next_values {
set vint [expr {$vprev*$wprev+$vnext*$wnext}]
lappend results $vint
}
return $results
}
}
# interp-table --
# Interpolate in a two-dimensional table
# (first column and first row are independent variables)
#
# Arguments:
# table Name of the table
# xval Value of the independent row-variable
# yval Value of the independent column-variable
#
# Results:
# Interpolated value
#
# Note:
# Use bilinear interpolation
#
proc ::math::interpolate::interp-table { table xval yval } {
#
# Search for the records that enclose the x-value
#
set xvalues [lrange [$table get column 0] 2 end]
foreach {row row2} [FindEnclosingEntries $xval $xvalues] break
incr row
incr row2
#
# Search for the columns that enclose the y-value
#
set yvalues [lrange [$table get row 1] 1 end]
foreach {col col2} [FindEnclosingEntries $yval $yvalues] break
set yvalues [concat "." $yvalues] ;# Prepend a dummy column!
set prev_values [$table get row $row]
set next_values [$table get row $row2]
set x1 [lindex $prev_values 0]
set x2 [lindex $next_values 0]
set y1 [lindex $yvalues $col]
set y2 [lindex $yvalues $col2]
set v11 [lindex $prev_values $col]
set v12 [lindex $prev_values $col2]
set v21 [lindex $next_values $col]
set v22 [lindex $next_values $col2]
#
# value = v0 + a*(x-x1) + b*(y-y1) + c*(x-x1)*(y-y1)
# if x == x1 and y == y1: value = v11
# if x == x1 and y == y2: value = v12
# if x == x2 and y == y1: value = v21
# if x == x2 and y == y2: value = v22
#
set a 0.0
if { $x1 != $x2 } {
set a [expr {($v21-$v11)/($x2-$x1)}]
}
set b 0.0
if { $y1 != $y2 } {
set b [expr {($v12-$v11)/($y2-$y1)}]
}
set c 0.0
if { $x1 != $x2 && $y1 != $y2 } {
set c [expr {($v11+$v22-$v12-$v21)/($x2-$x1)/($y2-$y1)}]
}
set result \
[expr {$v11+$a*($xval-$x1)+$b*($yval-$y1)+$c*($xval-$x1)*($yval-$y1)}]
return $result
}
# FindEnclosingEntries --
# Search within a sorted list
#
# Arguments:
# val Value to be searched
# values List of values to be examined
#
# Results:
# Returns a list of the previous and next indices
#
proc FindEnclosingEntries { val values } {
set found 0
set row2 1
foreach v $values {
if { $val <= $v } {
set row [expr {$row2-1}]
set found 1
break
}
incr row2
}
#
# Border cases: extrapolation needed
#
if { ! $found } {
incr row2 -1
set row $row2
}
if { $row == 0 } {
set row $row2
}
return [list $row $row2]
}
# interp-linear --
# Use linear interpolation
#
# Arguments:
# xyvalues List of x/y values to be interpolated
# xval x-value for which a value is sought
#
# Results:
# Estimated value at $xval
#
# Note:
# The list xyvalues must be sorted w.r.t. the x-value
#
proc ::math::interpolate::interp-linear { xyvalues xval } {
#
# Border cases first
#
if { [lindex $xyvalues 0] > $xval } {
return [lindex $xyvalues 1]
}
if { [lindex $xyvalues end-1] < $xval } {
return [lindex $xyvalues end]
}
#
# The ordinary case
#
set idxx -2
set idxy -1
foreach { x y } $xyvalues {
if { $xval < $x } {
break
}
incr idxx 2
incr idxy 2
}
set x2 [lindex $xyvalues $idxx]
set y2 [lindex $xyvalues $idxy]
if { $x2 != $x } {
set yval [expr {$y+($y2-$y)*($xval-$x)/($x2-$x)}]
} else {
set yval $y
}
return $yval
}
# interp-lagrange --
# Use the Lagrange interpolation method
#
# Arguments:
# xyvalues List of x/y values to be interpolated
# xval x-value for which a value is sought
#
# Results:
# Estimated value at $xval
#
# Note:
# The list xyvalues must be sorted w.r.t. the x-value
# Furthermore the Lagrange method is not a very practical
# method, as potentially the errors are unbounded
#
proc ::math::interpolate::interp-lagrange { xyvalues xval } {
#
# Border case: xval equals one of the "nodes"
#
foreach { x y } $xyvalues {
if { $x == $xval } {
return $y
}
}
#
# Ordinary case
#
set nonodes2 [llength $xyvalues]
set yval 0.0
for { set i 0 } { $i < $nonodes2 } { incr i 2 } {
set idxn 0
set xn [lindex $xyvalues $i]
set yn [lindex $xyvalues [expr {$i+1}]]
foreach { x y } $xyvalues {
if { $idxn != $i } {
set yn [expr {$yn*($x-$xval)/($x-$xn)}]
}
incr idxn 2
}
set yval [expr {$yval+$yn}]
}
return $yval
}
# interp-spatial --
# Use a straightforward interpolation method with weights as
# function of the inverse distance to interpolate in 2D and N-D
# space
#
# Arguments:
# xyvalues List of coordinates and values at these coordinates
# coord List of coordinates for which a value is sought
#
# Results:
# Estimated value(s) at $coord
#
# Note:
# The list xyvalues is a list of lists:
# { {x1 y1 z1 {v11 v12 v13 v14}
# {x2 y2 z2 {v21 v22 v23 v24}
# ...
# }
# The last element of each inner list is either a single number
# or a list in itself. In the latter case the return value is
# a list with the same number of elements.
#
# The method is influenced by the search radius and the
# power of the inverse distance
#
proc ::math::interpolate::interp-spatial { xyvalues coord } {
variable search_radius
variable inv_dist_pow
set result {}
foreach v [lindex [lindex $xyvalues 0] end] {
lappend result 0.0
}
set total_weight 0.0
if { $search_radius != {} } {
set max_radius2 [expr {$search_radius*$search_radius}]
} else {
set max_radius2 {}
}
foreach point $xyvalues {
set dist 0.0
foreach c [lrange $point 0 end-1] cc $coord {
set dist [expr {$dist+($c-$cc)*($c-$cc)}]
}
#
# Take care of coincident points
#
if { $dist == 0.0 } {
return [lindex $point end]
}
#
# The general case
#
if { $max_radius2 == {} || $dist <= $max_radius2 } {
if { $inv_dist_pow == 1 } {
set dist [expr {sqrt($dist)}]
}
set total_weight [expr {$total_weight+1.0/$dist}]
set idx 0
foreach v [lindex $point end] r $result {
lset result $idx [expr {$r+$v/$dist}]
incr idx
}
}
}
if { $total_weight == 0.0 } {
set idx 0
foreach r $result {
lset result $idx {}
incr idx
}
} else {
set idx 0
foreach r $result {
lset result $idx [expr {$r/$total_weight}]
incr idx
}
}
return $result
}
# interp-spatial-params --
# Set the parameters for spatial interpolation
#
# Arguments:
# max_search Search radius (if none: use {} or "")
# power Power for the inverse distance (1 or 2, defaults to 2)
#
# Results:
# None
#
proc ::math::interpolate::interp-spatial-params { max_search {power 2} } {
variable search_radius
variable inv_dist_pow
set search_radius $max_search
if { $power == 1 } {
set inv_dist_pow 1
} else {
set inv_dist_pow 2
}
}
#----------------------------------------------------------------------
#
# neville --
#
# Interpolate a function between tabulated points using Neville's
# algorithm.
#
# Parameters:
# xtable - Table of abscissae.
# ytable - Table of ordinates. Must be a list of the same
# length as 'xtable.'
# x - Abscissa for which the function value is desired.
#
# Results:
# Returns a two-element list. The first element is the
# requested ordinate. The second element is a rough estimate
# of the absolute error, that is, the magnitude of the first
# neglected term of a power series.
#
# Side effects:
# None.
#
#----------------------------------------------------------------------
proc ::math::interpolate::neville { xtable ytable x } {
set n [llength $xtable]
# Initialization. Set c and d to the ordinates, and set ns to the
# index of the nearest abscissa. Set y to the zero-order approximation
# of the nearest ordinate, and dif to the difference between x
# and the nearest tabulated abscissa.
set c [list]
set d [list]
set i 0
set ns 0
set dif [expr { abs( $x - [lindex $xtable 0] ) }]
set y [lindex $ytable 0]
foreach xi $xtable yi $ytable {
set dift [expr { abs ( $x - $xi ) }]
if { $dift < $dif } {
set ns $i
set y $yi
set dif $dift
}
lappend c $yi
lappend d $yi
incr i
}
# Compute successively higher-degree approximations to the fit
# function by using the recurrence:
# d_m[i] = ( c_{m-1}[i+1] - d{m-1}[i] ) * (x[i+m]-x) /
# (x[i] - x[i+m])
# c_m[i] = ( c_{m-1}[i+1] - d{m-1}[i] ) * (x[i]-x) /
# (x[i] - x[i+m])
for { set m 1 } { $m < $n } { incr m } {
for { set i 0 } { $i < $n - $m } { set i $ip1 } {
set ip1 [expr { $i + 1 }]
set ipm [expr { $i + $m }]
set ho [expr { [lindex $xtable $i] - $x }]
set hp [expr { [lindex $xtable $ipm] - $x }]
set w [expr { [lindex $c $ip1] - [lindex $d $i] }]
set q [expr { $w / ( $ho - $hp ) }]
lset d $i [expr { $hp * $q }]
lset c $i [expr { $ho * $q }]
}
# Take the straighest path possible through the tableau of c
# and d approximations back to the tabulated value
if { 2 * $ns < $n - $m } {
set dy [lindex $c $ns]
} else {
incr ns -1
set dy [lindex $d $ns]
}
set y [expr { $y + $dy }]
}
# Return the approximation and the highest-order correction term.
return [list $y [expr { abs($dy) }]]
}
# prepare-cubic-splines --
# Prepare interpolation based on cubic splines
#
# Arguments:
# xcoord The x-coordinates
# ycoord Y-values for these x-coordinates
# Result:
# Intermediate parameters describing the spline function,
# to be used in the second step, interp-cubic-splines.
# Note:
# Implicitly it is assumed that the function decribed by xcoord
# and ycoord has a second derivative 0 at the end points.
# To minimise the work if more than one value is needed, the
# algorithm is divided in two steps
# (Derived from the routine SPLINT in Davis and Rabinowitz:
# Methods for Numerical Integration, AP, 1984)
#
proc ::math::interpolate::prepare-cubic-splines {xcoord ycoord} {
if { [llength $xcoord] < 3 } {
return -code error "At least three points are required"
}
if { [llength $xcoord] != [llength $ycoord] } {
return -code error "Equal number of x and y values required"
}
set m2 [expr {[llength $xcoord]-1}]
set s 0.0
set h {}
set c {}
for { set i 0 } { $i < $m2 } { incr i } {
set ip1 [expr {$i+1}]
set h1 [expr {[lindex $xcoord $ip1]-[lindex $xcoord $i]}]
lappend h $h1
if { $h1 <= 0.0 } {
return -code error "X values must be strictly ascending"
}
set r [expr {([lindex $ycoord $ip1]-[lindex $ycoord $i])/$h1}]
lappend c [expr {$r-$s}]
set s $r
}
set s 0.0
set r 0.0
set t {--}
lset c 0 0.0
for { set i 1 } { $i < $m2 } { incr i } {
set ip1 [expr {$i+1}]
set im1 [expr {$i-1}]
set y2 [expr {[lindex $c $i]+$r*[lindex $c $im1]}]
set t1 [expr {2.0*([lindex $xcoord $im1]-[lindex $xcoord $ip1])-$r*$s}]
set s [lindex $h $i]
set r [expr {$s/$t1}]
lset c $i $y2
lappend t $t1
}
lappend c 0.0
for { set j 1 } { $j < $m2 } { incr j } {
set i [expr {$m2-$j}]
set ip1 [expr {$i+1}]
set h1 [lindex $h $i]
set yp1 [lindex $c $ip1]
set y1 [lindex $c $i]
set t1 [lindex $t $i]
lset c $i [expr {($h1*$yp1-$y1)/$t1}]
}
set b {}
set d {}
for { set i 0 } { $i < $m2 } { incr i } {
set ip1 [expr {$i+1}]
set s [lindex $h $i]
set yp1 [lindex $c $ip1]
set y1 [lindex $c $i]
set r [expr {$yp1-$y1}]
lappend d [expr {$r/$s}]
set y1 [expr {3.0*$y1}]
lset c $i $y1
lappend b [expr {([lindex $ycoord $ip1]-[lindex $ycoord $i])/$s
-($y1+$r)*$s}]
}
lappend d 0.0
lappend b 0.0
return [list $d $c $b $ycoord $xcoord]
}
# interp-cubic-splines --
# Interpolate based on cubic splines
#
# Arguments:
# coeffs Coefficients resulting from the preparation step
# x The x-coordinate for which to estimate the value
# Result:
# Interpolated value at x
#
proc ::math::interpolate::interp-cubic-splines {coeffs x} {
foreach {dcoef ccoef bcoef acoef xcoord} $coeffs {break}
#
# Check the bounds - no extrapolation
#
if { $x < [lindex $xcoord 0] } {error "X value too small"}
if { $x > [lindex $xcoord end] } {error "X value too large"}
#
# Which interval?
#
set idx -1
foreach xv $xcoord {
if { $xv > $x } {
break
}
incr idx
}
set a [lindex $acoef $idx]
set b [lindex $bcoef $idx]
set c [lindex $ccoef $idx]
set d [lindex $dcoef $idx]
set dx [expr {$x-[lindex $xcoord $idx]}]
return [expr {(($d*$dx+$c)*$dx+$b)*$dx+$a}]
}
#
# Announce our presence
#
package provide math::interpolate 1.1
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