# PHP interpolate points on cardinal curve

I have a set of x,y points and wish to interpolate a set of higher detailed points in-between on a cardinal curve in php

I can't get my head around how to turn the mathematical formula on the web to a php function or class

can any one help?

-

Here's the solution that I've come up with in case any one else is facing the same problem

``````function caculate_cardinal_points(\$points,\$tension=0.5,\$steps=20) {

\$return_points = array();
\$tangents = array();

// calculate tangents
\$previous_point = false;
for(\$i=0;\$i<count(\$points);\$i++) {
\$px = \$points[\$i][0];
\$py = \$points[\$i][1];
if (isset(\$points[\$i+1]) && isset(\$points[\$i-1])) {
\$tx = (\$tension * ((\$points[\$i+1][0]-\$px) - (\$points[\$i-1][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i+1][1]-\$py) - (\$points[\$i-1][1]-\$py)));
} elseif (isset(\$points[\$i+1])) {
\$tx = (\$tension * ((\$points[\$i+1][0]-\$px) - (\$points[\$i][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i+1][1]-\$py) - (\$points[\$i][1]-\$py)));
} elseif (isset(\$points[\$i-1])) {
\$tx = (\$tension * ((\$points[\$i][0]-\$px) - (\$points[\$i-1][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i][1]-\$py) - (\$points[\$i-1][1]-\$py)));
}
\$tangents[] = array(\$tx,\$ty);
\$previous_x = \$px;
\$previous_y = \$py;
}

// interpolate
for(\$i=0;\$i<count(\$tangents)-1;\$i++) {
\$p0x = \$points[\$i][0];
\$p0y = \$points[\$i][1];
\$p1x = \$points[\$i+1][0];
\$p1y = \$points[\$i+1][1];
\$t0x = \$tangents[\$i][0];
\$t0y = \$tangents[\$i][1];
\$t1x = \$tangents[\$i+1][0];
\$t1y = \$tangents[\$i+1][1];
\$previous_x = \$p0x;
\$previous_y = \$p0y;
\$return_points[] = array(\$p0x,\$p0y);
for (\$t=0; \$t < \$steps; \$t++) {
\$s = \$t / \$steps;    // scale s to go from 0 to 1
\$h1 = 2*pow(\$s,3) - 3*pow(\$s,2) + 1;
\$h2 = pow(\$s,3) - 2*pow(\$s,2) + \$s;
\$h3 = -2*pow(\$s,3) + 3*pow(\$s,2);
\$h4 = pow(\$s,3) - pow(\$s,2);
\$x = \$h1*\$p0x+\$h2*\$t0x+\$h3*\$p1x+\$h4*\$t1x;
\$y = \$h1*\$p0y+\$h2*\$t0y+\$h3*\$p1y+\$h4*\$t1y;
\$return_points[] = array(\$x,\$y);
\$previous_x = \$x;
\$previous_y = \$y;
}
\$return_points[] = array(\$p1x,\$p1y);
}
return \$return_points;
}
``````

Here an example of it in use:

``````<?php

\$width =  600;
\$height = 600;
\$factor = 1;
\$steps = 20;
\$tension = .25;

\$blue = 0x00257ac7;
\$green = 0x0096be44;
\$black = 0x009999999;
\$purple = 0x00b5499a;
\$red = 0x00ff5555;
\$bgreen = 0x0000ff00;

\$img = imagecreatetruecolor( \$width*\$factor, \$height*\$factor );

// background fill
imagefill(\$img, 0, 0, 0x00dddddd);

// some control points
\$points = array(
array(120 *\$factor,140 *\$factor),
array(140 *\$factor,350*\$factor),
array(180 *\$factor,500*\$factor),
array(430*\$factor,350*\$factor),
array(390*\$factor,210*\$factor),
array(540*\$factor,120 *\$factor)
);
\$last_point = false;
foreach(\$points as \$point) {
imagefilledellipse(\$img,\$point[0],\$point[1],8*\$factor,8*\$factor,\$blue);
if (\$last_point) {
imageline(\$img,\$point[0],\$point[1],\$last_point[0],\$last_point[1],\$purple);
}
\$last_point = \$point;
}

\$tangets = array();

// calculate tangents
\$previous_point = false;
for(\$i=0;\$i<count(\$points);\$i++) {
\$px = \$points[\$i][0];
\$py = \$points[\$i][1];
if (isset(\$points[\$i+1]) && isset(\$points[\$i-1])) {
\$tx = (\$tension * ((\$points[\$i+1][0]-\$px) - (\$points[\$i-1][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i+1][1]-\$py) - (\$points[\$i-1][1]-\$py)));
} elseif (isset(\$points[\$i+1])) {
\$tx = (\$tension * ((\$points[\$i+1][0]-\$px) - (\$points[\$i][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i+1][1]-\$py) - (\$points[\$i][1]-\$py)));
} elseif (isset(\$points[\$i-1])) {
\$tx = (\$tension * ((\$points[\$i][0]-\$px) - (\$points[\$i-1][0]-\$px)));
\$ty = (\$tension * ((\$points[\$i][1]-\$py) - (\$points[\$i-1][1]-\$py)));
}
\$tangets[] = array(\$tx,\$ty);
imageline(\$img,\$px+\$tx,\$py+\$ty,\$points[\$i][0],\$points[\$i][1],\$black);
imagefilledellipse(\$img,\$px+\$tx,\$py+\$ty,4*\$factor,4*\$factor,\$green);
imageline(\$img,\$px-\$tx,\$py-\$ty,\$points[\$i][0],\$points[\$i][1],\$black);
imagefilledellipse(\$img,\$px-\$tx,\$py-\$ty,4*\$factor,4*\$factor,\$green);
\$previous_x = \$px;
\$previous_y = \$py;
}

for(\$i=0;\$i<count(\$tangets)-1;\$i++) {
\$p0x = \$points[\$i][0];
\$p0y = \$points[\$i][1];
\$p1x = \$points[\$i+1][0];
\$p1y = \$points[\$i+1][1];
\$t0x = \$tangets[\$i][0];
\$t0y = \$tangets[\$i][1];
\$t1x = \$tangets[\$i+1][0];
\$t1y = \$tangets[\$i+1][1];
\$previous_x = \$p0x;
\$previous_y = \$p0y;
for (\$t=0; \$t < \$steps; \$t++) {
\$s = \$t / \$steps;    // scale s to go from 0 to 1
\$h1 = 2*pow(\$s,3) - 3*pow(\$s,2) + 1;
\$h2 = pow(\$s,3) - 2*pow(\$s,2) + \$s;
\$h3 = -2*pow(\$s,3) + 3*pow(\$s,2);
\$h4 = pow(\$s,3) - pow(\$s,2);
\$x = \$h1*\$p0x+\$h2*\$t0x+\$h3*\$p1x+\$h4*\$t1x;
\$y = \$h1*\$p0y+\$h2*\$t0y+\$h3*\$p1y+\$h4*\$t1y;
//imageline(\$img,\$previous_x,\$previous_y,\$x,\$y,\$red);
\$previous_x = \$x;
\$previous_y = \$y;
}
//imageline(\$img,\$previous_x,\$previous_y,\$p1x,\$p1y,\$red);
}

\$line_points = caculate_cardinal_points(\$points);
\$previous_point = false;
foreach(\$line_points as \$point) {
if (\$previous_point) {
imageline(\$img,\$previous_point[0],\$previous_point[1],\$point[0],\$point[1],\$red);
}
\$previous_point = \$point;
}

\$resampled = imagecreatetruecolor( \$width, \$height);
imagecopyresampled(\$resampled,\$img,0,0,0,0,\$width,\$height,\$width*\$factor,\$height*\$factor);