So I am trying to figure out how to take a range of numbers and scale the values down to fit a range. The reason for wanting to do this is that I am trying to draw ellipses in a java swing jpanel. I want the height and width of each ellipse to be in a range of say 130. I have methods that find the minimum and maximum values from my data set, but I won't have the min and max until runtime. Is there an easy way to do this?
Let's say you want to scale a range [min,max]
to [a,b]
. You're looking for a (continuous) function that satisfies
f(min) = a
f(max) = b
In your case, a
would be 1 and b
would be 30, but let's start with something simpler and try to map [min,max]
into the range [0,1]
.
Putting min
into a function and getting out 0 could be accomplished with
f(x) = x  min ===> f(min) = min  min = 0
So that's almost what we want. But putting in max
would give us max  min
when we actually want 1. So we'll have to scale it:
x  min max  min
f(x) =  ===> f(min) = 0; f(max) =  = 1
max  min max  min
which is what we want. So we need to do a translation and a scaling. Now if instead we want to get arbitrary values of a
and b
, we need something a little more complicated:
(ba)(x  min)
f(x) =  + a
max  min
You can verify that putting in min
for x
now gives a
, and putting in max
gives b
.
You might also notice that (ba)/(maxmin)
is a scaling factor between the size of the new range and the size of the original range. So really we are first translating x
by min
, scaling it to the correct factor, and then translating it back up to the new minimum value of a
.
Hope this helps.

I appreciate your help. I figured out a solution that does the job of looking aesthetically pleasing. However I will apply your logic to give a more accurate model. Thanks again :) Mar 16 '11 at 6:58

5Just a reminder: The model will be more accurate with
max != min
otherwise the function results indetermined :) Jun 13 '13 at 16:49 
11does this ensure that my rescaled variable retains the original distribution? Sep 9 '13 at 2:40

3This is a nice implementation of a linear scale. Can this be easily transformed to a logarighmic scale?– tomexxSep 22 '15 at 12:00

2@Andrew
min
andmax
can be either positive or negative. In general, in maths, we would state a condition on the variables if they needed one. If there is no condition, as in this case, we assume that min and max are any number. For linear transformations, it doesn't matter if the values are +ve or ve (just imagine a y = mx+c curve, it looks the same whether x > 0 or x < 0). Mar 30 at 9:49
Here's some JavaScript for copypaste ease (this is irritate's answer):
function scaleBetween(unscaledNum, minAllowed, maxAllowed, min, max) {
return (maxAllowed  minAllowed) * (unscaledNum  min) / (max  min) + minAllowed;
}
Applied like so, scaling the range 1050 to a range between 0100.
var unscaledNums = [10, 13, 25, 28, 43, 50];
var maxRange = Math.max.apply(Math, unscaledNums);
var minRange = Math.min.apply(Math, unscaledNums);
for (var i = 0; i < unscaledNums.length; i++) {
var unscaled = unscaledNums[i];
var scaled = scaleBetween(unscaled, 0, 100, minRange, maxRange);
console.log(scaled.toFixed(2));
}
0.00, 18.37, 48.98, 55.10, 85.71, 100.00
Edit:
I know I answered this a long time ago, but here's a cleaner function that I use now:
Array.prototype.scaleBetween = function(scaledMin, scaledMax) {
var max = Math.max.apply(Math, this);
var min = Math.min.apply(Math, this);
return this.map(num => (scaledMaxscaledMin)*(nummin)/(maxmin)+scaledMin);
}
Applied like so:
[4, 0, 5, 6, 9].scaleBetween(0, 100);
[0, 30.76923076923077, 69.23076923076923, 76.92307692307692, 100]

var arr = ["40000.00","2","3.000","4.5825","0.00008","1000000000.00008","0.02008","100","5000","82.0000048","0.02","0.005","3.0008","5","8","600","1000","5000"]; for this case, by your method ,numbers are getting too small . Is there any way, so that, scale should be(0,100) or (100,100) and gap between outputs should be 0.5 (or any number).– user8226204Jul 25 '17 at 17:14

Please consider my scenario for arr[] too.– user8226204Jul 25 '17 at 17:22

1It's a bit of an edge case, but this dies if the array only contains one value or only multiple copies of the same value. So [1].scaleBetween(1, 100) and [1,1,1].scaleBetween(1,100) both fill the output with NaN. Feb 8 '18 at 16:48

1@MalabarFront, good observation. I suppose it's undefined whether in that case the result should be
[1, 1, 1]
,[100, 100, 100]
, or even[50.5, 50.5, 50.5]
. You could put in the case:if (maxmin == 0) return this.map(num => (scaledMin+scaledMax)/2);
Feb 9 '18 at 1:38 
1
For convenience, here is Irritate's algorithm in a Java form. Add error checking, exception handling and tweak as necessary.
public class Algorithms {
public static double scale(final double valueIn, final double baseMin, final double baseMax, final double limitMin, final double limitMax) {
return ((limitMax  limitMin) * (valueIn  baseMin) / (baseMax  baseMin)) + limitMin;
}
}
Tester:
final double baseMin = 0.0;
final double baseMax = 360.0;
final double limitMin = 90.0;
final double limitMax = 270.0;
double valueIn = 0;
System.out.println(Algorithms.scale(valueIn, baseMin, baseMax, limitMin, limitMax));
valueIn = 360;
System.out.println(Algorithms.scale(valueIn, baseMin, baseMax, limitMin, limitMax));
valueIn = 180;
System.out.println(Algorithms.scale(valueIn, baseMin, baseMax, limitMin, limitMax));
90.0
270.0
180.0
Here's how I understand it:
What percent does x
lie in a range
Let's assume you have a range from 0
to 100
. Given an arbitrary number from that range, what "percent" from that range does it lie in? This should be pretty simple, 0
would be 0%
, 50
would be 50%
and 100
would be 100%
.
Now, what if your range was 20
to 100
? We cannot apply the same logic as above (divide by 100) because:
20 / 100
doesn't give us 0
(20
should be 0%
now). This should be simple to fix, we just need to make the numerator 0
for the case of 20
. We can do that by subtracting:
(20  20) / 100
However, this doesn't work for 100
anymore because:
(100  20) / 100
doesn't give us 100%
. Again, we can fix this by subtracting from the denominator as well:
(100  20) / (100  20)
A more generalized equation for finding out what % x
lies in a range would be:
(x  MIN) / (MAX  MIN)
Scale range to another range
Now that we know what percent a number lies in a range, we can apply it to map the number to another range. Let's go through an example.
old range = [200, 1000]
new range = [10, 20]
If we have a number in the old range, what would the number be in the new range? Let's say the number is 400
. First, figure out what percent 400
is within the old range. We can apply our equation above.
(400  200) / (1000  200) = 0.25
So, 400
lies in 25%
of the old range. We just need to figure out what number is 25%
of the new range. Think about what 50%
of [0, 20]
is. It would be 10
right? How did you arrive at that answer? Well, we can just do:
20 * 0.5 = 10
But, what about from [10, 20]
? We need to shift everything by 10
now. eg:
((20  10) * 0.5) + 10
a more generalized formula would be:
((MAX  MIN) * PERCENT) + MIN
To the original example of what 25%
of [10, 20]
is:
((20  10) * 0.25) + 10 = 12.5
So, 400
in the range [200, 1000]
would map to 12.5
in the range [10, 20]
TLDR
To map x
from old range to new range:
OLD PERCENT = (x  OLD MIN) / (OLD MAX  OLD MIN)
NEW X = ((NEW MAX  NEW MIN) * OLD PERCENT) + NEW MIN

1That's exactly how I worked it out. Trickiest part is to find out the ratio where a number lies in a given range. It should always be within [0, 1] range just like percentage, e.g. 0.5 is for 50%. Next you only have to expand/stretch and shift this number to fit in your required range. Oct 6 '18 at 9:35
I came across this solution but this does not really fit my need. So I digged a bit in the d3 source code. I personally would recommend to do it like d3.scale does.
So here you scale the domain to the range. The advantage is that you can flip signs to your target range. This is useful since the y axis on a computer screen goes top down so large values have a small y.
public class Rescale {
private final double range0,range1,domain0,domain1;
public Rescale(double domain0, double domain1, double range0, double range1) {
this.range0 = range0;
this.range1 = range1;
this.domain0 = domain0;
this.domain1 = domain1;
}
private double interpolate(double x) {
return range0 * (1  x) + range1 * x;
}
private double uninterpolate(double x) {
double b = (domain1  domain0) != 0 ? domain1  domain0 : 1 / domain1;
return (x  domain0) / b;
}
public double rescale(double x) {
return interpolate(uninterpolate(x));
}
}
And here is the test where you can see what I mean
public class RescaleTest {
@Test
public void testRescale() {
Rescale r;
r = new Rescale(5,7,0,1);
Assert.assertTrue(r.rescale(5) == 0);
Assert.assertTrue(r.rescale(6) == 0.5);
Assert.assertTrue(r.rescale(7) == 1);
r = new Rescale(5,7,1,0);
Assert.assertTrue(r.rescale(5) == 1);
Assert.assertTrue(r.rescale(6) == 0.5);
Assert.assertTrue(r.rescale(7) == 0);
r = new Rescale(3,3,0,1);
Assert.assertTrue(r.rescale(3) == 0);
Assert.assertTrue(r.rescale(0) == 0.5);
Assert.assertTrue(r.rescale(3) == 1);
r = new Rescale(3,3,1,1);
Assert.assertTrue(r.rescale(3) == 1);
Assert.assertTrue(r.rescale(0) == 0);
Assert.assertTrue(r.rescale(3) == 1);
}
}

"The advantage is that you can flip signs to your target range." I dont understand this. Can you explain? I cannot find the difference of the returned values from your d3version and the version from above (@irritate).– nimo23Nov 18 '17 at 8:12


I've taken Irritate's answer and refactored it so as to minimize the computational steps for subsequent computations by factoring it into the fewest constants. The motivation is to allow a scaler to be trained on one set of data, and then be run on new data (for an ML algo). In effect, it's much like SciKit's preprocessing MinMaxScaler for Python in usage.
Thus, x' = (ba)(xmin)/(maxmin) + a
(where b!=a) becomes x' = x(ba)/(maxmin) + min(b+a)/(maxmin) + a
which can be reduced to two constants in the form x' = x*Part1 + Part2
.
Here's a C# implementation with two constructors: one to train, and one to reload a trained instance (e.g., to support persistence).
public class MinMaxColumnSpec
{
/// <summary>
/// To reduce repetitive computations, the minmax formula has been refactored so that the portions that remain constant are just computed once.
/// This transforms the forumula from
/// x' = (ba)(xmin)/(maxmin) + a
/// into x' = x(ba)/(maxmin) + min(b+a)/(maxmin) + a
/// which can be further factored into
/// x' = x*Part1 + Part2
/// </summary>
public readonly double Part1, Part2;
/// <summary>
/// Use this ctor to train a new scaler.
/// </summary>
public MinMaxColumnSpec(double[] columnValues, int newMin = 0, int newMax = 1)
{
if (newMax <= newMin)
throw new ArgumentOutOfRangeException("newMax", "newMax must be greater than newMin");
var oldMax = columnValues.Max();
var oldMin = columnValues.Min();
Part1 = (newMax  newMin) / (oldMax  oldMin);
Part2 = newMin + (oldMin * (newMin  newMax) / (oldMax  oldMin));
}
/// <summary>
/// Use this ctor for previouslytrained scalers with known constants.
/// </summary>
public MinMaxColumnSpec(double part1, double part2)
{
Part1 = part1;
Part2 = part2;
}
public double Scale(double x) => (x * Part1) + Part2;
}
Based on Charles Clayton's response, I included some JSDoc, ES6 tweaks, and incorporated suggestions from the comments in the original response.
/**
* Returns a scaled number within its source bounds to the desired target bounds.
* @param {number} n  Unscaled number
* @param {number} tMin  Minimum (target) bound to scale to
* @param {number} tMax  Maximum (target) bound to scale to
* @param {number} sMin  Minimum (source) bound to scale from
* @param {number} sMax  Maximum (source) bound to scale from
* @returns {number} The scaled number within the target bounds.
*/
const scaleBetween = (n, tMin, tMax, sMin, sMax) => {
return (tMax  tMin) * (n  sMin) / (sMax  sMin) + tMin;
}
if (Array.prototype.scaleBetween === undefined) {
/**
* Returns a scaled array of numbers fit to the desired target bounds.
* @param {number} tMin  Minimum (target) bound to scale to
* @param {number} tMax  Maximum (target) bound to scale to
* @returns {number} The scaled array.
*/
Array.prototype.scaleBetween = function(tMin, tMax) {
if (arguments.length === 1  tMax === undefined) {
tMax = tMin; tMin = 0;
}
let sMax = Math.max(...this), sMin = Math.min(...this);
if (sMax  sMin == 0) return this.map(num => (tMin + tMax) / 2);
return this.map(num => (tMax  tMin) * (num  sMin) / (sMax  sMin) + tMin);
}
}
// ================================================================
// Usage
// ================================================================
let nums = [10, 13, 25, 28, 43, 50], tMin = 0, tMax = 100,
sMin = Math.min(...nums), sMax = Math.max(...nums);
// Result: [ 0.0, 7.50, 37.50, 45.00, 82.50, 100.00 ]
console.log(nums.map(n => scaleBetween(n, tMin, tMax, sMin, sMax).toFixed(2)).join(', '));
// Result: [ 0, 30.769, 69.231, 76.923, 100 ]
console.log([4, 0, 5, 6, 9].scaleBetween(0, 100).join(', '));
// Result: [ 50, 50, 50 ]
console.log([1, 1, 1].scaleBetween(0, 100).join(', '));
.asconsolewrapper { top: 0; maxheight: 100% !important; }
I sometimes find a variation of this useful.
 Wrapping the scale function in a class so that I do not need to pass around the min/max values if scaling the same ranges in several places
 Adding two small checks that ensures that the result value stays within the expected range.
Example in JavaScript:
class Scaler {
constructor(inMin, inMax, outMin, outMax) {
this.inMin = inMin;
this.inMax = inMax;
this.outMin = outMin;
this.outMax = outMax;
}
scale(value) {
const result = (value  this.inMin) * (this.outMax  this.outMin) / (this.inMax  this.inMin) + this.outMin;
if (result < this.outMin) {
return this.outMin;
} else if (result > this.outMax) {
return this.outMax;
}
return result;
}
}
This example along with a function based version comes from the page https://writingjavascript.com/scalingvaluesbetweentworanges