How do I map numbers, linearly, between a and b to go between c and d.
That is, I want numbers between 2 and 6 to map to numbers between 10 and 20... but I need the generalized case.
My brain is fried.
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How do I map numbers, linearly, between a and b to go between c and d.
That is, I want numbers between 2 and 6 to map to numbers between 10 and 20... but I need the generalized case.
My brain is fried.
If your number X falls between A and B, and you would like Y to fall between C and D, you can apply the following linear transform:
Y = (X-A)/(B-A) * (D-C) + C
That should give you what you want, although your question is a little ambiguous, since you could also map the interval in the reverse direction. Just watch out for division by zero and you should be OK.
Y=f(X)=m*X+b
, where m and b have been determined simultaneously from the following two constraint equations that result from substituting the values of X and Y at the required endpoints: C=m*A+b
and D=m*B+b
– Chris Chiasson
Mar 9 '17 at 16:57
X=A+(A-B)*t
to prove the equality between this approach and Peter's. t is essentially a nondimensionalization of X. (t=(X-A)/(A-B)
)
– Chris Chiasson
Mar 9 '17 at 18:32
Divide to get the ratio between the sizes of the two ranges, then subtract the starting value of your inital range, multiply by the ratio and add the starting value of your second range. In other words,
R = (20 - 10) / (6 - 2)
y = (x - 2) * R + 10
This evenly spreads the numbers from the first range in the second range.
It would be nice to have this functionality in the java.lang.Math
class, as this is such a widely required function and is available in other languages.
Here is a simple implementation:
final static double EPSILON = 1e-12;
public static double map(double valueCoord1,
double startCoord1, double endCoord1,
double startCoord2, double endCoord2) {
if (Math.abs(endCoord1 - startCoord1) < EPSILON) {
throw new ArithmeticException("/ 0");
}
double offset = startCoord2;
double ratio = (endCoord2 - startCoord2) / (endCoord1 - startCoord1);
return ratio * (valueCoord1 - startCoord1) + offset;
}
I am putting this code here as a reference for future myself and may be it will help someone.
As an aside, this is the same problem as the classic convert celcius to farenheit where you want to map a number range that equates 0 - 100 (C) to 32 - 212 (F).
https://rosettacode.org/wiki/Map_range
[a1, a2] => [b1, b2]
if s in range of [a1, a2]
then t which will be in range of [b1, b2]
t= b1 + ((s- a1) * (b2-b1))/ (a2-a1)
Each unit interval on the first range takes up (d-c)/(b-a) "space" on the second range.
Pseudo:
var interval = (d-c)/(b-a)
for n = 0 to (b - a)
print c + n*interval
How you handle the rounding is up to you.
int srcMin = 2, srcMax = 6;
int tgtMin = 10, tgtMax = 20;
int nb = srcMax - srcMin;
int range = tgtMax - tgtMin;
float rate = (float) range / (float) nb;
println(srcMin + " > " + tgtMin);
float stepF = tgtMin;
for (int i = 1; i < nb; i++)
{
stepF += rate;
println((srcMin + i) + " > " + (int) (stepF + 0.5) + " (" + stepF + ")");
}
println(srcMax + " > " + tgtMax);
With checks on divide by zero, of course.
In addition to @PeterAllenWebb answer, if you would like to reverse back the result use the following:
reverseX = (B-A)*(Y-C)/(D-C) + A
if your range from [a to b] and you want to map it in [c to d] where x is the value you want to map use this formula (linear mapping)
double R = (d-c)/(b-a)
double y = c+(x*R)+R
return(y)
Where X is the number to map from A-B to C-D, and Y is the result: Take the linear interpolation formula, lerp(a,b,m)=a+(m*(b-a)), and put C and D in place of a and b to get Y=C+(m*(D-C)). Then, in place of m, put (X-A)/(B-A) to get Y=C+(((X-A)/(B-A))*(D-C)). This is an okay map function, but it can be simplified. Take the (D-C) piece, and put it inside the dividend to get Y=C+(((X-A)*(D-C))/(B-A)). This gives us another piece we can simplify, (X-A)*(D-C), which equates to (X*D)-(X*C)-(A*D)+(A*C). Pop that in, and you get Y=C+(((X*D)-(X*C)-(A*D)+(A*C))/(B-A)). The next thing you need to do is add in the +C bit. To do that, you multiply C by (B-A) to get ((B*C)-(A*C)), and move it into the dividend to get Y=(((X*D)-(X*C)-(A*D)+(A*C)+(B*C)-(A*C))/(B-A)). This is redundant, containing both a +(A*C) and a -(A*C), which cancel each other out. Remove them, and you get a final result of: Y=((X*D)-(X*C)-(A*D)+(B*C))/(B-A)
TL;DR: The standard map function, Y=C+(((X-A)/(B-A))*(D-C)), can be simplified down to Y=((X*D)-(X*C)-(A*D)+(B*C))/(B-A)