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Lets say that I have a linear scale [100-1000] and I want to map it to a [10-200] scale on a logarithmic basis.

100 becomes 10
1000 becomes 200
450 however becomes lower than 95 since the new scale is logarithmic.

I need a formula that if given the min/max of both scales, it takes any number within the linear scale and returns the logarithmic scale equivalent.

I tried to use the formula suggested in this question but when using the numbers provided by the author as a test, I get 0.97 as a result instead of 1.02 which is apparently the correct one.

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  • You've already asked this.
    – duffymo
    Jan 10, 2019 at 16:09

2 Answers 2

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Logarithmic scale is represented by equation

Y = a + b * log(X)

for some convenient logarithm base (decimal or natural)

Make equation for two border points (I use log10):

a + b * log10(100) = a + b * 2 = 10
a + b * log10(1000) = a + b * 3 = 200
b = 190
a = 10 - 380 = -370

so formula is

Y = -370 + 190 * log10(X)
for X=450 Y=134
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  • I think you solved the reverse problem given that according to the author "450 however becomes lower than 95 since the new scale is logarithmic.". Your 134 is clearly more than 95.
    – SergGr
    Jan 10, 2019 at 15:47
  • @SergGr I believe that logarithmic scale maps 10-100-1000-10000 to equal-spaced values like 1,2,3,4, and here geometric mean value 316.2 maps to middle 105. Perhaps you are right, and author really wants exponential scale
    – MBo
    Jan 10, 2019 at 16:02
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Meteor I believe that the formula in the referenced answer is correct but it's application to case x=5 is wrong. 1.02 clearly can't be a valid mapping of 5 because 5 is slightly before the middle in the [0.1; 10] range (the middle is 5.05) and 1.02 is slightly above the middle of the logarithmic range [0.1; 10] (the middle is 1.0). This is probably due to the rounding errors by @DietrichEpp

Also I think that the formula he uses is a bit more prone to rounding errors. Particularly I think that starting from

y = a' * exp(b*(x-x1))

will produce a better formula. In such case a' is clearly y1.

b is still calculated the same way as

b = log (y2/y1) / (x2-x1)

The main difference is that in this formula a' = a*exp(b*x1) (where a is the a in @DietrichEpp's answer). If x1 is anything big, this reduces a lot of rounding errors.

For your particular case using e (2.71828...) as the base for logarithm and exponent I get b = 0,00332859141506 and a' = 10

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