# Math algorithm/function to convert this number to 40?

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I’m programming a knob that has an arrow the position of which is defined from an arc number.

I’m looking to find a way to convert this arc number to a number that will represent a temperature.

The minimum the arc number will be is 1.3 and the maximum will be 1.7.

1.3 needs to equal 40 and 1.7 needs to equal 99.

Is this possible?

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If it's linear, you can use the following formula to allow for any minimum and maximum:

``````from_min = -1.3
from_max = 1.7
to_min = 40
to_max = 99
from = <whatever value you want to convert>
to = (from - from_min) * (to_max - to_min) / (from_max - from_min) + to_min
``````

The `* (to_max - to_min) / (from_max - from_min)` bit scales the range from the `from` range to the `to` range. Subtracting `from_min` before and adding `to_min` after locates the correct point within the `to` range.

Examples, first the original:

``````(1.3..1.7) -> (40..99)
to = (from - from_min) * (to_max - to_min) / (from_max - from_min) + to_min
= (from - 1.3)      * 59                / 0.4                   + 40
= (from - 1.3) * 147.5 + 40 (same as Ignacio)
= from * 147.5 - 151.75     (same as Zebediah using expansion)
``````

Then the one using -1.3 as the lower bound as mentioned in one of your comments:

``````(-1.3..1.7) -> (40..99)
to = (from - from_min) * (to_max - to_min) / (from_max - from_min) + to_min
= (from - -1.3)      * 59                / 3                    + 40
= (from + 1.3) * 19.67 + 40
``````

This answer (and all the others to date of course) assume that it is a linear function. That's by no means clear based on your use of words like "arc" and "knob" in the question. You may need some trigonometry (sines, cosines and such) if it turns out linear doesn't suffice.

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Thanks so much, I need to go back to high school and take Algebra again. :/ – Frankie Laguna Jun 24 '10 at 1:08

`(n - 1.3) * 147.5 + 40`

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Sure, just fit a line to it.

In this case, `output = 147.5*input-151.75`

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 Both the answers are correct, but this one gets the result using less operations. – kiamlaluno Jun 24 '10 at 0:51 How would the function change if the minimum number was -1.3? I forgot to add the negative. – Frankie Laguna Jun 24 '10 at 0:53 Good old y = ax + b. – Dan Jun 24 '10 at 3:15

Simple little show of linear algebra here.

The two variable are the knob position (x) and some constant (p).

the two equations are then

``````1.3x + p = 40
1.7x + p = 99
``````

Solving the first equation for p in terms of x yields:

``````p = 40 - 1.3x
``````

If we put that new definition of p into the second equation we can simplify to:

``````1.7x + 40 - 1.3x = 99
.4x = 59
x = 147.5
``````

Then you can solve for p from either equation. Using the first equation:

``````p = 40 -1.3*147.5 = -151.75
``````

So your final equation to get temp from knob position should be

``````temp = 147.5*knobPosition - 151.75
``````
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That's what people usually call "algebra", not "linear algebra". You might say it is the algebra of a linear function, sometimes expressed in the form f(x) = mx + b, but it is not linear algebra. – Heath Hunnicutt Jun 24 '10 at 1:08

This is really a simple algebra problem, no linear algebra needed.

``````def scale_knob( knob_input ):

knob_low = -1.3
knob_high = 1.7
knob_range = knob_high - knob_low   # 1.7 - -1.3 = 3.0.

out_low = 40.0
out_high = 99.0
out_range = out_high - out_low      # 99.0 - 40.0 = 59.0

return ( knob_input - knob_low ) * ( out_range / knob_range ) + out_low
# scaled = ( input - (-1.3) ) * ( 59 / 3.0 ) + 40.0
``````
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Since I missed the easy solution here is another way to think of it:

``````let delta(q) denote the rate of change of some quantity q.
``````

``````delta(output)/delta(input) = (99 - 40) / (1.7 - 1.3) = 59/0.4 = 147.5
``````

thus

``````delta(output) = 147.5 * delta(input).
``````

Assuming that this function is continuous (meaning you can make arbitrarily tiny adjustments to the knob as opposed to discrete clicks) we can integrate both sides giving:

``````output = 147.5 * input + some_constant
``````

Since we know that when the input is 1.3 then the output is 40 we have

``````40 = 147.5 * (1.3) + some_constant
``````

Thus

``````some_constant = 40 - 147.5 * 1.3 = -151.75
``````

Hence the equation you want is

``````output = 147.5 * input - 151.75
``````
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