I have 4 data points, from which I want to calculate a hyperbola. It seems that the Excel trendline feature can't do it for me, so how do I find the relationship?
The points are: (x,y)
(3, 0.008) (6, 0,006) (10, 0.003) (13, 0.002)
Thanks!
I have 4 data points, from which I want to calculate a hyperbola. It seems that the Excel trendline feature can't do it for me, so how do I find the relationship?
The points are: (x,y)
(3, 0.008) (6, 0,006) (10, 0.003) (13, 0.002)
Thanks!
A hyperbola takes the form $y = k \frac{1}{x}$. This may be difficult to deal with. So instead, let's consider the reciprocals of our x values as J.M. suggested. For example, instead of looking at $(2.5, 0.007713)$, we consider $(\frac{1}{2.5}, 0.007713)$. Then since we have flipped all of our x values, we are looking to fit something of the form $y = k \dfrac{1}{ \frac{1}{x} } = k x$. This can be accomplished by doing any standard linear regression technique.
This is just an extension of J.M.'s comment.
If other people coming across this question want to fit a general hyperbola of the form $\frac{x^2}{a^2} - \frac{y^2}{b^2} = 1$ there is a slightly cheap way of getting an estimate.
Note: The best way is to do this is to use an iterative least squares model or something like that, but this'll give you a rough idea. (Thanks to Claude Leibovici for pointing this out)
You can rearrange the general formula to:
$y^2 = \frac{b^2x^2}{a^2} - b^2$
and then:
and voila! you can now do a standard linear regression to find $\theta_1$ and $\theta_2$ from the linear equation:
$Y = \theta_1X + \theta_2$
Example
You convert your data to X and Y first:
+----+------+ +-----+--------+
| x | y | | X | Y |
+----+------+ -> +-----+--------+
| 4 | 0 | | 16 | 0 |
| 5 | 2.3 | Y=y^2 | 25 | 5.29 |
| 6 | 3.34 | X=x^2 | 36 | 11.16 |
| 10 | 6.85 | | 100 | 46.92 |
| 12 | 8.48 | | 144 | 71.91 |
| 17 | 12.4 | | 289 | 153.76 |
| 20 | 14.7 | | 400 | 216.09 |
+----+------+ +-----+--------+
Then run a linear regression on $X$ and $Y$ to get $\theta_1 = 0.563$ and $\theta_2 = -9.054$
Which implies:
$b = \pm \sqrt{- \theta_2} \approx \pm 3.01$
and
$a = \pm\sqrt{\frac{b^2}{\theta_1}} \approx \pm 4.01$