Finding a fit using power function with integer coefficient

Question

Problem:
Consider fitting the following data (y-values): $$ 16, 60, 180, 400, 700, 1200, 2000, 3000, 4300, 6000, 8000, 10500$$ where the x-values range from 1 to 12

into the following model: $$ y = \alpha + \beta x^\gamma $$ where $\alpha,\beta \in \mathbb{N}$ and $\gamma \in \mathbb{R}$.
The integral constraints may be relaxed. Exponential model may be considered.

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Attempts and Questions:

I've tried:

• Building the model in Geogebra and fiddling around with the parameters.
• Using Wolfram Alpha, applying power fit, and exponential fit directly on the data. Wolfram uses least-squares best fit. The integral constraints were not satisfied.

• Linearise the model based on Ian Miller's answer using Excel with $\beta = 11.05077$ and $\gamma = 2.6908$.

  1. What would be a general way to approach this sort of problem?
  2. Ignoring $\alpha$, is my model equivalent to the one used in wolfram? (confusion on my part, addressed)
  3. Should I minimise the error using percentage (relative error) instead of traditional squared difference? $10500 \pm 200$ shold be more tolerable compared to $16 \pm 200$, for instance.

Here are the results: $$ \begin{array}{cc|cccc} & & \text{Geogebra} & \text{Wolfram (power)} & \text{Wolfram (exponential)} & \text{Linearisation} \\ x & y & 4x^{3.17} & 4.88906x^{3.08717} & 198.887e^{0.33343x} & 11.05077x^{2.6908}\\ \hline 1 & 16 & 6 & 4.88906 & 277.596 & 11.05077\\ 2 & 60 & 48 & 41.5486 & 387.4539 & 71.35166\\ 3 & 180 & 162 & 145.271 & 540.7877 & 212.4371\\ 4 & 400 & 384 & 353.091 & 754.803 & 460.6971915\\ 5 & 700 & 750 & 703.177 & 1053.514 & 839.81\\ 6 & 1200 & 1296 & 1234.56 & 1470.44 & 1371.646\\ 7 & 2000 & 2058 & 1986.95 & 2052.362 & 2076.741\\ 8 & 3000 & 3072 & 3000.67 & 2864.579 & 2974.59\\ 9 & 4300 & 4374 & 4316.52 & 3998.229 & 4083.836\\ 10 & 6000 & 6000 & 5975.79 & 5580.518 & 5422.412\\ 11 & 8000 & 7986 & 8020.13 & 7788.993 & 7007.643\\ 12 & 10500 & 10368 & 10491.6 & 10871.47 & 8856.323\\ \end{array} $$

Answer 1

Mathematica provides a NonlinearModelFit function. Using this on your data gives as best fit $y=23.0164 + 4.65795\,x^{3.10605}$. Unfortunately integer constraints are not accepted. However, the best fit suggests taking $\alpha=23$, $\beta=5$. This gives $y=23 + 5\,x^{3.07641}$. The residuals are $$ {-12., -5.17575, 10.1776, 21.2413, -29.7907, -61.4688, -12.945, -23.8777, -34.3632, 15.1153, -16.272, 30.331} $$

Answer 2

Note: Your model is a power model, e.g. $x$ is raised to a power. This is very different to a exponential model from Wolfram which has $x$ in the exponent position. There are many possible models you can attempt to fit your data to. Which one to pick will depend on the shape of the data and the physics behind what is generating the data - sometimes you know or suspect a certain link between the data.

This also depends what you mean by best fit. Wolfram probably has used a least squares fit. What you are describing is trying to minimize the percentage error (probably with a least squares approach). As such you will get two different results.

A lot of software packages will actually end up minimizing something other than the least squares fit as they will linearize the data based on the model then find the linear equation of best fit before converting the coefficients from that back to the chosen model. For example a standard exponential model of the form: $y=\alpha e^{\beta x}$ can be rewriten as $\ln y=\ln\alpha+\beta x$. If you plot $x$ vs $\ln y$ you will get a straight line with gradient of $\beta$ and intercept of $\ln\alpha$.

Your model however can not be linearized. Using three parameters prevents this (as far as I know). From your picture it appears you have set $\alpha$ to zero so if we do that your model can be linearized as follows:

$y=\beta x^\gamma$

$\ln y = \ln\beta + \gamma\ln x$

So if you take your data and make two new columns: $\ln y$ and $\ln x$ they should fit a straight line with gradient of $\gamma$ and intercept of $\ln\beta$. This will not minimize the sum of least squares but will minimize the sum of least squares of the logarithms of the values which might look more like what you were after. Again best fit can be somewhat subjective.

UPDATE: I've taken your table and looked at the sum of the least squares for both models and the the linearized model is better that the Wolfram one using the least squares of the logarithm as the metric for 'best fit'.

($y_m$ is from the linearized model and $y_w$ is from the Wolfram model)

$$ \begin{array}{c|c|cc} & y & \ln x & \ln y & y_m & y_w & \ln y_m & \ln y_w & \ln y_m - \ln y & \ln y_w - \ln y & (\ln y_m - \ln y)^2 & (\ln y_w - \ln y)^2 \\ \hline & y & ln x & ln y & y_m & y_w & ln y_m & ln y_w & ln y_m - ln y & ln y_w - ln y & (ln y_m - ln y)^2 & (ln y_w - ln y)^2 \\ & 16 & 0 & 2.77259 & 11.05062 & 4.88906 & 2.40249 & 1.587 & -0.3701 & -1.18559 & 0.13698 & 1.40562 \\ & 60 & 0.69315 & 4.09434 & 71.35208 & 41.54858 & 4.26763 & 3.72686 & 0.17328 & -0.36748 & 0.03003 & 0.13504 \\ & 180 & 1.09861 & 5.19296 & 212.44079 & 145.27129 & 5.35866 & 4.9786 & 0.16571 & -0.21435 & 0.02746 & 0.04595 \\ & 400 & 1.38629 & 5.99146 & 460.70883 & 353.09121 & 6.13277 & 5.86673 & 0.1413 & -0.12474 & 0.01997 & 0.01556 \\ & 700 & 1.60944 & 6.55108 & 839.83639 & 703.1769 & 6.73321 & 6.55561 & 0.18213 & 0.00453 & 0.03317 & 0.00002 \\ & 1200 & 1.79176 & 7.09008 & 1371.69573 & 1234.55534 & 7.2238 & 7.11847 & 0.13373 & 0.02839 & 0.01788 & 0.00081 \\ & 2000 & 1.94591 & 7.6009 & 2076.82579 & 1986.94883 & 7.6386 & 7.59436 & 0.03769 & -0.00655 & 0.00142 & 0.00004 \\ & 3000 & 2.07944 & 8.00637 & 2974.72218 & 3000.66617 & 7.99791 & 8.00659 & -0.00846 & 0.00022 & 0.00007 & 0 \\ & 4300 & 2.19722 & 8.36637 & 4084.0311 & 4316.52455 & 8.31484 & 8.37021 & -0.05153 & 0.00384 & 0.00266 & 0.00001 \\ & 6000 & 2.30259 & 8.69951 & 5422.68738 & 5975.79055 & 8.59835 & 8.69547 & -0.10117 & -0.00404 & 0.01023 & 0.00002 \\ & 8000 & 2.3979 & 8.9872 & 7008.01714 & 8020.13397 & 8.85481 & 8.98971 & -0.13239 & 0.00251 & 0.01753 & 0.00001 \\ & 10500 & 2.48491 & 9.25913 & 8856.81688 & 10491.59058 & 9.08894 & 9.25833 & -0.17019 & -0.0008 & 0.02896 & 0 \\ & & & & & & & & & \Sigma: & 0.32635 & 1.60308 \\ \end{array} $$

Answer 3

I have been doing almost the same as Julián Aguirre did. Using $\alpha,\beta \in \mathbb{N}$ and $\gamma \in \mathbb{R}$ as yo you wished, I varied parameters $\alpha,\beta$ (running the calculation over a quite large grid o values) until I get a minimum value of the sum of squares.

It appears that, whatever $\alpha$ could be, $\beta=5$ always leads to the minimum value of the sum of squares. For this value of $\beta$, the following table gives the sum of squares as a function of $\alpha$ in the area of the minimum of $SSQ$. $$\left( \begin{array}{cc} \alpha & SSQ \\ 0 & 6988 \\ 1 & 6908 \\ 2 & 6842 \\ 3 & 6790 \\ 4 & 6752 \\ 5 & 6729 \\ 6 & 6719 \\ 7 & 6724 \\ 8 & 6743 \\ 9 & 6776 \end{array} \right)$$

while $\alpha=23$ would lead to $SSQ=8723$.

For the optimum value $(\alpha=6)$, rounded to next integer, the predicted values are $$\{11,48,153,362,714,1247,2000,3013,4327,5982,8019,10479\}$$ the residuals being $$\{5,12,27,38,-14,-47,0,-13,-27,18,-19,21\}$$ and the model is $$y=6+5 \,x^{3.07743}$$