# Need SQL Server Query to solve 3rd Order Polynomial Regression

Can anyone help with some SQL query code to provide estimates of the co-efficients for a 3rd order Polynomial regression?

Please assume that I have a table of X and Y data values and want to estimate a, b and c in:

``````Y(X) = aX + bX^2 + cX^3 + E
``````
-
It would be helpful, if you could paste the formula for estimation of a, b and c, because, not everybody here is good with mathematics... –  Naveed Butt Feb 15 '12 at 11:12
If it is homework tag it. –  juergen d Feb 15 '12 at 11:13
added tag [math] –  hochgurgler Feb 15 '12 at 11:14
@MarkBannister: going off the title, I'd say SQL Server. –  bhamby Feb 15 '12 at 14:01
So ... you want us to work out exactly what a Javascript page is doing, then translate it into SQL for you? –  Mark Bannister Feb 15 '12 at 14:36

APPROXIMATE but fast solution would be to sample 4 representative points from the data and solve the polynomial equation for these points.

1. As for the sampling, you can split the data into equal sectors and compute average of X and Y for each sector - the split can be done using quartiles of X-values, averages of X-values, `min(x)+(max(x)-min(x))/4` or whatever you think is the most appropriate.

To illustrate the sampling by quartiles (i.e. by row numbers):

2. As for the solving, i used numberempire.com to solve these* equations for variables `k,a,b,c`:

``````k + a*X1 + b*X1^2 + c*X1^3 - Y1 = 0,
k + a*X2 + b*X2^2 + c*X2^3 - Y2 = 0,
k + a*X3 + b*X3^2 + c*X3^3 - Y3 = 0,
k + a*X4 + b*X4^2 + c*X4^3 - Y4 = 0
``````

*Since `Y(X) = 0 + ax bx^2 + cx^3 + ϵ` implicitly includes [0, 0] point as one of the sample points, it would create bad approximations for data sets that don't include [0, 0]. I took the liberty of solving `Y(X) = k + ax bx^2 + cx^3 + ϵ` instead.

The actual SQL would go like this:

``````select
-- returns 1 row with columns labeled K, A, B and C = coefficients in 3rd order polynomial equation for the 4 sample points
-(X1*(X2p2*(X3p3*Y4-X4p3*Y3)+X2p3*(X4p2*Y3-X3p2*Y4)+(X3p2*X4p3-X3p3*X4p2)*Y2)+X1p2*(X2*(X4p3*Y3-X3p3*Y4)+X2p3*(X3*Y4-X4*Y3)+(X3p3*X4-X3*X4p3)*Y2)+X1p3*(X2*(X3p2*Y4-X4p2*Y3)+X2p2*(X4*Y3-X3*Y4)+(X3*X4p2-X3p2*X4)*Y2)+(X2*(X3p3*X4p2-X3p2*X4p3)+X2p2*(X3*X4p3-X3p3*X4)+X2p3*(X3p2*X4-X3*X4p2))*Y1)/(X1*(X2p2*(X4p3-X3p3)-X3p2*X4p3+X3p3*X4p2+X2p3*(X3p2-X4p2))+X2*(X3p2*X4p3-X3p3*X4p2)+X1p2*(X3*X4p3+X2*(X3p3-X4p3)+X2p3*(X4-X3)-X3p3*X4)+X2p2*(X3p3*X4-X3*X4p3)+X1p3*(X2*(X4p2-X3p2)-X3*X4p2+X3p2*X4+X2p2*(X3-X4))+X2p3*(X3*X4p2-X3p2*X4))  as k,
(X1p2*(X2p3*(Y4-Y3)-X3p3*Y4+X4p3*Y3+(X3p3-X4p3)*Y2)+X2p2*(X3p3*Y4-X4p3*Y3)+X1p3*(X3p2*Y4+X2p2*(Y3-Y4)-X4p2*Y3+(X4p2-X3p2)*Y2)+X2p3*(X4p2*Y3-X3p2*Y4)+(X3p2*X4p3-X3p3*X4p2)*Y2+(X2p2*(X4p3-X3p3)-X3p2*X4p3+X3p3*X4p2+X2p3*(X3p2-X4p2))*Y1)/(X1*(X2p2*(X4p3-X3p3)-X3p2*X4p3+X3p3*X4p2+X2p3*(X3p2-X4p2))+X2*(X3p2*X4p3-X3p3*X4p2)+X1p2*(X3*X4p3+X2*(X3p3-X4p3)+X2p3*(X4-X3)-X3p3*X4)+X2p2*(X3p3*X4-X3*X4p3)+X1p3*(X2*(X4p2-X3p2)-X3*X4p2+X3p2*X4+X2p2*(X3-X4))+X2p3*(X3*X4p2-X3p2*X4))  as a,
-(X1*(X2p3*(Y4-Y3)-X3p3*Y4+X4p3*Y3+(X3p3-X4p3)*Y2)+X2*(X3p3*Y4-X4p3*Y3)+X1p3*(X3*Y4+X2*(Y3-Y4)-X4*Y3+(X4-X3)*Y2)+X2p3*(X4*Y3-X3*Y4)+(X3*X4p3-X3p3*X4)*Y2+(X2*(X4p3-X3p3)-X3*X4p3+X3p3*X4+X2p3*(X3-X4))*Y1)/(X1*(X2p2*(X4p3-X3p3)-X3p2*X4p3+X3p3*X4p2+X2p3*(X3p2-X4p2))+X2*(X3p2*X4p3-X3p3*X4p2)+X1p2*(X3*X4p3+X2*(X3p3-X4p3)+X2p3*(X4-X3)-X3p3*X4)+X2p2*(X3p3*X4-X3*X4p3)+X1p3*(X2*(X4p2-X3p2)-X3*X4p2+X3p2*X4+X2p2*(X3-X4))+X2p3*(X3*X4p2-X3p2*X4))  as b,
(X1*(X2p2*(Y4-Y3)-X3p2*Y4+X4p2*Y3+(X3p2-X4p2)*Y2)+X2*(X3p2*Y4-X4p2*Y3)+X1p2*(X3*Y4+X2*(Y3-Y4)-X4*Y3+(X4-X3)*Y2)+X2p2*(X4*Y3-X3*Y4)+(X3*X4p2-X3p2*X4)*Y2+(X2*(X4p2-X3p2)-X3*X4p2+X3p2*X4+X2p2*(X3-X4))*Y1)/(X1*(X2p2*(X4p3-X3p3)-X3p2*X4p3+X3p3*X4p2+X2p3*(X3p2-X4p2))+X2*(X3p2*X4p3-X3p3*X4p2)+X1p2*(X3*X4p3+X2*(X3p3-X4p3)+X2p3*(X4-X3)-X3p3*X4)+X2p2*(X3p3*X4-X3*X4p3)+X1p3*(X2*(X4p2-X3p2)-X3*X4p2+X3p2*X4+X2p2*(X3-X4))+X2p3*(X3*X4p2-X3p2*X4))  as c
from (select
samples.*,
-- precomputing the powers should give better performance (at least i hope it would)
power(X1,2) X1p2, power(X2,2) X2p2, power(X3,2) X3p2, power(X4,2) X4p2,
power(Y1,3) Y1p3, power(Y2,3) Y2p3, power(Y3,3) Y3p3, power(Y4,3) Y4p3
from (select
avg(case when sector = 1 then x end) X1,
avg(case when sector = 2 then x end) X2,
avg(case when sector = 3 then x end) X3,
avg(case when sector = 4 then x end) X4,
avg(case when sector = 1 then y end) Y1,
avg(case when sector = 2 then y end) Y2,
avg(case when sector = 3 then y end) Y3,
avg(case when sector = 4 then y end) Y4
from (select x, y,
-- splitting to sectors 1 - 4 by row number (SQL Server version)
ceiling(row_number() OVER (ORDER BY x asc) / count(*) * 4) sector
from original_data
)
) samples
)
``````

According to developer.mimer.com, these optional features need to be enabled in SQL Server:

``````T611, "Elementary OLAP operations"
F591, "Derived tables"
``````
-

SQL Server has a built-in ranking function NTILE(n) which will more easily create your sectors. I replaced:

``````ceiling(row_number() OVER (ORDER BY x asc) / count(*) * 4) sector
``````

with:

``````NTILE(4) OVER(ORDER BY x ASC) [sector]
``````

I also needed to add several "precomputed powers" to allow for the full column range as selected. The full list appears below:

``````POWER(samples.X1, 2) AS [X1p2],
POWER(samples.X1, 3) AS [X1p3],
POWER(samples.X2, 2) AS [X2p2],
POWER(samples.X2, 3) AS [X2p3],
POWER(samples.X3, 2) AS [X3p2],
POWER(samples.X3, 3) AS [X3p3],
POWER(samples.X4, 2) AS [X4p2],
POWER(samples.X4, 3) AS [X4p3],
POWER(samples.Y1, 3) AS [Y1p3],
POWER(samples.Y2, 3) AS [Y2p3],
POWER(samples.Y3, 3) AS [Y3p3],
POWER(samples.Y4, 3) AS [Y4p3]
``````

Overall, great answer by @Aprillion! Well explained and the numberempire.com h/t was very helpful.

-