where each is a variable in our -dimensional predictor , and is our outcome variable. represents our inherent error, which is assumed to have mean zero. The represent unspecified smooth functions of a single . Given the flexibility in the , we typically do not have a unique solution: is left unidentifiable as one can add any constants to any of the and subtract this value from . It is common to rectify this by constraining
for all
leaving
necessarily.
The backfitting algorithm is then:
Initialize,Do until converge:
For each predictor j:
(a) (backfitting step)
(b) (mean centering of estimated function)
where is our smoothing operator. This is typically chosen to be a cubic spline smoother but can be any other appropriate fitting operation, such as:
more complex operators, such as surface smoothers for second and higher-order interactions
In theory, step (b) in the algorithm is not needed as the function estimates are constrained to sum to zero. However, due to numerical issues this might become a problem in practice.[1]
If we consider the problem of minimizing the expected squared error:
There exists a unique solution by the theory of projections given by:
for i = 1, 2, ..., p.
This gives the matrix interpretation:
where . In this context we can imagine a smoother matrix, , which approximates our and gives an estimate, , of
or in abbreviated form
An exact solution of this is infeasible to calculate for large np, so the iterative technique of backfitting is used. We take initial guesses and update each in turn to be the smoothed fit for the residuals of all the others:
Looking at the abbreviated form it is easy to see the backfitting algorithm as equivalent to the Gauss–Seidel method for linear smoothing operators S.
Following,[2] we can formulate the backfitting algorithm explicitly for the two dimensional case. We have:
If we denote as the estimate of in the ith updating step, the backfitting steps are
By induction we get
and
If we set then we get
Where we have solved for by directly plugging out from .
We have convergence if . In this case, letting :
We can check this is a solution to the problem, i.e. that and converge to and correspondingly, by plugging these expressions into the original equations.
The choice of when to stop the algorithm is arbitrary and it is hard to know a priori how long reaching a specific convergence threshold will take. Also, the final model depends on the order in which the predictor variables are fit.
As well, the solution found by the backfitting procedure is non-unique. If is a vector such that from above, then if is a solution then so is is also a solution for any . A modification of the backfitting algorithm involving projections onto the eigenspace of S can remedy this problem.
We can modify the backfitting algorithm to make it easier to provide a unique solution. Let be the space spanned by all the eigenvectors of Si that correspond to eigenvalue 1. Then any b satisfying has and Now if we take to be a matrix that projects orthogonally onto , we get the following modified backfitting algorithm:
Initialize,, Do until converge:
Regress onto the space , setting For each predictor j:
Apply backfitting update to using the smoothing operator , yielding new estimates for
^ Härdle, Wolfgang; et al. (June 9, 2004). "Backfitting". Archived from the original on 2015-05-10. Retrieved 2015-08-19.
Breiman, L. & Friedman, J. H. (1985). "Estimating optimal transformations for multiple regression and correlations (with discussion)". Journal of the American Statistical Association. 80 (391): 580–619. doi:10.2307/2288473. JSTOR2288473.
Hastie, T. J. & Tibshirani, R. J. (1990). "Generalized Additive Models". Monographs on Statistics and Applied Probability. 43.
Härdle, Wolfgang; et al. (June 9, 2004). "Backfitting". Archived from the original on 2015-05-10. Retrieved 2015-08-19.