Difference between revisions of "Gradient Boosted Decision Tree"

GBDT is an additive regression algorithm consisting of an ensemble of trees, fitted to current residuals, gradients of the loss function, in a forward step-wise manner. It iteratively fits an additive model as

${\displaystyle f_{t}(x)=T_{t}(x;\Theta )+\lambda {\overset {T}{\underset {t=1}{\sum }}}\beta _{t}T_{t}(x;\Theta _{t})}$

such that a certain loss function ${\displaystyle L(y_{i},f_{T}(x+i))}$ is minimized, where ${\displaystyle T_{t}(x;\Theta _{t})}$ is a tree at iteration ${\displaystyle t}$, weighted by parameter ${\displaystyle \sigma _{t}}$, with a finite number of parameters, ${\displaystyle \Theta _{t}}$ and ${\displaystyle \lambda }$ is the learning rate. At iteration ${\displaystyle t}$, tree ${\displaystyle T_{t}(x;\sigma )}$ is induced to fit the negative gradient by least squares. That is

${\displaystyle {\hat {\Theta }}:=\operatorname {argmin} _{\beta }{\overset {N}{\underset {i}{\sum }}}(-G_{it}-\beta _{t}T_{t}(x_{i});\Theta )^{2}}$

where ${\displaystyle G_{it}}$ is the gradient over current prediction function

${\displaystyle G_{it}=[{\frac {\delta L(y_{i},f(x_{i}))}{\delta f(x_{i})}}]_{f=f_{t}-1}}$

The optimal weights of trees ${\displaystyle \beta _{t}}$ are determined by

${\displaystyle \beta _{t}=\operatorname {argmin} _{\beta }{\overset {N}{\underset {i}{\sum }}}L(y_{i},f_{t-1}(x_{i})+\beta T(x_{i},\theta ))}$

(Source: [Dong et al WWW 2010])