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diff --git a/report/paper.md b/report/paper.md index 0f385c1..aa998b4 100755 --- a/report/paper.md +++ b/report/paper.md @@ -172,7 +172,9 @@ The alternative method shows overall a better performance (see figure \ref{fig:a for M=5. The maximum M non zero eigenvectors that can be used will in this case be at most the amount of training samples per class minus one, since the same amount of eigenvectors will be used for each generated class-subspace. -A major drawback is the increase in execution time (from table \ref{tab:time}, 1.1s on average). +A major drawback is the increase in execution time (from table \ref{tab:time}, 1.1s on average). However the total memory used with the alternative +method is close to the one used with NN. As it can be seen in Appendix \ref{fig:mem}, since we only store the reconstruction error, and the +memory associated with storing the different eigenvectors is deallocated, the total memory usage for alternative method is slightly lower. \begin{figure} \begin{center} @@ -260,9 +262,7 @@ We can model the Lagrange optimization problem under the constraint of ||*e*|| To minimize we take the derivative with respect to *e* and equate L to zero: $\frac {\partial L(e\lambda)}{\partial e}=\frac{\partial F\textsubscript{t}(e)}{\partial e} -+\frac{\partial\lambda(||e||\textsuperscript{2}-1)}{\partial e}=0$. - -Being $\nabla F\textsubscript{t}(e)= (1-t)Se+\frac{t}{<e,S\textsubscript{W}e> ++\frac{\partial\lambda(||e||\textsuperscript{2}-1)}{\partial e}=0$. Being $\nabla F\textsubscript{t}(e)= (1-t)Se+\frac{t}{<e,S\textsubscript{W}e> +\epsilon}S\textsubscript{B}e-t\frac{<e,S\textsubscript{B}e>}{(<e,S\textsubscript{W} e>+\epsilon)\textsuperscript{2}S\textsubscript{W}e}$, we obtain that our goal is to find $\nabla F\textsubscript{t}(e)=\lambda e$, which means making $\nabla F\textsubscript{t}(e)$ @@ -421,7 +421,7 @@ The optimal number of constant and random eigenvectors to use is therefore an in \end{center} \end{figure} -The optimal randomness after doing an exhaustive search as seen on figure \ref{fig:opti-rand}peaks at +The optimal randomness after doing an exhaustive search as seen on figure \ref{fig:opti-rand} peaks at 95 randomised eigenvectors out of 155 total eigenvectors, or 60 static and 95 random eigenvectors. The values of $M_{\textrm{lda}}$ in the figures is 51. The red peaks on the 3d-plot represent the proportion of randomised eigenvectors which achieve the optimal accuracy, which have been further plotted in figure \ref{fig:opt-2d}. We found that for our data, the optimal ratio of random eigenvectors for a given $M$ is between $0.6$ and $0.9$. @@ -523,6 +523,17 @@ LDA-PCA & 0.11 & 0.19 & 0.13 \\ \hline \label{tab:time} \end{table} +### Memory Usage for NN and alternative method + +\begin{figure} +\begin{center} +\includegraphics[width=15em]{fig/memnn.pdf} +\includegraphics[width=15em]{fig/memalt.pdf} +\caption{Memory Usage for NN and alternative method} +\label{fig:mem} +\end{center} +\end{figure} + ## Code All code and \LaTeX sources are available at: |