- Define input and weight vectors. Following that define extended input and weight vectors.
- Define open (closed) positive and negative half-spaces such that the net input, i.e. dot product of the weight and input vectors are > (>=) or < (<=) 0, respectively.
- Define linear separability of the input data points with binary classification as belonging to sets A and B respectively. Also, at this point it can be proven that linear separability leads to absolute linear separability for finite sets.
start: The initial weight vector is randomly generated at t:=0.
test: A vector from the union of the negative and the positive half space is chosen randomly.
if classified correctly, go back to test,
if classified incorrectly, go to update.
update: Add/subtract the misclassified positive/negative point to the weight vector and update t:=t+1, go to test.
- Intuition: The normal to the line separating the two data sets in the positive half space is the ideal weight vector: w*.
- Make simplifying assumptions: The weight (w*) and the positive input vectors can be normalized WLOG.
- Assume that after t+1 steps, the weight vector (w_t+1) has been computed, meaning that at time t a positive vector p_i was misclassified.
- Look at the cosine of the angle between the ideal weight vector (w*) and w_t+1.
- Defining some delta to be the minimum of the dot products between the weight vector and the positive points, we can come up with a lower bound for the cosine of the angle.
- Following that the argument is that the lower bound grows as sqrt(t) while it is bound above by 1. Hence, the weights have to stop updating, i.e. converges, after a finite amount of changes.
Of course, this algorithm could take a long time to converge for pathological cases and that is where other algorithms come in.
Karamkars algorithms and simplex method leads to polynomial computation time.
Fontanari and Meir's genetic algorithm also figured out these rules.
This repository contains notes on the perceptron machine learning algorithm. The python scripts are from the book Python Machine Learning by Sebastian Raschka. Meanwhile, the R script is my implementation in the program R.
Furthermore, the algorithm is then applied to the iris data set of flower species and their dependence on petal and sepal dimensions.
I have played around with the data some more in the Rmd file beyond the python scripts.
However, Raschka outlines a plotting code to visualize the descision boundary for the 2D data set. This is very useful and would be nice to implement in R.
Also, the number of misclassifications made per epoch is given by:
If we look at the parameters for all three species, the separability plot becomes:
When we try to separate between Setosa and Non-setosa, we get the following misclassification plot:
Not only is it separable, it converges earlier as well. Of course more data points are used per epoch.
When, we try to separate virginica from non-virginica, we find that the errors do not go down to zero and hence, the weight does not converge:
Lastly, html file of the Rmd file published on my rpubs account is here.