I am trying to plot the decision boundary of a perceptron algorithm and am really confused about a few things. My input instances are in the form [(x1,x2),target_Value], basically a 2-d input instance and a 2 class target_value [1 or 0].
My weight vector hence is in the form: [w1,w2] Now I have to incorporate an additional bias parameter w0 and hence my weight vector becomes a 3x1 vector? is it 1x3 vector? I think it should be 1x3 since a vector has only 1 row and n columns.
Now let's say I instantiate [w0,w1,w2] to random values, how would I plot the decision boundary for this? Meaning what does w0 signify here? Is w0/norm(w) the distance of the decision region from the origin? If so how do I capture this and plot it in python using matplotlib.pyplot or its matlab equivalent? I would really appreciate even a little help regarding this matter.
from pylab import norm import matplotlib.pyplot as plt n = norm(weight_vector) #this is of the form [w0,w1,w2], w0 is bias parameter ww = weight_vector/n #unit vector in the direction of weight_vector ww1 = [ww,-ww] ww2 = [-ww,ww] plot([ww1, ww2],[ww1, ww2],'--k')
Here I want to incorporate the w0 parameter to indicate the distance of the displacement of the weight vector from the origin since that's what w0/norm(w) indicates?
When I plot the vector as mentioned in the comments below I get a vector of really small length, how would it be possible for me to extend this decision boundary in both directions?
The small dashed line near location [0,0] in the figure is my decision region, how can I make it longer in both directions? If I try to multiply each of its components, the figure scale changes, I am using matplotlib.pyplot.plot() function to achieve this.