I know that principal component analysis does a SVD on a matrix and then generates an eigen value matrix. To select the principal components we have to take only the first few eigen values. Now, how do we decide on the number of eigen values that we should take from the eigen value matrix?
To decide how many eigenvalues/eigenvectors to keep, you should consider your reason for doing PCA in the first place. Are you doing it for reducing storage requirements, to reduce dimensionality for a classification algorithm, or for some other reason? If you don't have any strict constraints, I recommend plotting the cumulative sum of eigenvalues (assuming they are in descending order). If you divide each value by the total sum of eigenvalues prior to plotting, then your plot will show the fraction of total variance retained vs. number of eigenvalues. The plot will then provide a good indication of when you hit the point of diminishing returns (i.e., little variance is gained by retaining additional eigenvalues). 


There is no correct answer, it is somewhere between 1 and n. Think of a principal component as a street in a town you have never visited before. How many streets should you take to get to know the town? Well, you should obviously visit the main street (the first component), and maybe some of the other big streets too. Do you need to visit every street to know the town well enough? Probably not. To know the town perfectly, you should visit all of the streets. But what if you could visit, say 10 out of the 50 streets, and have a 95% understanding of the town? Is that good enough? Basically, you should select enough components to explain enough of the variance that you are comfortable with. 


There are a number of heuristics use for that. E.g. taking the first k eigenvectors that capture at least 85% of the total variance. However, for high dimensionality, these heuristics usually are not very good. 


As others said, it doesn't hurt to plot the explained variance. If you use PCA as a preprocessing step for a supervised learning task, you should cross validate the whole data processing pipeline and treat the number of PCA dimension as an hyperparameter to select using a grid search on the final supervised score (e.g. F1 score for classification or RMSE for regression). If crossvalidated grid search on the whole dataset is too costly try on a 2 sub samples, e.g. one with 1% of the data and the second with 10% and see if you come up with the same optimal value for the PCA dimensions. 

