You seem to be a bit confused (I remember I was too) so I am going to simplify things for you. ;)
Sample Neural Network Scenario
Whenever you are given a task such as devising a neural network you are often also given a sample dataset to use for training purposes. Let us assume you are training a simple neural network system
Y = W · X where
Y is the output computed from calculating the scalar product (·) of the weight vector
W with a given sample vector
X. Now, the naive way to go about this would be using the entire dataset of, say, 1000 samples to train the neural network. Assuming that the training converges and your weights stabilise you can then safely say that you network will correctly classify the training data. But what happens to the network if presented with previously unseen data? Clearly the purpose of such systems is to be able to generalise and correctly classify data other than the one used for training.
In any real-world situation, however, previously-unseen/new data is only available once your neural network is deployed in a, let's call it, production environment. But since you have not tested it adequately you are probably going to have a bad time. :) The phenomenon by which any learning system matches its training set almost perfectly but constantly fails with unseen data is called overfitting.
The Three Sets
Here come in the validation and testing parts of the algorithm. Let's go back to the original dataset of 1000 samples. What you do is you split it into three sets -- training, validation and testing (
Te) -- using carefully selected proportions. (80-10-10)% is usually a good proportion, where:
Tr = 80%
Va = 10%
Te = 10%
Training and Validation
Now what happens is that the neural network is trained on the
Tr set and its weights are correctly updated. The validation set
Va is then used to compute the classification error
E = M - Y using the weights resulting from the training, where
M is the expected output vector taken from the validation set and
Y is the computed output resulting from the classification (
Y = W * X). If the error is higher than a user-defined threshold then the whole training-validation epoch is repeated. This training phase ends when the error computed using the validation set is deemed low enough.
Now, a smart ruse here is to randomly select which samples to use for training and validation from the total set
Tr + Va at each epoch iteration. This ensures that the network will not over-fit the training set.
The testing set
Te is then used to measure the performance of the network. This data is perfect for this purpose as it was never used throughout the training and validation phase. It is effectively a small set of previously unseen data, which is supposed to mimic what would happen once the network is deployed in the production environment.
The performance is again measured in term of classification error as explained above. The performance can also (or maybe even should) be measured in terms of precision and recall so as to know where and how the error occurs, but that's the topic for another Q&A.
Having understood this training-validation-testing mechanism, one can further strengthen the network against over-fitting by performing K-fold cross-validation. This is somewhat an evolution of the smart ruse I explained above. This technique involves performing K rounds of training-validation-testing on, different, non-overlapping, equally-proportioned
k = 10, for each value of K you will split your dataset into
Tr+Va = 90% and
Te = 10% and you will run the algorithm, recording the testing performance.
k = 10
for i in 1:k
# Select unique training and testing datasets
KFoldTraining <-- subset(Data)
KFoldTesting <-- subset(Data)
# Train and record performance
KFoldPerformance[i] <-- SmartTrain(KFoldTraining, KFoldTesting)
# Compute overall performance
TotalPerformance <-- ComputePerformance(KFoldPerformance)
I am taking the world-famous plot below from wikipedia to show how the validation set helps prevent overfitting. The training error, in blue, tends to decrease as the number of epochs increases: the network is therefore attempting to match the training set exactly. The validation error, in red, on the other hand follows a different, u-shaped profile. The minimum of the curve is when ideally the training should be stopped as this is the point at which the training and validation error are lowest.
For more references this excellent book will give you both a sound knowledge of machine learning as well as several migraines. Up to you to decide if it's worth it. :)