## Gradient Descent

Backpropagation is to reduce the cost `J`

of the entire system (softmax classifier here) and it is a problem to optimize the weight parameter `W`

to minimize the cost. Providing the cost function `J = f(W)`

is **convex**, the gradient descent `W = W - α * f'(W)`

will result in the `Wmin`

which minimizes `J`

. The hyperparameter `α`

is called **learning rate** which we need to optimize too, but not in this answer.

`Y`

should be read as `J`

in the diagram. Imagine you are on the surface of a place whose shape is defined as `J = f(W)`

and you need to reach the point `Wmin`

. There is no gravity so you do not know which way is toward the bottom but you know the function and your coordinate. How do you know which way you should go? You can find the direction from the derivative `f'(W)`

and move to a new coordinate by `W = W - α * f'(W)`

. By repeating this, you can get closer and closer to the point `Wmin`

.

## Back propagation at Affin Layer

At the node where multiply or dot operation happens (affin), the function is `J = f(W) = X * W`

. Suppose there are `m`

number of fixed two dimensional coordinates represented as X. How can we find the hyper-plane which minimizes `J = f(W) = X * W`

and its vector `W`

?

We can get closer to the optimal `W`

by repeating the gradient descent `W += -α * X`

if **α** is appropriate.

## Chain Rule

When there are layers after the Affine layer such as the **softmax** layer and the **log loss** layer in the softmax classifier, we can calculate the gradient with the chain rule. In the diagram, replace **sigmoid** with **softmax**.

As stated in Computing the Analytic Gradient with Backpropagation in the cs321 page, the gradient contribution from the **softmax** layer and the **log loss** layer is the **dscore** part. See the Note section below too.

By applying the gradient to that of the **affine** layer via the chain rule, the code is derived where **α** is replaced with **step_size**. In reality, the **step_size** needs to be learned as well.

```
dW = np.dot(X.T, dscores)
W += -step_size * dW
```

The bias gradient can be derived by applying the chain rule towards the bias **b** with the gradients (**dscore**) from the post layers.

```
db = np.sum(dscores, axis=0, keepdims=True)
```

## Regularization

As stated in Regularization of the cs231 page, the cost function (objective) is adjusted by adding the regularization, which is **reg_loss** in the code. It is to reduce the over-fitting. The intuition is, in my understanding, if specific feature(s) cause overfitting, we can reduce it by inflating the cost with their weight parameters **W**, because the gradient descent will work to reduce the cost contributions from the weights. Since we do not know which ones, use all **W**. The reason of **0.5 * W*W** is because it gives simple derivative **W**.

```
reg_loss = 0.5*reg*np.sum(W*W)
```

The gradient contribution `reg*W`

is from the derivative of **reg_loss**. The **reg** is a hyper parameter to be learned in the real training.

```
reg_loss/dw -> 0.5 * reg * 2 * W
```

It is added to the gradient from the layers after the affin.

```
dW += reg*W # regularization gradient
```

The process to get the derivative from the cost including the regularization is omitted in the cs231 page referenced in the post, probably because it is a common practice to just put the gradient of the regularization, but confusing for those who are learning. See Coursera Machine Learning Week 3 Cost Function by Andrew Ng for the regularization.

## Note

The bias parameter **b** is substituted with **X0** as the bias can be omitted by shifting to the base.