My question is about forward and backward propagation for deep neural networks when the number of hidden units is greater than 1.

I know what I have to do if I have a single hidden layer. In case of a single hidden layer, if my input data `X_train`

has `n`

samples, with `d`

number of features (i.e. `X_train`

is a `(n, d)`

dimensional matrix, `y_train`

is a `(n,1)`

dimensional vector) and if I have `h1`

number of hidden units in my first hidden layer, then I use `Z_h1 = (X_train * w_h1) + b_h1`

(where `w_h1`

is a weight matrix with random number entries which has the shape `(d, h1)`

and `b_h1`

is a bias unit with shape `(h1,1)`

. I use sigmoid activation `A_h1 = sigmoid(Z_h1)`

and find that both `A_h1`

and `Z_h1`

have shapes `(n, h1)`

. If I have `t`

number of output units, then I use a weight matrix `w_out`

with dimensions `(h1, t)`

and `b_out`

with shape `(t,1)`

to get the output `Z_out = (A_h1 * w_h1) + b_h1`

. From here I can get `A_out = sigmoid(Z_out)`

which has shape `(n, t)`

. **If I have a 2nd hidden layer (with h2 number of units) after the 1st hidden layer and before the output layer, then what steps must I add to the forward propagation and which steps should I modify?**

I also have idea about how to tackle backpropagation in case of single hidden layer neural networks. For the single hidden layer example in the previous paragraph, I know that in the first backpropagation step `(output layer -> hidden layer1)`

, I should do `Step1_BP1: Err_out = A_out - y_train_onehot`

(here `y_train_onehot`

is the onehot representation of `y_train`

. `Err_out`

has shape `(n,t)`

. This is followed by `Step2_BP1: delta_w_out = (A_h1)^T * Err_out`

and `delta_b_out = sum(Err_out)`

. The symbol `(.)^T`

denotes the transpose of matrix. For the second backpropagation step `(hidden layer1 -> input layer)`

, we do the following `Step1_BP2: sig_deriv_h1 = (A_h1) * (1-A_h1)`

. Here `sig_deriv_h1`

has shape `(n,h1)`

. In the next step, I do `Step2_BP2: Err_h1 = \Sum_i \Sum_j [ ( Err_out * w_out.T)_{i,j} * sig_deriv_h1__{i,j} )`

]. Here, `Err_h1`

has shape `(n,h1)`

. In the final step, I do `Step3_BP2: delta_w_h1 = (X_train)^T * Err_h1`

and `delta_b_h1 = sum(Err_h1)`

. **What backpropagation steps should I add if I have a 2nd hidden layer (h2 number of units) after the 1st hidden layer and before the output layer? Should I modify the backpropagation steps for the one hidden layer case that I have described here?**