In LSTM Network (Understanding LSTMs), Why input gate and output gate use tanh? what is the intuition behind this? it is just a nonlinear transformation? if it is, can I change both to another activation function (e.g. ReLU)?
Sigmoid
specifically, is used as the gating function for the 3 gates(in, out, forget) in LSTM
, since it outputs a value between 0 and 1, it can either let no flow or complete flow of information throughout the gates. On the other hand, to overcome the vanishing gradient problem, we need a function whose second derivative can sustain for a long range before going to zero. Tanh
is a good function with the above property.
A good neuron unit should be bounded, easily differentiable, monotonic (good for convex optimization) and easy to handle. If you consider these qualities, then i believe you can use ReLU
in place of tanh
function since they are very good alternatives of each other. But before making a choice for activation functions, you must know what are the advantages and disadvantages of your choice over others. I am shortly describing some of the activation functions and their advantages.
Sigmoid
Mathematical expression: sigmoid(z) = 1 / (1 + exp(-z))
1st order derivative: sigmoid'(z) = -exp(-z) / 1 + exp(-z)^2
Advantages:
(1) Sigmoid function has all the fundamental properties of a good activation function.
Tanh
Mathematical expression: tanh(z) = [exp(z) - exp(-z)] / [exp(z) + exp(-z)]
1st order derivative: tanh'(z) = 1 - ([exp(z) - exp(-z)] / [exp(z) + exp(-z)])^2 = 1 - tanh^2(z)
Advantages:
(1) Often found to converge faster in practice
(2) Gradient computation is less expensive
Hard Tanh
Mathematical expression: hardtanh(z) = -1 if z < -1; z if -1 <= z <= 1; 1 if z > 1
1st order derivative: hardtanh'(z) = 1 if -1 <= z <= 1; 0 otherwise
Advantages:
(1) Computationally cheaper than Tanh
(2) Saturate for magnitudes of z greater than 1
ReLU
Mathematical expression: relu(z) = max(z, 0)
1st order derivative: relu'(z) = 1 if z > 0; 0 otherwise
Advantages:
(1) Does not saturate even for large values of z
(2) Found much success in computer vision applications
Leaky ReLU
Mathematical expression: leaky(z) = max(z, k dot z) where 0 < k < 1
1st order derivative: relu'(z) = 1 if z > 0; k otherwise
Advantages:
(1) Allows propagation of error for non-positive z which ReLU doesn't
This paper explains some fun activation function. You may consider to read it.
LSTMs manage an internal state vector whose values should be able to increase or decrease when we add the output of some function. Sigmoid output is always non-negative; values in the state would only increase. The output from tanh can be positive or negative, allowing for increases and decreases in the state.
That's why tanh is used to determine candidate values to get added to the internal state. The GRU cousin of the LSTM doesn't have a second tanh, so in a sense the second one is not necessary. Check out the diagrams and explanations in Chris Olah's Understanding LSTM Networks for more.
The related question, "Why are sigmoids used in LSTMs where they are?" is also answered based on the possible outputs of the function: "gating" is achieved by multiplying by a number between zero and one, and that's what sigmoids output.
There aren't really meaningful differences between the derivatives of sigmoid and tanh; tanh is just a rescaled and shifted sigmoid: see Richard Socher's Neural Tips and Tricks. If second derivatives are relevant, I'd like to know how.
来源:https://stackoverflow.com/questions/40761185/what-is-the-intuition-of-using-tanh-in-lstm