The previous solutions do not compute the average of the accumulated gradients, which may lead to instability in training. I've modified the above code, which should solve this problem.

```
# Fetch a list of our network's trainable parameters.
trainable_vars = tf.trainable_variables()
# Create variables to store accumulated gradients
accumulators = [
tf.Variable(
tf.zeros_like(tv.initialized_value()),
trainable=False
) for tv in trainable_vars
]
# Create a variable for counting the number of accumulations
accumulation_counter = tf.Variable(0.0, trainable=False)
# Compute gradients; grad_pairs contains (gradient, variable) pairs
grad_pairs = optimizer.compute_gradients(loss, trainable_vars)
# Create operations which add a variable's gradient to its accumulator.
accumulate_ops = [
accumulator.assign_add(
grad
) for (accumulator, (grad, var)) in zip(accumulators, grad_pairs)
]
# The final accumulation operation is to increment the counter
accumulate_ops.append(accumulation_counter.assign_add(1.0))
# Update trainable variables by applying the accumulated gradients
# divided by the counter. Note: apply_gradients takes in a list of
# (grad, var) pairs
train_step = optimizer.apply_gradients(
[(accumulator / accumulation_counter, var) \
for (accumulator, (grad, var)) in zip(accumulators, grad_pairs)]
)
# Accumulators must be zeroed once the accumulated gradient is applied.
zero_ops = [
accumulator.assign(
tf.zeros_like(tv)
) for (accumulator, tv) in zip(accumulators, trainable_vars)
]
# Add one last op for zeroing the counter
zero_ops.append(accumulation_counter.assign(0.0))
```

This code is used in the same manner as that provided by @weixsong.