I haven't done this but it is possible but implementing is can be a little bit.
You can consider each network as a function, you want to - in some sense - compose these function to form your network, to do this you can compute the final function by just giving result of one network to the other and then use chain-rule to compute the derivatives(using symbolic differentiation from both packages).

I think a good way for implementing this you might be to wrap TF models as a PyTorch `Function`

and use `tf.gradients`

for computing the backward pass.
Doing gradient updates can really get hard (because some variables exist in TF's computation graph) you can turn TF variables to PyTorch `Variable`

turn them into `placeholde`

s in TF computation graph, feed them in `feed_dict`

and update them using PyTorch mechanisms, but I think it would be really hard to do, instead if you do your updates inside backward method of the function you might be able to do the job(it is really ugly but might do the job).

`per_process_gpu_memory_fraction`

in TF to limit memory usage by a single session and use FIFO queues to connect both models – y.selivonchyk Oct 17 '17 at 17:00