pix2pix + BEGAN

Install

pix2pixGAN
CUDA_VISIBLE_DEVICES=x python main_pix2pixgan.py --dataroot /path/to/facades/train --valDataroot /path/to/facades/val --exp /path/to/a/directory/for/checkpoints
pix2pixBEGAN
CUDA_VISIBLE_DEVICES=x python main_pix2pixBEGAN.py --dataroot /path/to/facades/train --valDataroot /path/to/facades/val --exp /path/to/a/directory/for/checkpoints
Most of the parameters are the same for a fair comparision.
The original pix2pix is modelled as a conditional GAN, however we didn't. Input samples are not given in D(Only target samples are given)
We used the image-buffer(analogyous to replay-buffer in DQN) in training D.
Try other datasets as your need. Similar results will be found.

We found out both L_D and L_G are balanced consistently(equilibrium parameter, gamma=0.7) and converged, even thought network D and G are different in terms of model capacity and detailed layer specification.
M_global

As the author said, M_global is a good indicator for monitoring convergence.
Parsing log: train-log file will be saved in the driectory, you specified, named as train.log
L_D and L_G \w GAN

pix2pixGAN vs. pix2pixBEGAN
CUDA_VISIBLE_DEVICES=x python compare.py --netG_GAN /path/to/netG.pth --netG_BEGAN /path/to/netG.pth --exp /path/to/a/dir/for/saving --tstDataroot /path/to/facades/test/
Checkout more results(order in input, real-target, fake(pix2pixBEGAN), fake(pix2pixGAN))
Interpolation on the input-space.
CUDA_VISIBLE_DEVICES=x python interpolateInput.py --tstDataroot ~/path/to/your/facades/test/ --interval 14 --exp /path/to/resulting/dir --tstBatchSize 4 --netG /path/to/your/netG_epoch_xxx.pth
Upper rows: pix2pixGAN, Lower rows: pix2pixBEGAN

We apologize for your inconvenience when cloning this project. Size of resulting images are huge. please be patient.(Downloading zip file seems to need less time.)

A pytorch implementation of pix2pix + BEGAN (Boundary Equilibrium Generative Adversarial Networks)

Language:HTML 81.6%Language:Python 18.4%