Task Assignment with Neural Network based on Potts Spin.
The method is a Neural Netork based on Potts Spin for the task assignment problem. The original implementation is by Jennifer David and in C++. I implemented this Python version under the supervision of Jennifer David.
Download, installing dependencies, and install package
# Download
$ git clone https://github.com/saeedghsh/PyPotts.git
$ cd PyPotts
# Install dependencies
$ pip install -r requirements.txt
# Install the package [optional]
python setup.py install- Solve assignment (From
D,TtoV):
$ not available yet...- Parsing the
Vmatrix (the assignments):
$ cd scripts/
$ python parse_V_mat.py --fname '../sample_data/3_6_Vmat__.txt' --m 3 --n 6 -verbose -visualize-
write the dev/find_optimal.py script that finds the optimal solution to the input, kinda brute-force, exhausting all the possible solutiuons, but also considering the conditions for the validity of solution (is_V_mat_valid
andparse_V_to_assignment`) as heuristic to limit the search space (how?). -
make the history-log-plot interactive, plot3D of the assignment at whatever iteration picked (to investigate the phase changing oscillation).
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The method is under developement! coordinate the update, developement, and debugging of the code with Jennifer David.
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Add a script to just check the validity of the V matrix, and if it is invalid, print what exactly is the problem.
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store the history of
V,E_task,P,R,Lin.txt. There is a problem here, there is an inconsistency among different configurations of the method. The length ofE_task,P,R,Lchange, so its not easy (straightforward) to store the results programatically (see examples below) I prefered storing in numpy.ndarray, because it would be easier to interact with the (e.g. plot and debug), and also file-IO is rather slow. But then storing as array is memeory consuming. Alternatively I could add a debugging mode, where these are stored to file, and add some functionality to read-load those required data. The first three that are consistent:# synchronous mode config['synchronous'] = True # shape of V_log is (len(KT), ndim, ndim) # shape of E (local, loop, task, and P, R, L) is (len(KT), ndim, ndim)
,
# asynchronous-batch mode - without frequent update config['synchronous'] = False config['update_E_local_per_row_col'] = False # shape of V_log is (len(KT), ndim, ndim) # shape of E (local, loop, task, and P, R, L) is (len(KT), ndim, ndim)
,
# asynchronous-beta mode - one row/column per iteration config['synchronous'] = False config['update_temperature_after_each_row_col'] = True # shape of V_log is (len(KT), ndim, ndim) # shape of E (local, loop, task, and P, R, L) is (len(KT), ndim, ndim)
but this config is not consistent with the previous ones:
# asynchronous-batch mode - with frequent update config['synchronous'] = False config['update_E_local_per_row_col'] = False # shape of V_log is (len(KT), ndim, ndim) # shape of E (local, loop, task, and P, R, L) is ((m+n)*len(KT), ndim, ndim)
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Implement with PyTorch or theano.
- Started, but there is a bug. In the 1st (or mayby 2nd?) iteration
infis generated and the process terminates. Don't know where it is comming from yet. I can't do the debugging right now, because I'm on the plain and the don't have access to internet, and the version of PyTorch on the machine I brought with me is too old and cannot even compile the torch version. my 0.1 version (vs the current 0.4) don't have thetorch.floattype defined. - So, it turns out I forgot to implement the method for converting the matrices to doubly connected stochastic... now the PyTorch version is working. Althought only the synchronous version is implemented, and more importantly, PyTorch is processing with CPU and takes more time than numpy version. Next step is to enable GPU processing and include asynchronous versions...
- Started, but there is a bug. In the 1st (or mayby 2nd?) iteration
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Add documentation and API examples.
Distributed with a GNU GENERAL PUBLIC LICENSE; see LICENSE.
Copyright (C) Saeed Gholami Shahbandi