%0 Generic %1 kumar2022membershipmappings %A Kumar, Mohit %A Zhang, Weiping %A Fischer, Lukas %A Freudenthaler, Bernhard %D 2022 %K deep-learning fuzzy mappings neural-networks %T Membership-Mappings for Practical Secure Distributed Deep Learning %U https://arxiv.org/abs/2204.05765 %X This study leverages the data representation capability of fuzzy based membership-mappings for practical secure distributed deep learning using fully homomorphic encryption. The impracticality issue of secure machine (deep) learning with fully homomorphic encrypted data, arising from large computational overhead, is addressed via applying fuzzy attributes. Fuzzy attributes are induced by globally convergent and robust variational membership-mappings based local deep models. Fuzzy attributes combine the local deep models in a robust and flexible manner such that the global model can be evaluated homomorphically in an efficient manner using a boolean circuit composed of bootstrapped binary gates. The proposed method, while preserving privacy in a distributed learning scenario, remains accurate, practical, and scalable. The method is evaluated through numerous experiments including demonstrations through MNIST dataset and Freiburg Groceries Dataset. Further, a biomedical application related to mental stress detection on individuals is considered.

@misc{kumar2022membershipmappings, abstract = {This study leverages the data representation capability of fuzzy based membership-mappings for practical secure distributed deep learning using fully homomorphic encryption. The impracticality issue of secure machine (deep) learning with fully homomorphic encrypted data, arising from large computational overhead, is addressed via applying fuzzy attributes. Fuzzy attributes are induced by globally convergent and robust variational membership-mappings based local deep models. Fuzzy attributes combine the local deep models in a robust and flexible manner such that the global model can be evaluated homomorphically in an efficient manner using a boolean circuit composed of bootstrapped binary gates. The proposed method, while preserving privacy in a distributed learning scenario, remains accurate, practical, and scalable. The method is evaluated through numerous experiments including demonstrations through MNIST dataset and Freiburg Groceries Dataset. Further, a biomedical application related to mental stress detection on individuals is considered.}, added-at = {2023-08-04T09:49:48.000+0200}, author = {Kumar, Mohit and Zhang, Weiping and Fischer, Lukas and Freudenthaler, Bernhard}, biburl = {https://www.bibsonomy.org/bibtex/25054d8a6f86c9a7b8c8606fce3455d9a/scch}, interhash = {7ebb65eff46af1ac1f63e5b881ea9aa1}, intrahash = {5054d8a6f86c9a7b8c8606fce3455d9a}, keywords = {deep-learning fuzzy mappings neural-networks}, note = {cite arxiv:2204.05765}, timestamp = {2023-08-04T09:49:48.000+0200}, title = {Membership-Mappings for Practical Secure Distributed Deep Learning}, url = {https://arxiv.org/abs/2204.05765}, year = 2022 }