en | de | ru )

 

Disambiguation of "Rahnama, Arash"

Author of the publication

copydeleteadd this publication to your clipboard
Passivation and performance optimization using an extremum seeking co-simulation framework with application to Adaptive Cruise Control systems.

, , , and . ACC, page 6109-6114. IEEE, (2016)

Please choose a person to relate this publication to

To differ between persons with the same name, the academic degree and the title of an important publication will be displayed. You can also use the button next to the name to display some publications already assigned to the person.

Mehdi Rahnama

Ramin Rahnama

Afshin Rahnama

Massud Rahnama

Laila Arash

 

Other publications of authors with the same name

Robustness Against Adversarial Attacks in Neural Networks Using Incremental Dissipativity., , , , and . IEEE Control. Syst. Lett., (2022)Learning-Based Event-Triggered Control for Synchronization of Passive Multiagent Systems Under Attack., and . IEEE Trans. Autom. Control., 65 (10): 4170-4185 (2020)Robust Design of Deep Neural Networks Against Adversarial Attacks Based on Lyapunov Theory., , and . CVPR, page 8175-8184. Computer Vision Foundation / IEEE, (2020)Control Design Using Passivation for Stability and Performance., , , and . IEEE Trans. Automat. Contr., 63 (9): 2987-2993 (2018)On guaranteeing passivity and performance with a human controller., , , and . MED, page 722-727. IEEE, (2015)A QSR-dissipativity and passivity based analysis of event-triggered networked control systems., , and . CDC, page 3072-3077. IEEE, (2016)Passivation and performance optimization using an extremum seeking co-simulation framework with application to Adaptive Cruise Control systems., , , and . ACC, page 6109-6114. IEEE, (2016)Performance optimization based on passivation of systems with applications to systems with input/output delay., , , and . ACC, page 973-978. IEEE, (2016)A passivity-based self-triggered strategy for cyber physical systems under denial-of-service attack., , , and . CDC, page 6082-6087. IEEE, (2017)An Adversarial Approach for Explaining the Predictions of Deep Neural Networks., and . CVPR Workshops, page 3253-3262. Computer Vision Foundation / IEEE, (2021)