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Filters: Author is Wu, Yuhao  [Clear All Filters]
2023-07-13
Wu, Yuhao, Wang, Yujie, Zhai, Shixuan, Li, Zihan, Li, Ao, Wang, Jinwen, Zhang, Ning.  2022.  Work-in-Progress: Measuring Security Protection in Real-time Embedded Firmware. 2022 IEEE Real-Time Systems Symposium (RTSS). :495–498.
The proliferation of real-time cyber-physical systems (CPS) is making profound changes to our daily life. Many real-time CPSs are security and safety-critical because of their continuous interactions with the physical world. While the general perception is that the security protection mechanism deployment is often absent in real-time embedded systems, there is no existing empirical study that measures the adoption of these mechanisms in the ecosystem. To bridge this gap, we conduct a measurement study for real-time embedded firmware from both a security perspective and a real-time perspective. To begin with, we collected more than 16 terabytes of embedded firmware and sampled 1,000 of them for the study. Then, we analyzed the adoption of security protection mechanisms and their potential impacts on the timeliness of real-time embedded systems. Besides, we measured the scheduling algorithms supported by real-time embedded systems since they are also security-critical.
ISSN: 2576-3172
2022-11-08
Wshah, Safwan, Shadid, Reem, Wu, Yuhao, Matar, Mustafa, Xu, Beilei, Wu, Wencheng, Lin, Lei, Elmoudi, Ramadan.  2020.  Deep Learning for Model Parameter Calibration in Power Systems. 2020 IEEE International Conference on Power Systems Technology (POWERCON). :1–6.
In power systems, having accurate device models is crucial for grid reliability, availability, and resiliency. Existing model calibration methods based on mathematical approaches often lead to multiple solutions due to the ill-posed nature of the problem, which would require further interventions from the field engineers in order to select the optimal solution. In this paper, we present a novel deep-learning-based approach for model parameter calibration in power systems. Our study focused on the generator model as an example. We studied several deep-learning-based approaches including 1-D Convolutional Neural Network (CNN), Long Short-Term Memory (LSTM), and Gated Recurrent Units (GRU), which were trained to estimate model parameters using simulated Phasor Measurement Unit (PMU) data. Quantitative evaluations showed that our proposed methods can achieve high accuracy in estimating the model parameters, i.e., achieved a 0.0079 MSE on the testing dataset. We consider these promising results to be the basis for further exploration and development of advanced tools for model validation and calibration.