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2018-05-23
King, Andrew, Fortino, Kelsea, Stevens, Nicholas, Shah, Sachin, Fortino-Mullen, Margaret, Lee, Insup.  2012.  Evaluation of a smart alarm for intensive care using clinical data. 34$^{th}$ Annual International Conference of the IEEE Engineering in Medicine and Biology Society.. :166–169.
Murphy, Christian, Raunak, M. S., King, Andrew, Chen, Sanjian, Imbriano, Christopher, Kaiser, Gail, Lee, Insup, Sokolsky, Oleg, Clarke, Lori, Osterweil, Leon.  2011.  On Effective Testing of Health Care Simulation Software. Proceedings of the 3rd Workshop on Software Engineering in Health Care (SEHC '11). :40–47.
I. Lee, O. Sokolsky, S. Chen, John Hatcliff, E. Jee, B. Kim, A. King, M. Fortino-Mullen, S. Park, A. Roederer et al..  2012.  Challenges and Research Directions in Medical Cyber-Physical Systems. Proceedings of the {IEEE} (special issue on Cyber-Physical Systems). 100:75–90.
2018-05-17
Green, G. Nathan, King, Martin, Humphreys, Todd E.  2015.  Fault Free Integrity of Mid-Level Voting for Triplex Differential GPS Solutions.
Xiong, Xiaobin, Aguilar, Jeffrey J, Rieser, Jennifer, Kim, Allison H, Ames, Aaron D, Goldman, Daniel I.  2017.  Overshoot intrusion forces promote robophysical bipedal walking on homogenous granular media. Bulletin of the American Physical Society. 62
Hubicki, Christian M, Aguilar, Jeffrey J, Kim, Allison H, Rieser, Jennifer, Ames, Aaron D, Goldman, Daniel I.  2017.  Paused intrusions improve robot jumping performance in granular media. Bulletin of the American Physical Society. 62
Hubicki, Christian M, Aguilar, Jeffrey J, Kim, Alison H, Ames, Aaron D, Goldman, Daniel I.  2017.  Manipulation of grain-scale mechanics improves robot jumping performance. Annual Meeting of the Society for Integrative and Comparative Biology.
Zhang, Mengxuan, Li, Nan, Kolmanovsky, Ilya, Girard, Anouck.  2017.  A finite state machine based automated driving controller and its stochastic optimization. Proceedings of ASME Dynamic Systems and Control Conference.
Taheri, Ehsan, Li, Nan I, Kolmanovsky, Ilya.  2017.  Co-state initialization for the minimum-time low-thrust trajectory optimization. Advances in Space Research. 59:2360–2373.
Taheri, Ehsan, Kolmanovsky, Ilya, Girard, Anouck.  2017.  Low-thrust trajectory optimization for multi-asteroid mission: an indirect approach. Proceedings of 27th AAS/AIAA Space Flight Mechanics Meeting. :687–700.
Taheri, Ehsan, Kolmanovsky, Ilya, Atkins, Ella.  2017.  Shaping velocity coordinates for generating low-thrust trajectories. Proceedings of 27th AAS/AIAA Space Flight Mechanics Meeting. :701–711.
Li, Nan I, Kolmanovsky, Ilya, Girard, Anouck.  2016.  A Reference Governor for Nonlinear Systems Based on Quadratic Programming. Proceedings of ASME Dynamic Systems and Control Conference.
Li, Nan, Zhang, Mengxuan, Yildiz, Yildiray, Kolmanovsky, Ilya, Girard, Anouck R.  2017.  Game theory based traffic modeling for calibration of automated driving algorithms. Proceedings of Workshop on Development, Testing and Verification of ADAS and ADF.
Li, Nan, Oyler, Dave W, Zhang, Mengxuan, Yildiz, Yildiray, Kolmanovsky, Ilya, Girard, Anouck R.  2017.  Game Theoretic Modeling of Driver and Vehicle Interactions for Verification and Validation of Autonomous Vehicle Control Systems. IEEE Transactions on Control Systems Technology.
Li, Nan, Kolmanovsky, Ilya, Girard, Anouck.  2017.  Model-free optimal control based automotive control system falsification. Proceedings of American Control Conference. :636–641.
Li, Nan, Chen, Hao, Kolmanovsky, Ilya, Girard, Anouck.  2017.  An explicit decision tree approach for automated driving. Proceedings of ASME Dynamic Systems and Control Conference.
Hudson, Jennifer, Gupta, Rohit, Li, Nan, Kolmanovsky, Ilya.  2017.  Iterative model and trajectory refinement for orbital trajectory optimization. Optimal Control Applications and Methods.
Li, Nan, Oyler, Dave, Zhang, Mengxuan, Yildiz, Yildiray, Girard, Anouck, Kolmanovsky, Ilya.  2016.  Hierarchical reasoning game theory based approach for evaluation and testing of autonomous vehicle control systems. Proceedings of 55th IEEE Conference on Decision and Control. :727–733.
Bloch, Anthony M, Gupta, Rohit, Kolmanovsky, Ilya V.  2016.  Neighboring extremal optimal control for mechanical systems on riemannian manifolds. Journal of Geometric Mechanics. 8
Weerakkody, Sean, Sinopoli, Bruno, Kar, Soummya, Datta, Anupam.  2016.  Information Flow for Security in Control Systems. 55th IEEE Conference on Decision and Control (CDC). :5065-5072.
Joseph Wang, Kirill Trapeznikov, Venkatesh Saligrama.  Submitted.  An LP for Sequential Learning Under Budgets. {AISTATS}. 33:987–995.
Tolga Bolukbasi, Kai{-}Wei Chang, Joseph Wang, Venkatesh Saligrama.  2017.  Resource Constrained Structured Prediction. {AAAI}. :1756–1762.
Perseghetti, Benjamin M., Roll, Jesse A., Gallagher, John C..  2014.  Design Constraints of a Minimally Actuated Four Bar Linkage Flapping-Wing Micro Air Vehicle. Robot Intelligence Technology and Applications 2: Results from the 2nd International Conference on Robot Intelligence Technology and Applications. :545–555.

This paper documents and discusses the design of a low-cost Flapping-Wing Micro Air Vehicle (FW-MAV) designed to be easy to fabricate using readily available materials and equipment. Basic theory of operation as well as the rationale underlying various design decisions will be provided. Using this paper, it should be possible for readers to construct their own devices quickly and at little expense.

Gallagher, John C., Humphrey, Laura R., Matson, Eric.  2014.  Maintaining Model Consistency during In-Flight Adaptation in a Flapping-Wing Micro Air Vehicle. Robot Intelligence Technology and Applications 2: Results from the 2nd International Conference on Robot Intelligence Technology and Applications. :517–530.

Machine-learning and soft computation methods are often used to adapt and modify control systems for robotic, aerospace, and other electromechanical systems. Most often, those who use such methods of self-adaptation focus on issues related to efficacy of the solutions produced and efficiency of the computational methods harnessed to create them. Considered far less often are the effects self-adaptation on Verification and Validation (V{&}V) of the systems in which they are used. Simply observing that a broken robotic or aerospace system seems to have been repaired is often not enough. Since self-adaptation can severely distort the relationships among system components, many V{&}V methods can quickly become useless. This paper will focus on a method by which one can interleave machine-learning and model consistency checks to not only improve system performance, but also to identify how those improvements modify the relationship between the system and its underlying model. Armed with such knowledge, it becomes possible to update the underlying model to maintain consistency between the real and modeled systems. We will focus on a specific application of this idea to maintaining model consistency for a simulated Flapping-Wing Micro Air Vehicle that uses machine learning to compensate for wing damage incurred while in flight. We will demonstrate that our method can detect the nature of the wing damage and update the underlying vehicle model to better reflect the operation of the system after learning. The paper will conclude with a discussion of potential future applications, including generalizing the technique to other vehicles and automating the generation of model consistency-testing hypotheses.

Goppert, James, Gallagher, John C., Hwang, Inseok, Matson, Eric.  2014.  Model Checking of a Flapping-Wing Mirco-Air-Vehicle Trajectory Tracking Controller Subject to Disturbances. Robot Intelligence Technology and Applications 2: Results from the 2nd International Conference on Robot Intelligence Technology and Applications. :531–543.

This paper proposes a model checking method for a trajectory tracking controller for a flapping wing micro-air-vehicle (MAV) under disturbance. Due to the coupling of the continuous vehicle dynamics and the discrete guidance laws, the system is a hybrid system. Existing hybrid model checkers approximate the model by partitioning the continuous state space into invariant regions (flow pipes) through the use of reachable set computations. There are currently no efficient methods for accounting for unknown disturbances to the system. Neglecting disturbances for the trajectory tracking problem underestimates the reachable set and can fail to detect when the system would reach an unsafe condition. For linear systems, we propose the use of the H-infinity norm to augment the flow pipes and account for disturbances. We show that dynamic inversion can be coupled with our method to address the nonlinearities in the flapping-wing control system.