1,576 research outputs found
Differential Flatness of Lifting-Wing Quadcopters Subject to Drag and Lift for Accurate Tracking
In this paper, we propose an effective unified control law for accurately
tracking agile trajectories for lifting-wing quadcopters with different
installation angles, which have the capability of vertical takeoff and landing
(VTOL) as well as high-speed cruise flight. First, we derive a differential
flatness transform for the lifting-wing dynamics with a nonlinear model under
coordinated turn condition. To increase the tracking performance on agile
trajectories, the proposed controller incorporates the state and input
variables calculated from differential flatness as feedforward. In particular,
the jerk, the 3-order derivative of the trajectory, is converted into angular
velocity as a feedforward item, which significantly improves the system
bandwidth. At the same time, feedback and feedforward outputs are combined to
deal with external disturbances and model mismatch. The control algorithm has
been thoroughly evaluated in the outdoor flight tests, which show that it can
achieve accurate trajectory tracking
RNN Controller for Lane-Keeping Systems with Robustness and Safety Verification
This paper proposes a Recurrent Neural Network (RNN) controller for
lane-keeping systems, effectively handling model uncertainties and
disturbances. First, quadratic constraints cover the nonlinearities brought by
the RNN controller, and the linear fractional transformation method models the
dynamics of system uncertainties. Second, we prove the robust stability of the
lane-keeping system in the presence of uncertain vehicle speed using a linear
matrix inequality. Then, we define a reachable set for the lane-keeping system.
Finally, to confirm the safety of the lane-keeping system with tracking error
bound, we formulate semidefinite programming to approximate the outer set of
the reachable set. Numerical experiments demonstrate that this approach
confirms the stabilizing RNN controller and validates the safety with an
untrained dataset with untrained varying road curvatures.Comment: 7 pages, 6 figure
Uncertainty Quantification of Autoencoder-based Koopman Operator
This paper proposes a method for uncertainty quantification of an
autoencoder-based Koopman operator. The main challenge of using the Koopman
operator is to design the basis functions for lifting the state. To this end,
this paper builds an autoencoder to automatically search the optimal lifting
basis functions with a given loss function. We approximate the Koopman operator
in a finite-dimensional space with the autoencoder, while the approximated
Koopman has an approximation uncertainty. To resolve the problem, we compute a
robust positively invariant set for the approximated Koopman operator to
consider the approximation error. Then, the decoder of the autoencoder is
analyzed by robustness certification against approximation error using the
Lipschitz constant in the reconstruction phase. The forced Van der Pol model is
used to show the validity of the proposed method. From the numerical simulation
results, we confirmed that the trajectory of the true state stays in the
uncertainty set centered by the reconstructed state.Comment: 6 pages, 3 figure
Fast capture of textured full-body avatar with RGB-D cameras
We present a practical system which can provide
a textured full-body avatar within three seconds. It uses sixteen
RGB-depth (RGB-D) cameras, ten of which are arranged
to capture the body, while six target the important
head region. The configuration of the multiple cameras is
formulated as a constraint-based minimum set space-covering
problem, which is approximately solved by a heuristic algorithm.
The camera layout determined can cover the fullbody
surface of an adult, with geometric errors of less than
5 mm. After arranging the cameras, they are calibrated using
a mannequin before scanning real humans. The 16 RGB-D
images are all captured within 1 s, which both avoids the
need for the subject to attempt to remain still for an uncomfortable
period, and helps to keep pose changes between different
cameras small. All scans are combined and processed
to reconstruct the photo-realistic textured mesh in 2 s. During
both system calibration and working capture of a real
subject, the high-quality RGB information is exploited to assist
geometric reconstruction and texture stitching optimization
Significantly reduced radiation dose to operators during percutaneous vertebroplasty using a new cement delivery device
BACKGROUND: Percutaneous vertebroplasy (PVP) might lead to significant radiation exposure to patients, operators, and operating room personnel. Therefore, radiaton exposure is a concern. The aim of this study was to present a remote control cement delivery device and study whether it can reduce dose exposue to operators. METHODS: After meticulous preoperative preparation, a series of 40 osteoporosis patients were treated with unilateral approach PVP using the new cement delivery divice. We compared levels of fluoroscopic exposure to operator standing on different places during operation. group A: operator stood about 4 meters away from X-ray tube behind the lead sheet. group B: operator stood adjacent to patient as using conventional manual cement delivery device. RESULTS: During whole operation process, radiation dose to the operator (group A) was 0.10 ± 0.03 (0.07-0.15) μSv, group B was 12.09 ± 4.67 (10–20) μSv. a difference that was found to be statistically significant (P < 0.001) between group A and group B. CONCLUSION: New cement delivery device plus meticulous preoperative preparation can significantly decrease radiation dose to operators
Fasting and systemic insulin signaling regulate phosphorylation of brain proteins that modulate cell morphology and link to neurological disorders
Diabetes is strongly associated with cognitive decline, but the molecular reasons are unknown. We found that fasting and peripheral insulin promote phosphorylation and dephosphorylation, respectively, of specific residues on brain proteins including cytoskeletal regulators such as slit-robo GTPase-activating protein 3 (srGAP3) and microtubule affinity-regulating protein kinases (MARKs), in which deficiency or dysregulation is linked to neurological disorders. Fasting activates protein kinase A (PKA) but not PKB/Akt signaling in the brain, and PKA can phosphorylate the purified srGAP3. The phosphorylation of srGAP3 and MARKs were increased when PKA signaling was activated in primary neurons. Knockdown of PKA decreased the phosphorylation of srGAP3. Furthermore, WAVE1, a protein kinase A-anchoring protein, formed a complex with srGAP3 and PKA in the brain of fasted mice to facilitate the phosphorylation of srGAP3 by PKA. Although brain cells have insulin receptors, our findings are inconsistent with the down-regulation of phosphorylation of target proteins being mediated by insulin signaling within the brain. Rather, our findings infer that systemic insulin, through a yet unknown mechanism, inhibits PKA or protein kinase(s) with similar specificity and/or activates an unknown phosphatase in the brain. Ser(858) of srGAP3 was identified as a key regulatory residue in which phosphorylation by PKA enhanced the GAP activity of srGAP3 toward its substrate, Rac1, in cells, thereby inhibiting the action of this GTPase in cytoskeletal regulation. Our findings reveal novel mechanisms linking peripheral insulin sensitivity with cytoskeletal remodeling in neurons, which may help to explain the association of diabetes with neurological disorders such as Alzheimer disease
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