Design of a Haptic Feedback System for Flight Envelope Protection

Baelen, D. van; Ellerbroek, Joost; Paassen, M.M. van

doi:10.2514/1.g004596

Cited by 18 publications

(15 citation statements)

References 27 publications

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“…The key to calculating flight safety set is to determine the boundary conditions f 0 (x) and seek the optimal solution of equation (11). Suppose the flight states are confined to a rectangular area K = ½V min , V max 3 ½a min , a max 3½u min , u max 3½q min , q max , then the boundary conditions f 0 (x) : R 3 !…”

Section: Safety Set Of Nonlinear Dynamics Systemsmentioning

confidence: 99%

“…The flight safety warning system evaluates the safety of the flight state and feeds safety information back to the pilot in some way. In Van Baelen et al, 11 , the risk-evolution analysis is used determine whether a flight state is safe or not, and the safety of the whole flight space is presented in the form of a cloud chart, which provides vivid and predictive information for the pilot by means of computational flight dynamics. In Van Baelen et al, 11 a haptic feedback system is designed by using force feedback through the control device to provide intuitive information on the state of the aircraft relative to the flight envelope protection.…”

Section: Introductionmentioning

confidence: 99%

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Flight safety warning of iced aircraft based on reachability analysis and fuzzy inference

Yuan,

Li,

2023

Measurement and Control

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A flight safety warning method based on reachability analysis and fuzzy inference is proposed against aircraft icing. A nonlinear model of iced aircraft with uncertainty is proposed based on the existing research results on the effects of icing and the uncertainty in icing detection. To deal with the uncertainty caused by icing, reachability analysis is used to estimate the safe flight envelope of iced aircraft. On this basis, fuzzy inference is employed for flight safety warning which can be used to enhance the pilot’s situational awareness in icing encounters. Simulations of the GTM (Generic Transport Model) aircraft show that, the proposed method has the potential to further increase the flight crew awareness about the risk of losing control in flight under icing.

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Section: Safety Set Of Nonlinear Dynamics Systemsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Flight safety warning of iced aircraft based on reachability analysis and fuzzy inference

Yuan,

Li,

2023

Measurement and Control

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“…Exploratory research first investigated a system which provided a change in force gradient near the flight envelope limits, and pilots indicated that it lacked discrete information, a 'tick-on-the-stick', indicating when the protections become active (Lombaerts et al, 2017). Therefore, the first design iteration involved both guidance and discrete haptic feedback (Van Baelen et al, 2020). Although one should ideally feel haptic feedback, the working principles are visualized in this paper using the haptic profile, i.e., the amount of force required on the side stick, to move that side stick to a certain deflection.…”

Section: Guidance and Discrete Feedbackmentioning

confidence: 99%

Flying by Feeling: Communicating Flight Envelope Protection through Haptic Feedback

Baelen

Paassen

Ellerbroek

et al. 2021

International Journal of Human–Computer Interaction

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Modern aircraft can be equipped with a flight envelope protection system: automation which modifies pilot control inputs to ensure that the aircraft remains within the allowable limits. Overruling the pilot inputs may lead to mode confusion, even when visual or auditory feedback is provided to alert pilots. We advocate using active control devices to make the flight envelope protection system tangible to the pilot. This paper presents the main findings of an evaluation of three haptic feedback designs for flight envelope protection. The first concept used both force feedback and vibro-tactile alerts, producing promising, yet inconclusive, results. The second concept used asymmetric vibrations to give directional alerting cues, which did not result in improved performance on initial use, but which did yield improved learning rate for the task. The third system employed force feedback to physically guide the pilot away from flight envelope limits, which yielded safety improvements from the first use, but created dependence: pilot performance degraded immediately after the force feedback was removed. From this, we advise to use asymmetric vibrations during training for flight envelope excursions, to leverage active control interfaces for providing force feedback during operation, and reevaluate a combination of both to combine their advantages for single-pilot operations.

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“…Full details are given in our earlier work, see Ref. [15], only the relevant elements for understanding the current experiment will be explained in this section. Two designs are elaborated which use haptic feedback to communicate the flight envelope protection limits by changing the feel on the control device.…”

Section: Feedback Designmentioning

confidence: 99%

Evaluating Stick Stiffness and Position Guidance for Feedback on Flight Envelope Protection

Baelen

Paassen

Ellerbroek

et al. 2021

AIAA Scitech 2021 Forum

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Contrary to this, however, it was found that haptic feedback mainly contributed to pilot learning, and performance persisted after haptic support was removed. In addition, haptic support did not improve performance during the first run, which indicates that when implemented on an aircraft, it might not provide pilots with support the very first time they encounter a new situation. As the haptic feedback system aimed to support pilots also in new, unforeseen circumstances, a new iteration of the haptic feedback is required.Actively supporting the pilot has been found to help at the first encounter, yet is subject to reversion to base performance when the support is removed. In a skill acquisition task where a slider had to be moved left and right, four groups of participants received feedback on their performance in a training phase at different times: after each run, or an average score after every five, ten or fifteen runs. [9] Their results showed that increasing the amount of feedback increases performance. Immediately after the training phase, another set of measurements was performed where no feedback was provided. There, the group with the most amount of feedback in the training performed worst, although not significantly different from the other groups. Another measurement was performed two days after the initial training, which showed again a tendency for decreasing performance with increasing feedback during training. This phenomenon is called the "guidance hypothesis": a dependency on the feedback develops while learning the task; disabling this feedback then results in worse performance, due to required re-adaption. This phenomenon was also reported in a similar, vertical task. [10] Within the field of haptic feedback, different applications have been recently designed to support the human operator in a task, and to provide support from the first encounter. Examples of this are a support for an abstract control task ([11]), a lane keeping assist in the automotive domain ([12, 13]), and an obstacle-avoidance system for UAV tele-operation. [14] These examples used active haptic feedback, for example an increased stiffness or actively moving control device, to guide the operator to complete the task. Transferring these active haptic feedback principles to the aircraft flight envelope protection system might provide a feedback system which supports pilots from the first run and solve the issue with our previous 'cueing' system. [8] Nevertheless, such implementations of haptic support have been found to be also hindered by to the guidance hypothesis described before, and it should be investigated whether this is also true in our particular application.The aim of this paper is to present a new haptic feedback for FEP design which is more actively 'guiding' the pilot, and to compare the results of this guidance haptic feedback system, as well as the existing 'cueing' haptic feedback system, to the results of a group of pilots who did not receive any haptic feedback at all. It is hypothesised that the group wi...

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Design of a Haptic Feedback System for Flight Envelope Protection

Cited by 18 publications

References 27 publications

Flight safety warning of iced aircraft based on reachability analysis and fuzzy inference

Flight safety warning of iced aircraft based on reachability analysis and fuzzy inference

Flying by Feeling: Communicating Flight Envelope Protection through Haptic Feedback

Evaluating Stick Stiffness and Position Guidance for Feedback on Flight Envelope Protection

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