Fault tolerant linear parameter varying flight control design, verification and validation

“…Finally, also during the preliminary design efforts, it was deemed necessary to include a constraint on the overshoot of the response from r to u in the nominal system. This was combined with (11) to avoid over-exciting the actuators in the absence of faults. The maximum overshoot was selected as 5%.…”

“…Standard, no‐fault, Y$$$ {}^{\ast } $$$ control design objectives are: 11 [ Obj‐1 ] roll angle tracking with response time of less than 4 s and 0$$$ {}^{\circ } $$$ steady‐state error, [ Obj‐2 ] sideslip angle tracking with response time of less than 2 s and 0$$$ {}^{\circ } $$$ steady‐state error, [ Obj‐3 ] decoupled sideslip and bank angles responses to each others step commands with less than respectively $$$ \pm $$$0.05$$$ {}^{\circ } $$$ and $$$ \pm $$$0.5$$$ {}^{\circ } $$$, and [ Obj‐4 ] robustness to actuator time delays (see the ranges given in (2)) and airspeeds between [100, 200] knots.…”

“…For this reason, in this paper the term AIL is preferred over the more broad notion of HIL. For more details about MuPAL‐$$$ \alpha $$$, the reader is referred to References 11, 26, 27.…”

“…Manually scheduling, however, relies on heuristics and lacks theoretical guarantees and systematic design rules 10 . An alternative is to use the linear parameter‐varying (LPV) framework which provides a methodological way to schedule a controller, see for example, Reference 11 for an example of an LPV aircraft control design and validation against aileron and rudder faults, as well as 12 . More recently, an approach (equivalent in many aspects to the LPV method) has appeared based on a so‐called self‐scheduling extension of the structured H$$$ {}_{\infty } $$$ optimization technique 13,14 .…”

Design and aircraft‐in‐the‐loop validation of structured‐H_∞ self‐scheduled fault‐tolerant controllers

“…Finally, also during the preliminary design efforts, it was deemed necessary to include a constraint on the overshoot of the response from r to u in the nominal system. This was combined with (11) to avoid over-exciting the actuators in the absence of faults. The maximum overshoot was selected as 5%.…”

“…Standard, no‐fault, Y$$$ {}^{\ast } $$$ control design objectives are: 11 [ Obj‐1 ] roll angle tracking with response time of less than 4 s and 0$$$ {}^{\circ } $$$ steady‐state error, [ Obj‐2 ] sideslip angle tracking with response time of less than 2 s and 0$$$ {}^{\circ } $$$ steady‐state error, [ Obj‐3 ] decoupled sideslip and bank angles responses to each others step commands with less than respectively $$$ \pm $$$0.05$$$ {}^{\circ } $$$ and $$$ \pm $$$0.5$$$ {}^{\circ } $$$, and [ Obj‐4 ] robustness to actuator time delays (see the ranges given in (2)) and airspeeds between [100, 200] knots.…”

“…For this reason, in this paper the term AIL is preferred over the more broad notion of HIL. For more details about MuPAL‐$$$ \alpha $$$, the reader is referred to References 11, 26, 27.…”

“…Manually scheduling, however, relies on heuristics and lacks theoretical guarantees and systematic design rules 10 . An alternative is to use the linear parameter‐varying (LPV) framework which provides a methodological way to schedule a controller, see for example, Reference 11 for an example of an LPV aircraft control design and validation against aileron and rudder faults, as well as 12 . More recently, an approach (equivalent in many aspects to the LPV method) has appeared based on a so‐called self‐scheduling extension of the structured H$$$ {}_{\infty } $$$ optimization technique 13,14 .…”

Design and aircraft‐in‐the‐loop validation of structured‐H_∞ self‐scheduled fault‐tolerant controllers

“…The MuPAL‐$$$ \alpha $$$ Aircraft‐in‐the‐loop (AIL) platform 50 is currently used by the Japan Aerospace Exploration Agency to validate the performance of user‐defined advanced guidance and control laws and FDD/FTC methodologies for both ground AIL tests inside the hanger (see Figure 1), 51,52 and actual flight tests including Simple Adaptive Control, 53 $$$ {\mathscr{H}}_{\infty } $$$ Control, 23,54‐57 Sliding Mode Control (SMC) 11,44 and an Indirect Adaptive Control strategy involving online parameter estimation 58 …”

Sliding mode observers for robust fault estimation in linear parameter varying systems

Flight Evaluation of a Sliding-Mode Fault-Tolerant Control Scheme