2017
DOI: 10.1016/j.ast.2017.02.007
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Aerodynamic database error filtering via SVD-like methods

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Cited by 7 publications
(4 citation statements)
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“…Furthermore, a maximum number of iterations is allowed. If, after these, the conditions in (28) are not met, the obtained solution is not accepted and the process is repeated. The latter situation almost never occurs if the maximum number of iterations is reasonable because, as it will be seen in Section 4, the process generally converges in less than five iterations.…”
Section: Condition Monitoring Tool 2: a Global Constrained Newton-bas...mentioning
confidence: 99%
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“…Furthermore, a maximum number of iterations is allowed. If, after these, the conditions in (28) are not met, the obtained solution is not accepted and the process is repeated. The latter situation almost never occurs if the maximum number of iterations is reasonable because, as it will be seen in Section 4, the process generally converges in less than five iterations.…”
Section: Condition Monitoring Tool 2: a Global Constrained Newton-bas...mentioning
confidence: 99%
“…Similar ROMs based on HOSVD plus interpolation have been already used in several fields, including generation of aerodynamic databases [23], continuous real-time control of reciprocating engines [24], and aircraft conceptual design [25,26]. HOSVD-based methods also permit constructing tools for recovering lost data [27] and filtering large errors [28] in multidimensional databases, which are relevant in condition monitoring tasks, including:…”
Section: Introductionmentioning
confidence: 99%
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“…-259 - There are multiple ways to present afterwards the health condition of the engines to the crew on board in an aircraft (similarly to the engine operators in a ship or in industrial facilities), like the one suggested for the Electronic Centralized Aircraft Monitor (ECAM) of an Airbus A320 in Figure 133 below, to inform about the current health condition of each main component of the engines: It is convenient to recall here that the methodology presented deals with data from the instrumentation, but it does not contain elements to treat signals coming from the different sensors. Signal conditioning is a task that can be performed by means of hardware (e.g., using specific circuits, like the one presented in [30], or in [229]), by software (e.g., applying HOSVD to the measured values, similarly to the way shown in [149]), or by a combination of both.…”
Section: 1-applicability Of the Methodologymentioning
confidence: 99%