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Abstract
This paper introduces a procedure to compare the functional behaviour of individual units of electronic hardware of the same type. The primary use case for this method is to estimate the functional integrity of an unknown device unit based on the behaviour of a known and proven reference unit. This method is based on the so-called virtual sensor network (VSN) approach, where the output quantity of a physical sensor measurement is replicated by a virtual model output. In the present study, this approach is extended to model the functional behaviour of electronic hardware by a neural network (NN) with Long-Short-Term-Memory (LSTM) layers to encapsulate potential time-dependence of the signals. The proposed method is illustrated and validated on measurements from a remote-controlled drone, which is operated with two variants of controller hardware: a reference controller unit and a malfunctioning counterpart. It is demonstrated that the presented approach successfully identifies and describes the unexpected behaviour of the test device. In the presented case study, the model outputs a signal sample prediction in 0.14 ms and achieves a reconstruction accuracy of the validation data with a root mean square error (RMSE) below 0.04 relative to the data range. In addition, three self-protection features (multidimensional boundary-check, Mahalanobis distance, auxiliary autoencoder NN) are introduced to gauge the certainty of the VSN model output.
Highlights
Rapid development of electronic hardware is in high demand due to the competitive market space, set product life cycles and customer demand [1]
The present study introduced a methodology for the identification of the functional integrity of electronic devices based on an neural network (NN) model of a reference device unit
The results of this experiment demonstrate the effective application of the proposed methodology as discussed in the previous chapter
Summary
Rapid development of electronic hardware is in high demand due to the competitive market space, set product life cycles and customer demand [1]. It is important to ensure that the manufactured hardware operates as intended and is tested in the development process based on prototypes. The result could lead to additional customer support, costly recalls or warranty claims. For safety-critical applications, the requirement for functional integrity usually has implications on the health and safety of humans [2] or critical infrastructures of whole societies [3,4]. An unexpected breach of the functional integrity of electronic hardware can occur due to a multitude of reasons. Internal factors include errors in the manufacturing process, software bugs, defective components, upgrades or redesigns of hardware/software
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