An Efficient Error Correction Method for Smart Sensor Applications in the Motor Vehicle 930357
In conventional sensor systems, mechanical and electronic components are generally operating at separated locations. Smart sensors integrate mechanical and electronic elements to a single system, thus offering new facilities for a common error compensation.
In this concept, a unit-specific temperature dependence and a non-linear characteristic curve of the mechanical sensor element can be tolerated, thus saving a lot of costs in the manufacturing process of the mechanical components. The behaviour of the mechanical sensor element is described by a two-dimensional sensor correction function: Given the output of the mechanical sensor element and a measured value for the temperature, the true measurement value can be calculated by an error correction unit.
In this paper, different error correction methods are examined and evaluated which can be used for a wide range of sensor types. They are applied to the example of a short-circuit ring displacement sensor. It is shown that the approximation of the error correction function by a two-dimensional characteristic offers advantages in both accuracy and simplicity of the correction procedure. The correction algorithm can be carried out by a simple dedicated processor which requires small chip area if the smart evaluation circuit is integrated into a single chip.
Citation: Dietz, R., Zabler, E., and Heintz, F., "An Efficient Error Correction Method for Smart Sensor Applications in the Motor Vehicle," SAE Technical Paper 930357, 1993, https://doi.org/10.4271/930357. Download Citation
Author(s):
Rainer Dietz, Erich Zabler, Frieder Heintz
Affiliated:
Robert Bosch GmbH
Pages: 8
Event:
International Congress & Exposition
ISSN:
0148-7191
e-ISSN:
2688-3627
Also in:
Sensors and Transducers-PT-68, Sensors and Actuators 1993-SP-0948
Related Topics:
Manufacturing processes
Sensors and actuators
Mathematical models
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