Title :
Magnetic velocity sensors
Author :
Lequesne, Bruno ; Pawlak, Andrzej M. ; Schroeder, Thaddeus
Author_Institution :
Dept. of Electr. & Electron. Eng., Gen. Motors Res. Labs., Warren, MI, USA
Abstract :
There are two types of low-cost velocity sensors based on magnetic principles, variable-reluctance sensors, and galvanomagnetic semiconductor (Hall effect or magnetoresistive) sensors. Variable-reluctance devices sense variations in flux linkage while semiconductors read variations in local flux density. The paper shows how recognizing this fundamental difference leads to markedly different sensor design approaches, and proposes new configurations with improved performance. The analysis of the sensors is based on a general theory specifically developed for these sensors. The magnetic field computations use the finite-element method, which is particularly well suited to this problem involving complex airgap configurations and a need for the calculation of local flux densities and flux linkages. Experiments were carried out to validate the models and confirm the predicted sensitivity improvements of the new sensor structures
Keywords :
Hall effect transducers; finite element analysis; magnetic fields; magnetic flux; magnetic sensors; magnetic variables measurement; magnetoresistive devices; velocity measurement; Hall effect sensors; airgap configurations; finite-element method; flux linkage variations; flux linkages; galvanomagnetic semiconductor sensors; local flux densities; local flux density; low-cost velocity sensors; magnetic field computations; magnetic velocity sensors; magnetoresistive sensors; variable-reluctance devices; variable-reluctance sensors; Couplings; Finite element methods; Hall effect; Magnetic analysis; Magnetic fields; Magnetic flux; Magnetic semiconductors; Magnetic sensors; Magnetoresistance; Predictive models;
Journal_Title :
Industry Applications, IEEE Transactions on
