Self-Oscillating Fluxgate-Based Quasi-Digital Sensor for DC High-Current Measurement

A quasi-digital dc current sensor with rated current of ±600 A while overload current of about ±750 A is proposed in this paper. The new sensor is based on the open-loop self-oscillating fluxgate technology, but its originality is using a microcontroller unit to detect the duty cycle of the exciting...

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Bibliographic Details
Published in:IEEE transactions on instrumentation and measurement 2015-12, Vol.64 (12), p.3555-3563
Main Authors: Wang, Nong, Zhang, Zhonghua, Li, Zhengkun, Zhang, Yang, He, Qing, Han, Bing, Lu, Yunfeng
Format: Article
Language:English
Subjects:
Accuracy
Current measurement
Current sensor
current transducer
high-current measurement
Linearity
Microcontrollers
quasi-digital sensor
self-oscillating fluxgate
Stability analysis
Transducers
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Summary:A quasi-digital dc current sensor with rated current of ±600 A while overload current of about ±750 A is proposed in this paper. The new sensor is based on the open-loop self-oscillating fluxgate technology, but its originality is using a microcontroller unit to detect the duty cycle of the exciting voltage of the fluxgate. Compared with the published similar method, the whole signal chain of the new sensor is quasi-digital and without low-pass filter and analog-to-digital converter required when connected to digital systems. A precisely theoretical equation with respect to the linear dependence between the duty cycle and the current to be measured is established. Based on the equation, factors affecting the sensor sensitivity, accuracy, and resolution are determined, which constitutes the theoretical basis on the optimization design of the new sensor. The sensor linearity is improved using the least-squares polynomial fitting method. Some key specifications including the linearity, repeatability, and power supply effect of the sensor are characterized. The measurement results show that the linearity of the new sensor with the theoretical equation is better than 1.7% in the full scale of ±600 A, and can be improved to 0.3% when the fifth-order polynomial fitting method is used.
ISSN:0018-9456
1557-9662
DOI:10.1109/TIM.2015.2444258