| Project Detail |
Optimising magnetic field sensors for use in more industrial applications
From transport to medicine, magnetoresistive sensors are a type of magnetic field sensor that has become ubiquitous. Designed to sense an applied magnetic field, these low-cost components are small and operate on very little power. However, several limitations keep them from reaching their full potential in a broad range of applications. Funded by the European Research Council, the NANOSENSE project intends to build on the proof of concept for a magnetic field sensor that has already been proposed and patented. It will demonstrate the sensor’s excellent performance, then follow this up with commercialisation and licensing involving a sensors manufacturer.
Magnetic sensors are present everywhere in our daily lives. We often use them in cars, robotics, medical applications, for power sensing, electronic compass, etc. Among them, magnetoresistive sensors play an increasing role thanks to their relatively small size, good sensitivity and low cost. However, magnetoresistive sensors saturate above typically a few milli-Tesla which is too low for a number of applications. Besides, reducing the sensor footprint is important in terms of costs. In addition, smaller sensors have also a reduced power consumption which is very important for wearable applications and sensors used in Internet of Things. Therefore, it is commercially desirable to be able to develop a low cost, nano-size, magnetoresistive sensor in which the dynamic range could be extended and easily adjusted in the range 80mT-400mT commonly used in linear or angular encoders.
Within an ERC project which just ended entitled “CMOS/Magnetoelectronic Integrated Circuits
with Multifunctional Capabilities”, a novel concept of magnetic field sensor sensitive to out-of-plane field was proposed and patented. Initial experiments performed within this ERC project provided very promising results. The purpose of this ERC project is to make a full proof of concept of this sensor demonstrating its outstanding performance and subsequently move towards a start-up creation or licensing of the technology to an existing sensors manufacturer. Within NANOSENSE, we aim to achieve gains over existing sensors by 10x in terms of footprint reduction, 50x in power consumption, 10x in signal to noise ratio while increasing the sensing range up to ~800mT. This will make these sensors suitable for integration in sensors network for IoT, sensors for wearable applications, automotive, detection of leakage current in electronic circuits, detection of microcracks in metals, navigation of surgical tools (e.g.endoscopes). |
