Jan Jeske

Title: Innovations of Jan Jeske in Magneto-Encephalography

Introduction

Jan Jeske is an accomplished inventor based in Fitzroy North, Australia. She has made significant contributions to the field of magneto-encephalography, with a focus on developing advanced devices for measuring magnetic fields. With a total of two patents to her name, Jan's work is at the forefront of innovative technology in neuroscience.

Latest Patents

Jan Jeske's latest patents include a magneto-encephalography device and a laser-based sensor for measuring external magnetic fields. The magneto-encephalography device features a plurality of laser threshold magnetometers designed to measure magnetic fields. Each magnetometer consists of an optical cavity, a laser medium, a laser pump, and a radio-frequency drive. This configuration allows for precise measurements of magnetic fields by inducing transitions between different states of the laser medium. The device is intended to be placed on the head of a subject for monitoring purposes.

The second patent, a laser-based sensor, is aimed at measuring external magnetic fields. Similar to the magneto-encephalography device, it includes an optical cavity, a laser medium, and a radio-frequency drive. The sensor's design allows for variations in the laser threshold based on changes in the external magnetic field, providing accurate measurements of the field's value.

Career Highlights

Jan has worked with notable institutions such as RMIT University and the Royal Melbourne Institute of Technology. Her experience in these organizations has contributed to her expertise in the field of magneto-encephalography and laser technology.

Collaborations

Jan has collaborated with esteemed colleagues, including Andrew Greentree and Jared Cole. These partnerships have further enhanced her research and development efforts in innovative technologies.

Conclusion

Jan Jeske's contributions to the field of magneto-encephalography through her innovative patents demonstrate her commitment to advancing technology in neuroscience. Her work continues to pave the way for future developments in measuring magnetic fields.