Company Filing History:
Years Active: 2015-2019
Title: Innovations of Jae-Jin Lee
Introduction
Jae-Jin Lee is a prominent inventor based in Tuscaloosa, Alabama. He has made significant contributions to the field of technology, particularly in the development of advanced antenna modules and magnetic supercapacitors. With a total of four patents to his name, Lee's work showcases his innovative spirit and dedication to enhancing electronic devices.
Latest Patents
One of Jae-Jin Lee's latest patents is for antenna modules having ferrite substrates. This invention features an antenna formed on a ferrite substrate, which is strategically positioned within a small direct current (DC) magnetic field. By controlling the magnetic loss tangent of the ferrite through the application of this magnetic field, the antenna's radiation efficiency is improved, and its bandwidth is increased. Another notable patent is for magnetic supercapacitors. This invention includes a dielectric layer situated between magnetic layers, which may consist of hard or soft magnetic materials. The magnetic flux generated by these layers enhances the permittivity of the dielectric layer, thereby increasing the capacitance and stored energy of the supercapacitor. Additionally, the capacitance can be varied by controlling the current passing through a conductive segment near the magnetic layers.
Career Highlights
Jae-Jin Lee is affiliated with the University of Alabama, where he continues to pursue his research and innovation in the field of electronics. His work has garnered attention for its potential applications in various technologies, making him a valuable asset to the academic and research community.
Collaborations
Some of Jae-Jin Lee's notable coworkers include Yang-Ki Hong and Seok Bae. Their collaborative efforts contribute to the advancement of research and innovation in their respective fields.
Conclusion
Jae-Jin Lee's contributions to technology through his patents reflect his commitment to innovation and excellence. His work in antenna modules and magnetic supercapacitors demonstrates the potential for advancements in electronic devices.