Title: Innovations by Chung Lee
Introduction
Chung Lee is an accomplished inventor based in the United States. He has made significant contributions to the field of fiber optic technology, particularly in distributed temperature sensing systems. His innovative approaches have led to advancements that enhance the accuracy and range of temperature measurements.
Latest Patents
Chung Lee's latest patents include "Dual Source Auto-Correction In Distributed Temperature Systems." This patent presents an automatic and continuous method to improve the accuracy of fiber optic distributed temperature measurements derived from Raman back scatterings. It utilizes two light sources with different wavelengths, ensuring that the primary source's return anti-Stokes component overlaps with the incident wavelength of the secondary light source. This overlap effectively cancels out the non-identical attenuations generated by the wavelength differences between Stokes and anti-Stokes bands. Another notable patent is "Methods And Systems For Extending The Range Of Fiber Optic Distributed Temperature Sensing (DTS) Systems." This patent outlines systems and methods for extending the range of a fiber optic DTS system, detailing steps for transmitting optical signals at varying energy levels and collecting backscatter signals to determine parameter profiles, such as temperature profiles.
Career Highlights
Chung Lee is currently employed at Sensortran, Inc., where he continues to develop innovative solutions in the field of temperature sensing. His work has been instrumental in advancing the capabilities of fiber optic technology.
Collaborations
Chung collaborates with talented individuals such as Kent Kalar and Mahesh Ajgaonkar, contributing to a dynamic team focused on innovation and excellence in their field.
Conclusion
Chung Lee's contributions to fiber optic technology and distributed temperature sensing systems highlight his role as a significant inventor in the industry. His innovative patents and collaborative efforts continue to push the boundaries of what is possible in temperature measurement technology.