Company Filing History:
Years Active: 2009
Title: The Innovations of Etienne Puyoo
Introduction
Etienne Puyoo is a notable inventor based in St. Paul les Dax, France. He has made significant contributions to the field of optical measurement systems, particularly in the area of ultra-short light pulses. His innovative work has led to the development of a unique patent that enhances the efficiency and affordability of measuring light pulses.
Latest Patents
Etienne Puyoo holds a patent for "Systems and methods for measuring ultra-short light pulses." This patent describes a system that processes a number of substantially similar light pulses to measure their pulse length. The system utilizes an autocorrelation optical system that receives light pulses and creates two beams with an associated optical path length difference. By varying this optical path length for each light pulse, an autocorrelation interference pattern is generated, which is representative of the light pulse. The system includes an LED detector that captures this pattern and produces an autocorrelation signal. A signal-processing unit then calculates the pulse length based on the optical path length and the number of counted peaks in the autocorrelation signal. This measurement system is compact, cost-effective, and user-friendly compared to previous technologies.
Career Highlights
Etienne Puyoo is affiliated with the University of Central Florida Research Foundation, Inc. His work there has focused on advancing optical measurement techniques, contributing to both academic research and practical applications in the field.
Collaborations
Etienne has collaborated with notable colleagues such as Robert Bernath and Martin C Richardson. Their combined expertise has furthered the development of innovative solutions in optical measurement.
Conclusion
Etienne Puyoo's contributions to the field of optical measurement through his patent on ultra-short light pulses exemplify his innovative spirit and dedication to advancing technology. His work continues to influence the way light pulses are measured, making significant strides in both research and practical applications.