Company Filing History:
Years Active: 2021
Title: Duorui Gao: Innovator in High-Speed Laser Communication Systems
Introduction
Duorui Gao is a prominent inventor based in Shaanxi, China. He has made significant contributions to the field of laser communication systems, particularly in developing technologies that enhance modulation format compatibility. With a total of 2 patents, his work is paving the way for advancements in high-speed communication.
Latest Patents
Duorui Gao's latest patents include a "Multi-modulation-format compatible high-speed laser signal generation system and method." This invention greatly improves the modulation format compatibility of laser communication systems, thereby reducing system upgrading and resource costs. The system comprises several key components, including a control instruction unit, a serial-parallel changeover switch unit, and an IQ modulator, among others.
Another notable patent is the "Phase-lock-free system and method for receiving multi-modulation-format compatible high-speed laser signal." This system enhances the compatibility of communication systems at relay nodes within existing laser communication networks. It features a control instruction unit, a low-noise high-gain optical amplifier, and multiple optical delay interferometers, which work together to improve signal reception.
Career Highlights
Duorui Gao is affiliated with the Chinese Academy of Sciences, where he continues to innovate and contribute to research in laser communication technologies. His work is recognized for its practical applications and potential to transform communication systems.
Collaborations
Duorui Gao collaborates with esteemed colleagues such as Xiaoping Xie and Xinning Huang. Their combined expertise fosters an environment of innovation and progress in their research endeavors.
Conclusion
Duorui Gao's contributions to high-speed laser communication systems exemplify the impact of innovative thinking in technology. His patents not only advance the field but also offer practical solutions to existing challenges in communication systems.