Company Filing History:
Years Active: 2017-2018
Title: Mohammed Petiwala: Innovator in Timing Packet Security
Introduction
Mohammed Petiwala is a notable inventor based in Wheeling, IL (US). He has made significant contributions to the field of network security, particularly in the area of timing packet synchronization. With a total of 2 patents, his work focuses on enhancing the security and accuracy of timing protocols over untrusted networks.
Latest Patents
One of Mohammed's latest patents is a method and apparatus for securing timing packets over untrusted packet transport networks. This invention provides methods, devices, systems, techniques, and computer program products designed to secure timing synchronization for network nodes connected over inherently insecure public networks. The patent includes mechanisms to improve the accuracy of timing protocols, such as a statistically estimated edge timestamp offset encoded into the timing message. This accounts for network jitter and processing latency variances due to security packet processing and encryption. Additionally, it ensures that slave network nodes only accept timing messages from trusted sources, establishes a secure tunnel for timing packet exchange, and enhances message anonymity with variable payload padding.
Career Highlights
Mohammed Petiwala is currently employed at Nokia Solutions and Networks Oy, where he continues to innovate in the field of network security. His work is crucial in developing secure communication protocols that are essential for modern networking.
Collaborations
Some of his notable coworkers include David T Chen and Umamaheswar Achari Kakinada. Their collaboration contributes to the advancement of technologies that enhance network security and reliability.
Conclusion
In summary, Mohammed Petiwala is a distinguished inventor whose work in securing timing packets over untrusted networks is paving the way for more reliable and secure communication systems. His contributions are vital in addressing the challenges posed by insecure public networks.