Narasimha Prasad Salagame Nagaraj

Title: Innovations by Narasimha Prasad Salagame Nagaraj

Introduction

Narasimha Prasad Salagame Nagaraj is a notable inventor based in Sunnyvale, CA. He has made significant contributions to the field of technology, particularly in networking solutions. With a total of 2 patents, his work focuses on enhancing control plane mechanisms for dense topologies.

Latest Patents

Narasimha's latest patents include a groundbreaking approach titled "Hierarchical ECMP control plane for dense topologies." This invention introduces techniques and mechanisms for a control plane that emphasizes discovering shared Equal-Cost Multi-Path (ECMP) groups. This approach operates independently of per-prefix learning, allowing for the learning of prefixes through these shared ECMP groups. In dense topologies, this innovation minimizes BGP path scale and corresponding signaling, enabling control plane scaling that is significantly higher than traditional eBGP control planes. Furthermore, during link and node topology changes, this control plane approach facilitates prefix-independent signaling, resulting in a lower order of magnitude in signaling requirements. The method also supports prefix-independent convergence (PIC) in scenarios that would otherwise be unachievable with traditional FIB-driven path-list sharing.

Career Highlights

Narasimha Prasad Salagame Nagaraj is currently employed at Cisco Technology, Inc., where he continues to develop innovative solutions in networking. His expertise in control plane technologies has positioned him as a valuable asset to the company.

Collaborations

He has collaborated with notable colleagues such as Neeraj Malhotra and Satya Ranjan Mohanty, contributing to various projects that enhance networking technologies.

Conclusion

Narasimha Prasad Salagame Nagaraj's contributions to the field of networking through his patents and work at Cisco Technology, Inc. highlight his innovative spirit and dedication to advancing technology. His inventions are paving the way for more efficient networking solutions in dense topologies.