Reimagining interconnects: The expanding role of optical circuit switching in telecom, AI, and data infrastructure

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Why interconnects matter: The backbone of modern digital infrastructure

Interconnects are the silent enablers of digital transformation. Whether it is routing traffic across telecom core networks, enabling real-time AI inference, supporting lawful intercept operations, or ensuring seamless disaster recovery between data centers, the efficiency of interconnects determines how well systems perform.

As workloads become more distributed and data-intensive, the need for high-performance, low-latency, and energy-efficient interconnects has grown exponentially. This applies not only to computing clusters but also to telecom networks, surveillance systems and cloud-native architectures

How systems are interconnected

Traditionally, telecom and data systems relied on electronic packet switches - Ethernet, IP/MPLS, or InfiniBand - involving multiple Optical-Electrical-Optical (OEO) conversions. These conversions introduce latency and power overhead, which become significant at scale.

  • In telecom networks, it means slower routing, higher energy costs, and limited scalability.
  • In AI/ML clusters, it means bottlenecks in GPU-to-GPU communication.
  • In lawful intercept, it means delays in traffic capture and analysis.

OCS: A paradigm shift in interconnect technology

An Optical Circuit Switch (OCS) changes this paradigm. Instead of repeatedly converting optical signals to electrical form, OCS keeps the signal entirely in the optical domain - from source to destination. Think of it as a reconfigurable fiber patch panel but controlled by software in milliseconds. When two servers or racks need to communicate, the OCS creates a dedicated optical path between them - no packets to process, no queues, no buffers, no conversions.

Optical Circuit Switches use a variety of technologies including piezoelectric actuators, MEMS mirrors, liquid crystal or silicon photonics to steer light paths in a non-blocking, scalable manner.

Benefits of OCS over traditional technologie


Feature

Traditional OEO Switch

Optical Circuit Switch
Signal conversionOEO at each hopNone- remains optical
Latency    
 
Microseconds per hop
 
Nanoseconds end-to-end
 
Energy Consumption
 
High (due to electronics)
 
Ultra-low (passive optical path)
 
Bandwidth Scalability
 
Limited by ASIC I/O
 
Line-rate optical bandwidth
 
Determinism
 
Packetized and variable
 
Dedicated, predictable circuits
 
Maintenance
 
Complex and power-hungry
 
Simple, transparent, scalable

Use cases where OCS shines

OCS enables a true optical interconnect fabric - dynamic, high-capacity, and energy-efficient - ideal for:

  • Telecom Core Networks: Facilitates dynamic routing and bypassing congested nodes.
  • AI/ML Workloads: Facilitates high-bandwidth, low-latency interconnects between GPUs or accelerators in photonic fabrics.
  • Lawful Intercept: Enables secure, low-latency optical paths for monitoring traffic without packet inspection overhead.
  • Disaster Recovery: Allows rapid reconfiguration of optical paths between geographically distributed data centers.
  • Edge Computing and 5G: Supports flexible, scalable interconnects between edge nodes and central clouds.
Explore how Huber Suhner Polatis is shaping the future of connectivity:   www.polatis.com