Gaganpreet Singh

NR-ARFCN (New Radio Absolute Radio Frequency Channel Number) defines how 5G identifies and calculates carrier frequencies across sub-6 GHz and mmWave bands. Here’s a complete, technical yet easy-to-understand breakdown.

Discover how NR-ARFCN (Absolute Radio Frequency Channel Number) operates in 5G FR2 (>6GHz) bands. Learn about frequency mapping, duplex modes, and 5G mmWave bands for optimized network performance.

NR-ARFCN defines how 5G New Radio channels are mapped across different frequency bands. Discover how ARFCN works for FR1 (<6GHz) and why it’s crucial for 5G network design and performance.

CUPS (Control and User Plane Separation) in EPC enhances 4G and 5G networks by separating control and user planes. Learn how this architecture improves scalability, flexibility, and latency performance across telecom systems.

Learn how MEC applications interact across UE, edge, and cloud layers, enabling ultra-low latency, efficient traffic routing, and real-time service delivery in 5G networks.

Discover how beamforming enhances 5G and future wireless networks by using multiple antenna elements to focus energy, reduce interference, and boost performance.

Explore how beamforming and null steering enhance 5G networks by dynamically directing antenna beams toward users while minimizing interference and maximizing coverage.

Learn how the NFV Architecture Framework transforms telecom networks by virtualizing network functions through VNFs, MANO, and NFVI layers for agility and scalability.

Learn how the synergy between 3GPP and ETSI MEC architectures enables next-generation edge computing with ultra-low latency, intelligent orchestration, and seamless 5G integration.

Learn how the MEC-in-NFV reference architecture combines edge computing and network virtualization to create scalable, automated, and high-performance telecom networks.