5g

Seamless mobility between 5G Core (5GC) and EPS is enabled by N26 and indirect data forwarding. Here’s a detailed breakdown of signaling, architecture, and process flow.

RAN functional splits define how network functions are divided across CU, DU, and RU in 4G and 5G. Here’s a deep dive into the architecture, benefits, and trade-offs.

Ericsson’s Performance Optimizer Architecture automates diagnostics, root cause analysis, and optimization, ensuring smarter, faster, and more reliable networks.

The 5G link budget is key to network design. Explore how transmit power, antenna gain, and receiver sensitivity determine signal coverage and quality.

Open RAN enables flexibility and multi-vendor ecosystems but introduces new security challenges. Learn about risks, vulnerabilities, and how operators can mitigate them.

Discover how 5G integrates RAN, CN, and MEC under common infrastructure, enabling open interfaces, automation, and efficient orchestration for future-ready networks.

The RIC roadmap shows how 5G networks evolve from automated call configuration to advanced, multi-layered optimization across RAN and ICT resources.

Discover how 5G NR uses sub-6 GHz and mmWave spectrum bands to deliver ultra-fast speeds, low latency, and reliable connectivity across diverse applications.

5G uses low-band, mid-band, and mmWave spectrum to balance coverage, capacity, and speed. Discover how each frequency band powers the future of telecom.

5G mmWave spectrum spans 24–300 GHz, enabling ultra-fast speeds and massive capacity. Here’s a breakdown of key bands, spectrum sharing, and telecom use cases.