Introduction
Telecom has advanced from 1G’s analog systems to 5G’s high-speed networks. 6G will revolutionize connectivity, supporting 7 billion smartphone users and 25 billion IoT devices by 2025, per Statista. The 6G wireless technology roadmap delivers ultra-low latency networks (<1 ms), Tbps speeds, and AI-driven systems for holographic communication and autonomous vehicles.
6G powers immersive applications with Tbps throughput. South Korea and China lead next-gen wireless, with Nokia and Samsung driving hardware innovation. This six-phase roadmap explores IEEE 6G Group standards, terahertz communication, and buy 6G chipsets opportunities. Learn more via the Android/iOS Mobile Apps Dev Roadmap 2025.
What’s Coming After 5G?
What’s coming after 5G? 5G offers 20 Gbps and 1–5 ms latency, but falls short for 2030’s IoT and immersive telecom demands. 6G targets 1 Tbps speeds, ultra-low latency (<1 ms), and 10x device density (10^7 devices/km²).
Terahertz communication (100 GHz–3 THz) enables real-time holography. 6G integrates AI for 100x telecom efficiency. South Korea’s Samsung and China’s Huawei test next-gen prototypes, guided by IEEE 6G Group. Next-gen wireless will transform connectivity.
Roadmap for 6G Wireless Technology
The roadmap for 6G wireless technology outlines six phases for transformative deployment by 2030.
Phase 1: Research & Standardization
Research, initiated in 2018, is led by the IEEE Next-Gen Wireless Group for IMT-2030 standards. 3GPP establishes KPIs for Tbps speeds and ultra-low latency. South Korea’s $325M MSIT fund and China’s IMT-2030 drive terahertz communication. Nokia’s Hexa-X ensures telecom interoperability.
Phase 2: Hardware Innovation
Next-gen wireless demands advanced chipsets. Nokia and Samsung develop terahertz multiplexers, with Samsung focusing on amplifiers and Nokia using PTFE materials. Source chipsets from Qualcomm by 2027 for prototyping.
Phase 3: Network Architecture Design
Future wireless integrates AI and edge computing for telecom. AI optimizes spectrum, achieving microsecond latency. South Korea’s K-Network 2030 and China’s trials ensure scalability. Nokia advances Open RAN for advanced connectivity.
Phase 4: Spectrum Allocation & Policy
Terahertz communication requires global spectrum allocation. ITU defines 7–20 GHz bands. South Korea and China test terahertz via satellites. Dynamic sharing supports ultra-low latency networks.
Phase 5: Pilot Deployments & Trials
South Korea and China launch trials in 2028–2029. South Korea’s Next-Gen Wireless Society tests 100 Gbps smart cities. China’s Huawei trials terahertz. Samsung validates future connectivity solutions.
Phase 6: Commercial Launch & Rollout
Advanced wireless launches in 2030 in South Korea and China. Global rollout requires $800B. Ultra-low latency networks enable XR applications. Nokia drives telecom readiness for next-gen connectivity.
Buy Next-Gen Wireless Chipsets: Transformative Industry Opportunities
To invest in chipsets for the roadmap to advanced wireless technology, focus on Qualcomm, Nokia, and Samsung. Telecom vendors evaluate chipsets for ultra-low latency and terahertz compatibility. SK Telecom supports testing for future connectivity solutions. Compliance with IEEE standards ensures readiness by 2028.
Spotlight on IEEE Next-Gen Wireless Group
The IEEE Next-Gen Wireless Group leads the roadmap for 6G wireless technology standardization, publishing terahertz communication whitepapers. IEEE 802.15 establishes 1 Tbps performance targets. The annual Summit fosters collaboration between Nokia and Samsung, shaping transformative telecom solutions for 2030.
Branded Case Study: Nokia & Samsung
Nokia and Samsung drive innovation in advanced wireless technology. Nokia’s Hexa-X project develops terahertz antennas, while Samsung’s UK trials achieve 206.25 Gbps speeds. Both align with IEEE standards to deliver ultra-low latency networks.
Global Case Studies (South Korea, China)
South Korea’s $200M K-Network initiative tests smart cities with future connectivity solutions, leveraging Samsung’s terahertz advancements. In China, Huawei trials satellites for next-gen wireless networks. Both collaborate with the IEEE group to set global standards.
Challenges and Future Projections
Next-gen wireless faces challenges like terahertz attenuation, $800B infrastructure costs, and security concerns. Quantum communication is poised to redefine telecom. The IEEE group must unify standards for ultra-low latency networks by 2030 to ensure a transformative future.
Conclusion
The roadmap for 6G wireless technology promises transformative Tbps speeds and ultra-low latency networks, revolutionizing telecommunications. This next-gen wireless enables real-time diagnostics in healthcare and instant decision-making for autonomous systems, reshaping industries by 2030.
South Korea, China, Nokia, and Samsung are at the forefront of innovation, guided by the IEEE 6G Group. Stakeholders should prioritize investments in advanced chipsets and terahertz communication to prepare for the future beyond 5G. Explore synergies with the Android/iOS Mobile Apps Development Roadmap 2025 to stay ahead. Act now to embrace the connected future of next-gen wireless.
