6G Communications
Learn the essentials of 6G
Next-Generation Wireless: A Guide to the Fundamentals of 6G
This 6G eBook breaks down the new technologies and use cases for the evolution of wireless communication technology and gives you everything you need to build a foundation of 6G knowledge.
Shaping the 6G Future with a Keysight Network Digital Twin
Learn how AI models for 6G will be simulated and optimized in the digital twin before being deployed in the physical network.
Collaborative Synergy: The Key to Unlocking 6G’s Potential
Learn how areas synergistic 6G wireless technology use cases in smart everything, sensing, and global coverage are set to unlock the potential of 6G.
Top Five Questions About 6G Technology
Discover the most common questions surrounding 6G and gain more insight into the vision for 6G and how it will achieve critical goals.
Featured courses
Discover 6G research areas
Sub-Terahertz Test Bed for 6G Research Demo
This demo walks you through the Keysight R&D sub-terahertz test bed for 6G research.
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6G: Go deeper
Explore 6G and its role in accelerating innovation across industries with these resources and insights from Keysight
Related use cases
How To Characterize 6G Components
Characterizing sub-THz components for 6G requires more than S-parameters to be comprehensive. Noise figure, gain compression, and error vector magnitude as well as a number of other modulated measurements are needed to create a complete picture to predict component performance in a system.
How to Characterize 6G Sub-THz Wideband Signals
Engineers researching 6G require a wideband modulated signal generator with a high carrier frequency signal to evaluate the behavior of 6G modulated signals. Conducting tests in the sub-THz H-band requires an arbitrary waveform generator in place of a standalone vector signal generator, to overcome limitations in intermediate frequency (IF) bandwidth and modulation bandwidth.
How to Perform 6G FR3 System Test
6G frequency range three (FR3) system test requires phase and time-coherent multichannel emulation using semi-deterministic and deterministic channel models. Key performance metrics for 6G FR3 testing include beamforming gain, beam width, and sidelobe levels from the physical layer (PHY) to the application layer.
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