Channel Emulation
Keysight channel emulation solutions enable end-to-end real-world performance testing of wireless devices, network infrastructure equipment, and wireless local area network (WLAN) access points in a laboratory environment. Emulate radio conditions, model mobility, interference, and fading, and validate performance under a wide range of repeatable and controllable scenarios using a combination of hardware emulators and software tools. From OTA and mobile ad hoc network (MANET) scenarios to satellite and field-to-lab solutions, find the toolset that is right for your application. Need help selecting? Check out the resources below.
Evaluating FR3 and Next-Gen Networks
6G is predicted to connect physical, digital, and human worlds, shaping around new spectrum utilization, AI, digital twins, and new network architectures. See how to perform the upper mid-band (FR3) end-to-end testing in the lab, enabling the evaluation of new 6G technologies such as network sensing, extreme MIMO, and more with the Keysight AI-assisted radio channel emulation solutions.
Find Compatible Software and Accessories For Your Channel Emulator
Choose from a wide variety of channel emulator software for link emulation, fading profiles, and scenario modeling, as well as accessories such as transceiver and interface units, and more.
Explore Channel Emulator Use Cases
Channel emulators support a wide range of measurements across various industries, discover them all
Aerospace and Defense
How to Recreate Satellite Radio Links Between Network Entities
Re-create the satellite radio links between different network entities by understanding satellite trajectory dynamics, Doppler effects, and frequency errors.
Aerospace and Defense
How to Validate NTN Base Stations
Simulate a realistic lab-based environment with emulated end-user devices and satellite channels.
Wireless Communication
Set up a test to emulate real-world field conditions to verify 5G device performance under various mobility scenarios.
Aerospace and Defense
How to Test a NTN Unmodified Device
Compensate for the satellite-related delays and distortions by testing NTN unmodified devices in the lab under different conditions.
Wireless Communication
Perform 6G FR3 testing with geometry-based stochastic channel modeling and semi-deterministic and deterministic site-specific channel modeling.
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Frequently asked questions
Choosing the right channel emulator starts with the wireless device, network equipment, or access point you need to test and the real-world radio conditions you need to recreate. Different applications may require different capabilities for OTA validation, MIMO OTA testing, satellite and aerospace links, mobile ad hoc network (MANET) scenarios, RF field-to-lab workflows, or 6G FR3 research.
Look for a solution that can emulate radio conditions, model mobility, interference, and fading, and validate performance under repeatable and controllable scenarios. For advanced applications, consider whether the test setup needs high-performance RF signal processing, realistic OTA emulation, satellite delay and Doppler compensation, dynamic field-condition modeling, or software for link emulation, fading profiles, and scenario modeling.
Key channel emulator considerations include the number of RF channels, scalability, supported fading profiles, delay and Doppler capabilities, interference modeling, mobility modeling, and the ability to recreate complex radio channel conditions in the lab. These capabilities determine how effectively the emulator can reproduce the conditions a wireless signal experiences in real-world operation.
You should also consider the software and accessories needed for the full workflow. Channel emulator software can support link emulation, fading profiles, and scenario modeling, while accessories such as transceiver and interface units can help complete the test configuration for more complex wireless, OTA, satellite, MANET, or field-to-lab scenarios.
Channel emulators can be used to test wireless devices, network infrastructure equipment, and WLAN access points in a laboratory environment. They also support applications such as OTA validation, MIMO OTA testing, satellite and aerospace communications, non-terrestrial network testing, MANET and tactical radio ecosystems, 5G device benchmarking, and emerging 6G FR3 research.
The required setup depends on the application. 5G device testing may focus on real-world field conditions and mobility scenarios. Satellite and NTN testing may require emulated satellite channels, long delay compensation, Doppler effects, frequency errors, and link distortions. 6G FR3 research may require geometry-based stochastic channel modeling, semi-deterministic modeling, or deterministic site-specific channel modeling.
Channel emulators support modern wireless testing by recreating the multipath, fading, delay, Doppler, interference, and mobility effects that influence end-to-end system performance. In MIMO OTA environments, they help engineers test devices under realistic over-the-air conditions without relying only on uncontrolled field testing.
This is important for advanced wireless systems because performance depends on how devices and network equipment respond to complex and changing radio environments. For 5G, WLAN, NTN, and 6G FR3 workflows, channel emulation enables repeatable testing of realistic scenarios such as mobility, fading, satellite channel behavior, and extreme MIMO research conditions.
A channel emulator is typically part of a larger wireless test environment that may include hardware emulators, software tools, OTA systems, anechoic chambers, transceiver units, interface units, and application-specific test equipment. The goal is to recreate real-world radio conditions in the lab while maintaining control, repeatability, and measurement consistency.
For OTA, MIMO OTA, satellite, MANET, and RF field-to-lab workflows, integration should account for the complete signal path, scenario modeling, RF path behavior, mobility conditions, and repeatable test execution. Software for link emulation, fading profiles, and scenario modeling helps engineers configure and reproduce test conditions across development and validation workflows.
Common channel emulation challenges include recreating realistic field conditions, modeling complex fading and interference, scaling test setups for advanced scenarios, and maintaining repeatability across OTA, satellite, MANET, MIMO, and 6G research workflows. These challenges become more demanding when testing mobility, high Doppler shift, long delay compensation, or dynamic field environments.
They can be addressed by selecting a channel emulation solution matched to the application and by using the right combination of hardware, software, accessories, and scenario models. Field-to-lab workflows, fading profiles, link emulation, repeatable scenario control, and application-specific toolsets help engineers validate wireless performance with more confidence while reducing reliance on unpredictable field trials.