Simulate, analyze, and test the physical layer of LTE and LTE-Advanced wireless communications systems
LTE Toolbox™ provides standard-compliant functions and apps for the design, simulation, and verification of LTE, LTE-Advanced, and LTE-Advanced Pro communications systems. The system toolbox accelerates LTE algorithm and physical layer (PHY) development, supports golden reference verification and conformance testing, and enables test waveform generation.
With the toolbox you can configure, simulate, measure, and analyze end-to-end communications links. You can also create and reuse a conformance test bench to verify that your designs, prototypes, and implementations comply with the LTE standard.
Using LTE Toolbox with RF instruments or hardware support packages, you can connect transmitter and receiver models to radio devices and verify your designs via over-the-air transmission and reception.
Generate downlink physical signals, physical channels, transport channels, and control information.
Generate uplink physical signals, physical channels, transport channels, and control information.
Propagation Channel Models
Characterize and simulate 3D channels, MIMO fading channels (EPA, EVA, and ETU), and moving high-speed train MIMO channels.
Perform link-level BER, BLER, and throughput conformance tests.
Configure downlink and uplink reference measurement channels.
Perform uplink and downlink measurements, including EVM, ACLR, and in-band emissions.
Build UMTS reference measurement channel (RMC) configuration structures and generate UMTS waveforms.
Downlink and Uplink Receivers
Perform LTE downlink and uplink operations, including frame synchronization, frequency offset, frequency correction, channel estimation, and zero-forcing and MMSE-based equalization.
Signal Recovery Procedures
Model UE detection, cell identity search, MIB decoding, and SIB1 recovery.
Model narrowband Internet-of-Things (NB-IoT) uplink and downlink transport and physical signals.
Model the Release 13 (Cat-M1) and Release 14 (Cat-M2) LTE-M uplink and downlink transport and physical signals.
Transmit LTE waveforms from MATLAB using RF instruments or software-defined radios (SDR).
Acquire and analyze over-the-air received signals in MATLAB using RF instruments or software-defined radios.
Physical Layer Subcomponents
Use low-level downlink and uplink physical layer functions as a golden reference for implementations of your LTE designs.
NB-IoT Uplink Shared Channel Modeling
Generate and decode the narrowband Internet of Things (NB-IoT) uplink shared channel
Support for NPUSCH Channel Processing and DRS Generation
Generate and decode the narrowband physical uplink shared channel (NPUSCH) using its demodulation reference signals (DRSs)
NB-IoT Uplink Practical Synchronization and Channel Estimation
Measure the timing offset and estimate the channel of NB-IoT uplink slots
1024-QAM LTE E-TM presets in wireless waveform generator app
Generate, visualize and transmit 2b & 3.1b LTE 1024-QAM E-TM waveforms using the wireless waveform generator app.