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Ixiasoft
Visible to Intel only — GUID: hco1423076698447
Ixiasoft
6.13. DSP Builder Reference Designs
This folder accesses groups of reference designs that illustrate the design of DDC and DUC systems for digital intermediate frequency (IF) processing.
The first group implements IF modem designs compatible with the Worldwide Interoperability for Microwave Access (WiMAX) standard. Intel provides separate models for one and two antenna receivers and transmitters.
The second group implement IF modem designs compatible with the wideband Code Division Multiple Access (W-CDMA) standard.
This folder also contains reference designs.
STAP for radar systems applies temporal and spatial filtering to separate slow moving targets from clutter and null jammers. Applications demand highprocessing requirements and low latency for rapid adaptation. High-dynamic ranges demand floating-point datapaths.
- 1-Antenna WiMAX DDC
This reference design uses IP and Interface blocks to build a 2-channel, 1-antenna, single-frequency modulation DDC for use in an IF modem design compatible with the WiMAX standard. - 2-Antenna WiMAX DDC
This reference design uses IP and Interface blocks to build a 4-channel, 2-antenna, 2-frequency modulation DDC for use in an IF modem design compatible with the WiMAX standard. - 1-Antenna WiMAX DUC
This reference design uses IP, Interface, and Primitive library blocks to build a 2-channel, 1-antenna, single-frequency modulation DUC for use in an IF modem design compatible with the WiMAX standard. - 2-Antenna WiMAX DUC
This reference design uses IP, Interface, and Primitivelibrary blocks to build a 4-channel, 2-antenna, single-frequency modulation DUC for use in an IF modem design compatible with the WiMAX standard. - 4-Carrier, 2-Antenna W-CDMA DDC
This reference design uses IP and Interface blocks to build a 16-channel, 2-antenna, multiple-frequency modulation DDC for use in an IF modem design compatible with the W-CDMA standard. - 1-Carrier, 2-Antenna W-CDMA DDC
This reference design uses IP and Interface blocks to build a 4-channel, 2-antenna, single-frequency modulation DDC for use in an IF modem design compatible with the W-CDMA standard. - 4-Carrier, 2-Antenna W-CDMA DUC
This reference design uses IP and Interface blocks to build a 16-channel, 2-antenna, multiple-frequency modulation DUC for use in an IF modem design compatible with the W-CDMA standard. - 4-Carrier, 4-Antenna DUC and DDC for LTE
- 1-Carrier, 2-Antenna W-CDMA DDC
This reference design uses IP and Interface blocks to build a 4-channel, 2-antenna, single-frequency modulation DUC for an IF modem design compatible with the W-CDMA standard. - 4-Carrier, 2-Antenna High-Speed W-CDMA DUC at 368.64 MHz with Total Rate Change 32
This reference design uses IP and Interface blocks to build a high-speed 16-channel, 2-antenna, multiple-frequency modulation DUC for use in an IF modem design compatible with the W-CDMA standard. - 4-Carrier, 2-Antenna High-Speed W-CDMA DUC at 368.64 MHz with Total Rate Change 48
This reference design uses IP and Interface blocks to build a high-speed 16-channel, 2-antenna, multiple-frequency modulation DUC for use in an IF modem design compatible with the W-CDMA standard. - 4-Carrier, 2-Antenna High-Speed W-CDMA DUC at 307.2 MHz with Total Rate Change 40
This reference design uses IP and Interface blocks to build a high-speed 16-channel, 2-antenna, multiple-frequency modulation DUC for use in an IF modem design compatible with the W-CDMA standard - Cholesky-based Matrix Inversion
The DSP Builder Cholesky-based Matrix Inversion reference design offers an efficient implementation of matrix inversion for minimized resource utilization and improved latency and throughput. - Cholesky Solver Multiple Channels
The Cholesky Solver Multiple Channels reference design performs Cholesky decomposition to solve column vector x in Ax = b - Crest Factor Reduction
This reference design implements crest factor reduction, based on the peak cancelling algorithm. - Direct RF with Synthesizable Testbench
This very large reference design implements a digital upconversion to RF and digital predistortion, with a testbench that you can synthesize to hardware for easier on-chip testing. - Dynamic Decimating FIR Filter
The dynamic decimating FIR reference design offers multichannel run-time decimation ratios in integer power of 2 and run-time control of channel count (in trading with bandwidth).The design supports dynamic channel count to signal bandwidth trade off (if you halve the channel count, the input sample rate doubles). - Multichannel QR Decompostion
This reference design is a complete linear equations system solution that uses QR decomposition. - QR Decompostion
This reference design is a complete linear equations system solution that uses QR decomposition. - QRD Solver
The QRD Solver reference design is a complete linear equations system solution using QR decomposition. The input of the design is a system matrix A [n x m] and input vector [b]. - Reconfigurable Decimation Filter
The reconfigurable decimation filter reference design uses primitive blocks to build a variable integer rate decimation FIR filter. - Single-Channel 10-MHz LTE Transmitter
This reference design uses IP, Primitive, and blocks from the FFT Blockset library to build a single-channel 10-MHz LTE transmitter. - STAP Radar Forward and Backward Substitution
The QR decomposition reference design produces an upper triangular matrix and a lower triangular matrix. - STAP Radar Steering Generation
The STAP radar steering generation reference design uses ForLoop blocks and floating-point primitives to generate the steering vector. You input the angle of arrival and Doppler frequency. - STAP Radar QR Decomposition 192x204
The QR decomposition reference design implements a sequence of floating-point vector operations. - Time Delay Beamformer
The time delay beamformer reference design implements a time-delay beamformer that has many advantages over traditional phase-shifted beamformer. It uses a (full-band) Nyquist filter and Farrow-like structure for optimal performance and resource usages. - Transmit and Receive Modem
The transmit and receive modem design contains a QAM transmitter, a synthesizeable channel model and a receiver, working at sample rates that match or exceed the clock rate. The design works at different sample rates, and can provide up to 16 parallel data streams between transmitter and receiver. - Variable Integer Rate Decimation Filter
The variable integer rate decimation filter reference design implements a 16-channel interpolate-by-2 symmetrical 49-tap FIR filter. The target system clock frequency is 320 MHz.