Technical InsightsDesigning Next-Generation Wireless Systems: an FPGA-centric approach using XtremeDSP and Serial RapidIO solutionsBy Narinder Lall, Senior Manager, DSP Product and Solutions Marketing, Xilinx, Inc., narinder.lall@xilinx.comThe demands of next-generation wireless infrastructures require system designers to address not only processing bottlenecks, but connectivity bottlenecks. Today’s domain optimized FPGAs provide the ideal mix of high-performance DSP to handle the most demanding chip-rate and radio algorithms and serial MGTs, addressing high-speed connectivity and interoperability challenges. Tomorrow’s wireless infrastructure equipment designers will face an increase in algorithmic complexity and data rate brought on by the convergence of data, video, and voice. Solutions based on discrete devices such as microprocessors, DSPs, and transceivers provide tremendous headaches related to interoperability and latency, and can quickly drive up both cost and power per channel. An FPGA-centric approach that combines high-performance DSP capability and Serial RapidIO will help alleviate some of these system performance bottlenecks and provide an integrated solution that better meets economic and energy constraints. In addition, an FPGA-centric approach provides designers with the flexibility to recover from mistakes and make hardware changes even after system deployment, thereby reducing overall design risk.  Figure 1 The DSP Industry Embraces Serial RapidIO Designers have implemented ASICs – and more increasingly FPGAs – in wireless systems to handle digital radio (modulation/demodulation, DDC/DUC) and high-chip-rate processing. FPGAs exploit parallel processing techniques through hard-wired embedded multipliers and provide the flexibility to make algorithmic changes even after system deployment, saving millions in maintenance or field upgrade costs. Second, the need to transport such high information packets presents new connectivity challenges. Traditional buses are fast running out of bandwidth. Wide parallel buses are becoming too complicated to design and increasingly difficult to scale. As serial I/O technology begins to mature, wireless infrastructure equipment designers are looking towards system interconnect architectures based on MGTs to handle their transport problems. This gives rise to potential chip-to-chip and board-to-board interoperability headaches for system designers. What is encouraging is that leading DSP IC suppliers that supply chip-rate and symbol-rate processing solutions (such as Texas Instruments™, Motorola™, and Xilinx®) are at the forefront of the Serial RapidIO revolution and are keen to address connectivity and interoperability challenges in next-generation wireless infrastructure systems.  Figure 2 Figure 2: High performance domain-optimized FPGAs incorporate embedded high-performance DSP capability, Serial RapidIO connectivity, and control functions through embedded PowerPC™ 405 processors. As chip-rate processors, FPGAs provide an ideal complement to DSP processors, which have traditionally been used for lower sample- and symbol-rate processing. Serial RapidIO Benefits Using FPGAs
One such implementation could use an FPGA solely as a central switch between chip and symbol-rate devices. Conclusion |
