Xilinx
Inc. has taped-out the first 20nm All Programmable Device with first
UltraScale ASIC-class programmable architecture. It is said to be the
semiconductor industry’s first 20nm device, and the PLD industry’s first
20nm All Programmable device. Xilinx implemented the industry’s first
ASIC-class programmable architecture called UltraScale.
These
milestones expand on Xilinx’s industry first 28nm tape-out, All
Programmable SoCs, All Programmable 3D ICs, and SoC-strength design
suite. Xilinx already has several firsts in the 28nm space, such as:
* First 28nm tape-out.
* First All Programmable SoC.
* First All Programmable 3D IC.
* First SoC-strength design suite.
Neeraj
Varma, director-Sales, India, said that Xilinx’s global market share in
the 28nm portfolio was 65 percent in March 2013. With the launch of the
industry’s first 20nm All Programmable Device with first UltraScale
ASIC-class programmable architecture, there are improvements such as
1.5-2x performance and integration, and a year ahead of the competition.
It handles massive I/O bandwidth, massive memory bandwidth, massive
data flow and routing, and fastest DSP processing. The architecture will
scale — from monolithic to 3D IC, planar to FinFET, and ASIC-class
performance.
The UltraSCALE architecture points to high
performance smarter systems. For example, 1Tps in OTN networking, 8K in
digital video, LTE-A in wireless communications, and digital array in
radar. There will be requirements for massive packet processing over 400
Gbps wire-speed, massive data flow over 5Tbps, as well as massive I/O
and memory bandwidth over 5Tbps, and DSP performance over 7 TMACs.
The
mandate for ASIC-class programmable architecture is to remove
bottlenecks for massive data flow and smart processing, high throughput
with low latency, and efficient design closure with greater than 90
percent utilization without performance degradation. These are the
benefits of applying leading edge ASIC techniques in a fully
programmable architecture.
ASIC-like clocking maximizes
performance margin for highest throughput. UltraSCALE ASIC-like
clocking enables clock placement virtually anywhere on the die, making
the clock skew problem go away. Also, highly optimized critical paths
remove bottlenecks in DSP and packet processing. There is greatly
enhanced DSP processing, high-speed memory cascading, and hardened IP
for I/O intensive functions.
Next generation power
management features also enable a leap in performance. The process node
is up to 35 percent static at 20nm. There are more buffers for granular
or coarse clock gating. Block RAM is dynamic power gating, hardened
cascading. For transceivers, there are architectural optimizations.
There is efficient packing and utilization of the logic fabric. For DSP,
there are wider multipliers and fewer blocks per function. As for
memory, there is DDR4, which operates at 1.2v vs.1.5v, voltage scaling.
The
Xilinx KINTEX UltraSCALE will power 4×4 mixed-mode radios, 100G traffic
manager NICs, super high-vision processing, 256-channel ultrasound and
48-channel T/R radar processing. The Xilinx VIRTEX UltraSCALE will power
400G OTN switching, 400G transponder, 400G MAC-to-Interlaken bridge,
2x100G muxponder and ASIC prototyping.
Xilinx worked
with TSMC to infuse high-end FPGA requirements into the TSMC 20SoC
development process, just as it had done in the development of 28HPL.
The Xilinx Vivado Design Suite early access supporting UltraScale
architecture-based FPGAs is now available. Initial UltraScale devices
will be available in Q4-2013.
Friday, July 19, 2013
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