epiphany

Epiphany Architecture Promises Massive Floating-Point Gains

Epiphany Architecture

Earlier this month BittWare announced “A New Approach to Floating Point DSP” with the release of the Anemone Co-Processor. The Anemone floating point co-processor chip is designed for use with Altera’s high performance FPGAs. OEM’d from Adapteva’s new Epiphany architecture, BittWare’s Anemone chip is a scalable, true C-programmable, floating point engine that enables novel solutions for complex and evolving signal processing applications.

It’s something which has already caught the eye of FPGA and DSP specialist BittWare, which has licensed Adapteva’s Epiphany technology for use in its own Altera-based FPGAs under the name Anemone. “We believe that Adapteva’s Epiphany architecture represents a flash of brilliance that reintroduces some much needed creativity into the embedded signal processing world,” BittWare’s chief Jeff Milrod crowed at the launch of Anemone. “The resulting Anemone chip, combined with Altera’s family of FPGAs, creates an insanely cool solution for complex signal processing tasks that can be optimised for power, performance, and productivity.”

So what is Epiphany? Here’s the opening section of an interview with Andreas Olofsson of Adapteva with THINQ:

While chip giants ARM, Intel, and AMD battle for control of your smartphones and PCs, a small company in Massachusetts called Adapteva is starting a revolution: many-core processors that offer a significant performance boost over anything currently on the market. We chat to its founder Andreas Olofsson to find out what’s going on.

Initially, it’s easy to dismiss Adapteva’s chances of success as slim to none: in markets where a single processor architecture holds overwhelming dominance, such as x86 in mainstream computing and ARM in the world of smartphones, Olofsson has decided to develop an entirely new architecture.

Olofsson readily admits that history is littered with companies who have tried the same approach and failed. “In the mobile space there’s MIPS, for example,” he explained to thinq_ during our interview. “That’s another architecture, which has been around for 25, 30 years now – you know, it’s a great architecture, and yet they have very low traction. Everybody – 98 per cent of the market – uses ARM.”

To avoid falling into the same trap, Olofsson has a new idea – or, specifically, a variation on an old one. In the early days of personal computing, it was common for a central processor to have a ‘math co-processor’ chip alongside it – a secondary processor which was designed specifically to carry out floating point arithmetic at speeds significantly faster than the main processor. Intel had its 8087, Motorola its 68881, and AMD the stand-alone 9511.

Over time, however, these chips became integrated into the processor itself – evolving into the high-performance floating-point units, or FPUs, that are a feature of all modern central processors. Olofsson’s big idea, he explained, is to bring the days of the math co-processor back – and promises some major performance-per-watt gains for those making the step.

Read more / Source – THINQ

See Also – Wall Street Journal, BittWare Anemone, Adapteva