Periodic Reporting for period 2 - EPIC (Enabling Practical Wireless Tb/s Communications with Next Generation Channel Coding)
Período documentado: 2019-03-01 hasta 2020-08-31
• to advance state-of-the-art and design next generation FEC for wireless Tb/s technology and Beyond-5G systems.
• to devise a disruptive FEC design framework to unify algorithmic and implementation domains.
• to validate and demonstrate the developed FEC technology in virtual silicon tape-out and provide first-in-class wireless Tb/s FEC architecture blocks.
• to put the scientific excellence and contributions to wireless industry in the domain of B5G standardization and technology development at the centre of the project execution.
EPIC key performance metrics (KPI) in advanced semiconductor technology nodes, i.e. 7nm, are throughput in the order of 1 Tb/s, an energy efficiency of about 1 pJ/bit, and an area efficiency > 0.1 Tb/s/mm2, while meeting communications and flexibility requirements derived from selected EPIC use-case.
For turbo code we investigated: a new architecture-aware interleaver design that lowers the error floor and enables flexibility for unrolled high throughput architectures; a new low complexity soft-output decoding algorithm that largely reduces the implementation complexity at negligible degradation in error correction capability; a new high throughput unrolled architectural template and its virtual silicon implementation that outperforms state of the art by 2 orders of magnitude in throughput and one order of magnitude in area efficiency with outstanding communications performance.
For LDPC codes we investigated: new protograph based LDPC block codes that are optimized for low number of iterations and frame interleaved architectures and corresponding spatially coupled LDPC codes; architectural templates for unrolled block LDPC decoder, multi-core frame-based block LDPC decoder, unrolled layered block LDPC decoder, layered windowed SC-LDPC decoder, unrolled window SC-LDPC decoder and a LDPC decoder exploration framework that automatically generates these decoder architectures; virtual silicon implementations for all architectures and an in-depth investigation of the trade-offs and comparison of these different architectures, that go especially w.r.t. implementation efficiency far beyond state-of-the-art.
For polar codes we investigated: new codes that are generated via density evolution; SC, SCL, SCL-CRC and majority based decoding algorithms and advanced quantization techniques that largely reduces the implementation complexity; unrolled SC and SCL architectures with optimized register balancing, single core and multi-core architectural templates and a polar decoder exploration framework that automatically generates decoder architectures; virtual silicon implementations for all architectures and an in-depth investigation of the trade-offs and comparison of these different architectures, that go especially w.r.t. implementation efficiency far beyond state-of-the-art.
EPIC results provide a framework and database to efficiently assess the most important soft-information based FEC techniques as fundamental enabler of practicable beyond 5G wireless Tb/s solutions.