Wireless communication is a key technology of our information society and there is a continuous demand for higher throughput, higher spectral efficiency, lower latencies, lower power and large scalability on communication systems. This imposes large challenges on the baseband signal processing. Channel coding, or forward error correction (FEC), is a crucial technology component of any digital communication system. FEC provides reliable communication in the face of noise that corrupts the transmitted signal, but does at the expense of decreased information throughput and increased implementation complexity. FEC is a major source of power consumption, silicon area and largely contributes to the overall latency and throughput limitations in baseband signal processing. Beyond-5G use cases are expected to require wireless data rates in the Terabit/s range in a power envelope in the order of some Watts. In the past, progress in microelectronic silicon technology driven by Moore’s law was an enabler of large leaps in throughput, lower latency, lower power etc. However, we have reached a point where microelectronics can no more keep pace with the increased requirements from communication systems, especially in energy efficiency for wireless transceivers, which have tightly constrained power and energy budgets. The complexity of implementing advanced FEC schemes to operate at Tb/s data rates is a huge challenge. To achieve excellent communications performance, advanced channel coding schemes are mandatory. Turbo-, LDPC-, and Polar Codes are the most advanced channel coding schemes known today that exhibit excellent communications performance. However, this comes at the cost of large implementation challenges, especially when targeting throughput towards 1Tb/s under stringent power constraints. The EPIC project addresses these challenges and develops an implementation-ready FEC technology for Turbo-, LDPC-, and Polar codes that meets the cost and performance requirements of a variety of potential wireless Tb/s use-cases. EPIC methodology differentiates itself by combining code construction, decoding algorithm design and architecture/implementation in a holistic way so that optimization can be carried out jointly over a larger domain. The primary goals of the project are:
• 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.