Networked Music Performance (NMP) applications are acknowledged to be a particularly challenging field due to their stringent latency requirements and their demand for high audio quality. Most solutions developed in the last decades tried to overcome these obstacles by leveraging software approaches, that can introduce excessive time delays as a consequence of the general-purpose nature of the architectures on which they are implemented. Alternatively, a dedicated audio processor can be employed to minimize the mouth-to-ear latency.This paper presents the ongoing development of an hardware system that exploits an Application-Specific Instruction set Processor (ASIP) implemented on a Field-Programmable Gate Array (FPGA) to accelerate audio sample management. Specifically, a Transport Triggered Architecture (TTA) is being investigated as a processor design that aligns well with the required application domains. Preliminary empirical results indicate that the proposed solution has the potential to achieve extremely low latency, compatible with NMP requirements. Further optimizations and enhancements are actively being pursued to address the yet open challenges posed by NMP applications.

FPGA-based Low-Latency Audio Coprocessor for Networked Music Performance / Bert, Diego; Domini, Nicola; Peloso, Riccardo; Severi, Leonardo; Sacchetto, Matteo; Bianco, Andrea; Rottondi, Cristina. - ELETTRONICO. - (2023), pp. 1-8. (Intervento presentato al convegno 4th International Symposium on the Internet of Sounds tenutosi a Pisa (Italy nel October 26-27, 2023) [10.1109/IEEECONF59510.2023.10335333].

FPGA-based Low-Latency Audio Coprocessor for Networked Music Performance

Bert, Diego;Domini, Nicola;Peloso, Riccardo;Severi, Leonardo;Sacchetto, Matteo;Bianco, Andrea;Rottondi, Cristina
2023

Abstract

Networked Music Performance (NMP) applications are acknowledged to be a particularly challenging field due to their stringent latency requirements and their demand for high audio quality. Most solutions developed in the last decades tried to overcome these obstacles by leveraging software approaches, that can introduce excessive time delays as a consequence of the general-purpose nature of the architectures on which they are implemented. Alternatively, a dedicated audio processor can be employed to minimize the mouth-to-ear latency.This paper presents the ongoing development of an hardware system that exploits an Application-Specific Instruction set Processor (ASIP) implemented on a Field-Programmable Gate Array (FPGA) to accelerate audio sample management. Specifically, a Transport Triggered Architecture (TTA) is being investigated as a processor design that aligns well with the required application domains. Preliminary empirical results indicate that the proposed solution has the potential to achieve extremely low latency, compatible with NMP requirements. Further optimizations and enhancements are actively being pursued to address the yet open challenges posed by NMP applications.
2023
979-8-3503-8254-9
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2984718