Summary
Emerging communications and computing fields are pushing the limits of integrated electronics demanding growing performance and requiring to symbiotically team up with integrated photonics. The development of multipurpose programmable photonic integrated circuits promises cost-effective mass production and the system versatility required in novel dynamic processing scenarios. However, their scalability is a major challenge constrained both by hardware and software.
To unleash the potential of programmable photonics it is essential to create novel circuits and components as well as to re-define its fundamentals. Multicore architectures are a potential unexplored solution offering scalability, multitasking, and parallelization, but key technology enablers are required to jump to practical large-scale applications.
The aim of this project is to develop the theoretical and technological fundamentals of programmable integrated photonics to unlock their limited-scale by developing the first large-scale multicore programmable photonic processor and its application as a complex-valued neuromorphic computer.
To achieve this aim, we will (i) identify the main scalability limits, advanced photonic circuit architectures and component development solutions for large-scale programmable photonic circuits; (ii) develop a functional single-core programmable photonic processor with more than 2500 phase actuators; (iii) demonstrate large-scale complex-valued coherent neuromorphic circuits; and (iv) develop a functional 4-core programmable photonic processor with more than 10000 actuators and demonstrate its experimental application to photonic neuromorphic systems.
LS-PHOTONICS’s will have a major impact on high-density integrated photonics circuits by facilitating a new paradigm of general-purpose/application, advanced photonic computing and ready-to-use and flexible devices that will extend the penetration of advanced photonics technology into seamless areas of application.
To unleash the potential of programmable photonics it is essential to create novel circuits and components as well as to re-define its fundamentals. Multicore architectures are a potential unexplored solution offering scalability, multitasking, and parallelization, but key technology enablers are required to jump to practical large-scale applications.
The aim of this project is to develop the theoretical and technological fundamentals of programmable integrated photonics to unlock their limited-scale by developing the first large-scale multicore programmable photonic processor and its application as a complex-valued neuromorphic computer.
To achieve this aim, we will (i) identify the main scalability limits, advanced photonic circuit architectures and component development solutions for large-scale programmable photonic circuits; (ii) develop a functional single-core programmable photonic processor with more than 2500 phase actuators; (iii) demonstrate large-scale complex-valued coherent neuromorphic circuits; and (iv) develop a functional 4-core programmable photonic processor with more than 10000 actuators and demonstrate its experimental application to photonic neuromorphic systems.
LS-PHOTONICS’s will have a major impact on high-density integrated photonics circuits by facilitating a new paradigm of general-purpose/application, advanced photonic computing and ready-to-use and flexible devices that will extend the penetration of advanced photonics technology into seamless areas of application.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101076175 |
| Start date: | 01-09-2023 |
| End date: | 31-08-2028 |
| Total budget - Public funding: | 1 499 325,00 Euro - 1 499 325,00 Euro |
Cordis data
Original description
Emerging communications and computing fields are pushing the limits of integrated electronics demanding growing performance and requiring to symbiotically team up with integrated photonics. The development of multipurpose programmable photonic integrated circuits promises cost-effective mass production and the system versatility required in novel dynamic processing scenarios. However, their scalability is a major challenge constrained both by hardware and software.To unleash the potential of programmable photonics it is essential to create novel circuits and components as well as to re-define its fundamentals. Multicore architectures are a potential unexplored solution offering scalability, multitasking, and parallelization, but key technology enablers are required to jump to practical large-scale applications.
The aim of this project is to develop the theoretical and technological fundamentals of programmable integrated photonics to unlock their limited-scale by developing the first large-scale multicore programmable photonic processor and its application as a complex-valued neuromorphic computer.
To achieve this aim, we will (i) identify the main scalability limits, advanced photonic circuit architectures and component development solutions for large-scale programmable photonic circuits; (ii) develop a functional single-core programmable photonic processor with more than 2500 phase actuators; (iii) demonstrate large-scale complex-valued coherent neuromorphic circuits; and (iv) develop a functional 4-core programmable photonic processor with more than 10000 actuators and demonstrate its experimental application to photonic neuromorphic systems.
LS-PHOTONICS’s will have a major impact on high-density integrated photonics circuits by facilitating a new paradigm of general-purpose/application, advanced photonic computing and ready-to-use and flexible devices that will extend the penetration of advanced photonics technology into seamless areas of application.
Status
SIGNEDCall topic
ERC-2022-STGUpdate Date
31-07-2023
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