Summary
Modern information and communication technology has been propelling the rapid expansion of signal spectrum bandwidth towards the level of hundreds of GHz and even 1 Terahertz. Such wideband analog signals produced in physical world must be converted to a stream of data bits via analog-to-digital conversion (ADC), for ultra-fast and flexible digital signal processing (DSP). However, the random electron fluctuations in semiconductors set a fundamental limitation on the performance of electronic (ADCs), leading to an inherent trade-off between the sampling accuracy and bandwidth. State-of-the-art electronic ADCs typically have only GHz-level analog bandwidth, which is becoming an increasingly severe limitation on high-speed DSP applications. Although the adoption of mode-locked lasers (MLLs) can overcome some limitations using the ultra-stable pulse train for precise time-domain sampling, the GHz-level repetition rate and the challenging integration of MLLs prevents any usability of photonics-assisted ADC in practical applications. In the CompADC project, I propose to develop a radically-new photonic ADC scheme using chip-scale dual optical frequency combs, enabling real-time digitization of ultra-wideband RF and microwave signals with a bandwidth of > 100 GHz. This envisaged performance is enabled by the emerging dissipative Kerr soliton (DKS) microcombs generated in SiN microresonators, which produces a new type of on-chip mode-locked emission of optical pulses with repetition rates exceeding 100 GH. These phase-locked dual microcombs (signal comb and local oscillator comb) will perform precise frequency-domain decomposition and parallel frequency down-conversion of ultra-wideband microwave signals to the detectable range of lower-speed electronics. This CompADC approach has the clear potential to offer unparalleled performance and chip-scale integration for modern ultra-wideband signal processing and communication applications.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/898594 |
| Start date: | 01-12-2020 |
| End date: | 30-11-2022 |
| Total budget - Public funding: | 203 149,44 Euro - 203 149,00 Euro |
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Original description
Modern information and communication technology has been propelling the rapid expansion of signal spectrum bandwidth towards the level of hundreds of GHz and even 1 Terahertz. Such wideband analog signals produced in physical world must be converted to a stream of data bits via analog-to-digital conversion (ADC), for ultra-fast and flexible digital signal processing (DSP). However, the random electron fluctuations in semiconductors set a fundamental limitation on the performance of electronic (ADCs), leading to an inherent trade-off between the sampling accuracy and bandwidth. State-of-the-art electronic ADCs typically have only GHz-level analog bandwidth, which is becoming an increasingly severe limitation on high-speed DSP applications. Although the adoption of mode-locked lasers (MLLs) can overcome some limitations using the ultra-stable pulse train for precise time-domain sampling, the GHz-level repetition rate and the challenging integration of MLLs prevents any usability of photonics-assisted ADC in practical applications. In the CompADC project, I propose to develop a radically-new photonic ADC scheme using chip-scale dual optical frequency combs, enabling real-time digitization of ultra-wideband RF and microwave signals with a bandwidth of > 100 GHz. This envisaged performance is enabled by the emerging dissipative Kerr soliton (DKS) microcombs generated in SiN microresonators, which produces a new type of on-chip mode-locked emission of optical pulses with repetition rates exceeding 100 GH. These phase-locked dual microcombs (signal comb and local oscillator comb) will perform precise frequency-domain decomposition and parallel frequency down-conversion of ultra-wideband microwave signals to the detectable range of lower-speed electronics. This CompADC approach has the clear potential to offer unparalleled performance and chip-scale integration for modern ultra-wideband signal processing and communication applications.Status
CLOSEDCall topic
MSCA-IF-2019Update Date
28-04-2024
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