V. Lal scite author profile

We present a 32 channel indium phosphide integrated pulse shaper with 25 GHz channel spacing, where each channel is equipped with a semiconductor optical amplifier allowing for programmable line-by-line gain control with submicrosecond reconfigurability. We critically test the integrated pulse shaper by using it in comb-based RF-photonic filtering experiments where the precise gain control is leveraged to synthesize high-fidelity RF filters which we reconfigure on a microsecond time scale. Our on-chip pulse shaping demonstration is unmatched in its combination of speed, fidelity, and flexibility, and will likely open new avenues in the field of advanced broadband signal generation and processing.

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800G DSP ASIC Design Using Probabilistic Shaping and Digital Sub-Carrier Multiplexing

Sun

Torbatian

Karimi

et al. 2020

J. Lightwave Technol.

213

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The design of application-specific integrated circuit (ASIC) is at the core of modern ultra-high-speed transponders employing advanced digital signal processing (DSP) algorithms. This manuscript discusses the motivations for jointly utilizing transmission techniques such as probabilistic shaping and digital sub-carrier multiplexing in digital coherent optical transmissions systems. We firstly report the key-building blocks of high-speed modern DSP-based transponders working up to 800G per wave. Secondly, we show the benefits of these transmission methods in terms of system level performance. Finally, we report, to the best of our knowledge, the first long-haul experimental transmission -e.g., over 1000 km -with a real-time 7 nm DSP ASIC and digital coherent optics (DCO) capable of data rates up to 1.6 Tb/s using two waves (2×800G).

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System-on-Chip Photonic Integrated Circuits

Kish

Lal

Evans

et al. 2018

IEEE J. Select. Topics Quantum Electron.

134

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Current Status of Large-Scale InP Photonic Integrated Circuits

Kish

Welch

Nagarajan

et al. 2011

IEEE J. Select. Topics Quantum Electron.

110

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Monolithically integrated active components: a quantum-well intermixing approach

Skogen

Raring

Morrison

et al. 2005

IEEE J. Select. Topics Quantum Electron.

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V. Lal

Integrated line-by-line optical pulse shaper for high-fidelity and rapidly reconfigurable RF-filtering

800G DSP ASIC Design Using Probabilistic Shaping and Digital Sub-Carrier Multiplexing

System-on-Chip Photonic Integrated Circuits

Current Status of Large-Scale InP Photonic Integrated Circuits

Monolithically integrated active components: a quantum-well intermixing approach

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