TY - JOUR
T1 - Design Methodologies for Integrated Quantum Frequency Processors
AU - Nussbaum, Benjamin E.
AU - Pizzimenti, Andrew J.
AU - Lingaraju, Navin B.
AU - Lu, Hsuan Hao
AU - Lukens, Joseph M.
N1 - Publisher Copyright:
© 1983-2012 IEEE.
PY - 2022/12/1
Y1 - 2022/12/1
N2 - Frequency-encoded quantum information offers intriguing opportunities for quantum communications and networking, with the quantum frequency processor paradigm - based on electro-optic phase modulators and Fourier-transform pulse shapers - providing a path for scalable construction of quantum gates. Yet all experimental demonstrations to date have relied on discrete fiber-optic components that occupy significant physical space and impart appreciable loss. In this article, we introduce a model for the design of quantum frequency processors comprising microring resonator-based pulse shapers and integrated phase modulators. We estimate the performance of single and parallel frequency-bin Hadamard gates, finding high fidelity values that extend to frequency bins with relatively wide bandwidths. By incorporating multi-order filter designs as well, we explore the limits of tight frequency spacings, a regime extremely difficult to obtain in bulk optics. Overall, our model is general, simple to use, and extendable to other material platforms, providing a much-needed design tool for future frequency processors in integrated photonics.
AB - Frequency-encoded quantum information offers intriguing opportunities for quantum communications and networking, with the quantum frequency processor paradigm - based on electro-optic phase modulators and Fourier-transform pulse shapers - providing a path for scalable construction of quantum gates. Yet all experimental demonstrations to date have relied on discrete fiber-optic components that occupy significant physical space and impart appreciable loss. In this article, we introduce a model for the design of quantum frequency processors comprising microring resonator-based pulse shapers and integrated phase modulators. We estimate the performance of single and parallel frequency-bin Hadamard gates, finding high fidelity values that extend to frequency bins with relatively wide bandwidths. By incorporating multi-order filter designs as well, we explore the limits of tight frequency spacings, a regime extremely difficult to obtain in bulk optics. Overall, our model is general, simple to use, and extendable to other material platforms, providing a much-needed design tool for future frequency processors in integrated photonics.
KW - Quantum computing
KW - optical pulse shaping
KW - optical resonators
KW - phase modulation
KW - photonic integrated circuits
KW - silicon photonics
UR - http://www.scopus.com/inward/record.url?scp=85135208224&partnerID=8YFLogxK
U2 - 10.1109/JLT.2022.3192759
DO - 10.1109/JLT.2022.3192759
M3 - Article
AN - SCOPUS:85135208224
SN - 0733-8724
VL - 40
SP - 7648
EP - 7657
JO - Journal of Lightwave Technology
JF - Journal of Lightwave Technology
IS - 23
ER -