Enregistré dans:
Détails bibliographiques
Auteurs principaux: Nakamura, Takuma, Groman, William, Ji, Qing-Xin, Kara, Oguzhan, Rudin, Benjamin, Savchenkov, Anatoliy, Iltchenko, Vladimir, Zhang, Wei, Matsko, Andrey, Bowers, John E., Emaury, Florian, Vahala, Kerry J., Diddams, Scott A., Quinlan, Franklyn
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2511.20504
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866918473634938880
author Nakamura, Takuma
Groman, William
Ji, Qing-Xin
Kara, Oguzhan
Rudin, Benjamin
Savchenkov, Anatoliy
Iltchenko, Vladimir
Zhang, Wei
Matsko, Andrey
Bowers, John E.
Emaury, Florian
Vahala, Kerry J.
Diddams, Scott A.
Quinlan, Franklyn
author_facet Nakamura, Takuma
Groman, William
Ji, Qing-Xin
Kara, Oguzhan
Rudin, Benjamin
Savchenkov, Anatoliy
Iltchenko, Vladimir
Zhang, Wei
Matsko, Andrey
Bowers, John E.
Emaury, Florian
Vahala, Kerry J.
Diddams, Scott A.
Quinlan, Franklyn
contents Optically generated microwave signals exhibit some of the lowest phase noise and timing jitter of any microwave-generating technology to date. The success of octave-spanning optical frequency combs in down-converting ultrastable optical frequency references has motivated the development of compact, robust and highly manufacturable optical systems that maintain the ultralow microwave phase noise of their tabletop counterparts. Two-point optical frequency division using chip-scale components and ~1 THz-spanning microcombs has been quite successful, but with stringent requirements on the comb source's free-running noise and feedback control dynamics. Here we introduce a major simplification of this architecture that replaces feedback control of the frequency comb in favor of electronic feedforward noise cancelation that significantly relaxes the comb requirements. Demonstrated with both a high repetition rate solid-state mode-locked laser and a microcomb, feedforward on a 10 GHz carrier results in more robust operation with phase noise as low as -153 dBc/Hz at offsets >10 kHz, femtosecond timing jitter, and elimination of the large "servo bump" noise increase at high offset frequency. The system's compatibility with a variety of highly manufacturable mode-locked laser designs and its resilience and straightforward implementation represents an important step forward towards a fully chip-scale implementation of optically generated microwaves, with applications in radar, sensing, and position, navigation and timing.
format Preprint
id arxiv_https___arxiv_org_abs_2511_20504
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ultralow noise microwaves with free-running frequency combs and electrical feedforward
Nakamura, Takuma
Groman, William
Ji, Qing-Xin
Kara, Oguzhan
Rudin, Benjamin
Savchenkov, Anatoliy
Iltchenko, Vladimir
Zhang, Wei
Matsko, Andrey
Bowers, John E.
Emaury, Florian
Vahala, Kerry J.
Diddams, Scott A.
Quinlan, Franklyn
Optics
Optically generated microwave signals exhibit some of the lowest phase noise and timing jitter of any microwave-generating technology to date. The success of octave-spanning optical frequency combs in down-converting ultrastable optical frequency references has motivated the development of compact, robust and highly manufacturable optical systems that maintain the ultralow microwave phase noise of their tabletop counterparts. Two-point optical frequency division using chip-scale components and ~1 THz-spanning microcombs has been quite successful, but with stringent requirements on the comb source's free-running noise and feedback control dynamics. Here we introduce a major simplification of this architecture that replaces feedback control of the frequency comb in favor of electronic feedforward noise cancelation that significantly relaxes the comb requirements. Demonstrated with both a high repetition rate solid-state mode-locked laser and a microcomb, feedforward on a 10 GHz carrier results in more robust operation with phase noise as low as -153 dBc/Hz at offsets >10 kHz, femtosecond timing jitter, and elimination of the large "servo bump" noise increase at high offset frequency. The system's compatibility with a variety of highly manufacturable mode-locked laser designs and its resilience and straightforward implementation represents an important step forward towards a fully chip-scale implementation of optically generated microwaves, with applications in radar, sensing, and position, navigation and timing.
title Ultralow noise microwaves with free-running frequency combs and electrical feedforward
topic Optics
url https://arxiv.org/abs/2511.20504