Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
134 tokens/sec
GPT-4o
10 tokens/sec
Gemini 2.5 Pro Pro
47 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
38 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Tunable X-band opto-electronic synthesizer with ultralow phase noise (2404.00136v1)

Published 29 Mar 2024 in physics.optics and eess.SP

Abstract: Modern communication, navigation, and radar systems rely on low noise and frequency-agile microwave sources. In this application space, photonic systems provide an attractive alternative to conventional microwave synthesis by leveraging high spectral purity lasers and optical frequency combs to generate microwaves with exceedingly low phase noise. However, these photonic techniques suffer from a lack of frequency tunability, and also have substantial size, weight, and power requirements that largely limit their use to laboratory settings. In this work, we address these shortcomings with a hybrid opto-electronic approach that combines simplified optical frequency division with direct digital synthesis to produce tunable low-phase-noise microwaves across the entire X-band. This results in exceptional phase noise at 10 GHz of -156 dBc/Hz at 10 kHz offset and fractional frequency instability of 1x10-13 at 0.1 s. Spot tuning away from 10 GHz by 500 MHz, 1 GHz, and 2 GHz, yields phase noise at 10 kHz offset of -150 dBc/Hz, -146 dBc/Hz, and -140 dBc/Hz, respectively. The synthesizer architecture is fully compatible with integrated photonic implementations that will enable a versatile microwave source in a chip-scale package. Together, these advances illustrate an impactful and practical synthesis technique that shares the combined benefits of low timing noise provided by photonics and the frequency agility of established digital synthesis.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (37)
  1. C. H. Townes and A. L. Schawlow, Microwave spectroscopy. Courier Corporation, 2013.
  2. Springer Science & Business Media, 2012.
  3. Chalmers University of Technology, 2015.
  4. Prentice hall New York, 2012.
  5. A. G. Armada, “Understanding the effects of phase noise in orthogonal frequency division multiplexing (ofdm),” IEEE transactions on broadcasting, vol. 47, no. 2, pp. 153–159, 2001.
  6. G. Serafino, F. Scotti, L. Lembo, B. Hussain, C. Porzi, A. Malacarne, S. Maresca, D. Onori, P. Ghelfi, and A. Bogoni, “Toward a new generation of radar systems based on microwave photonic technologies,” Journal of Lightwave Technology, vol. 37, no. 2, pp. 643–650, 2019.
  7. P. Ghelfi, F. Laghezza, F. Scotti, G. Serafino, A. Capria, S. Pinna, D. Onori, C. Porzi, M. Scaffardi, A. Malacarne, et al., “A fully photonics-based coherent radar system,” Nature, vol. 507, no. 7492, pp. 341–345, 2014.
  8. J. D. McKinney, “Photonics illuminates the future of radar,” Nature, vol. 507, no. 7492, pp. 310–312, 2014.
  9. M. I. Skolnik et al., “Introduction to radar systems mcgraw-hill,” New York, vol. 19621, 2001.
  10. G. Krieger and M. Younis, “Impact of oscillator noise in bistatic and multistatic sar,” IEEE Geoscience and Remote Sensing Letters, vol. 3, no. 3, pp. 424–428, 2006.
  11. S. Diddams, A. Bartels, T. Ramond, C. Oates, S. Bize, E. Curtis, J. Bergquist, and L. Hollberg, “Design and control of femtosecond lasers for optical clocks and the synthesis of low-noise optical and microwave signals,” IEEE Journal of Selected Topics in Quantum Electronics, vol. 9, no. 4, pp. 1072–1080, 2003.
  12. T. M. Fortier, M. S. Kirchner, F. Quinlan, J. Taylor, J. Bergquist, T. Rosenband, N. Lemke, A. Ludlow, Y. Jiang, C. Oates, et al., “Generation of ultrastable microwaves via optical frequency division,” Nature Photonics, vol. 5, no. 7, pp. 425–429, 2011.
  13. X. Xie, R. Bouchand, D. Nicolodi, M. Giunta, W. Hänsel, M. Lezius, A. Joshi, S. Datta, C. Alexandre, M. Lours, et al., “Photonic microwave signals with zeptosecond-level absolute timing noise,” Nature Photonics, vol. 11, no. 1, pp. 44–47, 2017.
  14. T. Nakamura, J. Davila-Rodriguez, H. Leopardi, J. A. Sherman, T. M. Fortier, X. Xie, J. C. Campbell, W. F. McGrew, X. Zhang, Y. S. Hassan, et al., “Coherent optical clock down-conversion for microwave frequencies with 10- 18 instability,” Science, vol. 368, no. 6493, pp. 889–892, 2020.
  15. D. Eliyahu, D. Seidel, and L. Maleki, “Phase noise of a high performance oeo and an ultra low noise floor cross-correlation microwave photonic homodyne system,” pp. 811–814, 2008.
  16. T. Fortier, A. Rolland, F. Quinlan, F. Baynes, A. Metcalf, A. Hati, A. Ludlow, N. Hinkley, M. Shimizu, T. Ishibashi, et al., “Optically referenced broadband electronic synthesizer with 15 digits of resolution,” Laser & Photonics Reviews, vol. 10, no. 5, pp. 780–790, 2016.
  17. J. Wei, D. Kwon, S. Zhang, S. Pan, and J. Kim, “All-fiber-photonics-based ultralow-noise agile frequency synthesizer for x-band radars,” Photonics Research, vol. 6, no. 1, pp. 12–17, 2018.
  18. I. Kudelin, W. Groman, Q.-X. Ji, J. Guo, M. L. Kelleher, D. Lee, T. Nakamura, C. A. McLemore, P. Shirmohammadi, S. Hanifi, H. Cheng, N. Jin, L. Wu, S. Halladay, Y. Luo, Z. Dai, W. Jin, J. Bai, Y. Liu, W. Zhang, C. Xiang, L. Chang, V. Iltchenko, O. Miller, A. Matsko, S. M. Bowers, P. T. Rakich, J. C. Campbell, J. E. Bowers, K. J. Vahala, F. Quinlan, and S. A. Diddams, “Photonic chip-based low-noise microwave oscillator,” Nature, vol. 627, pp. 534–539, 2024.
  19. J. Li, X. Yi, H. Lee, S. A. Diddams, and K. J. Vahala, “Electro-optical frequency division and stable microwave synthesis,” Science, vol. 345, no. 6194, pp. 309–313, 2014.
  20. S. Sun, B. Wang, K. Liu, M. W. Harrington, F. Tabatabaei, R. Liu, J. Wang, S. Hanifi, J. S. Morgan, M. Jahanbozorgi, Z. Yang, S. M. Bowers, P. A. Morton, K. D. Nelson, A. Beling, D. J. Blumenthal, and X. Yi, “Integrated optical frequency division for microwave and mmwave generation,” Nature, vol. 627, pp. 540–545, 2024.
  21. Y. Zhao, J. K. Jang, G. J. Beals, K. J. McNulty, X. Ji, Y. Okawachi, M. Lipson, and A. L. Gaeta, “All-optical frequency division on-chip using a single laser,” Nature, vol. 627, pp. 546–552, 2024.
  22. X. Jin, Z. Xie, X. Zhang, H. Hou, F. Zhang, X. Zhang, L. Chang, Q. Gong, and Q.-F. Yang, “Microresonator-referenced soliton microcombs with zeptosecond-level timing noise,” arXiv:2401.12760, 2024.
  23. J. Li and K. Vahala, “Small-sized, ultra-low phase noise photonic microwave oscillators at x-ka bands,” Optica, vol. 10, pp. 33–34, Jan 2023.
  24. Y. He, L. Cheng, H. Wang, Y. Zhang, R. Meade, K. Vahala, M. Zhang, and J. Li, “Chip-scale high-performance photonic microwave oscillator,” arXiv preprint arXiv:2402.16229, 2024.
  25. W. C. Swann, E. Baumann, F. R. Giorgetta, and N. R. Newbury, “Microwave generation with low residual phase noise from a femtosecond fiber laser with an intracavity electro-optic modulator,” Optics express, vol. 19, no. 24, pp. 24387–24395, 2011.
  26. R. W. Drever, J. L. Hall, F. V. Kowalski, J. Hough, G. Ford, A. Munley, and H. Ward, “Laser phase and frequency stabilization using an optical resonator,” Applied Physics B, vol. 31, pp. 97–105, 1983.
  27. S. Häfner, S. Falke, C. Grebing, S. Vogt, T. Legero, M. Merimaa, C. Lisdat, and U. Sterr, “8×\times× 10- 17 fractional laser frequency instability with a long room-temperature cavity,” Optics letters, vol. 40, no. 9, pp. 2112–2115, 2015.
  28. Springer, 2019.
  29. D. Matei, T. Legero, S. Häfner, C. Grebing, R. Weyrich, W. Zhang, L. Sonderhouse, J. Robinson, J. Ye, F. Riehle, et al., “1.5 μ𝜇\muitalic_μm lasers with sub-10 mhz linewidth,” Physical Review Letters, vol. 118, no. 26, p. 263202, 2017.
  30. C. A. McLemore, N. Jin, M. L. Kelleher, J. P. Hendrie, D. Mason, Y. Luo, D. Lee, P. Rakich, S. A. Diddams, and F. Quinlan, “Miniaturizing ultrastable electromagnetic oscillators: Sub-10−14superscript1014{10}^{-14}10 start_POSTSUPERSCRIPT - 14 end_POSTSUPERSCRIPT frequency instability from a centimeter-scale fabry-perot cavity,” Phys. Rev. Appl., vol. 18, p. 054054, Nov 2022.
  31. M. L. Kelleher, C. A. McLemore, D. Lee, J. Davila-Rodriguez, S. A. Diddams, and F. Quinlan, “Compact, portable, thermal-noise-limited optical cavity with low acceleration sensitivity,” Optics Express, vol. 31, no. 7, pp. 11954–11965, 2023.
  32. A. Parriaux, K. Hammani, and G. Millot, “Electro-optic frequency combs,” Advances in Optics and Photonics, vol. 12, no. 1, pp. 223–287, 2020.
  33. T. M. Fortier, F. Quinlan, A. Hati, C. Nelson, J. A. Taylor, Y. Fu, J. Campbell, and S. A. Diddams, “Photonic microwave generation with high-power photodiodes,” Opt. Lett., vol. 38, pp. 1712–1714, May 2013.
  34. J. Zang, X. Xie, Q. Yu, Z. Yang, A. Beling, and J. C. Campbell, “Reduction of amplitude-to-phase conversion in charge-compensated modified unitraveling carrier photodiodes,” Journal of Lightwave Technology, vol. 36, no. 22, pp. 5218–5223, 2018.
  35. Y. Liu, D. Lee, T. Nakamura, N. Jin, H. Cheng, M. L. Kelleher, C. A. McLemore, I. Kudelin, W. Groman, S. A. Diddams, et al., “Low-noise microwave generation with an air-gap optical reference cavity,” APL Photonics, vol. 9, no. 1, 2024.
  36. E. Murphy and C. Slattery, “Ask the application engineer—33 all about direct digital synthesis,” Analog Dialogue, vol. 38, no. 3, pp. 8–12, 2004.
  37. C. E. Calosso, Y. Gruson, and E. Rubiola, “Phase noise and amplitude noise in dds,” in 2012 IEEE International Frequency Control Symposium Proceedings, pp. 1–6, IEEE, 2012.
Citations (1)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
X Twitter Logo Streamline Icon: https://streamlinehq.com

Tweets