锁定电子模块: FALC & PFD
一键式相位频率锁定
- 强大的相位及频率锁定
- 远程控制及锁定
- 方便的软件界面,集成DFC GUI(TOPAS DFC)
- 配备用于偏移相位频率锁定的可调谐射频源
- 10 MHz 参考输入
- 配备用于拍频检测及频率计数的拍频信号调节
DFC锁定电子单元由相位频率探测器(PFD)以及为光梳应用提供高端相频锁定的FALC 110组成。PFD的射频输入设计搭配DFC MD射频输出使用。PFD产生的误差信号被输入至FALC110调节器。FALC的主输出信号将通过PFD,从而实现激光半导体电流调制快速反馈环路的快速切换。误差信号的一个副本(见下图中mon.out)被用于闭合慢反馈环路,该慢反馈环路与DLC pro的全数字化PID控制器以通作用于DL pro的光压器件(Fine In)上。快慢反馈环路可在DFC用户界面中一键启动及关闭(TOPAS DFC)。
示例:将DLC DL pro锁定到DFC的相频 (看视频)
Request a Quotation Download the Product Brochure Application Note Phase and Frequency Locking of Diode Lasers
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Specification
PFD FALC110 DLC pro Lock DFC CORE +
internal Lock描述 相位频率检测器 快速模拟PID 全数字PID 全数字PID 推荐用于将DL pro锁定到DFC x x x 推荐用于DFC锁定选择。 参考 x x x 任务 错误信号生成 高带宽锁相 对DLC Pro激光器反馈缓慢 对DFC反馈缓慢 最大带宽 ≈ 45 MHz ≈ 30 kHz ≈ 30 kHz 遥控 x via PFD x x 机架兼容性 x x x x 独立型系统 x DLC pro的可选软件许可 包含在任何DFC CORE中+ 电源 DLC Ext DLC Ext 尺寸图 PFD, FALC110, DLC EXT 131 x 184 x 286 mm³ 包含在DLC pro中 包含在任何DFC CORE中+ -
Applications
由相位频率检测器(PFD)和FALC 110组成的DFC锁定电子器件为频梳应用提供高端的相位频率锁定。PFD与著名的快速激光锁定模块FALC 110结合使用可实现远程控制和锁定。PFD射频输入是为配合DFC MD的射频输出信号而设计的。PFD产生的误差信号被输入FALC 110的稳压器。FALC的主输出通过PFD传递,以实现对快速反馈环路的远程切换,该环路对激光二极管电流进行调制。错误信号的一个拷贝(mono . out)被用来使DLC pro的全数字PID来关闭作用于DL pro piezo (Fine In)的慢反馈。通过按下DFC用户界面(TOPAS DFC)中的按钮可以启用和禁用慢反馈回路和快速反馈回路。
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Downloads
- Product Broshure: Optical Clocks
- Product Broshure: Rydberg Flyer
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Literature
- Scientific Article: E. Benkler et al., End-to-end topology for fiber comb based optical frequency transfer at the 10−21 level, Optics Express [27], 36886 (2019)
- Scientific Article: E. C. Cook et al., Resonant two-photon spectroscopy of the 2s3d 1D2 level of neutral 9Be Phys. Rev. Applied 101, 042503 (2020)
- Scientific Article: M. Collombon et al., Experimental Demonstration of Three-Photon Coherent Population Trapping in an Ion Cloud, Phys. Rev. Applied 12, 034035, (2019)
- Scientific Article: M. Collombon et al., Phase transfer between three visible lasers for coherent population trapping, Optics Letters Vol. 44, Issue 4 (2019)
- Scientific Article: A. Liehl et al., Ultrabroadband out-of-loop characterization of the carrier-envelope phase noise of an offset-free Er:fiber frequency comb. Optics Letters Vol. 42, Issue 10 (2017)
- Scientific Article: T. Puppe et al., Characterization of a DFG comb showing quadratic scaling of the phase noise with frequency, Optics Letters Vol. 41, Issue 8 (2016)
- Scientific Article: G. Krauss et al., All-passive phase locking of a compact Er:fiber laser system, Opt. Lett., 36, 540 (2011)
- Scientific Article: D. Fehrenbacher et al., Free-running performance and full control of a passively phase-stable Er:fiber frequency comb. Optica Vol. 2, Issue 10 (2015)
- Scientific Article: R. Kliese et al., Difference-frequency combs in cold atom physics, arXiv:1605.02426v1 (2016)
- Scientific Article: D. Brida et al., Ultrabroadband Er:fiber lasers, Laser & Photonics Review 8(3) (2014)
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