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  • MENHIR-1550系列 GHz 飞秒激光器

  • MENHIR-1550系列 GHz 飞秒激光器

    Menhir-Photonics的MENHIR-1550 系列,是全球首款1550 nm 波段、GHz重复频率工业级飞秒激光器。
    典型应用:量子光学、光通信、太赫兹产生、定时分发、光频梳、模数转换器、超低噪声微波产生



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Menhir-Photonics的MENHIR-1550 系列,是全球首款1550 nm 波段、GHz重复频率工业级飞秒激光器。
典型应用:量子光学、光通信、太赫兹产生、定时分发、光频梳、模数转换器、超低噪声微波产生



核心特点

  • 超低噪声

  • 全密封激光腔体

  • 一体化集成系统

  • 可按需定制MENHIR-1550系列,全面适配工业及科研各类应用场景


核心参数

  • 最高重复频率:2.5 GHz

  • 集成重复频率(frep)与载波包络偏移频率(fCEO)驱动执行器

  • 纯净孤子脉冲:脉宽<250 fs

典型应用

  • 量子光学

  • 光通信

  • 太赫兹产生

  • 定时分发

  • 光频梳

  • 模数转换器

  • 超低噪声微波产生

参数|型号

MENHIR-1550 at 250 MHz

MENHIR-1550 at 1 GHz 

MENHIR-1550 at 2.5 GHz

重复频率 frep250 MHz
1 GHz2.5 GHz
输出光功率>100 mW>50 mW>20 mW
中心波长 λ01545 – 1565 nm1545 – 1565 nm1545 – 1565 nm
脉冲类型纯净孤子脉冲 Clean soliton pulse纯净孤子脉冲 Clean soliton pulse纯净孤子脉冲 Clean soliton pulse
光谱宽度>10 nm>10 nm>10 nm
脉冲宽度<250 fs<250 fs<250 fs
光谱形态双曲正割平方(Sech2-shaped)型光谱双曲正割平方(Sech²-shaped)型光谱双曲正割平方(Sech²-shaped)型光谱
光束特性TEM₀₀ M² < 1.05TEM₀₀, M² < 1.05TEM₀₀, M² < 1.05

孤子脉冲

相位噪声 时间抖动

纯净的光谱

纯净的频谱


相关文章 微波信号产生-GHz高重频飞秒激光器的应用

MENHIR-1550系列 GHz 飞秒激光器

Performance_MENHIR-1550-250MHz

Performance_MENHIR-1550-1GHz

Performance_MENHIR-1550-2.5GHz

一、White Papers 科学白皮书

Self-Referenced Optical Frequency Comb[EB/OL]. Menhir Photonics, [2026].

Optical Frequency Comb Stabilization[EB/OL]. Menhir Photonics, [2026].

Timing Distribution Based on MENHIR-1550[EB/OL]. Menhir Photonics, [2026].

Industrial-Grade Optical Frequency Comb Technology[EB/OL]. Menhir Photonics, [2026].

二、Application Notes & Datasheets 应用笔记、产品手册

  1. Coherent Optical Comb Characterization: AppNote7[EB/OL]. Menhir Photonics & APEX Technologies, [2026].

  2. MENHIR 1550 Series (250 MHz) Datasheet[EB/OL]. Menhir Photonics, [2026].

  3. MENHIR 1550 Series (1.00 GHz) Datasheet[EB/OL]. Menhir Photonics, [2026].

  4. MENHIR 1550 Series (2.5 GHz) Datasheet[EB/OL]. Menhir Photonics, [2026].

  5. Optical Frequency Comb Application Note[EB/OL]. Menhir Photonics, [2026].

  6. Photonic ADC Application Note[EB/OL]. Menhir Photonics, [2026].

  7. RF Generation Application Note[EB/OL]. Menhir Photonics, [2026].

  8. Timing Distribution Application Note[EB/OL]. Menhir Photonics, [2026].

三、Journal Articles 期刊论文

3.1 Microwave Generation 微波生成方向

  1. Amaro-Losada L, et al. Photonic Sampler for mmWave Signals up to 70 GHz Using a 1-GHz MLL and a Silicon PIC[J]. IEEE Photonics Technology Letters, 2026.

  2. Şafak K, et al. Photonically referenced extremely stable oscillator[J]. Optics Letters, 2024, 49.

  3. Boerma, et al. Microwave Photonic PS-Pulse and 140 GHz RF Comb Generator[J]. Journal of Lightwave Technology, 2023.

  4. Surendranath-Shroff V, et al. Ultra-Low Phase Noise Frequency Synthesis Using Electro-Optic Detector-Based Comb-Microwave Synchronization[J]. IEEE Xplore, 2025.

  5. Ayissi Manga A, et al. Experimental Validation of an RF-Over-Fiber Reference Signal for Frequency Conversion in Large Multi-Tile Electronically Scanned Antennas[J]. Microwave and Optical Technology Letters, 2025.

3.2 Optical Frequency Comb & Spectroscopy 光频梳与光谱方向

  1. 1-GHz dual-comb spectrometer with high mutual coherence for fast and broadband measurements[J]. [Journal Name], [Year].

  2. Direct frequency comb spectroscopy of HCN to evaluate line lists[J]. [Journal Name], [Year].

  3. Broadband 1-GHz mid-infrared frequency comb[J]. [Journal Name], [Year].

  4. Low-noise transfer of the spectral purity of an optical comb line using a feedforward scheme[J]. [Journal Name], [Year].

  5. Squeezed dual-comb spectroscopy[J]. [Journal Name], [Year].

四、Conference Papers 会议论文

  1. Gläsel J, et al. Microwave Photonic RF Comb Generator for D- and J-Band[C]//International Topical Meeting on Microwave Photonics, 2024.

  2. Şafak K, et al. Optical Frequency and Timing Distribution System for ESA Deep Space Tracking Stations[C]//2023 EFTF/IFCS, 2023.

五、Preprints 预印本

  1. Nakamura T, et al. Ultralow noise microwaves with free-running frequency combs and electrical feedforward[R]. arXiv, 2025.