Design and Research of Laser Power Converter (LPC) for Passive Optical Fiber Audio Transmission System Terminal

Zhou, Yikai; Guan, Chenggang; Lv, Hui; Zhang, Yihao; Zhou, Ruling; Chu, Wenxiu; Lv, Puchu; Qin, Haixin; Li, Shasha; Li, Xiaoqiang

doi:10.3390/photonics10111257

Cited by 3 publications

(1 citation statement)

References 29 publications

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“…While research on laser power converter devices continues to progress in many groups [18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37], our present study has expanded the possibilities for stable and reliable power-over-fiber or power-beaming devices that are obtained using vertical multijunction power converters. The multijunction design enables practical optimal loads and tailored output voltages.…”

Section: Discussionmentioning

confidence: 99%

67.5% Efficient InP-Based Laser Power Converters at 1470 nm at 77 K

Fafard,

Masson

2024

Photonics

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Recent developments in long wavelength and cryogenic laser power converters have unlocked record performances in both areas. Here, devices for an optical input at ~1470 nm are studied for cryogenic applications, combining these cryogenic and long-wavelength attributes. Multijunction laser power converters are demonstrated to have a high-efficiency operation at 77 K. The photovoltaic-power-converting III-V semiconductor devices are designed with InGaAs-absorbing layers, here with 10 thin subcells (PT10), connected by transparent tunnel junctions. Unprecedented conversion efficiencies of up to 67.5% are measured at liquid nitrogen temperatures with an output power of Pmpp = 1.35 W at an average optical input intensity of ~62 W/cm2. A remarkably low bandgap voltage offset value of Woc~50 mV is obtained at an average optical input intensity of ~31 W/cm2.

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Section: Discussionmentioning

confidence: 99%

67.5% Efficient InP-Based Laser Power Converters at 1470 nm at 77 K

Fafard,

Masson

2024

Photonics

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Passive Bidirectional Audio-Over-Fiber System Integrating Sensing, Power Supply, and Communication

Liu,

Qin,

Guan

et al. 2024

IEEE Sensors J.

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Demonstration of Power-over-Fiber with Watts of Output Power Capabilities over Kilometers or at Cryogenic Temperatures

Fafard,

Masson

2024

Photonics

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We demonstrate the use of laser diodes and multijunction photovoltaic power converters to efficiently deliver watts of electrical power for long-distance or cryogenic applications. Transmission through single-mode and multi-mode fibers at the wavelengths of 808 nm and 1470/1550 nm are studied. An electrical output power of ~0.1 W is obtained after a 5 km transmission through a standard single-mode SMF28 fiber fed with 0.25 W of optical power. An electrical output power of ~1 W is demonstrated after a 5 km transmission with a standard OM1 multi-mode fiber fed with ~2.5 W. Photovoltaic conversion efficiencies reaching Eff ~49% are obtained with an output voltage of ~5 V using commercial multijunction laser power converters. For low-temperature applications, an ultra-sensitive silicon photomultiplier (SiPM) is used to detect the residual light leaked from fibers as the temperature is decreased. Our study demonstrates that specific fiber types enable low-loss transmission compatible with cryogenic requirements and without light leakage triggering of the SiPM. A cryogenic power-over-fiber system at ~1470 nm is demonstrated with ~2 W of electrical power converted over a 10 m distance having a conversion efficiency of Eff > 65% at 77 K.

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Design and Research of Laser Power Converter (LPC) for Passive Optical Fiber Audio Transmission System Terminal

Cited by 3 publications

References 29 publications

67.5% Efficient InP-Based Laser Power Converters at 1470 nm at 77 K

67.5% Efficient InP-Based Laser Power Converters at 1470 nm at 77 K

Passive Bidirectional Audio-Over-Fiber System Integrating Sensing, Power Supply, and Communication

Demonstration of Power-over-Fiber with Watts of Output Power Capabilities over Kilometers or at Cryogenic Temperatures

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