Engineering of Coherently Combined, High‐Power Laser Systems

Goodno, Gregory D.; Rothenberg, Joshua E.

doi:10.1002/9783527652778.ch01

Cited by 9 publications

(5 citation statements)

References 66 publications

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“…A patented technique [22] allows the distributed antenna aperture to coherently up-convert an incident RF field to the optical domain for passive beam-space processing. This preservation of an incident phase front through the up-conversion process enables beam-space processing of the incident field using free-space interferometry of optical beams [23], [24]. A series of bi-convex lenses take the Fourier transform of the optical field at the input of the free-space optics ("Optical Processor") while distributed Bragg reflector (DBR) filters isolate the first lower sideband of the optical signal generated by the phase modulation of the incident light, while the rejected optical carriers are used to maintain spatial coherence among the array elements as described in [22]- [24]…”

Section: A Overviewmentioning

confidence: 99%

RF-Photonic Spatial-Spectral Channelizing Receiver

Beardell

Mazur

Ryan

et al. 2022

J. Lightwave Technol.

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As mobile beam-bandwidth-product requirements accelerate, millimeter-wave (mmW) bands have been opened to telecommunications networks to enable wider channel bandwidths, while Massive Multiple-Input Multiple-Output (mMIMO) technology has been implemented to concurrently address multiple devices at the same frequency from a single base station. Such space-division multiplexing can be combined with spectral multiplexing to enable a very large number of concurrent users, but currently is implemented through computationally intensive digital beamforming networks. We show that a radio-frequency (RF) photonic receiver system, previously shown to be capable of sorting signals into respective spatial-spectral 'bins' is further capable, through an injection-locked tunable optical local oscillator (TOLO), of recovering the data upon each signal in the RF scene. The TOLO is combined in free-space with an up-converted optical sideband and the combined optical field impinges upon an array of photodetectors, each corresponding to separate points in k-space, defined by unique combinations of angle-of-arrival (AoA) and carrier frequency. Using this free-space LO insertion, we demonstrate simultaneous recovery of multiple spatially colocated data streams with resilience to interference.

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Section: A Overviewmentioning

confidence: 99%

RF-Photonic Spatial-Spectral Channelizing Receiver

Beardell

Mazur

Ryan

et al. 2022

J. Lightwave Technol.

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“…It requires a proper and stable phase relationship of the sampled gain medium. Different approaches have been demonstrated: active phase locking of amplifiers seeded by a single frequency laser split into several beams or passive phase locking of emitters in an extended cavity [14]. Impressive results for CBC using a limited number of high power fiber amplifiers (P > 100W per channel) show the potential of power scaling by CBC reaching kW level powers [15,16].…”

Section: Coherent Beam Combiningmentioning

confidence: 99%

Coherent combining of high brightness tapered amplifiers for efficient non-linear conversion

Albrodt¹,

Jamal²,

Hansen³

et al. 2019

Opt. Express

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We report on a coherent beam combination of three high-brightness tapered amplifiers, which are seeded by a single-frequency laser at λ = 976 nm in a simple architecture with efficiently cooled emitters. The maximal combined power of 12.9 W is achieved at a combining efficiency of > 65%, which is limited by the amplifiers' intrinsic beam quality. The coherent combination cleans up the spatial profile, as the central lobe's power content increases by up to 86%. This high-brightness infrared beam is converted into the visible by second harmonic generation. This results in a high non-linear conversion efficiency of 4.5%/W and a maximum power over 2 W at 488 nm, which is limited by thermal effects in the periodically poled lithium niobate (PPLN).

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“…For decades, laser coherent combination has been proved to be an efficient way to combine multiple laser beams together for achieving high power output due to its advantage of maintaining good beam quality. And many studies have demonstrated filling factor [4]- [6] is an important parameter to affect coherent combination efficiency [7]- [9]. To increase beam coherent combination, people need to reduce beams space and increase the filling factor of coherent combination array.…”

Section: Introductionmentioning

confidence: 99%

Laser Coherent Combination With Circular Array of Airy Beams

Wang,

Liu,

et al. 2024

IEEE Photonics J.

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A high-efficiency laser coherent combination method based on the virtue of the self-transverse acceleration effect of Airy beams is proposed and demonstrated by converting an array of Gaussian beams into Airy beams array to reduce laser beams separation distance. The coherent combination procedures of circular array for both Airy and Gaussian beams are theoretically and experimentally studied. The results show that the central intensity of the laser coherent combination of the circular array of Airy beams is 14.33 times higher than that of the Gaussian beams array, and the combined efficiency of the circular array of Airy beams is 1.64 times higher than that of the Gaussian beams circular array. The method may provide an efficient way to increase combination efficiency of laser coherent combination array and may have a broad application prospect in optical communication, particle capture, material processing.

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Engineering of Coherently Combined, High‐Power Laser Systems

Cited by 9 publications

References 66 publications

RF-Photonic Spatial-Spectral Channelizing Receiver

RF-Photonic Spatial-Spectral Channelizing Receiver

Coherent combining of high brightness tapered amplifiers for efficient non-linear conversion

Laser Coherent Combination With Circular Array of Airy Beams

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