Draft:Laser Feedback Interferometry

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Last edited by Ldm1954 (talk | contribs) 1 second ago. (Update)

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Comment: See talk page for comments on the first version. Ldm1954 (talk) 23:39, 22 April 2025 (UTC)

Laser Feedback Interferometry (LFI) is a highly sensitive optical sensing technique in which a portion of the emitted laser light is reflected back into the laser cavity, interacting with the lasing medium and modulating the output power. This modulation encodes information about the target object, such as its position, velocity, vibration, or refractive index. Unlike traditional interferometry, which requires external optical components like beam splitters and detectors, LFI uses the laser itself as both the emitter and detector, resulting in a compact and self-aligned system.^[1]^[2].

Principle of operation

Laser feedback interferometry is based on the phenomenon of self-mixing. When a laser beam is directed at a target, a fraction of the reflected light re-enters the laser cavity. This backscattered light interferes with the lasing field inside the cavity, causing variations in the output power, frequency, or phase of the laser. These variations depend on the optical path length difference and contain information about the target's motion or properties.

The magnitude and nature of the feedback determine the operating regime of the LFI system, typically categorized into^[1]:

Weak feedback: where modulation is linear and ideal for displacement or vibration sensing.
Moderate feedback: showing more complex interference patterns, often requiring signal processing.
Strong feedback: leading to nonlinear behaviors and even laser chaos in some configurations.

Advantages

Laser feedback interferometry offers several key advantages over conventional interferometry:

Self-alignment: Since the laser acts as both the source and detector, alignment complexity is greatly reduced.
Compactness: Fewer external components are needed, enabling miniaturization.
High sensitivity: Capable of detecting displacements on the order of nanometers or smaller.
High bandwidth: Suitable for high-frequency vibration or velocity measurements.
Coherent detection: Enables phase-sensitive measurements, enhancing signal-to-noise ratio^[3]

Applications

LFI is used across a range of scientific and industrial applications, including:^[1]^[2]^[3]

Metrology: Non-contact displacement and vibration measurement in precision engineering.
Biomedical Imaging: Used in experimental skin cancer diagnostics with quantum cascade lasers (QCLs), providing high-resolution images with enhanced sensitivity.
Material Characterization: Measurement of surface roughness and acoustic wave propagation in solids.
Flow and Vibration Sensing: Detection of fluid flow velocities and structural resonances.
Security and Defense: Vibration detection for surveillance or structural monitoring.

Implementation

Typical LFI systems involve a diode laser (such as a distributed feedback laser or quantum cascade laser), optics to direct light to the target and collect the backscattered signal, and electronics to process the laser’s output power variations. Advanced implementations incorporate digital signal processing and phase-unwrapping algorithms for enhanced resolution and real-time feedback.

Related technologies

Self-Mixing Interferometry (SMI): A broader category that encompasses laser feedback interferometry.
Fabry–Pérot Interferometry: Uses external cavities, as opposed to internal modulation in LFI.

References

^ ^a ^b ^c "Optica Publishing Group". opg.optica.org. Retrieved 2025-04-21.
^ ^a ^b "https://www.spiedigitallibrary.org/journals/Optical_Engineering/volume-56/issue-5/050901/Laser-feedback-interferometry-and-applications-a-review/10.1117/1.OE.56.5.050901.full". doi:10.1117/1.oe.56.5.050901.full. {{cite journal}}: Cite journal requires |journal= (help); External link in |title= (help)
^ ^a ^b Mohun, Daniel; Sulollari, Nikollao; Salih, Mohammed; Li, Lianhe H.; Cunningham, John E.; Linfield, Edmund H.; Davies, A. Giles; Dean, Paul (2024-02-08). "Terahertz microscopy using laser feedback interferometry based on a generalised phase-stepping algorithm". Scientific Reports. 14 (1): 3274. doi:10.1038/s41598-024-53448-8. ISSN 2045-2322.

[:0-1] "Optica Publishing Group". opg.optica.org. Retrieved 2025-04-21.

[:1-2] "https://www.spiedigitallibrary.org/journals/Optical_Engineering/volume-56/issue-5/050901/Laser-feedback-interferometry-and-applications-a-review/10.1117/1.OE.56.5.050901.full". doi:10.1117/1.oe.56.5.050901.full. {{cite journal}}: Cite journal requires |journal= (help); External link in |title= (help)

[:2-3] Mohun, Daniel; Sulollari, Nikollao; Salih, Mohammed; Li, Lianhe H.; Cunningham, John E.; Linfield, Edmund H.; Davies, A. Giles; Dean, Paul (2024-02-08). "Terahertz microscopy using laser feedback interferometry based on a generalised phase-stepping algorithm". Scientific Reports. 14 (1): 3274. doi:10.1038/s41598-024-53448-8. ISSN 2045-2322.

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