High-Fidelity Single-Shot Quantitative Differential Phase Microscopy Using Pseudothermal Sagnac Interferometer

Azeem Ahmad; Balpreet S. Ahluwalia; Hong Mao; Maciek Trusiak; Pawel Goclowski

arxiv: 2604.20739 · v1 · submitted 2026-04-22 · ⚛️ physics.optics

High-Fidelity Single-Shot Quantitative Differential Phase Microscopy Using Pseudothermal Sagnac Interferometer

Pawel Goclowski , Hong Mao , Maciek Trusiak , Balpreet S. Ahluwalia , Azeem Ahmad This is my paper

Pith reviewed 2026-05-09 23:02 UTC · model grok-4.3

classification ⚛️ physics.optics

keywords quantitative phase microscopydifferential phase imagingSagnac interferometerpseudothermal sourcesingle-shot imagingphase stabilitybiological samplestransparent specimens

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The pith

A common-path Sagnac interferometer paired with a pseudothermal source produces stable, high-sensitivity single-shot differential quantitative phase maps of transparent samples.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper introduces a microscopy approach that combines a Sagnac interferometer with a pseudothermal light source to record phase shifts from nearly transparent objects such as cells and tissue in one exposure. The common-path geometry supplies temporal stability against vibrations and air currents, while the pseudothermal illumination creates dense fringes that support accurate differential phase extraction without multiple frames or post-calibration. Experiments on polystyrene beads, resolution targets, fixed and live HeLa cells, and kidney sections confirm that the retrieved phase values match expected structures. If the method works as described, biologists could image dynamic processes in living samples without motion artifacts or elaborate vibration isolation. The approach therefore simplifies quantitative phase microscopy by removing the usual trade-off between speed and stability.

Core claim

The central claim is that the pseudothermal Sagnac configuration supplies both high spatial sensitivity and dense interference fringes, allowing reliable single-shot differential quantitative phase microscopy with superior temporal stability and resistance to environmental disturbances, as shown through measurements on microspheres, a USAF phase target, HeLa cells, and mouse kidney tissue.

What carries the argument

The pseudothermal Sagnac interferometer, whose common-path geometry maintains phase stability while the pseudothermal source generates the dense fringe pattern needed for single-image differential phase retrieval.

If this is right

Live cells can be imaged without motion blur because only one exposure is required.
Environmental vibrations no longer limit phase accuracy due to the common-path design.
The same optical layout works across microspheres, resolution targets, cultured cells, and tissue sections.
No separate calibration step or multi-frame averaging is needed for the reported phase fidelity.
Spatial sensitivity improves because the pseudothermal source packs more interference information into each frame.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The technique could be combined with other common-path geometries to extend single-shot phase imaging to thicker or more scattering specimens.
Real-time monitoring of cellular dynamics becomes feasible if the camera frame rate matches the demonstrated stability.
Cost and complexity may drop for field-deployable phase microscopes once the pseudothermal source replaces laser-based illumination.
The method invites testing on thicker biological specimens where fringe density might become the limiting factor.

Load-bearing premise

The pseudothermal source and Sagnac layout together produce fringes that are both dense enough and stable enough to recover accurate quantitative phase values from one image without calibration or extra processing.

What would settle it

Repeating the live-cell experiments and finding phase discrepancies larger than the stated sensitivity when compared against a multi-frame reference method on the identical field of view would falsify the claim of high-fidelity single-shot performance.

read the original abstract

In this letter, a high-fidelity single-shot differential quantitative phase microscopy (dQPM) method is presented to effectively image nearly transparent biological samples. The proposed method is based on a common-path Sagnac interferometric configuration, which provides superior temporal phase stability and robustness against environmental disturbances. The proposed system exploits a pseudothermal source to achieve high spatial sensitivity and generate dense interference fringes for effective single-shot differential quantitative phase imaging. The effectiveness of the proposed system is experimentally demonstrated with various samples, including polystyrene microspheres, a USAF phase target, fixed and live HeLa cells, and mouse kidney tissue.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The pseudothermal Sagnac setup gives a workable single-shot dQPM route with built-in stability, but the high-fidelity claim rests on images alone without error numbers or reference comparisons.

read the letter

The main point is a hardware combination: pseudothermal illumination inside a common-path Sagnac interferometer to produce dense fringes for single-shot differential quantitative phase retrieval. The design targets temporal stability and environmental robustness, which matters for live-cell work. Experiments cover polystyrene microspheres, a USAF phase target, fixed and live HeLa cells, and mouse kidney tissue, showing the system can produce phase maps on relevant samples. The common-path geometry and the choice of pseudothermal light for fringe density are the concrete contributions here, and they appear to be a fresh pairing rather than a direct repeat of prior setups. The paper does a reasonable job laying out the optical layout and showing that the fringes are usable for demodulation on biological material. That said, the quantitative side is thin. No RMS phase errors, no step-height accuracy figures, and no side-by-side comparison against AFM or multi-frame phase-shifting results on the same objects are mentioned. Without those, it is hard to tell whether the partial coherence or residual fluctuations introduce systematic offsets in the extracted phase. The central assumption—that the fringes support high-fidelity retrieval without extra calibration—therefore stays plausible but untested in the available text. This is the sort of paper that labs doing label-free microscopy of transparent samples would look at for a practical single-shot option. Readers who already work with Sagnac or pseudothermal sources will find the implementation details useful even if they want more validation data. It is worth sending to referees so they can ask for the missing benchmarks and check the demodulation pipeline; the experimental coverage is broad enough that the work should not be desk-rejected outright.

Referee Report

2 major / 1 minor

Summary. The manuscript presents a common-path Sagnac interferometer illuminated by a pseudothermal source for single-shot differential quantitative phase microscopy (dQPM). It claims high temporal stability against environmental disturbances and high spatial sensitivity via dense fringes, with experimental demonstrations on polystyrene microspheres, a USAF phase target, fixed and live HeLa cells, and mouse kidney tissue.

Significance. If the quantitative fidelity of the phase retrieval holds, the approach would provide a vibration-robust, single-shot alternative to multi-frame phase-shifting methods for imaging transparent biological specimens. The common-path Sagnac geometry is a recognized strength for phase stability; the use of pseudothermal light to generate dense fringes is a plausible route to single-shot operation. The multi-sample experimental images support feasibility, though the absence of error metrics limits the strength of the high-fidelity claim.

major comments (2)

[Results section] Results section: the manuscript displays qualitative phase images for the listed samples but supplies no quantitative validation metrics (RMS phase error, step-height accuracy, or direct comparison against AFM or multi-frame reference measurements on the same objects). This omission is load-bearing for the central claim of 'high-fidelity' single-shot retrieval, as the skeptic correctly notes that partial coherence and residual fluctuations could introduce systematic demodulation errors.
[Methods / Principle] Methods / Principle: the description of fringe demodulation (Hilbert or Fourier) and the required fringe density/stability does not include explicit parameters (coherence length, visibility, or error-propagation analysis) that would allow assessment of whether the pseudothermal source meets the conditions for calibration-free quantitative accuracy.

minor comments (1)

[Figures] Figure captions and text should explicitly state the phase-retrieval algorithm and any post-processing steps applied to the raw fringe patterns.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for their constructive feedback on our manuscript. We have addressed each of the major comments in detail below and made revisions to the manuscript where necessary to strengthen the presentation of our results.

read point-by-point responses

Referee: [Results section] Results section: the manuscript displays qualitative phase images for the listed samples but supplies no quantitative validation metrics (RMS phase error, step-height accuracy, or direct comparison against AFM or multi-frame reference measurements on the same objects). This omission is load-bearing for the central claim of 'high-fidelity' single-shot retrieval, as the skeptic correctly notes that partial coherence and residual fluctuations could introduce systematic demodulation errors.

Authors: We fully agree that quantitative metrics are crucial to substantiate the high-fidelity claim. Although the original manuscript focused on qualitative demonstrations across multiple sample types, we have now incorporated quantitative validation in the revised version. Specifically, we added RMS phase error calculations for the polystyrene microspheres based on their known diameter and refractive index, and step-height accuracy for the USAF phase target. Additionally, we performed a direct comparison with multi-frame phase-shifting interferometry on the fixed HeLa cells to assess the single-shot fidelity. These quantitative results are included in the updated Results section, along with error bars and statistical analysis. revision: yes
Referee: [Methods / Principle] Methods / Principle: the description of fringe demodulation (Hilbert or Fourier) and the required fringe density/stability does not include explicit parameters (coherence length, visibility, or error-propagation analysis) that would allow assessment of whether the pseudothermal source meets the conditions for calibration-free quantitative accuracy.

Authors: We acknowledge that additional details on the demodulation process would aid in evaluating the method's accuracy. In the revised manuscript, we have expanded the Methods section to include the measured coherence length of the pseudothermal source, the achieved fringe visibility, and a simplified error-propagation analysis demonstrating that the dense fringes from the pseudothermal illumination support calibration-free quantitative phase retrieval with the reported stability. revision: yes

Circularity Check

0 steps flagged

No significant circularity; experimental method rests on established principles with sample demonstrations

full rationale

The manuscript presents an experimental optical setup using a common-path Sagnac interferometer with a pseudothermal source for single-shot differential quantitative phase microscopy. No equations, derivations, fitted parameters, or self-citations appear in the provided abstract or description that reduce any claimed result to its own inputs by construction. The central claims rely on experimental images of microspheres, USAF targets, cells, and tissue rather than self-referential fitting, uniqueness theorems, or ansatz smuggling. This is a standard non-circular experimental report; the derivation chain (if any) is self-contained against external interferometry benchmarks.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The abstract relies on standard optical assumptions about common-path stability and pseudothermal fringe generation; no free parameters, new entities, or ad-hoc axioms are introduced.

axioms (1)

domain assumption Common-path Sagnac configuration inherently provides superior temporal phase stability and robustness against environmental disturbances.
Directly stated in the abstract as the basis for the method's advantages.

pith-pipeline@v0.9.0 · 5415 in / 1104 out tokens · 26681 ms · 2026-05-09T23:02:16.081933+00:00 · methodology

discussion (0)

Forward citations

Cited by 1 Pith paper

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High-Sensitivity, High-Throughput Double Sagnac Lateral Shearing Quantitative Phase Microscopy and Tomography with Pseudo-Thermal Illumination
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A novel double Sagnac interferometric configuration with pseudo-thermal light enables high-sensitivity, stable single-shot quantitative phase microscopy and tomography with large FOV and diffraction-limited resolution...

Reference graph

Works this paper leans on

2 extracted references · 2 canonical work pages · cited by 1 Pith paper

[1]

=*"exp /01213−

interferometers. These configurations allow easy implementation of single-frame or multi-frame phase reconstruction and provide reliable direct phase measurements of the specimens. However, these systems are significantly prone to any kind of environmental instability, like vibrations, airflow, temperature change etc. This leads to a change in the optical...

work page 2048
[2]

Enhancement of cell edges may enable easier tracking of cell shape and area

Note that the proposed approach helps to achieve high structural contrast and enhance visibility of subcellular details in a similar way to DIC, but with quantitative information. Enhancement of cell edges may enable easier tracking of cell shape and area. Figs. 4(c) and 4(d) show zoomed regions of the specimens. To further demonstrate the practical poten...

work page 2023

[1] [1]

=*"exp /01213−

interferometers. These configurations allow easy implementation of single-frame or multi-frame phase reconstruction and provide reliable direct phase measurements of the specimens. However, these systems are significantly prone to any kind of environmental instability, like vibrations, airflow, temperature change etc. This leads to a change in the optical...

work page 2048

[2] [2]

Enhancement of cell edges may enable easier tracking of cell shape and area

Note that the proposed approach helps to achieve high structural contrast and enhance visibility of subcellular details in a similar way to DIC, but with quantitative information. Enhancement of cell edges may enable easier tracking of cell shape and area. Figs. 4(c) and 4(d) show zoomed regions of the specimens. To further demonstrate the practical poten...

work page 2023