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arxiv: 2604.06399 · v2 · pith:6VDIWPRNnew · submitted 2026-04-07 · 🌌 astro-ph.IM

Reliability of uGMRT Band-4 Polarimetry: Results from a Quadrature Hybrid Polarizer Bypass Experiment

Arpan Pal , Sanjeet Rai , Ganesh Kumbhar This is my paper

Pith reviewed 2026-05-25 06:50 UTC · model grok-4.3

classification 🌌 astro-ph.IM
keywords uGMRT Band 4polarimetryquadrature hybrid polarizerinstrumental leakageFaraday rotationpolarization calibrationsub-GHz observations
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The pith

Bypassing the quadrature hybrid polarizer in seven uGMRT antennas stabilizes cross-hand phases and cuts leakage to under 0.2 percent residual.

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

The paper traces unstable polarization calibration at 550-750 MHz to the quadrature hybrid polarizer in the uGMRT Band 4 frontend, where cross-hand phase shifts depend on source polarization. A controlled bypass converting seven antennas to linear feeds removes this dependence and lowers instrumental leakage from 10-15 percent to 2-5 percent. The change also lets the system recover the known 25-degree polarization angle swing across the band for source DA 240. This matters for studies of cosmic magnetic fields that rely on accurate Faraday rotation and depolarization measurements at sub-GHz frequencies.

Core claim

The quadrature hybrid polarizer is the dominant source of polarimetric instability in uGMRT Band 4; bypassing it in seven antennas produces stable cross-hand phases independent of source polarization, reduces instrumental leakage to 2-5 percent, leaves residual leakage below 0.2 percent after calibration, and correctly recovers the expected polarization angle rotation for DA 240.

What carries the argument

The controlled bypass experiment that removes the quadrature hybrid polarizer from seven antennas and converts them to linear polarization feeds.

If this is right

  • The bypassed system recovers the expected 25-degree polarization angle rotation across the band for DA 240.
  • Residual leakage after calibration drops below 0.2 percent.
  • Cross-hand phases become independent of source fractional polarization.
  • Linear feed configuration is recommended for science requiring accurate polarization angle and rotation measure measurements.

Where Pith is reading between the lines

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

  • Similar quadrature hybrid components in other low-frequency arrays may introduce comparable calibration instabilities.
  • The linear-feed approach could be tested on uGMRT Band 3 or 5 to check whether the same fix applies at neighboring frequencies.
  • Reliable sub-GHz polarimetry opens routine rotation measure grids for extended sources that were previously limited by angle errors.

Load-bearing premise

The bypass in seven antennas isolates the quadrature hybrid polarizer effect without other changes to the signal chain, antenna response, or calibration process.

What would settle it

A repeat of the bypass experiment on more antennas that still shows polarization-dependent cross-hand phase variations would falsify the claim that the quadrature hybrid is the dominant instability source.

read the original abstract

Polarimetric observations at sub-GHz frequencies offer unique access to the magnetized universe through Faraday rotation and depolarization studies, but achieving reliable polarization calibration at these frequencies remains challenging. We report the identification and resolution of a systematic polarization calibration instability in the upgraded Giant Metrewave Radio Telescope (uGMRT) Band 4 (550--750\,MHz). Through diagnostic observations of multiple calibrators, we discovered that the cross-hand phase response varies with the fractional polarization of the observed source, violating the fundamental assumption of calibration transferability in radio interferometry. Systematic engineering tests traced this behaviour to the Quadrature Hybrid (QH) polarizer in the frontend signal chain. We conducted a controlled experiment in which the QH was bypassed in seven antennas, converting them to linear polarization feeds. The bypassed system shows dramatically improved performance: instrumental leakage reduced from 10--15\% to 2--5\%, residual leakage after calibration reduced from $\sim$0.5\% to less than $0.2\%$, and stable cross-hand phases independent of source polarization. For the polarized source DA\,240 (RM\,$=$\,3.3\,rad\,m$^{-2}$), the QH-bypassed system accurately recovers the expected $25^\circ$ polarization angle rotation across the band, which the with QH system fails to reproduce. These results establish that the QH polarizer is the dominant source of polarimetric instability in uGMRT Band\,4 and demonstrate that its removal enables reliable sub-GHz polarimetry. We recommend the linear feed configuration for science cases requiring accurate polarization angle and rotation measure measurements.

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.

Referee Report

1 major / 0 minor

Summary. The paper reports diagnostic observations and a controlled bypass experiment on seven uGMRT Band-4 antennas in which the Quadrature Hybrid (QH) polarizer was removed, converting the feeds to linear polarization. It claims that the bypassed configuration reduces instrumental leakage from 10-15% to 2-5%, residual leakage after calibration from ~0.5% to <0.2%, yields polarization-independent cross-hand phases, and correctly recovers the expected 25° polarization-angle rotation (RM = 3.3 rad m^{-2}) across the band on DA 240, whereas the standard QH configuration fails. The central conclusion is that the QH polarizer is the dominant source of polarimetric instability and that its removal enables reliable sub-GHz polarimetry.

Significance. If the attribution to the QH alone can be isolated from the simultaneous change in feed basis, the result would directly enable more reliable Faraday-rotation and depolarization studies with uGMRT Band 4. The use of a controlled hardware modification on a known polarized source (DA 240) and quantitative metrics on multiple calibrators constitutes a strength of the experimental design.

major comments (1)
  1. [bypass experiment description] Bypass experiment description (abstract and corresponding methods/results section): the reported stability gains (leakage drop, phase independence, correct RM recovery) are obtained after simultaneously bypassing the QH and converting the feeds from circular to linear polarization. No control measurement is described in which the same antennas are re-observed in an otherwise identical circular-feed configuration without the QH, nor are post-bypass changes to antenna response, beam, or calibration assumptions quantified. This leaves open the possibility that the observed improvement is partly or wholly due to the basis change rather than QH removal alone, undermining the claim that the QH is isolated as the dominant instability source.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their careful review and constructive feedback on our manuscript. We address the single major comment below, providing clarification on the experimental design and acknowledging the limitations in fully isolating the QH effect.

read point-by-point responses

  1. Referee: Bypass experiment description (abstract and corresponding methods/results section): the reported stability gains (leakage drop, phase independence, correct RM recovery) are obtained after simultaneously bypassing the QH and converting the feeds from circular to linear polarization. No control measurement is described in which the same antennas are re-observed in an otherwise identical circular-feed configuration without the QH, nor are post-bypass changes to antenna response, beam, or calibration assumptions quantified. This leaves open the possibility that the observed improvement is partly or wholly due to the basis change rather than QH removal alone, undermining the claim that the QH is isolated as the dominant instability source.

    Authors: We acknowledge that bypassing the quadrature hybrid (QH) simultaneously removes the polarizer and converts the feeds from circular to linear polarization, since the QH is the hardware element that combines the native linear feed signals into circular polarization. A control measurement maintaining an otherwise identical circular-feed configuration without the QH is therefore not feasible with the existing uGMRT Band-4 frontend. Our diagnostic observations that initially identified the polarization-dependent cross-hand phase behavior were performed with the standard QH configuration in place; systematic engineering tests then traced the instability to the QH itself. The bypass experiment was intended to test removal of this identified component. We agree that the manuscript does not quantify post-bypass changes to antenna response, beam pattern, or calibration assumptions, which is a genuine limitation of the presented analysis. In the revised manuscript we will add a dedicated paragraph in the discussion section that explicitly addresses this caveat, describes how calibration was performed in the linear basis, and notes the assumptions involved. We will also revise the abstract and conclusions to state more precisely that the improvement is observed in the linear-feed configuration after QH removal, rather than claiming complete isolation of the QH effect independent of the basis change. revision: partial

Circularity Check

0 steps flagged

No circularity; central claim follows from direct hardware comparison experiment

full rationale

The paper reports results from a controlled bypass experiment on seven antennas, comparing polarimetric metrics (leakage, cross-hand phase stability, RM recovery on DA 240) between the standard QH configuration and the bypassed linear-feed configuration. The claim that the QH is the dominant instability source is an empirical attribution based on the observed performance differences, not a derivation, equation, or fitted parameter that reduces to its own inputs by construction. No self-definitional steps, fitted-input predictions, or load-bearing self-citations appear in the provided text. The experiment description and results stand as self-contained observational evidence against external benchmarks.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The central claim is grounded in experimental comparison rather than theoretical derivation; no free parameters are fitted and no new entities are postulated. The key background assumption is the standard domain assumption of calibration transferability in radio interferometry.

axioms (1)
  • domain assumption Instrumental responses in radio interferometry are independent of source fractional polarization (calibration transferability).
    The paper identifies and tests the violation of this assumption caused by the QH polarizer.

pith-pipeline@v0.9.0 · 5836 in / 1279 out tokens · 48368 ms · 2026-05-25T06:50:35.945453+00:00 · methodology

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Works this paper leans on

1 extracted references · 1 canonical work pages

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