What question did this study set out to answer?

The aim is to calibrate a 36+1 coil rotational detector for precise measurement of scalar torsion fields.

April 21, 2026Open Access

Calibration Report: 36+1 Coil Rotational Detector with Table Rotation Asymmetry

Key Points

The aim is to calibrate a 36+1 coil rotational detector for precise measurement of scalar torsion fields.
Developed calibration parameters based on a 36+1 coil rotational interferometer design.
Conducted numerical simulations to determine optimal central coil gain and assess performance metrics.
Analyzed the impact of table rotation asymmetry on measurement accuracy.
Achieved an optimal central coil gain of 1.9694, enhancing detector performance.
Demonstrated an RMS saturation of 0.7050, approaching the theoretical limit of 0.7071.
Improved sensitivity and calibration ease compared to previous designs.

Abstract

We present the calibration parameters for a 36+1 coil rotational interferometer designedto detect scalar torsion fields predicted by the Universal Applicable Time (UAT) and UnifiedPrinciple of Causality (UPC) frameworks. The detector employs thirty-six peripheral coilsarranged with a 10◦ base phase step, a 7% table rotation asymmetry, and a central observercoil with a fixed gain. Logarithmic phase modulation is governed by the torsion parameterτ =0.3697. Numerical simulations yield an optimal central coil gain of 1.9694, resulting inan RMS saturation of 0.7050 (99.70% of the theoretical causal buffer limit 0.7071). Thisconfiguration offers a robust, easily calibrated alternative to the 8+1 design, with enhanceddirectional sensitivity and simplified hardware requirements.Keywords: scalar torsion, dark matter, phase interferometry, 36-coil array, table rotation asymmetry

Calibration Report: 36+1 Coil Rotational Detector with Table Rotation Asymmetry

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Abstract

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