Rapid FRD determination for multiplexed fibre systems -- I. The quasi-near field model and its uncertainties

TL;DR

This paper introduces a rapid, quasi-near field model-based method for measuring focal ratio degradation in densely packed multiplexed fibre systems, significantly improving efficiency and accuracy over traditional techniques.

Contribution

The paper presents a novel quasi-near field model enabling fast, simultaneous FRD measurement in highly multiplexed fibre systems like IFUs, with validated accuracy and potential for broader fibre property assessments.

Findings

Achieved FRD measurement error below 0.35 in F-ratio.

Validated method on FASOT-IFU with FRD within 5.0-7.0 range.

Method allows rapid, simultaneous assessment of multiple fibres.

Abstract

Focal Ratio Degradation (FRD) in fibres is a crucial factor to control in astronomical instruments in order to minimize light loss. As astronomical instrumentation has advanced, the integration of large populations of fibres has become common. However, determining FRD in multiplexed fibre systems has become a challenging and time-consuming task. The Integral Field Unit for the Fiber Arrayed Solar Optical Telescope (FASOT-IFU) represents the most densely arranged fibre-based IFU in a single unit. Due to the close packing of fibres in the V-groove of the slit end, measuring FRD is particularly challenging as the output spots are prone to overlapping with adjacent fibres. In this paper, a novel method based on the quasi-near field model is proposed to enable rapid FRD measurement in highly multiplexed fibre systems like IFUs and multi-object observation systems. The principle and uncertainties associated with the method are investigated. The method's validity is demonstrated by applying it to determine the FRD in FASOT-IFU, with the achieved FRD performance meeting the acceptable requirements of FASOT-IFU, where the output focal ratio primarily falls within the range of 5.0-7.0. The results indicate that the proposed method offers several advantages, including the simultaneous and rapid measurement of FRD in multiple fibres with high accuracy (error smaller than 0.35 in F-ratio). Furthermore, besides FRD, the method exhibits potential for extensive measurements of throughput, scrambling, and spectral analysis.