Lucy Wright, Nicholas A. Teanby, Patrick G. J. Irwin, Conor A. Nixon
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引用次数: 0
Abstract
The Composite InfraRed Spectrometer (CIRS) instrument onboard the Cassini spacecraft performed 8.4 million spectral observations of Titan at resolutions between 0.5–15.5 cm\(^{\varvec{-1}}\). More than 3 million of these were acquired at a low spectral resolution (SR) (13.5–15.5 cm\(^{\varvec{-1}}\)), which have excellent spatial and temporal coverage in addition to the highest spatial resolution and lowest noise per spectrum of any of the CIRS observations. Despite this, the CIRS low-SR dataset is currently underused for atmospheric composition analysis, as spectral features are often blended and subtle compared to those in higher SR observations. The vast size of the dataset also poses a challenge as an efficient forward model is required to fully exploit these observations. Here, we show that the CIRS FP3/4 nadir low-SR observations of Titan can be accurately forward modelled using a computationally efficient correlated-\(\varvec{k}\) method. We quantify wavenumber-dependent forward modelling errors, with mean 0.723 nW cm\(^{\varvec{-2}}\,\)sr\(^{\varvec{-1}}\)/cm\(^{\varvec{-1}}\) (FP3: 600–890 cm\(^{\varvec{-1}}\)) and 0.248 nW cm\(^{\varvec{-2}}\,\)sr\(^{\varvec{-1}}\,\)/ cm\(^{\varvec{-1}}\) (FP4: 1240–1360 cm\(^{\varvec{-1}}\)), that can be used to improve the rigour of future retrievals. Alternatively, in cases where more accuracy is required, we show observations can be forward modelled using an optimised line-by-line method, significantly reducing computation time.
摘要 卡西尼号航天器上的复合红外光谱仪(CIRS)对土卫六进行了 840 万次光谱观测,分辨率介于 0.5-15.5 cm \(^{\varvec{-1}}\)之间。其中有 300 多万次是在低光谱分辨率(SR)(13.5-15.5 厘米)下获得的,除了在 CIRS 观测中具有最高的空间分辨率和最低的单位光谱噪声之外,还具有出色的空间和时间覆盖范围。尽管如此,CIRS 低 SR 数据集目前在大气成分分析中使用不足,因为与高 SR 观测数据相比,它的光谱特征往往是混合的、微妙的。数据集的庞大规模也带来了挑战,因为需要一个高效的前向模型来充分利用这些观测数据。在这里,我们展示了土卫六的CIRS FP3/4天顶低SR观测数据可以通过一种计算高效的相关-(\varvec{k}\)方法进行精确的前向建模。我们量化了与波长相关的前向建模误差,其平均值为 0.723 nW cm ((^{\varvec{-2}}\,\) sr \(^{\varvec{-1}}\) /cm \(^{\varvec{-1}}\)(FP3:600-890 cm \(^{\varvec{-1}}\))和 0.248 nW cm \(^{\varvec{-2}}\,\) sr \(^{\varvec{-1}}\,\) / cm \(^{\varvec{-1}}\) (FP4: 1240-1360 cm \(^{\varvec{-1}}\) ),可用于提高未来检索的严谨性。另外,在需要更高精度的情况下,我们展示了可以使用逐行优化的方法对观测数据进行前向建模,从而大大减少计算时间。
期刊介绍:
Many new instruments for observing astronomical objects at a variety of wavelengths have been and are continually being developed. Furthermore, a vast amount of effort is being put into the development of new techniques for data analysis in order to cope with great streams of data collected by these instruments.
Experimental Astronomy acts as a medium for the publication of papers of contemporary scientific interest on astrophysical instrumentation and methods necessary for the conduct of astronomy at all wavelength fields.
Experimental Astronomy publishes full-length articles, research letters and reviews on developments in detection techniques, instruments, and data analysis and image processing techniques. Occasional special issues are published, giving an in-depth presentation of the instrumentation and/or analysis connected with specific projects, such as satellite experiments or ground-based telescopes, or of specialized techniques.
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