# TFAW: wavelet-based signal reconstruction to reduce photometric noise in   time-domain surveys

**Authors:** D. del Ser (1, 2, 3), O. Fors (1, 2, 3), J. N\'u\~nez (1, and 3) ((1) Dept. de F\'isica Qu\`antica i Astrof\'isica, Institut de, Ci\`encies del Cosmos (ICCUB), Universitat de Barcelona, (2) University of, North Carolina at Chapel Hill, Department of Physics, Astronomy, (3), Observatori Fabra, Reial Acad\`emia de Ci\`encies i Arts de Barcelona)

arXiv: 1702.06547 · 2018-11-14

## TL;DR

TFAW is a wavelet-enhanced version of the Trend Filtering Algorithm that significantly improves the detection and characterization of astrophysical signals in noisy time-domain survey data.

## Contribution

TFAW introduces wavelet-based noise filtering into TFA, enhancing signal detection and parameter estimation without altering intrinsic signal characteristics.

## Key findings

- Increases signal detection efficiency up to 2.5 times for low SNR data.
- Improves transit detection rate by 2-5 times in low-SNR regimes.
- Reduces noise standard deviation by approximately 40 times compared to TFA.

## Abstract

There have been many efforts to correct systematic effects in astronomical light curves to improve the detection and characterization of planetary transits and astrophysical variability. Algorithms like the Trend Filtering Algorithm (TFA) use simultaneously-observed stars to remove systematic effects, and binning is used to reduce high-frequency random noise. We present TFAW, a wavelet-based modified version of TFA. TFAW aims to increase the periodic signal detection and to return a detrended and denoised signal without modifying its intrinsic characteristics. We modify TFA's frequency analysis step adding a Stationary Wavelet Transform filter to perform an initial noise and outlier removal and increase the detection of variable signals. A wavelet filter is added to TFA's signal reconstruction to perform an adaptive characterization of the noise- and trend-free signal and the noise contribution at each iteration while preserving astrophysical signals. We carried out tests over simulated sinusoidal and transit-like signals to assess the effectiveness of the method and applied TFAW to real light curves from TFRM. We also studied TFAW's application to simulated multiperiodic signals, improving their characterization. TFAW improves the signal detection rate by increasing the signal detection efficiency (SDE) up to a factor ~2.5x for low SNR light curves. For simulated transits, the transit detection rate improves by a factor ~2-5x in the low-SNR regime compared to TFA. TFAW signal approximation performs up to a factor ~2x better than bin averaging for planetary transits. The standard deviations of simulated and real TFAW light curves are ~40x better than TFA. TFAW yields better MCMC posterior distributions and returns lower uncertainties, less biased transit parameters and narrower (~10x) credibility intervals for simulated transits. We present a newly-discovered variable star from TFRM.

## Full text

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## Figures

18 figures with captions in the complete paper: https://tomesphere.com/paper/1702.06547/full.md

## References

59 references — full list in the complete paper: https://tomesphere.com/paper/1702.06547/full.md

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Source: https://tomesphere.com/paper/1702.06547