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Main Authors: Yu, Xinghang, Yu, Ce, Shao, Zeguang, Yang, Bin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.18784
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author Yu, Xinghang
Yu, Ce
Shao, Zeguang
Yang, Bin
author_facet Yu, Xinghang
Yu, Ce
Shao, Zeguang
Yang, Bin
contents With the exponential growth of time-domain surveys, the volume of light curves has increased rapidly. However, many survey projects, such as Gaia, still rely on offline batch-processing workflows in which data are calibrated, merged, and released only after an observing phase is completed. This latency delays scientific analysis and causes many high-value transient events to be buried in archival data, missing the window for timely follow-up. While existing alert brokers handle heterogeneous data streams, it remains difficult to deploy a unified framework that combines high-performance incremental storage with real-time classification on local infrastructure. To address this challenge, we propose TDLight, a scalable system that adapts the time-series database TDengine (a high-performance IoT database) for astronomical data using a one-table-per-source schema. This architecture supports high-throughput ingestion, achieving 954,000 rows s^-1 for archived data and 541,000 rows s^-1 for incremental streams, while Hierarchical Equal Area isoLatitude Pixelization (HEALPix) indexing enables efficient cone-search queries. Building on this storage layer, we integrate the pre-trained hierarchical Random Forest classifier from the LEAVES framework to construct an incremental classification pipeline. Using the LEAVES dataset, we simulate data accumulation and evaluate a trigger-based strategy that performs early classification at specific observational milestones. In addition, by monitoring the evolution of classification probabilities, the system identifies "high-value candidates" -- sources that show high early confidence but later undergo significant label shifts. TDLight is released as an open-source Dockerized environment, providing a deployable infrastructure for next-generation time-domain surveys.
format Preprint
id arxiv_https___arxiv_org_abs_2511_18784
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle TDLight: A Framework for Incremental Light Curve Management and Smart Classification
Yu, Xinghang
Yu, Ce
Shao, Zeguang
Yang, Bin
Instrumentation and Methods for Astrophysics
With the exponential growth of time-domain surveys, the volume of light curves has increased rapidly. However, many survey projects, such as Gaia, still rely on offline batch-processing workflows in which data are calibrated, merged, and released only after an observing phase is completed. This latency delays scientific analysis and causes many high-value transient events to be buried in archival data, missing the window for timely follow-up. While existing alert brokers handle heterogeneous data streams, it remains difficult to deploy a unified framework that combines high-performance incremental storage with real-time classification on local infrastructure. To address this challenge, we propose TDLight, a scalable system that adapts the time-series database TDengine (a high-performance IoT database) for astronomical data using a one-table-per-source schema. This architecture supports high-throughput ingestion, achieving 954,000 rows s^-1 for archived data and 541,000 rows s^-1 for incremental streams, while Hierarchical Equal Area isoLatitude Pixelization (HEALPix) indexing enables efficient cone-search queries. Building on this storage layer, we integrate the pre-trained hierarchical Random Forest classifier from the LEAVES framework to construct an incremental classification pipeline. Using the LEAVES dataset, we simulate data accumulation and evaluate a trigger-based strategy that performs early classification at specific observational milestones. In addition, by monitoring the evolution of classification probabilities, the system identifies "high-value candidates" -- sources that show high early confidence but later undergo significant label shifts. TDLight is released as an open-source Dockerized environment, providing a deployable infrastructure for next-generation time-domain surveys.
title TDLight: A Framework for Incremental Light Curve Management and Smart Classification
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2511.18784