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Main Authors: Bender, Clara, Davidsen, Line, Olesen, Søren Schou, Cichosz, Simon Lebech
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.00608
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author Bender, Clara
Davidsen, Line
Olesen, Søren Schou
Cichosz, Simon Lebech
author_facet Bender, Clara
Davidsen, Line
Olesen, Søren Schou
Cichosz, Simon Lebech
contents Aim/background: Continuous glucose monitoring (CGM) generates dense time-series data, posing challenges for efficient storage, transmission, and analysis. This study evaluates novel encoding strategies that reduce CGM profiles to a compact set of landmark points while maintaining fidelity in reconstructed signals and derived glycemic metrics. Methods: We utilized two complementary CGM datasets, synthetic data generated via a Conditional Generative Adversarial Network (CGAN) and real-world measurements from a randomized crossover trial, to develop and validate three encoding approaches: (1) Peaks & Nadirs (PN), (2) Peaks, Nadirs, and Support Points (PN+), and (3) Uniform Downsampling. Each method compresses CGM profiles by selecting key timestamps and glucose values, followed by signal reconstruction via interpolation. Performance was assessed using compression ratio, mean absolute error (MAE), and R^2 between original and reconstructed clinically relevant CGM-derived metrics. Statistical analyses evaluated the preservation of clinically relevant glucose features. Results: Across varying compression settings, PN+ consistently outperformed PN and downsampling, achieving the highest R^2 and lowest MAE. At a compression ratio of 13 (22 landmark points per 24-hour profile), PN+ reduced MAE by a factor of 3.6 compared to downsampling (0.77 vs. 2.75), with notable improvements in metrics sensitive to glucose excursions. Encoding and decoding required an average of 0.13 seconds per profile. Validation on real-world data confirmed these trends. Conclusions: The proposed PN+ method produces a compact CGM representation that retains critical glycemic dynamics while discarding redundant portions of the profiles. The CGM signal can be reconstructed with high precision from the encoding representation.
format Preprint
id arxiv_https___arxiv_org_abs_2601_00608
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Peak-Nadir Encoding for Efficient CGM Data Compression and High-Fidelity Reconstruction
Bender, Clara
Davidsen, Line
Olesen, Søren Schou
Cichosz, Simon Lebech
Quantitative Methods
Aim/background: Continuous glucose monitoring (CGM) generates dense time-series data, posing challenges for efficient storage, transmission, and analysis. This study evaluates novel encoding strategies that reduce CGM profiles to a compact set of landmark points while maintaining fidelity in reconstructed signals and derived glycemic metrics. Methods: We utilized two complementary CGM datasets, synthetic data generated via a Conditional Generative Adversarial Network (CGAN) and real-world measurements from a randomized crossover trial, to develop and validate three encoding approaches: (1) Peaks & Nadirs (PN), (2) Peaks, Nadirs, and Support Points (PN+), and (3) Uniform Downsampling. Each method compresses CGM profiles by selecting key timestamps and glucose values, followed by signal reconstruction via interpolation. Performance was assessed using compression ratio, mean absolute error (MAE), and R^2 between original and reconstructed clinically relevant CGM-derived metrics. Statistical analyses evaluated the preservation of clinically relevant glucose features. Results: Across varying compression settings, PN+ consistently outperformed PN and downsampling, achieving the highest R^2 and lowest MAE. At a compression ratio of 13 (22 landmark points per 24-hour profile), PN+ reduced MAE by a factor of 3.6 compared to downsampling (0.77 vs. 2.75), with notable improvements in metrics sensitive to glucose excursions. Encoding and decoding required an average of 0.13 seconds per profile. Validation on real-world data confirmed these trends. Conclusions: The proposed PN+ method produces a compact CGM representation that retains critical glycemic dynamics while discarding redundant portions of the profiles. The CGM signal can be reconstructed with high precision from the encoding representation.
title Peak-Nadir Encoding for Efficient CGM Data Compression and High-Fidelity Reconstruction
topic Quantitative Methods
url https://arxiv.org/abs/2601.00608