Efﬁcient Data Compression for 3D Sparse TPC via Bicephalous Convolutional Autoencoder

doi:doi:10.57702/qmvzf6r4

Efﬁcient Data Compression for 3D Sparse TPC via Bicephalous Convolutional Autoencoder

Real-time data collection and analysis in large experimental facilities present a great challenge across multiple domains, including high energy physics, nuclear physics, and cosmology. To address this, machine learning (ML)-based methods for real-time data compression have drawn significant attention. However, unlike natural image data, such as CIFAR and ImageNet that are relatively small-sized and continuous, scientific data often come in as three-dimensional (3D) data volumes at high rates with high sparsity (many zeros) and non-Gaussian value distribution.

BibTex:

@dataset{Yi_Huang_and_Yihui_Ren_and_Shinjae_Yoo_and_Jin_Huang_2024,
    abstract = {Real-time data collection and analysis in large experimental facilities present a great challenge across multiple domains, including high energy physics, nuclear physics, and cosmology. To address this, machine learning (ML)-based methods for real-time data compression have drawn significant attention. However, unlike natural image data, such as CIFAR and ImageNet that are relatively small-sized and continuous, scientific data often come in as three-dimensional (3D) data volumes at high rates with high sparsity (many zeros) and non-Gaussian value distribution.},
    author = {Yi Huang and Yihui Ren and Shinjae Yoo and Jin Huang},
    doi = {10.57702/qmvzf6r4},
    institution = {No Organization},
    keyword = {'3D data', 'Real-time data compression', 'Sparse data'},
    month = {dec},
    publisher = {TIB},
    title = {Efﬁcient Data Compression for 3D Sparse TPC via Bicephalous Convolutional Autoencoder},
    url = {https://service.tib.eu/ldmservice/dataset/ef-cient-data-compression-for-3d-sparse-tpc-via-bicephalous-convolutional-autoencoder},
    year = {2024}
}