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Tran, Trung Hieu

Trung Hieu Tran

Dr. rer. nat.

Research Assistant
ITI
Computational Imaging Systems

Contact

+49 711 685 88216
+49 711 685 88250
Email

Universitätsstraße 38
70569 Stuttgart
Deutschland
Room: 2.205

Office Hours

on appointment

Publications

2022
1. FL-MISR: fast large-scale multi-image super-resolution for computed tomography based on multi-GPU acceleration. Kaicong Sun; Trung-Hieu Tran; Jajnabalkya Guhathakurta and Sven Simon. Journal of Real-Time Image Processing 19, 2 (2022), pp. 331--344. DOI: https://doi.org/10.1007/s00138-014-0623-4
  - BibTeX
  - DOI
  BibTeX
  @article{sun2022fl, abteilung = {cis}, author = {Sun, Kaicong and Tran, Trung-Hieu and Guhathakurta, Jajnabalkya and Simon, Sven}, doi = {10.1007/s00138-014-0623-4}, journal = {Journal of Real-Time Image Processing}, number = 2, pages = {331--344}, publisher = {Springer}, title = {FL-MISR: fast large-scale multi-image super-resolution for computed tomography based on multi-GPU acceleration}, volume = 19, year = 2022 }
  DOI
  10.1007/s00138-014-0623-4
2. 3DVSR: 3D EPI volume-based approach for angular and spatial light field image super-resolution. Trung-Hieu Tran; Jan Berberich and Sven Simon. Signal Processing 192, (2022), pp. 108373. DOI: https://doi.org/10.1016/j.sigpro.2021.108373
  Abstract
  Light field (LF) imaging, which captures both spatial and angular information of a scene, is undoubtedly beneficial to numerous applications. Although various techniques have been proposed for LF acquisition, achieving both angularly and spatially high-resolution LF remains a technology challenge. In this paper, a learning-based approach applied to 3D epipolar image (EPI) is proposed to reconstruct high-resolution LF. Through a 2-stage super-resolution framework, the proposed approach effectively addresses various LF super-resolution (SR) problems, i.e., spatial SR, angular SR, and angular-spatial SR. While the first stage provides flexible options to up-sample EPI volume to the desired resolution, the second stage, which consists of a novel EPI volume-based refinement network (EVRN), substantially enhances the quality of the high-resolution EPI volume. An extensive evaluation on 90 challenging synthetic and real-world light field scenes from 7 published datasets shows that the proposed approach outperforms state-of-the-art methods to a large extend for both spatial and angular super-resolution problem, i.e., an average peak signal to noise ratio improvement of more than 2.0 dB, 1.4 dB, and 3.14 dB in spatial SR ×2, spatial SR ×4, and angular SR respectively. The reconstructed 4D light field demonstrates a balanced performance distribution across all perspective images and presents superior visual quality compared to the previous works.
  BibTeX
  @article{TRAN2022108373, abstract = {Light field (LF) imaging, which captures both spatial and angular information of a scene, is undoubtedly beneficial to numerous applications. Although various techniques have been proposed for LF acquisition, achieving both angularly and spatially high-resolution LF remains a technology challenge. In this paper, a learning-based approach applied to 3D epipolar image (EPI) is proposed to reconstruct high-resolution LF. Through a 2-stage super-resolution framework, the proposed approach effectively addresses various LF super-resolution (SR) problems, i.e., spatial SR, angular SR, and angular-spatial SR. While the first stage provides flexible options to up-sample EPI volume to the desired resolution, the second stage, which consists of a novel EPI volume-based refinement network (EVRN), substantially enhances the quality of the high-resolution EPI volume. An extensive evaluation on 90 challenging synthetic and real-world light field scenes from 7 published datasets shows that the proposed approach outperforms state-of-the-art methods to a large extend for both spatial and angular super-resolution problem, i.e., an average peak signal to noise ratio improvement of more than 2.0 dB, 1.4 dB, and 3.14 dB in spatial SR ×2, spatial SR ×4, and angular SR respectively. The reconstructed 4D light field demonstrates a balanced performance distribution across all perspective images and presents superior visual quality compared to the previous works.}, abteilung = {cis}, author = {Tran, Trung-Hieu and Berberich, Jan and Simon, Sven}, doi = {10.1016/j.sigpro.2021.108373}, issn = {0165-1684}, journal = {Signal Processing}, pages = 108373, title = {3DVSR: 3D EPI volume-based approach for angular and spatial light field image super-resolution}, url = {https://www.sciencedirect.com/science/article/pii/S0165168421004102}, volume = 192, year = 2022 }
  Link
  https://www.sciencedirect.com/science/article/pii/S0165168421004102
  DOI
  10.1016/j.sigpro.2021.108373
2021
1. GVLD: A Fast and Accurate GPU-Based Variational Light-Field Disparity Estimation Approach. Trung-Hieu Tran; Gasim Mammadov and Sven Simon. IEEE Transactions on Circuits and Systems for Video Technology 31, 7 (2021), pp. 2562–2574. DOI: https://doi.org/10.1109/TCSVT.2020.3028258
  - BibTeX
  - DOI
  BibTeX
  @article{9210556, abteilung = {cis}, author = {Tran, Trung-Hieu and Mammadov, Gasim and Simon, Sven}, doi = {10.1109/TCSVT.2020.3028258}, journal = {IEEE Transactions on Circuits and Systems for Video Technology}, number = 7, pages = {2562-2574}, title = {GVLD: A Fast and Accurate GPU-Based Variational Light-Field Disparity Estimation Approach}, volume = 31, year = 2021 }
  DOI
  10.1109/TCSVT.2020.3028258
2. A lightweight and robust VCSEL-based 3D-depth sensing approach for mobile application. Trung-Hieu Tran; Sven Simon; Bo Chen; Detlef Russ and Daniel Claus. In Digital Optical Technologies 2021, 2021, pp. 70-- 77. DOI: https://doi.org/10.1117/12.2591653
  BibTeX
  @inproceedings{10.1117/12.2591653, abteilung = {cis}, author = {Tran, Trung-Hieu and Simon, Sven and Chen, Bo and Russ, Detlef and Claus, Daniel}, booktitle = {Digital Optical Technologies 2021}, doi = {10.1117/12.2591653}, editor = {Kress, Bernard C. and Peroz, Christophe}, organization = {International Society for Optics and Photonics}, pages = {70 -- 77}, publisher = {SPIE}, title = {{A lightweight and robust VCSEL-based 3D-depth sensing approach for mobile application}}, url = {https://doi.org/10.1117/12.2591653}, volume = 11788, year = 2021 }
  Link
  https://doi.org/10.1117/12.2591653
  DOI
  10.1117/12.2591653
3. 3DVSR: 3D EPI Volume-based Approach for Angular and Spatial Light filed Image Super-resolution. T. H. Tran; J. Berberich and S. Simon. Signal processing (2021), pp. 108373.
  - BibTeX
  BibTeX
  @article{tbs21, abteilung = {cis}, author = {Tran, T. H. and Berberich, J. and Simon, S.}, journal = {Signal processing}, pages = 108373, title = {3DVSR: 3D EPI Volume-based Approach for Angular and Spatial Light filed Image Super-resolution}, year = 2021 }
2020
1. Multi-frame Super-resolution Reconstruction based on Mixed Poisson-Gaussian Noise. K. Sun; T.-H. Tran; R. Krawtschenko and S. Simon. Signal Processing: Image Communication, Elsevier 82, (2020), pp. 1–10.
  - BibTeX
  BibTeX
  @article{stks20, abteilung = {cis}, author = {Sun, K. and Tran, T.-H. and Krawtschenko, R. and Simon, S.}, journal = {Signal Processing: Image Communication, Elsevier}, pages = {1-10}, title = {Multi-frame Super-resolution Reconstruction based on Mixed Poisson-Gaussian Noise}, volume = 82, year = 2020 }
2019
1. A JND-Based Pixel-Domain Algorithm and Hardware Architecture for Perceptual Image Coding. Zhe Wang; Trung-Hieu Tran; Ponnanna Kelettira Muthappa and Sven Simon. Journal of Imaging 5, 5 (2019). DOI: https://doi.org/10.3390/jimaging5050050
  Abstract
  This paper presents a hardware efficient pixel-domain just-noticeable difference (JND) model and its hardware architecture implemented on an FPGA. This JND model architecture is further proposed to be part of a low complexity pixel-domain perceptual image coding architecture, which is based on downsampling and predictive coding. The downsampling is performed adaptively on the input image based on regions-of-interest (ROIs) identified by measuring the downsampling distortions against the visibility thresholds given by the JND model. The coding error at any pixel location can be guaranteed to be within the corresponding JND threshold in order to obtain excellent visual quality. Experimental results show the improved accuracy of the proposed JND model in estimating visual redundancies compared with classic JND models published earlier. Compression experiments demonstrate improved rate-distortion performance and visual quality over JPEG-LS as well as reduced compressed bit rates compared with other standard codecs such as JPEG 2000 at the same peak signal-to-perceptible-noise ratio (PSPNR). FPGA synthesis results targeting a mid-range device show very moderate hardware resource requirements and over 100 Megapixel/s throughput of both the JND model and the perceptual encoder.
  BibTeX
  @article{jimaging5050050, abstract = {This paper presents a hardware efficient pixel-domain just-noticeable difference (JND) model and its hardware architecture implemented on an FPGA. This JND model architecture is further proposed to be part of a low complexity pixel-domain perceptual image coding architecture, which is based on downsampling and predictive coding. The downsampling is performed adaptively on the input image based on regions-of-interest (ROIs) identified by measuring the downsampling distortions against the visibility thresholds given by the JND model. The coding error at any pixel location can be guaranteed to be within the corresponding JND threshold in order to obtain excellent visual quality. Experimental results show the improved accuracy of the proposed JND model in estimating visual redundancies compared with classic JND models published earlier. Compression experiments demonstrate improved rate-distortion performance and visual quality over JPEG-LS as well as reduced compressed bit rates compared with other standard codecs such as JPEG 2000 at the same peak signal-to-perceptible-noise ratio (PSPNR). FPGA synthesis results targeting a mid-range device show very moderate hardware resource requirements and over 100 Megapixel/s throughput of both the JND model and the perceptual encoder.}, abteilung = {cis}, article-number = {50}, author = {Wang, Zhe and Tran, Trung-Hieu and Muthappa, Ponnanna Kelettira and Simon, Sven}, doi = {10.3390/jimaging5050050}, issn = {2313-433X}, journal = {Journal of Imaging}, number = 5, title = {A JND-Based Pixel-Domain Algorithm and Hardware Architecture for Perceptual Image Coding}, url = {https://www.mdpi.com/2313-433X/5/5/50}, volume = 5, year = 2019 }
  Link
  https://www.mdpi.com/2313-433X/5/5/50
  DOI
  10.3390/jimaging5050050
2. An Architecture for Asymmetric Numeral Systems Entropy Decoder-A Comparison with a Canonical Huffman Decoder. S. M. Najmabadi; T. H. Tran; S. Eissa; S. Tungal and S. Simon. Journal of Signal Processing Systems 91, 7 (2019), pp. 805–817.
  - BibTeX
  BibTeX
  @article{ntets19, abteilung = {cis}, author = {Najmabadi, S. M. and Tran, T. H. and Eissa, S. and Tungal, S. and Simon, S.}, journal = {Journal of Signal Processing Systems}, number = 7, pages = {805-817}, title = {An Architecture for Asymmetric Numeral Systems Entropy Decoder-A Comparison with a Canonical Huffman Decoder}, volume = 91, year = 2019 }
3. An Architecture for Asymmetric Numeral Systems Entropy Decoder - A Comparison with a Canonical Huffman Decoder. Seyyed Mahdi Najmabadi; Trung-Hieu Tran; Sherif Eissa; Harsimran Singh Tungal and Sven Simon. J. Signal Process. Syst. 91, 7 (2019), pp. 805--817. DOI: https://doi.org/10.1007/s11265-018-1421-4
  BibTeX
  @article{DBLP:journals/vlsisp/NajmabadiTETS19, abteilung = {cis}, author = {Najmabadi, Seyyed Mahdi and Tran, Trung{-}Hieu and Eissa, Sherif and Tungal, Harsimran Singh and Simon, Sven}, bibsource = {dblp computer science bibliography, https://dblp.org}, doi = {10.1007/s11265-018-1421-4}, journal = {J. Signal Process. Syst.}, number = 7, pages = {805--817}, title = {An Architecture for Asymmetric Numeral Systems Entropy Decoder - {A} Comparison with a Canonical Huffman Decoder}, url = {https://doi.org/10.1007/s11265-018-1421-4}, volume = 91, year = 2019 }
  Link
  https://doi.org/10.1007/s11265-018-1421-4
  DOI
  10.1007/s11265-018-1421-4
2018
1. GPU-Accelerated Light-Field Image Super-Resolution. Trung-Hieu Tran; Gasim Mammadov; Kaicong Sun and Sven Simon. In 2018 International Conference on Advanced Computing and Applications (ACOMP), 2018, pp. 7–13. DOI: https://doi.org/10.1109/ACOMP.2018.00010
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{8589482, abteilung = {cis}, author = {Tran, Trung-Hieu and Mammadov, Gasim and Sun, Kaicong and Simon, Sven}, booktitle = {2018 International Conference on Advanced Computing and Applications (ACOMP)}, doi = {10.1109/ACOMP.2018.00010}, pages = {7-13}, title = {GPU-Accelerated Light-Field Image Super-Resolution}, year = 2018 }
  DOI
  10.1109/ACOMP.2018.00010
2017
1. Variational disparity estimation framework for plenoptic images. Trung-Hieu Tran; Zhe Wang and Sven Simon. In 2017 IEEE International Conference on Multimedia and Expo (ICME), 2017, pp. 1189–1194. DOI: https://doi.org/10.1109/ICME.2017.8019377
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{8019377, abteilung = {cis}, author = {Tran, Trung-Hieu and Wang, Zhe and Simon, Sven}, booktitle = {2017 IEEE International Conference on Multimedia and Expo (ICME)}, doi = {10.1109/ICME.2017.8019377}, pages = {1189-1194}, title = {Variational disparity estimation framework for plenoptic images}, year = 2017 }
  DOI
  10.1109/ICME.2017.8019377
2. Hardware-based architecture for asymmetric numeral systems entropy decoder. Seyyed Mahdi Najmabadi; Harsimran Singh Tungal; Trung-Hieu Tran and Sven Simon. In 2017 Conference on Design and Architectures for Signal and Image Processing (DASIP), 2017, pp. 1–6. DOI: https://doi.org/10.1109/DASIP.2017.8122109
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{8122109, abteilung = {cis}, author = {Najmabadi, Seyyed Mahdi and Tungal, Harsimran Singh and Tran, Trung-Hieu and Simon, Sven}, booktitle = {2017 Conference on Design and Architectures for Signal and Image Processing (DASIP)}, doi = {10.1109/DASIP.2017.8122109}, pages = {1-6}, title = {Hardware-based architecture for asymmetric numeral systems entropy decoder}, year = 2017 }
  DOI
  10.1109/DASIP.2017.8122109
3. A resource-efficient monitoring architecture for hardware accelerated self-adaptive online data stream compression. Seyyed Mahdi Najmabadi; Prajwala Pandit; Trung-Hieu Tran and Sven Simon. In 2017 Signal Processing: Algorithms, Architectures, Arrangements, and Applications (SPA), 2017, pp. 222–227. DOI: https://doi.org/10.23919/SPA.2017.8166868
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{8166868, abteilung = {cis}, author = {Najmabadi, Seyyed Mahdi and Pandit, Prajwala and Tran, Trung-Hieu and Simon, Sven}, booktitle = {2017 Signal Processing: Algorithms, Architectures, Arrangements, and Applications (SPA)}, doi = {10.23919/SPA.2017.8166868}, pages = {222-227}, title = {A resource-efficient monitoring architecture for hardware accelerated self-adaptive online data stream compression}, year = 2017 }
  DOI
  10.23919/SPA.2017.8166868
4. Light-field image compression based on variational disparity estimation and motion-compensated wavelet decomposition. Trung-Hieu Tran; Yousef Baroud; Zhe Wang; Sven Simon and David Taubman. In 2017 IEEE International Conference on Image Processing (ICIP), 2017, pp. 3260–3264. DOI: https://doi.org/10.1109/ICIP.2017.8296885
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{8296885, abteilung = {cis}, author = {Tran, Trung-Hieu and Baroud, Yousef and Wang, Zhe and Simon, Sven and Taubman, David}, booktitle = {2017 IEEE International Conference on Image Processing (ICIP)}, doi = {10.1109/ICIP.2017.8296885}, pages = {3260-3264}, title = {Light-field image compression based on variational disparity estimation and motion-compensated wavelet decomposition}, year = 2017 }
  DOI
  10.1109/ICIP.2017.8296885

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