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ORCIDDavid S. Taubman
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Publications
- 2025
[j57]James L. Gray
, Aous Thabit Naman, David S. Taubman:
Multi-View Disparity Estimation Using the Gradient Consistency Model. IEEE Trans. Image Process. 34: 4676-4690 (2025)- 2024
- [j56]Priyabrata Karmakar, M. Manzur Murshed, Manoranjan Paul, David Taubman:
Efficient motion modelling with variable-sized blocks from hierarchical cuboidal partitioning. Multim. Tools Appl. 83(7): 20743-20757 (2024) - [j55]Xinyue Li, Aous Thabit Naman, David Taubman:
Exploration of Learned Lifting-Based Transform Structures for Fully Scalable and Accessible Wavelet-Like Image Compression. IEEE Trans. Image Process. 33: 6173-6188 (2024) - [i7]Xinyue Li, Aous Thabit Naman, David Taubman:
Exploration of Learned Lifting-Based Transform Structures for Fully Scalable and Accessible Wavelet-Like Image Compression. CoRR abs/2402.18761 (2024) - [i6]Xinyue Li, Aous Thabit Naman, David Taubman:
Neural Network Assisted Lifting Steps For Improved Fully Scalable Lossy Image Compression in JPEG 2000. CoRR abs/2403.01647 (2024) - [i5]James L. Gray, Aous Thabit Naman, David S. Taubman:
Multi-view Disparity Estimation Using a Novel Gradient Consistency Model. CoRR abs/2405.17029 (2024) - 2023
- [j54]Reji Mathew, Aous Thabit Naman, Yue Li, David Taubman:
JPEG 2000 Extensions for Scalable Coding of Discontinuous Media. IEEE Trans. Image Process. 32: 3092-3107 (2023) - [c147]Yue Li, Reji Mathew, David Taubman:
JPEG Pleno Light Field Encoder with Mesh based View Warping. ICIP 2023: 2100-2104 - [c146]Xinyue Li, Aous Thabit Naman, David Taubman:
Improved Transform Structures for Learned Wavelet-Like Fully Scalable Image Compression. MMSP 2023: 1-6 - 2022
- [j53]Sean I. Young, Zhe Wang, David Taubman, Bernd Girod:
Transform Quantization for CNN Compression. IEEE Trans. Pattern Anal. Mach. Intell. 44(9): 5700-5714 (2022) - [j52]Fariha Afsana, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Efficient Scalable UHD/360-Video Coding by Exploiting Common Information With Cuboid-Based Partitioning. IEEE Trans. Circuits Syst. Video Technol. 32(6): 3961-3977 (2022) - [j51]Ashek Ahmmed, M. Manzur Murshed, Manoranjan Paul, David Taubman:
A Commonality Modeling Framework for Enhanced Video Coding Leveraging on the Cuboidal Partitioning Based Representation of Frames. IEEE Trans. Multim. 24: 4446-4457 (2022) - [c145]Fariha Afsana, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Efficient Scalable 360-degree Video Compression Scheme using 3D Cuboid Partitioning. ICIP 2022: 996-1000 - [c144]Xinyue Li, Aous Thabit Naman, David Taubman:
A Neural Network Lifting Based Secondary Transform for Improved Fully Scalable Image Compression in Jpeg 2000. ICIP 2022: 1606-1610 - [c143]Reji Mathew, David Taubman:
Breakpoint Dependent Scalable Coding of Optical Flow Volume. ICIP 2022: 1956-1960 - [c142]Reji Mathew, David Taubman:
JPEG Pleno Light Field Encoder with Breakpoint Dependent Affine Wavelet Transform for Disparity Maps. ICIP 2022: 2451-2455 - [c141]James L. Gray, Aous Thabit Naman, David S. Taubman:
Gradient Consistency Based Multi-Scale Optical Flow. MMSP 2022: 1-6 - [i4]Priyabrata Karmakar, M. Manzur Murshed, Manoranjan Paul, David Taubman:
Efficient Motion Modelling with Variable-sized blocks from Hierarchical Cuboidal Partitioning. CoRR abs/2208.13137 (2022) - 2021
- [j50]Fariha Afsana, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Efficient High-Resolution Video Compression Scheme Using Background and Foreground Layers. IEEE Access 9: 157411-157421 (2021) - [c140]Ashek Ahmmed, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Dynamic Point Cloud Compression Using A Cuboid Oriented Discrete Cosine Based Motion Model. ICASSP 2021: 1935-1939 - [c139]Ashek Ahmmed, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Human-Machine Collaborative Video Coding Through Cuboidal Partitioning. ICIP 2021: 2074-2078 - [c138]Reji Mathew, Yue Li, David Taubman:
Scalable Coding Of Motion And Depth Fields With Shared Breakpoints. ICIP 2021: 2139-2143 - [c137]Ashek Ahmmed, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Dynamic Point Cloud Geometry Compression using Cuboid based Commonality Modeling Framework. ICIP 2021: 2159-2163 - [c136]James L. Gray, Aous Thabit Naman, David S. Taubman:
Welsch Based Multiview Disparity Estimation. ICIP 2021: 3223-3227 - [c135]Xinyue Li, Aous Thabit Naman, David Taubman:
Machine-Learning Based Secondary Transform for Improved Image Compression in JPEG2000. ICIP 2021: 3752-3756 - [i3]Ashek Ahmmed, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Human-Machine Collaborative Video Coding Through Cuboidal Partitioning. CoRR abs/2102.01307 (2021) - [i2]James L. Gray, Aous Thabit Naman, David S. Taubman:
Welsch Based Multiview Disparity Estimation. CoRR abs/2110.00803 (2021) - 2020
- [j48]Sean I. Young, Aous Thabit Naman, David Taubman:
Graph Laplacian Regularization for Robust Optical Flow Estimation. IEEE Trans. Image Process. 29: 3970-3983 (2020) - [j47]Maryam Haghighat, Reji Mathew, David Taubman:
Rate-Distortion Driven Decomposition of Multiview Imagery to Diffuse and Specular Components. IEEE Trans. Image Process. 29: 5469-5480 (2020) - [j46]Sean I. Young, Bernd Girod, David Taubman:
Gaussian Lifting for Fast Bilateral and Nonlocal Means Filtering. IEEE Trans. Image Process. 29: 6082-6095 (2020) - [j45]Sean I. Young, Bernd Girod, David Taubman:
Fast Optical Flow Extraction From Compressed Video. IEEE Trans. Image Process. 29: 6409-6421 (2020) - [c134]Sean I. Young, David B. Lindell, Bernd Girod, David Taubman, Gordon Wetzstein:
Non-Line-of-Sight Surface Reconstruction Using the Directional Light-Cone Transform. CVPR 2020: 1404-1413 - [c133]Aous Thabit Naman, David Taubman:
Encoding High-Throughput Jpeg2000 (Htj2k) Images On A Gpu. ICIP 2020: 1171-1175 - [c132]Xinyue Li, Aous Thabit Naman, David Taubman:
Adaptive Secondary Transform For Improved Image Coding Efficiency In JPEG2000. ICIP 2020: 1216-1220 - [c130]Fariha Afsana, Manoranjan Paul, M. Manzur Murshed, David Taubman:
Efficient Low Bit-Rate Intra-Frame Coding using Common Information for 360-degree Video. MMSP 2020: 1-6 - [c129]Ashek Ahmmed, Manoranjan Paul, M. Manzur Murshed, David Taubman:
A Coarse Representation of Frames Oriented Video Coding By Leveraging Cuboidal Partitioning of Image Data. MMSP 2020: 1-6 - [c128]Yue Li, Reji Mathew, David Taubman:
Scalable Mesh Representation for Depth from Breakpoint-Adaptive Wavelet Coding. MMSP 2020: 1-6 - [i1]Sean I. Young, Zhe Wang, David Taubman, Bernd Girod:
Transform Quantization for CNN Compression. CoRR abs/2009.01174 (2020) - 2019
- [j44]Dominic Rüfenacht, Reji Mathew, David Taubman:
Temporal Frame Interpolation With Motion-Divergence-Guided Occlusion Handling. IEEE Trans. Circuits Syst. Video Technol. 29(2): 293-307 (2019) - [j43]Sean I. Young, Aous Thabit Naman, David Taubman:
COGL: Coefficient Graph Laplacians for Optimized JPEG Image Decoding. IEEE Trans. Image Process. 28(1): 343-355 (2019) - [j42]Dominic Rüfenacht, Aous Thabit Naman, Reji Mathew, David Taubman:
Base-Anchored Model for Highly Scalable and Accessible Compression of Multiview Imagery. IEEE Trans. Image Process. 28(7): 3205-3218 (2019) - [j41]Maryam Haghighat, Reji Mathew, Aous Thabit Naman, David Taubman:
Illumination Estimation and Compensation of Low Frame Rate Video Sequences for Wavelet-Based Video Compression. IEEE Trans. Image Process. 28(9): 4313-4327 (2019) - [c126]Sean I. Young, Aous Thabit Naman, Bernd Girod, David Taubman:
Solving Vision Problems via Filtering. ICCV 2019: 5591-5600 - [c125]Maryam Haghighat, Reji Mathew, David Taubman:
Rate-Distortion Driven Separation of Diffuse and Specular Components in Multiview Imagery. ICIP 2019: 954-958 - [c124]David Taubman, Aous Thabit Naman, Reji Mathew:
High Throughput Block Coding in the HTJ2K Compression Standard. ICIP 2019: 1079-1083 - [c123]Aous Thabit Naman, David Taubman:
Decoding High-Throughput Jpeg2000 (HTJ2K) On A G. ICIP 2019: 1084-1088 - [c122]Reji Mathew, David Taubman:
WaSP Encoder with Breakpoint Adaptive DWT Coding of Disparity Maps. ICIP 2019: 3172-3176 - [c121]Yue Li, Reji Mathew, Dominic Rüfenacht, Aous Thabit Naman, David Taubman:
Consistent Disparity Synthesis for Inter-View Prediction in Lightfield Compression. PCS 2019: 1-5 - 2018
- [j40]Aous Thabit Naman, Yu Wang, Hassan Habibi Gharakheili, Vijay Sivaraman, David Taubman:
Responsive high throughput congestion control for interactive applications over SDN-enabled networks. Comput. Networks 134: 152-166 (2018) - [j39]Dominic Rüfenacht, David Taubman:
HEVC-EPIC: Fast Optical Flow Estimation From Coded Video via Edge-Preserving Interpolation. IEEE Trans. Image Process. 27(6): 3100-3113 (2018) - [c119]Yue Li, Reji Mathew, David Taubman:
Disparity Guided Texture Inpainting for Light Field View Synthesis. DICTA 2018: 1-7 - [c118]Sean I. Young, David Taubman:
Fast Optical Flow Extraction from Compressed Video. DICTA 2018: 1-8 - [c117]Maryam Haghighat, Reji Mathew, Aous Thabit Naman, Sean I. Young, David Taubman:
Rate-Distortion Optimized Illumination Estimation for Wavelet-Based Video Coding. ICASSP 2018: 1213-1217 - [c116]Ashek Ahmmed, Aous Thabit Naman, David Taubman:
Enhanced Homogeneous Motion Discovery Oriented Prediction for Key Intermediate Frames. PCS 2018: 238-242 - 2017
- [c115]Maryam Haghighat, Reji Mathew, Aous Thabit Naman, David Taubman:
Lifting-based Illumination Adaptive Transform (LIAT) using mesh-based illumination modelling. ICIP 2017: 3006-3010 - [c113]Dominic Rüfenacht, David Taubman:
HEVC-EPIC: Edge-preserving interpolation of coded HEVC motion with applications to framerate upsampling. ICME 2017: 1261-1266 - [c112]Dominic Rüfenacht, David Taubman:
Leveraging decoded HEVC motion for fast, high quality optical flow estimation. MMSP 2017: 1-6 - 2016
- [j37]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
A Novel Motion Field Anchoring Paradigm for Highly Scalable Wavelet-Based Video Coding. IEEE Trans. Image Process. 25(1): 39-52 (2016) - [j36]Rui Xu, David S. Taubman, Aous Thabit Naman:
Motion Estimation Based on Mutual Information and Adaptive Multi-Scale Thresholding. IEEE Trans. Image Process. 25(3): 1095-1108 (2016) - [c111]Jie Miao, Xiaoyi Jia, Reji Mathew, Xiangmin Xu, David Taubman, Chunmei Qing:
Efficient action recognition from compressed depth maps. ICIP 2016: 16-20 - [c110]Aous Thabit Naman, David S. Taubman, Reji Mathew:
Optimization and compression of geometry discontinuities for graph-based representation of piecewise smooth media. ICIP 2016: 1544-1548 - [c109]Sean I. Young, Reji K. Mathew, David Taubman:
Optimizing block-coded motion parameters with block-partition graphs. ICIP 2016: 2037-2041 - [c108]Dominic Rüfenacht, David Taubman:
Temporally consistent high frame-rate upsampling with motion sparsification. MMSP 2016: 1-6 - [c107]Ashek Ahmmed, David S. Taubman, Aous Thabit Naman, Mark R. Pickering:
Homogeneous motion discovery oriented reference frame for high efficiency video coding. PCS 2016: 1-5 - [c106]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
Higher-order motion models for temporal frame interpolation with applications to video coding. PCS 2016: 1-5 - [c105]Sean I. Young, Aous Thabit Naman, Reji K. Mathew, David S. Taubman:
Optimized decoding of JPEG images based on generalized graph Laplacians. PCS 2016: 1-5 - 2015
- [c104]Sean I. Young, David S. Taubman:
Rate-distortion optimized optical flow estimation. ICIP 2015: 1677-1681 - [c103]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
Motion blur modelling for hierarchically anchored motion with discontinuities. MMSP 2015: 1-6 - [c102]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
Bidirectional, occlusion-aware temporal frame interpolation in a highly scalable video setting. PCS 2015: 5-9 - [c101]Mitchell S. Ward, David S. Taubman, Reji Mathew:
Spatial induction policies for scalable depth coding. PCS 2015: 45-49 - [c100]Ashek Ahmmed, Md. Jahangir Alam, Aous Thabit Naman, Mark R. Pickering, David S. Taubman:
Motion hints mode for macroblock coding in bi-predictive slices. PCS 2015: 55-59 - [c99]Reji Mathew, Sean I. Young, David Taubman:
Optimization of optical flow for scalable coding. PCS 2015: 70-74 - [c98]Rui Xu, Aous Thabit Naman, Reji Mathew, Dominic Rüfenacht, David S. Taubman:
Motion estimation with accurate boundaries. PCS 2015: 184-188 - 2014
- [j34]Rui Xu, David S. Taubman, Aous Thabit Naman:
Nonlinear Transform for Robust Dense Block-Based Motion Estimation. IEEE Trans. Image Process. 23(5): 2222-2234 (2014) - [j33]Aous Thabit Naman, David Taubman:
Flexible Synthesis of Video Frames Based on Motion Hints. IEEE Trans. Image Process. 23(9): 3802-3815 (2014) - [c97]Rui Xu, David Taubman, Aous Thabit Naman:
Block motion matching on directional subbands with interband suppression. ICIP 2014: 219-223 - [c96]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
Hierarchical anchoring of motion fields for fully scalable video coding. ICIP 2014: 3180-3184 - [c95]Aous Thabit Naman, David Taubman, Rui Xu:
Overlapping motion hints with polynomial motion for video communication. ICIP 2014: 5986-5990 - [c94]Dominic Rüfenacht, Reji Mathew, David S. Taubman:
Bidirectional hierarchical anchoring of motion fields for scalable video coding. MMSP 2014: 1-6 - [c93]Sean I. Young, Reji Mathew, David S. Taubman:
Embedded coding of optical flow fields for scalable video compression. MMSP 2014: 1-6 - 2013
- [j32]Reji Mathew, David Taubman, Pietro Zanuttigh:
Scalable Coding of Depth Maps With R-D Optimized Embedding. IEEE Trans. Image Process. 22(5): 1982-1995 (2013) - [j31]Ruiqin Xiong, David S. Taubman, Vijay Sivaraman:
PET Protection Optimization for Streaming Scalable Videos With Multiple Transmissions. IEEE Trans. Image Process. 22(11): 4364-4379 (2013) - [c92]Sean I. Young, Reji Mathew, David S. Taubman:
Joint estimation of motion and arc breakpoints for scalable compression. GlobalSIP 2013: 479-482 - [c91]Aous Thabit Naman, Rui Xu, David Taubman:
Inter-frame prediction using motion hints. ICIP 2013: 1792-1796 - [c90]Rui Xu, David Taubman:
Robust dense block-based motion estimation using a 2-bit transform on a Laplacian pyramid. ICIP 2013: 1938-1942 - [c89]Aous Thabit Naman, David Taubman:
A soft measure for identifying structure from randomness in images. ICIP 2013: 2939-2943 - [c88]Ashek Ahmmed, Rui Xu, Aous Thabit Naman, Md. Jahangir Alam, Mark R. Pickering, David Taubman:
Motion segmentation initialization strategies for bi-directional inter-frame prediction. MMSP 2013: 58-63 - [c87]Sean I. Young, Reji Mathew, David S. Taubman:
Robust sum of Linear-Log Squared Differences distortion measure and its applications. PCS 2013: 73-76 - [c86]Ashek Ahmmed, Md. Jahangir Alam, Mark R. Pickering, Rui Xu, Aous Thabit Naman, David Taubman:
Motion hints based inter-frame prediction for hybrid video coding. PCS 2013: 177-180 - 2012
- [c85]Reji Mathew, Pietro Zanuttigh, David Taubman:
Highly Scalable Coding of Depth Maps with Arc Breakpoints. DCC 2012: 42-51 - [c83]Reji Mathew, David Taubman, Pietro Zanuttigh:
Scalable depth maps with R-D optimized embedding. MMSP 2012: 266-271 - 2011
- [j29]Reji Mathew, David S. Taubman:
Scalable Modeling of Motion and Boundary Geometry With Quad-Tree Node Merging. IEEE Trans. Circuits Syst. Video Technol. 21(2): 178-192 (2011) - [j27]Aous Thabit Naman, David Taubman:
JPEG2000-Based Scalable Interactive Video (JSIV). IEEE Trans. Image Process. 20(5): 1435-1449 (2011) - [j26]Aous Thabit Naman, David Taubman:
JPEG2000-Based Scalable Interactive Video (JSIV) With Motion Compensation. IEEE Trans. Image Process. 20(9): 2650-2663 (2011) - [c81]Aous Thabit Naman, Duncan Edwards, David Taubman:
Efficient communication of video using metadata. ICIP 2011: 581-584 - 2010
- [j25]Reji Mathew, David S. Taubman:
Quad-Tree Motion Modeling With Leaf Merging. IEEE Trans. Circuits Syst. Video Technol. 20(10): 1331-1345 (2010) - [j24]Ruiqin Xiong, David Taubman, Vijay Sivaraman:
Optimal PET Protection for Streaming Scalably Compressed Video Streams With Limited Retransmission Based on Incomplete Feedback. IEEE Trans. Image Process. 19(9): 2382-2395 (2010) - [c80]Aous Thabit Naman, David Taubman:
Predictor selection using quantization intervals in JPEG2000-Based Scalable Interactive Video (JSIV). ICIP 2010: 2897-2900 - 2009
- [c77]Aous Thabit Naman, David Taubman:
Rate-distortion optimized JPEG2000-based scalable interactive video (JSIV) with motion and quantization bin side-information. ICIP 2009: 3081-3084 - [c76]Reji Mathew, David S. Taubman:
Joint scalable modeling of motion and boundary geometry with quad-tree node merging. ICIP 2009: 3745-3748 - 2008
- [c69]Aous Thabit Naman, David Taubman:
Rate-distortion optimized delivery of JPEG2000 compressed video with hierarchical motion side information. ICIP 2008: 2312-2315 - [c67]Reji Mathew, David S. Taubman:
Joint motion and geometry modeling with quad-tree leaf merging. ICIP 2008: 2872-2875 - [c66]Reji Mathew, David S. Taubman:
Motion modeling with separate quad-tree structures for geometry and motion. MMSP 2008: 371-377 - [c65]Aous Thabit Naman, David S. Taubman:
Distortion estimation for optimized delivery of JPEG2000 compressed video with motion. MMSP 2008: 433-438 - [c64]Ruiqin Xiong, David S. Taubman:
Optimal LR-PET protection for scalable video streams over lossy channels with random delay. MMSP 2008: 439-444 - 2007
- [c59]Aous Thabit Naman, David Taubman:
A Novel Paradigm for Optimized Scalable Video Transmission Based on JPEG2000 with Motion. ICIP (5) 2007: 93-96 - [c56]Reji Mathew, David S. Taubman:
Motion Modeling with Geometry and Quad-tree Leaf Merging. ICIP (2) 2007: 297-300 - [c54]Aous Thabit Naman, David Taubman:
Optimized scalable video transmission based on conditional replenishment of jpeg2000 code-blocks with motion compensation. MV@MM 2007: 43-48 - 2006
- [j20]Guido M. Cortelazzo, David S. Taubman:
Interactive representation of still and dynamic scenes. Signal Process. Image Commun. 21(9): 705-708 (2006) - [j19]Pietro Zanuttigh, Nicola Brusco, David Taubman, Guido M. Cortelazzo:
A novel framework for the interactive transmission of 3D scenes. Signal Process. Image Commun. 21(9): 787-811 (2006) - [j16]Nagita Mehrseresht, David S. Taubman:
A flexible structure for fully scalable motion-compensated 3-D DWT with emphasis on the impact of spatial scalability. IEEE Trans. Image Process. 15(3): 740-753 (2006) - [j15]Nagita Mehrseresht, David S. Taubman:
An efficient content-adaptive motion-compensated 3-D DWT with enhanced spatial and temporal scalability. IEEE Trans. Image Process. 15(6): 1397-1412 (2006) - [c53]Nicola Brusco, Pietro Zanuttigh, David Taubman, Guido Maria Cortelazzo:
Distortion-Sensitive Synthesis of Texture and Geometry in Interactive 3D Visualization. 3DPVT 2006: 256-263 - [c47]Nagita Mehrseresht, David Taubman:
Spatially Continuous Orientation Adaptive Discrete Packet Wavelet Decomposition for Image Compression. ICIP 2006: 1593-1596 - [c46]Reji Mathew, David S. Taubman:
Hierarchical and Polynomial Motion Modeling with Quad-Tree Leaf Merging. ICIP 2006: 1881-1884 - [c44]Pietro Zanuttigh, Nicola Brusco, David Taubman, Guido Maria Cortelazzo:
Server Policies For Interactive Transmission Of 3D Scenes. MMSP 2006: 59-64 - 2005
- [c43]David Taubman, Reji Mathew, Nagita Mehrseresht:
Fully scalable video compression with sample-adaptive lifting and overlapped block motion. Electronic Imaging: Image and Video Communications and Processing 2005 - [c39]Pietro Zanuttigh, Nicola Brusco, David Taubman, Guido M. Cortelazzo:
Greedy non-linear approximation of the plenoptic function for interactive transmission of 3D scenes. ICIP (1) 2005: 629-632 - 2004
- [c31]Nagita Mehrseresht, David Taubman:
Spatial scalability and compression efficiency within a flexible motion compensated 3D-DWT. ICIP 2004: 1325-1328 - [c30]Nagita Mehrseresht, David Taubman:
An efficient content-adaptive MC 3D-DWT with enhanced spatial and temporal scalability. ICIP 2004: 1329-1332 - 2003
- [c22]Nagita Mehrseresht, David Taubman:
Adaptively weighted update steps in motion compensated lifting based scalable video compression. ICIP (2) 2003: 771-774
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