School of Engineering Science
Simon Fraser University
8888 University Drive
Burnaby, BC, V5A 1S6, Canada
T: +1-778-782-7159
F: +1-778-782-4951
E: ibajic@ensc.sfu.ca @IvanBajic@IvanBajic
Bio
I am a Professor of Engineering Science at Simon Fraser University. My professional interests revolve around signal processing, machine learning, and their applications in image and video processing, coding, communications, and collaborative intelligence. My group's work has received a number of international recognitions, including the 2023 IEEE TCSVT Best Paper Award, conference paper awards at ISCAS 2023, MMSP 2022, ICIP 2019, and ICME 2012, as well as other recognitions (e.g., paper award finalist, top n%) at Asilomar, ICIP, ICME, ISBI, and CVPR. This is in large part due to my outstanding students, among whom are recipients of the Vanier Scholarship, multiple Governor General's Gold Medalists, NSERC Doctoral and Masters Scholars, and winners of competitive conference travel grants.
I have served on the organizing and program committees of the main conferences in my field, and have received several awards in these roles, including Outstanding Reviewer Award (six times), Outstanding Area Chair Award, and Outstanding Service Award. I was the Chair of the Vancouver Chapter of the IEEE Signal Processing Society in 2013-2019, during which the Chapter received the Chapter of the Year Award from IEEE SPS. I was the Chair of the IEEE Multimedia Signal Processing Technical Committee during 2022-2023 and I am currently serving as a Senior Area Editor of IEEE Signal Processing Letters. I have previously served on editorial boards of several journals, including IEEE Signal Processing Magazine, IEEE Transactions on Multimedia, and Signal Processing: Image Communication.
I was born in Belgrade, Serbia, in 1976. I received the B.Sc.Eng. degree (summa cum laude) in Electronic Engineering from the University of Natal, South Africa, in 1998, and the M.S. degree in Electrical Engineering, the M.S. degree in Mathematics, and the Ph.D. degree in Electrical Engineering from Rensselaer Polytechnic Institute, Troy, NY, USA, in 2000, 2002, and 2003, respectively.
Besides professional life, I am also a wine enthusiast. I’ve been fortunate enough to visit some of the top wine producing regions in the world in the last number of years, including the Napa and Sonoma valleys in California, Cape Town/Stellenbosch region in South Africa, La Rioja in Spain, Douro valley in Portugal, Chianti in Italy and, closer to home, Okanagan and Cowichan valleys in British Columbia, as well as the Olympic Peninsula wineries in Washington State.
Teaching
At SFU (2005 - present):
ENSC 180 - Introduction to Engineering Analysis Tools
Spring 2015
ENSC 380 - Linear Systems
Spring 2006, 2007, 2015, Fall 2019
ENSC 424 - Multimedia Communications Engineering
Fall 2006, 2007, 2008, 2009, 2010, 2011, 2018
ENSC 428 - Digital Communications
Spring 2009, Summer 2014, Spring 2018, 2020
ENSC 429 - Digital Signal Processing
Summer 2023
ENSC 802 - Stochastic Systems
Fall 2010, 2011, 2012, 2016, 2021, 2022, 2023
ENSC 808 - Information Theory
Summer 2007, Spring 2008, 2010, 2012, 2023
ENSC 813/413 - Deep Learning Systems in Engineering
Fall 2017, Spring 2019, 2020, 2021, 2022, 2024
ENSC 861 - Source Coding for Digital Communications
Fall 2015
At UM (2003-2005):
EEN 404 - Communication Systems
Spring 2004, 2005
EEN 436 - Introduction to Digital Signal Processing
Fall 2003
EEN 538 - Introduction to Digital Image Processing
Fall 2004
Research
My research interests are in the field of signal processing and its many applications. Signal processing is the science behind our digital life. In our work, my students, collaborators, and I, use the tools from signal processing, machine/deep learning, probability, statistics and optimization to analyze and solve problems related to all kinds of signals - images, video, audio, power - and others. Most of this work takes place in the Multimedia Lab (ASB 8803.1) and the Computational Sustainability Lab. Some of my ongoing projects are listed below.
Collaborative intelligence
Collaborative intelligence is a way to distribute computation of an Artificial Intelligence (AI) model across multiple devices. It has been shown to be an efficient way to deploy AI on mobile devices and is one of the promising avenues to bring AI "to the edge." We want to understand the various trade-offs in designing collaborative intelligence systems, and to develop efficient tools for their deployment, including model splitting, feature compression, feature transmission, error control, feature error concealment, and others.
Click to see selected publications.
K. Uyanik et al., “Grad-FEC: Unequal loss protection of deep features in collaborative intelligence,” Proc. IEEE ICIP, Kuala Lumpur, Malaysia, Oct. 2023. [arXiv]
N. Shlezinger and I. V. Bajić, “Collaborative inference for AI-Empowered IoT devices,” IEEE Internet of Things Magazine, vol. 5, no. 4, pp. 92-98, Dec. 2022. [IEEEXplore] [arXiv]
S. R. Alvar et al., “License plate privacy in collaborative visual analysis of traffic scenes,” Proc. IEEE MIPR'22, Aug. 2022. [IEEEXplore] [arXiv]
S. R. Alvar and I. V. Bajić, “Pareto-optimal bit allocation for collaborative intelligence,” IEEE Trans. Image Processing, vol. 30, pp. 3348-3361, Feb. 2021. [IEEEXplore] [arXiv]
A. Dhondea et al., “CALTeC: Content-adaptive linear tensor completion for collaborative intelligence,” Proc. IEEE ICIP'21, pp. 2179-2183, Anchorage, AK, Sep. 2021. [IEEEXplore] [arXiv]
I. V. Bajić, “Latent space inpainting for loss-resilient collaborative object detection,” Proc. IEEE ICC'21, Montreal, Canada, Jun. 2021. [IEEEXplore] [arXiv]
M. Ulhaq and I. V. Bajić, “Latent space motion analysis for collaborative intelligence,” Proc. IEEE ICASSP'21, pp. 8498-8502, Toronto, Canada, Jun. 2021. [IEEEXplore] [arXiv]
I. V. Bajić, W. Lin, and Y. Tian, “Collaborative intelligence: Challenges and opportunities,” Proc. IEEE ICASSP'21, pp. 8493-8497, Toronto, Canada, Jun. 2021. [IEEEXplore] [arXiv]
Coding for machines
Much of the sensory information captured today is intended for automated machine-based analysis, rather than human use.
This necessitates rethinking of traditional compression and pre-/post-processing methods to facilitate efficient machine-based analysis. We are interested in understanding fundamental limits as well as creating practical solutions for signal compression targeted at machine use. Our group is among the pioneers in this field, having been the first to demonstrate significant gains in coding for object detection (at ICIP 2018) and point cloud classification (MMSP 2023), and to derive the first rate-distortion results (arXiv 2021, TIP 2022) in this area.
Click to see selected publications.
H. Hadizadeh and I. V. Bajić, “Learned scalable video coding for humans and machines,” EURASIP J. Image and Video Processing, vol. 2024, article no. 41, Special Issue on Visual Coding for Humans and Machines, Nov. 2024. [DOI] [arXiv] [GitHub]
M. Ulhaq and I. V. Bajić, “Scalable human-machine point cloud compression,” Proc. PCS, Taichung, Taiwan, June 2024. [arXiv]
M. Ulhaq and I. V. Bajić, “Learned point cloud compression for classification,” Proc. IEEE MMSP, Poitiers, France, Sept. 2023. [arXiv]
H. Hadizadeh and I. V. Bajić, “Learned scalable video coding for humans and machines,” arXiv preprint arXiv:2307.08978, Jul. 2023. [arXiv]
A. Harell et al., “Rate-distortion theory in coding for machines and its application,” arXiv preprint arXiv:2305.17295, May 2023. [arXiv]
A. de Andrade et al., “Conditional and residual methods in scalable coding for humans and machines,” Proc. IEEE ICME Workshop on Coding for Machines, Brisbane, Australia, Jul. 2023. [arXiv] [code]
B. Azizian and I. V. Bajić, “Privacy-preserving feature coding for machines,” Proc. Picture Coding Symposium, San Jose, CA, USA, Dec. 2022. [IEEEXplore] [arXiv]
H. Choi and I. V. Bajić, “Scalable image coding for humans and machines,” IEEE Trans. Image Processing, vol. 31, pp. 2739-2754, Mar. 2022. [IEEEXplore] [arXiv]
R. A. Cohen et al., “Lightweight compression of intermediate neural network features for collaborative intelligence,” IEEE Open J. Circuits Syst., vol. 2, pp. 350-362, May 2021. [IEEEXplore] [arXiv]
H. Choi and I. V. Bajić, “Deep feature compression for collaborative object detection,” Proc. IEEE ICIP'18, pp. 3743-3747, Athens, Greece, Oct. 2018. [IEEEXplore]
H. Choi and I. V. Bajić, “High efficiency compression for object detection,” Proc. IEEE ICASSP'18, pp. 1729-1796, Calgary, AB, Apr. 2018. [IEEEXplore]
Compressed vision
In the cult movie The Matrix, the character called Cypher is able to spot objects and people from endless streams of coded data. "I don't even see the code, all I see is blonde, brunette, redhead," he says. Is this really possible? For humans, unlikely. But we have suceeded in training machines to do something like that. Being able to analyze compressed streams, without decoding, is one of the key technologies needed to handle massive amounts of video in the era of Big Data.
Click to see selected publications.
S. R. Alvar et al., “Can you find a face in a HEVC bitstream?” Proc. IEEE ICASSP, pp. 1288-1292, Calgary, AB, Apr. 2018. [IEEEXplore])
S. H. Khatoonabadi et al., “Compressed-domain visual saliency models: A comparative study,” Multimedia Tools and Applications, vol. 76, no. 24, pp. 26297–26328, Dec. 2017. [DOI]
H. Choi and I. V. Bajić, “HEVC intra features for human detection,” Proc. IEEE GlobalSIP'17, pp. 393-397, Montreal, QC, Nov. 2017. [ResearchGate]
H. Choi and I. V. Bajić, “Corner proposals from HEVC bitstreams,” Proc. IEEE ISCAS'17, pp. 1-4, Baltimore, MD, May 2017. [ResearchGate]
S. H. Khatoonabadi et al., “Compressed-domain correlates of human fixations in dynamic scenes,” Multimedia Tools and Applications, vol. 74, no. 22, pp. 10057-10075, Nov. 2015. [DOI] [code]
S. H. Khatoonabadi et al., “How many bits does it take for a stimulus to be salient?,” Proc. IEEE CVPR'15, pp. 5501-5510, Boston, MA, Jun. 2015. [ResearchGate] [code]
S. H. Khatoonabadi and I. V. Bajić, "Video object tracking in the compressed domain using spatio-temporal Markov random fields," IEEE Trans. Image Processing, vol. 22, no. 1, pp. 300-313, Jan. 2013. [IEEEXplore] [code]
Y.-M. Chen et al., "Moving region segmentation from compressed video using global motion estimation and Markov random fields," IEEE Trans. Multimedia, vol. 13, no. 3, pp. 421-431, Jun. 2011. [IEEEXplore]
Point clouds
Point clouds are sets of points in 3D space that describe the surface or shape of an object, and may carry additional attributes such as color. They were used for some time in computer graphics and animation industry, then 3D printing, and are now making their way towards mainstream through virtual/augmented reality and immersive media. Their irregular sampling makes their processing more challenging.
Click to see selected publications.
M. Ulhaq and I. V. Bajić, “Scalable human-machine point cloud compression,” Proc. PCS, Taichung, Taiwan, June 2024. [arXiv]
H. Naderi and I. V. Bajić, “Adversarial attacks and defenses on 3D point cloud classification: A survey,” IEEE Access, vol. 11, pp. 144274-144295, Dec. 2023. [IEEEXplore]
M. Ulhaq and I. V. Bajić, “Learned point cloud compression for classification,” Proc. IEEE MMSP, Poitiers, France, Sept. 2023. [arXiv]
C. Dinesh et al., “Point cloud sampling via graph balancing and Gershgorin disc alignment,” IEEE Trans. Pattern Analysis and Machine Intelligence, vol. 45, no. 1, pp. 868-886, Jan. 2023. [IEEEXplore] [arXiv]
C. Dinesh et al., “Point cloud video super-resolution via partial point coupling and graph smoothness,” IEEE Trans. Image Processing, vol. 31, pp. 4117-4132, Jun. 2022. [IEEEXplore]
C. Dinesh et al., “3D point cloud denoising via feature graph Laplacian regularization,” IEEE Trans. Image Processing, vol. 29, pp. 4143-4158, Dec. 2020. [IEEEXplore]
C. Dinesh et al., “Sampling of 3D point cloud via Gershgorin disc alignment,” Proc. IEEE ICIP'20, pp. 2736-2740, Abu Dhabi, UAE, Oct. 2020. [IEEEXplore]
C. Dinesh et al., “Super-resolution of 3D color point clouds via fast graph total variation,” Proc. IEEE ICASSP'20, pp. 1983-1987, Barcelona, Spain, May 2020. [IEEEXplore]
C. Dinesh et al., “3D point cloud color denoising using convex graph-signal smoothness priors,” Proc. IEEE MMSP'19, pp. 1-6, Kuala Lumpur, Malaysia, Sep. 2019. [IEEEXplore]
C. Dinesh et al., “Adaptive nonrigid inpainting of 3D point cloud geometry,” IEEE Signal Processing Letters, vol. 25, no. 6, pp. 878-882, Jun. 2018. [ResearchGate] [code]
Computational sustainability
Computational sustainability tries to balance the needs of the environment, the economy, and society to solve sustainability problems using computational tools, models and algorithms. We are particularly interested in solving climate change and energy challenges through the theme of conservation and habitual change. To this end, we work with both academic and industry partners to develop and commercialize our discoveries and solutions.
I. V. Bajić, “Visual coding for humans and machines,” keynote at IEEE/CVF WACV 2024 Workshop on Quality in Computer Vision and Generative AI. [SigPort]
I. V. Bajić, “Visual coding for humans and machines,” keynote at IEEE ICASSP 2023 HMM-QoE. [SigPort]
I. V. Bajić, “Multi-task image and video compression,” tutorial at IEEE ICIP 2022. [SigPort]
I. V. Bajić, “Edge-cloud collaborative multimedia analysis,” tutorial at IEEE ICME 2022. [SigPort]
Selected preprints
A. Harell, Y. Foroutan, N. Ahuja, P. Datta, B. Kanzariya, V. S. Somayazulu, O. Tickoo, A. de Andrade, and I. V. Bajić, “Rate-distortion theory in coding for machines and its application,” arXiv preprint arXiv:2305.17295, May 2023. [arXiv]
C. Dinesh, G. Cheung, S. Bagheri, and I. V. Bajić, “Efficient signed graph sampling via balancing and Gershgorin disc perfect alignment,” arXiv preprint arXiv:2208.08726, Jan. 2023. [arXiv]
Selected publications
2024
H. Hadizadeh and I. V. Bajić, “Learned scalable video coding for humans and machines,” EURASIP J. Image and Video Processing, vol. 2024, article no. 41, Special Issue on Visual Coding for Humans and Machines, Nov. 2024. [DOI] [arXiv] [GitHub]
B. Azizian and I. V. Bajić, “Privacy preserving autoencoder for collaborative object detection,” IEEE Trans. Image Processing, vol. 33, pp. 4937-4951, Oct. 2024. [IEEEXplore] [arXiv] [GitHub]
H. Hadizadeh and I. V. Bajić, “Learned multimodal compression for autonomous driving,” Proc. IEEE MMSP, Purdue University, IN, USA, Oct. 2024. [arXiv]
M. Ulhaq and I. V. Bajić, “Learned compression of encoding distributions,” Proc. IEEE ICIP, pp. 3716-3722, Abu Dhabi, UAE, Oct. 2024. [arXiv] [IEEEXplore] (Top 5% Paper)
H. Hadizadeh, S. F. Yeganli, B. Rashidi, and I. V. Bajić, “Mutual information analysis in multimodal learning systems,” Proc. IEEE MIPR, pp. 390-395, San Jose, CA, USA August 2024. [arXiv] [IEEEXplore]
A. de Andrade and I. V. Bajić, “Towards task-compatible compressible representations,” Proc. IEEE ICME Workshop on Coding for Machines, Niagara Falls, Canada, July 2024. [arXiv] [IEEEXplore] [GitHub]
S. R. Alvar and I. V. Bajić, “Compressive feature selection for remote visual multi-task inference,” Proc. IEEE ICME Workshop on Coding for Machines, Niagara Falls, Canada, July 2024. [arXiv] [IEEEXplore]
M. Ulhaq and I. V. Bajić, “Scalable human-machine point cloud compression,” Proc. Picture Coding Symposium, Taichung, Taiwan, June 2024. [arXiv] [IEEEXplore]
2023
H. Naderi and I. V. Bajić, “Adversarial attacks and defenses on 3D point cloud classification: A survey,” IEEE Access, vol. 11, pp. 144274-144295, Dec. 2023. [IEEEXplore]
I. V. Bajić, M. Mrak, F. Dufaux, E. Magli and T. Chen, “Multimedia Signal Processing: A History of the Multimedia Signal Processing Technical Committee,” IEEE Signal Processing Magazine, vol. 40, no. 4, pp. 72-79, Jun. 2023. [IEEEXplore]
C. Shiranthika, P. Saeedi, and I. V. Bajić, “Decentralized learning in healthcare: A review of emerging techniques,” IEEE Access, vol. 11, pp. 54188-54209, Jun. 2023. [IEEEXplore]
C. Dinesh, G. Cheung, and I. V. Bajić, “Point cloud sampling via graph balancing and Gershgorin disc alignment,” IEEE Trans. Pattern Analysis and Machine Intelligence, vol. 45, no. 1, pp. 868-886, Jan. 2023. [IEEEXplore] [arXiv]
C. Shiranthika, Z. Hafezi Kafshgari, P. Saeedi, and I. V. Bajić, “SplitFed resilience to packet loss: Where to split, that is the question,” Proc. MICCAI Workshop on Distributed, Collaborative and Federated Learning, Vancouver, BC, Canada, Oct. 2023. [arXiv] (Spotlight Paper)
Y. Foroutan, A. Harell, A. de Andrade, and I. V. Bajić, “Base layer efficiency in scalable human-machine coding,” Proc. IEEE ICIP, Kuala Lumpur, Malaysia, Oct. 2023. [arXiv]
K. Uyanik, S. F. Yeganli, and I. V. Bajić, “Grad-FEC: Unequal loss protection of deep features in collaborative intelligence,” Proc. IEEE ICIP, Kuala Lumpur, Malaysia, Oct. 2023. [arXiv]
M. Ulhaq and I. V. Bajić, “Learned point cloud compression for classification,” Proc. IEEE MMSP, Poitiers, France, Sept. 2023. [IEEEXplore] [arXiv] [GitHub]
A. de Andrade, A. Harell, Y. Foroutan, and I. V. Bajić, “Conditional and residual methods in scalable coding for humans and machines,” Proc. IEEE ICME Workshop on Coding for Machines, Brisbane, Australia, Jul. 2023. [IEEEXplore] [arXiv] [GitHub]
A. Harell, Y. Foroutan, and I. V. Bajić, “VVC+M: Plug and play scalable image coding for humans and machines,” Proc. IEEE ICME Workshop on Coding for Machines, Brisbane, Australia, Jul. 2023. [IEEEXplore] [arXiv]
H. Hadizadeh and I. V. Bajić, “LCCM-VC: Learned conditional coding modes for video compression,” Proc. IEEE ICASSP Workshop on Humans, Machines and Multimedia - Quality of Experience and Beyond, Rhodes Island, Greece, Jun. 2023. [IEEEXplore] [arXiv] [GitHub]
Z. Hafezi Kafshgari, I. V. Bajić and P. Saeedi, “Smart split-federated learning over noisy channels for embryo image segmentation,” Proc. IEEE ICASSP, Rhodes Island, Greece, Jun. 2023. [IEEEXplore]
R. Zamanshoar Heris and I. V. Bajić, “Multi-task learning for screen content image coding,” Proc. IEEE ISCAS, Monterey, CA, USA, May 2023. [IEEEXplore] [arXiv] [GitHub] (IEEE MSA-TC Best Paper Award)
Z. Hafezi Kafshgari, C. Shiranthika, P. Saeedi, and I. V. Bajić, “Quality-adaptive split-federated learning for segmenting medical images with inaccurate annotations,” Proc. IEEE ISBI, Cartagena de Indias, Colombia, Apr. 2023. [IEEEXplore] [arXiv] (Best Paper Runner-up)
2022
N. Shlezinger and I. V. Bajić, “Collaborative inference for AI-Empowered IoT devices,” IEEE Internet of Things Magazine, vol. 5, no. 4, pp. 92-98, Dec. 2022. [IEEEXplore] [arXiv]
S. R. Alvar, M. Ulhaq, H. Choi, and I. V. Bajić, “Joint image compression and denoising via latent-space scalability,” Front. Signal Process., Sec. Image Processing, Sep. 2022. [DOI]
H. Choi and I. V. Bajić, “Scalable image coding for humans and machines,” IEEE Trans. Image Processing, vol. 31, pp. 2739-2754, Mar. 2022. [IEEEXplore] [arXiv] [GitHub]
C. Dinesh, G. Cheung, and I. V. Bajić, “Point cloud video super-resolution via partial point coupling and graph smoothness,” IEEE Trans. Image Processing, vol. 31, pp. 4117-4132, Jun. 2022. [IEEEXplore]
T. Tanaka, H. Choi, and I. V. Bajić, “Updating a dataset of labelled objects on raw video sequences with unique object IDs,” Data in Brief, vol. 41, article no. 107892, Apr. 2022. [DOI]
B. Azizian and I. V. Bajić, “Privacy-preserving feature coding for machines,” Proc. Picture Coding Symposium, San Jose, CA, USA, Dec. 2022. [IEEEXplore] [arXiv]
A. Harell, A. de Andrade, and I. V. Bajić, “Rate-distortion in image coding for machines,” Proc. Picture Coding Symposium, San Jose, CA, USA, Dec. 2022. [IEEEXplore] [arXiv]
H. Choi and I. V. Bajić, “Scalable video coding for humans and machines,” Proc. IEEE MMSP'22, Shanghai, China, Sep. 2022. [IEEEXplore] [arXiv] (Best Paper - Honorable Mention)
S. R. Alvar, K. Uyanik, and I. V. Bajić, “License plate privacy in collaborative visual analysis of traffic scenes,” Proc. IEEE MIPR'22, Aug. 2022. [IEEEXplore] [arXiv]
T. Tanaka, A. Harell, and I. V. Bajić, “Does video compression impact tracking accuracy?” Proc. IEEE ISCAS'22, pp. 1517-1521, May-June 2022. [IEEEXplore] [arXiv]
C. Dinesh, S. Bagheri, G. Cheung, and I. V. Bajić, “Linear-time sampling on signed graphs via Gershgorin disc perfect alignment,” Proc. IEEE ICASSP'22, pp. 5942-5946, May 2022. [IEEEXplore] (SPS Travel Grant)
2021
R. A. Cohen, H. Choi, and I. V. Bajić, “Lightweight compression of intermediate neural network features for collaborative intelligence,” IEEE Open J. Circuits Syst., vol. 2, pp. 350-362, May 2021. (Special Section on IEEE ICME 2020) [IEEEXplore] [arXiv]
A. Harell, R. Jones, S. Makonin, and I. V. Bajić, “TraceGAN: Synthesizing appliance power signatures using generative adversarial networks,” IEEE Trans. Smart Grid, vol. 12, no. 5, pp. 4553-4563, Sept. 2021. [IEEEXplore] [arXiv]
H. Choi and I. V. Bajić, “Affine transformation-based deep frame prediction,” IEEE Trans. Image Processing, vol. 30, pp. 3321-3334, Feb. 2021. [IEEEXplore] [arXiv] (TIP Featured Article)
S. R. Alvar and I. V. Bajić, “Pareto-optimal bit allocation for collaborative intelligence,” IEEE Trans. Image Processing, vol. 30, pp. 3348-3361, Feb. 2021. [IEEEXplore] [arXiv]
H. Choi, E. Hosseini, S. R. Alvar, R. A. Cohen, and I. V. Bajić, “A dataset of labelled objects on raw video sequences,” Data in Brief, vol. 34, article no. 106701, Feb. 2021. [DOI]
Z. A. Bhotto, R. Jones, S. Makonin, and I. V. Bajić, “Short-term demand prediction using an ensemble of linearly-constrained estimators,” IEEE Trans. Power Systems, vol. 36, no. 4, pp. 3163-3175, Jul. 2021. [IEEEXplore]
H. Hadizadeh and I. V. Bajić, “Soft video multicasting using adaptive compressed sensing,” IEEE Trans. Multimedia, vol. 23, pp. 12-25, Jan. 2021. [IEEEXplore] [arXiv] (TMM Featured Article)
S. R. Alvar and I. V. Bajić, “Scalable privacy in multi-task image compression,” Proc. IEEE VCIP'21, Munich, Germany, Dec. 2021. [IEEEXplore]
A. Dhondea, R. A. Cohen, and I. V. Bajić, “DFTS2: Deep feature transmission simulation for collaborative intelligence,” Proc. IEEE VCIP'21, Munich, Germany, Dec. 2021. [IEEEXplore] [arXiv] [GitHub]
H. Choi and I. V. Bajić, “Latent-space scalability for multi-task collaborative intelligence,” Proc. IEEE ICIP'21, pp. 3562-3566, Anchorage, AK, Sep. 2021. [IEEEXplore] [arXiv] (Extended version under the title "Scalable image coding for humans and machines" on arXiv)
A. Dhondea, R. A. Cohen, and I. V. Bajić, “CALTeC: Content-adaptive linear tensor completion for collaborative intelligence,” Proc. IEEE ICIP'21, pp. 2179-2183, Anchorage, AK, Sep. 2021. [IEEEXplore] [arXiv] [GitHub]
T. Woinoski and I. V. Bajić, “Swimmer stroke rate estimation from overhead race video,” Proc. IEEE ICME Workshop on Artifical Intelligence in Sports (AI-Sports), Shenzhen, China, Jul. 2021. [IEEEXplore] [arXiv]
I. V. Bajić, “Latent space inpainting for loss-resilient collaborative object detection,” Proc. IEEE ICC'21, Montreal, Canada, Jun. 2021. [IEEEXplore] [arXiv]
M. Ulhaq and I. V. Bajić, “Latent space motion analysis for collaborative intelligence,” Proc. IEEE ICASSP'21, pp. 8498-8502, Toronto, Canada, Jun. 2021. [IEEEXplore] [arXiv]
I. V. Bajić, W. Lin, and Y. Tian, “Collaborative intelligence: Challenges and opportunities,” Proc. IEEE ICASSP'21, pp. 8493-8497, Toronto, Canada, Jun. 2021. [IEEEXplore] [arXiv]
S. Lee and I. V. Bajić, “Information flow through U-Nets,” Proc. IEEE ISBI'21, pp. 812-816, Nice, France, Apr. 2021. [IEEEXplore] [arXiv]
2020
C. Dinesh, G. Cheung, and I. V. Bajić, “3D point cloud denoising via feature graph Laplacian regularization,” IEEE Trans. Image Processing, vol. 29, pp. 4143-4158, Dec. 2020. [IEEEXplore]
H. Choi and I. V. Bajić, “Deep frame prediction for video coding,” IEEE Trans. Circuits Syst. Video Technol., vol. 30, no. 7, pp. 1843-1855, Jul. 2020. [IEEEXplore] [arXiv] (TCSVT Best Paper Award)
C. Dinesh, S. Makonin, and I. V. Bajić, “Residential power forecasting based on affinity aggregation spectral clustering,” IEEE Access, vol. 8, pp. 99431-99444, May 2020. [IEEEXplore]
L. Bragilevsky and I. V. Bajić, “Tensor completion methods for collaborative intelligence,” IEEE Access, vol. 8, pp. 41162-41174, Feb. 2020. [IEEEXplore]
M. Ulhaq and I. V. Bajić, “ColliFlow: A Library for Executing Collaborative Intelligence Graphs,” NeurIPS'20 demo, Vancouver, Canada, Dec. 2020. [GitHub]
H. Choi and I. V. Bajić, “A lightweight model for deep frame prediction in video coding,” Proc. Asilomar Conf. Signals, Systems, and Computers, pp. 1122-1126, Pacific Grove, CA, Nov. 2020. [IEEEXplore] (Student Paper Contest Finalist)
C. Dinesh, G. Cheung, F. Wang, and I. V. Bajić, “Sampling of 3D point cloud via Gershgorin disc alignment,” Proc. IEEE ICIP'20, pp. 2736-2740, Abu Dhabi, UAE, Oct. 2020. [IEEEXplore]
R. A. Cohen, H. Choi, and I. V. Bajić, “Lightweight compression of neural network feature tensors for collaborative intelligence,” Proc. IEEE ICME'20, pp. 1-6, London, UK, Jul. 2020. [IEEEXplore]
H. Choi, R. A. Cohen, and I. V. Bajić, “Back-and-forth prediction for deep tensor compression,” Proc. IEEE ICASSP'20, pp. 4467-4471, Barcelona, Spain, May 2020. [arXiv]
C. Dinesh, G. Cheung, and I. V. Bajić, “Super-resolution of 3D color point clouds via fast graph total variation,” Proc. IEEE ICASSP'20, pp. 1983-1987, Barcelona, Spain, May 2020. [IEEEXplore]
S. R. Alvar and I. V. Bajić, “Bit allocation for multi-task collaborative intelligence,” Proc. IEEE ICASSP'20, pp. 4342-4346, Barcelona, Spain, May 2020. [arXiv]
T. Woinoski, A. Harell, and I. V. Bajić, “Towards automated swimming analytics using deep neural networks,” AAAI Workshop on AI in Team Sports, New York, NY, Feb. 2020. [arXiv]
A. Harell and I. V. Bajić, “The data gap in sports analytics and how to close it,” AAAI Workshop on AI in Team Sports, New York, NY, Feb. 2020. [PDF]
2019
J. Fu, I. V. Bajić, and R. G. Vaughan, “Datasets for face and object detection in fisheye images,” Data in Brief, vol. 27, article no. 104752, Dec. 2019. [DOI]
C. Dinesh, S. Makonin, and I. V. Bajić, “Residential power forecasting using load identification and graph spectral clustering,” IEEE Trans. Circuits and Systems II: Express Briefs, vol. 66, no. 11, pp. 1900-1904, Nov. 2019. [ResearchGate]
M. Gaur, S. Makonin, I. V. Bajić, and A. Majumdar, “Performance evaluation of techniques for identifying abnormal energy consumption in buildings,” IEEE Access, vol. 7, pp. 62721-62733, May 2019. [IEEEXplore]
H. Hadizadeh, A. R. Heravi, I. V. Bajić, and P. Karami, “A perceptual distinguishability predictor for JND-noise-contaminated images,” IEEE Trans. Image Processing, vol. 28, no. 5, pp. 2242-2256, May 2019. [IEEEXplore]
X. Shang, G. Wang, X. Zhao, Y. Zuo, J. Liang, and I. V. Bajić, “Weighting quantization matrices for HEVC/H.265-coded RGB videos,” IEEE Access, vol. 7, pp. 36019-36032, Apr. 2019. [IEEEXplore]
M. Ulhaq and I. V. Bajić, “Shared mobile-cloud inference for collaborative intelligence,” demo at NeurIPS'19, Vancouver, BC, Dec. 2019. [arXiv]
E. Ideli, B. Sharpe, I. V. Bajić, and R. G. Vaughan, “Visually assisted time-domain speech enhancement,” Proc. IEEE GlobalSIP'19, Ottawa, ON, Nov. 2019. [IEEEXplore]
C. Dinesh, G. Cheung, and I. V. Bajić, “3D point cloud color denoising using convex graph-signal smoothness priors,” Proc. IEEE MMSP'19, pp. 1-6, Kuala Lumpur, Malaysia, Sep. 2019. [IEEEXplore]
S. R. Alvar and I. V. Bajić, “Multi-task learning with compressible features for collaborative intelligence,” Proc. IEEE ICIP'19, pp. 1705-1709, Taipei, Taiwan, Sep. 2019. [arXiv] [code] (Best Student Paper Award)
C. Dinesh, G. Cheung, and I. V. Bajić, “3D point cloud super-resolution via graph total variation on surface normals,” Proc. IEEE ICIP'19, pp. 4390-4394, Taipei, Taiwan, Sep. 2019. [arXiv] (Spotlight Paper - top 10%)
A. Harell, S. Makonin, and I. V. Bajić, “WaveNILM: A causal neural network for power disaggregation from the complex power signal,” Proc. IEEE ICASSP'19, pp. 8335-8339, Brighton, UK, May 2019. [arXiv] [GitHub]
J. Fu, S. R. Alvar, I. V. Bajić, and R. G. Vaughan, “FDDB-360: Face detection in 360-degree fisheye images,” Proc. IEEE MIPR'19, pp. 15-19, San Jose, CA, Mar. 2019. [arXiv] [data]
2018
C. Dinesh, I. V. Bajić, and G. Cheung, “Adaptive nonrigid inpainting of 3D point cloud geometry,” IEEE Signal Processing Letters, vol. 25, no. 6, pp. 878-882, Jun. 2018. [ResearchGate] [code]
H. Hadizadeh and I. V. Bajić, “Full-reference objective quality assessment of tone-mapped images,” IEEE Trans. Multimedia, vol. 20, no. 2, pp. 392-404, Feb. 2018. [ResearchGate]
H. Choi and I. V. Bajić, “Deep feature compression for collaborative object detection,” Proc. IEEE ICIP'18, pp. 3743-3747, Athens, Greece, Oct. 2018. [ResearchGate] (IEEE SPS Student Travel Grant)
H. Unnibhavi, H. Choi, S. R. Alvar, and I. V. Bajić, “DFTS: Deep Feature Transmission Simulator,” demo paper at IEEE MMSP'18, Vancouver, BC, Aug. 2018. [ResearchGate] [GitHub]
A. Harell, S. Makonin, and I. V. Bajić, “A Recurrent Neural Network for Multisensory Non-Intrusive Load Monitoring on a Raspberry Pi,” demo paper at IEEE MMSP'18, Vancouver, BC, Aug. 2018. [ResearchGate]
S. R. Alvar and I. V. Bajić, “MV-YOLO: Motion vector-aided tracking by semantic object detection,” Proc. IEEE MMSP'18, Vancouver, BC, Aug. 2018. [ResearchGate]
H. Choi and I. V. Bajić, “Near-lossless deep feature compression for collaborative intelligence,” Proc. IEEE MMSP'18, Vancouver, BC, Aug. 2018. [ResearchGate]
C. Dinesh, G. Cheung, I. V. Bajić, and C. Yang, “Fast 3D point cloud denoising via bipartite graph approximation and total variation,” Proc. IEEE MMSP'18, Vancouver, BC, Aug. 2018. [ResearchGate]
S. R. Alvar, H. Choi, and I. V. Bajić, “Can you find a face in a HEVC bitstream?” Proc. IEEE ICASSP'18, pp. 1288-1292, Calgary, AB, Apr. 2018. [ResearchGate] (Featured in IEEE Signal Processing Magazine, May 2020 [IEEEXplore])
H. Choi and I. V. Bajić, “High efficiency compression for object detection,” Proc. IEEE ICASSP'18, pp. 1729-1796, Calgary, AB, Apr. 2018. [ResearchGate]
S. R. Alvar, H. Choi, and I. V. Bajić, “Can you tell a face from a HEVC bitstream?” Proc. IEEE MIPR'18, Miami, FL, Apr. 2018. [ResearchGate]
2017
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Compressed-domain visual saliency models: A comparative study,” Multimedia Tools and Applications, vol. 76, no. 24, pp. 26297–26328, Dec. 2017. [ResearchGate]
H. Hadizadeh, A. Rajati, and I. V. Bajić, “Saliency-guided just noticeable distortion estimation using the normalized Laplacian pyramid,” IEEE Signal Processing Letters, vol. 24, no. 8, pp. 1218-1222, Aug. 2017. [ResearchGate]
M. Z. A. Bhotto, S. Makonin, and I. V. Bajić, “Load disaggregation based on aided linear integer programming,” IEEE Trans. Circuits and Systems II: Express Briefs, vol. 64, no. 7, pp. 792 - 796, Jul. 2017. [ResearchGate] [code]
C.-H. Kwak and I. V. Bajić, “Online MoCap data coding with bit allocation, rate control, and motion-adaptive post-processing,” IEEE Trans. Multimedia, vol. 19, no. 6, pp. 1127-1141, Jun. 2017. [ResearchGate] [code]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “A simulation study of a 3D sound field reproduction system for immersive communication,” IEEE/ACM Trans. Audio, Speech, and Language Processing, vol. 25, no. 5, pp. 980-995, May 2017. [ResearchGate] [code]
C. Dinesh, I. V. Bajić, and G. Cheung, “Exemplar-based framework for 3D point cloud hole filling,” Proc. IEEE VCIP'17, St. Petersburg, FL, Dec. 2017. [ResearchGate] [code]
H. Choi and I. V. Bajić, “HEVC intra features for human detection,” Proc. IEEE GlobalSIP'17, pp. 393-397, Montreal, QC, Nov. 2017. [ResearchGate]
C. Dinesh, S. Makonin, and I. V. Bajić, “Incorporating time-of-day usage patterns into non-intrusive load monitoring,” Proc. IEEE GlobalSIP'17, pp. 1110-1114, Montreal, QC, Nov. 2017. [ResearchGate]
H. Choi and I. V. Bajić, “Corner proposals from HEVC bitstreams,” Proc. IEEE ISCAS'17, pp. 1-4, Baltimore, MD, May 2017. [ResearchGate]
2016
I. V. Bajić, “Video streaming,” AccessScience, McGraw-Hill Education, 2016 [AccessScience]
H. Hadizadeh and I. V. Bajić, “Color Gaussian jet features for no-reference quality assessment of multiply-distorted images,” IEEE Signal Processing Letters, vol. 23, no. 12, pp. 1717-1721, Dec. 2016. [ResearchGate] [code]
S. Makonin, F. Popowich, I. V. Bajić, B. Gill, and L. Bartram, “Exploiting HMM sparsity to perform online real-time nonintrusive load monitoring (NILM),” IEEE Trans. Smart Grid, vol. 7, no. 6, pp. 2575-2585, Nov. 2016. [ResearchGate] [code] (ISI Highly Cited Paper)
H. Hadizadeh and I. V. Bajić, “No-reference image quality assessment using statistical wavelet-packet features,” Pattern Recognition Letters, vol. 80, pp. 144–149, Sep. 2016. [pdf] [code]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “Comparison of loudspeaker placement methods for sound field reproduction,” IEEE/ACM Trans. Audio, Speech, and Language Processing, vol. 24, no.8, pp. 1364 – 1379, Aug. 2016. [ResearchGate] [code] (Front cover of July/August issue)
S. Makonin, B. Ellert, I. V. Bajić, and F. Popowich, “Electricity, water, and natural gas consumption of a residential house in Canada from 2012 to 2014,” Scientific Data (Nature Publishing Group), vol. 3, article no. 160037, Jun. 2016. [nature.com]
V. A. Mateescu and I. V. Bajić, “Visual attention retargeting,” IEEE MultiMedia, vol. 23, no. 1, pp. 82-91, Jan.-Mar. 2016. [IEEEXplore]
M. P. Stapleton and I. V. Bajić, “Robust domain-filling plumb-line lens distortion correction,” Proc. IEEE ISM'16, pp. 507-514, San Jose, CA, Dec. 2016. [IEEEXplore] [code]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “Learning to reproduce a sound field,” Proc. IEEE MLSP'16, Salerno, Italy, Sep. 2016. [ResearchGate] (MLSP Student Travel Grant)
J. Lin and I. V. Bajić, “A platform for subjective image quality evaluation on mobile devices,” Proc. IEEE CCECE'16, Vancouver, BC, May 2016. [IEEEXplore]
M. P. Stapleton, M. Z. A. Bhotto and I. V. Bajić, “A simulation environment for visual-inertial sensor fusion,” Proc. IEEE CCECE'16, Vancouver, BC, May 2016. [IEEEXplore]
2015
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Compressed-domain correlates of human fixations in dynamic scenes,” Multimedia Tools and Applications, vol. 74, no. 22, pp. 10057-10075, Nov. 2015. (Special Issue on Perception Inspired Video Processing) [ResearchGate] [code]
Md. Z. A. Bhotto and I. V. Bajić, “Constant modulus blind adaptive beamforming based on unscented Kalman filtering,” IEEE Signal Processing Letters, vol. 22, no. 4, pp. 474-478, Apr. 2015. [IEEEXplore]
K. Min, J. Ma, D. Sim, and I. V. Bajić, “Bi-directional mesh-based frame rate up-conversion with a dense motion vector map,” IEEE MultiMedia, vol. 22, no. 2, pp. 36-45, Apr.-Jun. 2015. [IEEEXplore]
K.-Y. Min, W. Lim, J. Nam, D. Sim, and I. V. Bajić, “Distributed video coding supporting hierarchical GOP structures with transmitted motion vectors,” EURASIP J. Image and Video Processing, 2015:12, May 2015. [Springer]
S. H. Khatoonabadi, N. Vasconcelos, I. V. Bajić, and Y. Shan, “How many bits does it take for a stimulus to be salient?,” Proc. IEEE CVPR'15, pp. 5501-5510, Boston, MA, Jun. 2015. [ResearchGate] [code] (podium presentation, 3.3% acceptance rate)
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “Joint optimization of loudspeaker placement and radiation patterns for sound field reproduction,” Proc. IEEE ICASSP'15, pp. 519-523, Brisbane, Australia, Apr. 2015. [IEEEXplore] (IEEE SPS Student Travel Grant)
2014
H. Hadizadeh and I. V. Bajić, “Saliency-aware video compression,” IEEE Trans. Image Processing, vol. 23, no. 1, pp. 19-33, Jan. 2014. [IEEEXplore] [code]
V. A. Mateescu and I. V. Bajić, “Can subliminal flicker guide attention in natural images?,” Proc. ACM Multimedia PIVP, pp. 33-34, Orlando, FL, Nov. 2014. [ACM DL] [supplement]
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Compressed-domain correlates of fixations in video,” Proc. ACM Multimedia PIVP, pp. 3-8, Orlando, FL, Nov. 2014. [ACM DL] [code]
V. A. Mateescu and I. V. Bajić, “Attention retargeting by color manipulation in images,” Proc. ACM Multimedia PIVP, pp. 15-20, Orlando, FL, Nov. 2014. [ACM DL] [code]
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Comparison of visual saliency models for compressed video,” Proc. IEEE ICIP'14, pp. 1081-1085, Paris, France, Oct. 2014. [IEEEXplore] [code]
C.-H. Kwak and I. V. Bajić, “Hybrid compression of dynamic 3D mesh data,” Proc. IEEE ICASSP'14, pp. 6183-6187, Florence, Italy, May 2014. [IEEEXplore]
B. Macchiavello, C. Dorea, E. Hung, G. Cheung, and I. V. Bajić, “Low-saliency prior for disocclusion hole filling in DIBR-synthesized images,” Proc. IEEE ICASSP'14, pp. 579-583, Florence, Italy, May 2014. [IEEEXplore]
2013
H. Choi, J. Yoo, J. Nam, D. Sim, and I. V. Bajić, “Pixel-wise unified rate-quantization model for multi-level rate control,” IEEE J. Sel. Topics Signal Process., vol. 7, no. 6, pp. 1112-1123, Dec. 2013. (Special Issue on Video Coding: HEVC and Beyond) [IEEEXplore]
H. Hadizadeh, I. V. Bajić, and G. Cheung, “Video error concealment using a computation-efficient low saliency prior,” IEEE Trans. Multimedia, vol. 15, no. 8, pp. 2099-2113, Dec. 2013. [IEEEXplore]
H. Khalilian and I. V. Bajić, “Video watermarking with empirical PCA-based decoding,” IEEE Trans. Image Processing, vol. 22, no. 12, pp. 4825-4840, Dec. 2013. [IEEEXplore] [code]
P. Wan, Y. Feng, G. Cheung, I. V. Bajić, and O. C. Au, “3D motion estimation for visual saliency modeling,” IEEE Signal Processing Letters, vol. 20, no. 10, pp. 972-975, Oct. 2013. [IEEEXplore]
S. H. Khatoonabadi and I. V. Bajić, "Video object tracking in the compressed domain using spatio-temporal Markov random fields," IEEE Trans. Image Processing, vol. 22, no. 1, pp. 300-313, Jan. 2013. [IEEEXplore] [code]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “Loudspeaker placement for sound field reproduction by constrained matching pursuit,” Proc. IEEE WASPAA'13, New Paltz, NY, Oct. 2013. [IEEEXplore]
C. Qian and I. V. Bajić, “Global motion estimation under translation-zoom ambiguity,” Proc. IEEE PacRim'13, pp. 46-51, Victoria, BC, Aug. 2013. [IEEEXplore]
S. Makonin, F. Popowich, L. Bartram, B. Gill, and I. V. Bajić, “AMPds: A public dataset for load disaggregation and eco-feedback research,” Proc. IEEE EPEC'13, Halifax, NS, Aug. 2013. [IEEEXplore]
C. Qian and I. V. Bajić, “Frame rate up-conversion using global and local higher-order motion,” Proc. IEEE ICME'13, San Jose, CA, Jul. 2013. [IEEEXplore] (Best Paper Finalist)
V. A. Mateescu and I. V. Bajić, “Guiding visual attention by manipulating orientation in images,” Proc. IEEE ICME'13, San Jose, CA, Jul. 2013. [IEEEXplore] [YouTube]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “3D sound field reproduction using diverse loudspeaker patterns,” Proc. IEEE ICME'13 Workshops, short papers track, San Jose, CA, Jul. 2013. [IEEEXplore]
S. H. Khatoonabadi and I. V. Bajić, “Still visualization of object motion in compressed video,” Proc. IEEE ICME'13 Workshops - MMIX, San Jose, CA, Jul. 2013. [IEEEXplore] [code]
S. H. Khatoonabadi and I. V. Bajić, “Compressed-domain global motion estimation based on the Normalized Direct Linear Transform algorithm,” presented at ITC-CSCC'13, Yeosu, Korea, Jul. 2013. [ResearchGate] [code]
J. Nam, I. V. Bajić, and D. Sim, “Novel motion and disparity prediction for multi-view video coding,” Proc. IEEE IVMSP'13, Seoul, Korea, June 2013. [IEEEXplore]
W. Lim, I. V. Bajić, and D. Sim, “QP initialization and adaptive MAD prediction for rate control in HEVC-based multi-view video coding,” Proc. IEEE IVMSP'13, Seoul, Korea, June 2013. [IEEEXplore]
C.-H. Kwak and I. V. Bajić, “MoCap data coding with unrestricted quantization and rate control,” Proc. IEEE ICASSP'13, pp. 3741-3745, Vancouver, BC, May 2013. [IEEEXplore]
P. Wan, Y. Feng, G. Cheung, I. V. Bajić, O. C. Au, and Y. Ji, “3D motion in visual saliency modeling,” Proc. IEEE ICASSP'13, pp. 1831-1835, Vancouver, BC, May 2013. [IEEEXplore]
H. Khalilian, I. V. Bajić, and R. G. Vaughan, “Towards optimal loudspeaker placement for sound field reproduction,” Proc. IEEE ICASSP'13, pp. 321-325, Vancouver, BC, May 2013. [IEEEXplore]
W. Lim, I. V. Bajić, and D. Sim, “QP initialization and interview MAD prediction for rate control in HEVC-based multi-view video coding,” Proc. IEEE ICASSP'13, pp. 2045-2049, Vancouver, BC, May 2013. [IEEEXplore]
2012
H. Hadizadeh, M. J. Enriquez, and I. V. Bajić, "Eye-tracking database for a set of standard video sequences," IEEE Trans. Image Processing, vol. 21, no. 2, pp. 898-903, Feb. 2012. [IEEEXplore] [dataset]
V. A. Mateescu, H. Hadizadeh, and I. V. Bajić, “Evaluation of several visual saliency models in terms of gaze prediction accuracy on video,” Proc. IEEE Globecom'12 Workshop: QoEMC, pp. 1304-1308, Anaheim, CA, Dec. 2012. [IEEEXplore]
H. Hadizadeh, M. Fatourechi, and I. V. Bajić, “An automatic lyrics recognition system for digital videos,” presented at IEEE MMSP'12 (On-going Work Track), Banff, AB, Sep. 2012. [pdf]
H. Hadizadeh, I. V. Bajić, and G. Cheung, “Saliency-cognizant error concealment in loss-corrupted streaming video,” Proc. IEEE ICME'12, pp. 73-78, Melbourne, Australia, Jul. 2012. [IEEEXplore] (Best Paper Runner-up Award)
J. Nam, D. Sim, and I. V. Bajić, “HEVC-based adaptive quantization for screen content videos,” Proc. IEEE BMSB'12, Seoul, Korea, Jun. 2012. [IEEEXplore]
2011
I. V. Bajić, "Robust SWT video coding," Section 13.2 in Multidimensional Signal, Image and Video Processing and Coding, (J. W. Woods), pp. 540-550, Second Edition, Elsevier - Academic Press, 2011. ISBN 978-0123814203 [Amazon]
H. Hadizadeh and I. V. Bajić, "Burst loss resilient packetization of video," IEEE Trans. Image Processing, vol. 20, no. 11, pp. 3195-3206, Nov. 2011. [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "A joint approach to global motion estimation and motion segmentation from a coarsely sampled motion vector field," IEEE Trans. Circuits Syst. Video Technol., vol. 21, no. 9, pp. 1316-1328, Sep. 2011. [IEEEXplore] [code]
H. Hadizadeh and I. V. Bajić, "Rate-distortion optimized pixel-based motion vector concatenation for reference picture selection," IEEE Trans. Circuits Syst. Video Technol., vol. 21, no. 8, pp. 1139-1151, Aug. 2011. [IEEEXplore]
Y.-M. Chen, I. V. Bajić, and P. Saeedi, "Moving region segmentation from compressed video using global motion estimation and Markov random fields," IEEE Trans. Multimedia, vol. 13, no. 3, pp. 421-431, Jun. 2011. (Special Issue on ICME 2010) [IEEEXplore]
W. Zhang, X. Shao, M. Torki, A. HajShirMohammadi, and I. V. Bajić, "Unequal error protection of JPEG2000 images using short block length turbo codes," IEEE Communications Letters, vol. 15, no. 6, pp. 659-661, Jun. 2011. [IEEEXplore]
I. V. Bajić and X. Ma, "A testbed and methodology for comparing live video frame rate control methods," IEEE Signal Processing Letters, vol. 18, no. 1, pp. 31-34, Jan. 2011. [IEEEXplore]
H. Hadizadeh, I. V. Bajić, P. Saeedi, and S. Daly, "Good-looking green images," Proc. IEEE ICIP'11, pp. 3177-3180, Brussels, Belgium, Sep. 2011. [IEEEXplore]
H. Choi, J. Nam, D. Sim, and I. V. Bajić, "Scalable video coding based on high efficiency video coding (HEVC)," Proc. IEEE PacRim'11, pp. 346-351, Victoria, BC, Aug. 2011. [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "Spatio-temporal super-resolution from compressed video employing global and local motion," Proc. IEEE PacRim'11, pp. 907-912, Victoria, BC, Aug. 2011. [IEEEXplore]
H. Khalilian and I. V. Bajić, "Multiplicative video watermarking with semi-blind maximum likelihood decoding for copyright protection," Proc. IEEE PacRim'11, pp. 125-130, Victoria, BC, Aug. 2011. [IEEEXplore]
J. Nam, W. Lim, D. Sim, and I. V. Bajić, "Multi-view video coding based on high efficiency video coding (HEVC)," presented at ITC-CSCC 2011, Gyeongju, Korea, Jun. 2011.
Y.-M. Chen and I. V. Bajić, "Predictive video decoding using GME and motion reliability," Proc. SPIE Applications of Digital Image Processing XXXIV, vol. 8135, San Diego, CA, Aug. 2011.
H. Hadizadeh and I. V. Bajić, "Saliency-preserving video compression," presented at IEEE AVCC, in conjunction with IEEE ICME'11, Barcelona, Spain, Jul. 2011. [IEEEXplore]
C.-H. Kwak and I. V. Bajić, "Error concealment strategies for motion capture data streaming," presented at IEEE StreamComm, in conjunction with IEEE ICME'11, Barcelona, Spain, Jul. 2011. [IEEEXplore]
C.-H. Kwak and I. V. Bajić, "Hybrid low-delay compression of motion capture data," Proc. IEEE ICME'11, Barcelona, Spain, Jul. 2011. [IEEEXplore]
2010
S. Bahmani, I. V. Bajić, and A. HajShirMohammadi, "Joint decoding of unequally protected JPEG2000 bitstreams and Reed-Solomon codes," IEEE Trans. Image Processing, vol. 19, no. 10, pp. 2693 - 2704, Oct. 2010. [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "Region-based predictive decoding of video," IEEE Trans. Circuits Syst. Video Technol., vol. 20, no. 3, pp. 452-457, Mar. 2010. [IEEEXplore] [code]
Y.-M. Chen and I. V. Bajić, "Motion vector outlier rejection cascade for global motion estimation," IEEE Signal Processing Letters, vol. 17, no. 2, pp. 197-200, Feb. 2010. [IEEEXplore] [code]
Y.-M. Chen, I. V. Bajić, and P. Saeedi, "Motion segmentation in compressed video using Markov random fields," Proc. IEEE ICME'10, pp. 760-765, Singapore, July 2010. [IEEEXplore]
H. Hadizadeh and I. V. Bajić, "Pixel-based motion vector concatenation for reference picture selection," Proc. IEEE ICME'10, pp. 209-213, Singapore, July 2010. [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "Predictive video decoding based on ordinal depth of moving regions," Proc. IEEE ICC'10, Cape Town, South Africa, May 2010. [IEEEXplore]
H. Hadizadeh and I. V. Bajić, "Burst loss resilient packetization of video," Proc. IEEE ICC'10, Cape Town, South Africa, May 2010. [IEEEXplore]
I. V. Bajić and X. Ma, "MCL.JIT library for scalable live video in Max/MSP/Jitter," Proc. IEEE CCECE 2010, Calgary, AB, May 2010. [IEEEXplore]
H. Hadizadeh and I. V. Bajić, "NAL-SIM: An interactive simulator for H.264/AVC video coding and transmission," Proc. IEEE CCNC'10, Las Vegas, NV, Jan. 2010. [IEEEXplore] [code]
2009
Y. Shan, I. V. Bajić, J. W. Woods, and S. Kalyanaraman, "Scalable video streaming with fine grain adaptive forward error correction," IEEE Trans. Circuits Syst. Video Technol., vol. 19, no. 9, pp. 1302-1314, Sep. 2009. [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "Compressed-domain moving region segmentation with pixel precision using motion integration," Proc. IEEE PacRim'09, pp. 442-447, Victoria, BC, August 2009. [IEEEXplore]
Y.-M. Chen, I. V. Bajić, and C. Qian, "Frame rate up-conversion of compressed video using region segmentation and depth ordering," Proc. IEEE PacRim'09, pp. 431-436, Victoria, BC, August 2009. [IEEEXplore]
S. Bahmani, I. V. Bajić, and A. HajShirMohammadi, "Improved joint source-channel decoding of JPEG2000 images and Reed-Solomon codes," Proc. IEEE ICC'09, Dresden, Germany, June 2009. [IEEEXplore]
S. M. Amiri and I. V. Bajić, "Subset selection in Type-II hybrid ARQ/FEC for video multicast," Proc. IEEE ICC'09, Dresden, Germany, June 2009.
Y.-M. Chen, I. V. Bajić, and P. Saeedi, "Coarse-to-fine moving region segmentation in compressed video," Proc. IEEE WIAMIS'09, pp. 45-48, London, UK, May 2009. [IEEEXplore]
2008
I. V. Bajić, Robust Subband/Wavelet Coding and Transmission of Images and Video, VDM Verlag, 2008. ISBN 978-3639104400 [amazon]
I. V. Bajić, "Error control for broadcasting and multicasting: An overview," in Mobile Multimedia Broadcasting Standards: Technology and Practice, (F.-L. Luo, ed.), pp. 313-335, Springer, 2008. ISBN 978-0-387-78262-1 [pdf][amazon]
S. Bahmani, I. V. Bajić, and A. HajShirMohammadi, "Joint source-channel decoding of JPEG2000 images with unequal loss protection," Proc. IEEE ICASSP'08, pp. 1365-1368, Las Vegas, NV, March 2008. [IEEEXplore]
S. M. Amiri and I. V. Bajić, "A two-stage H.264/AVC encoder for video streaming with fast reference picture selection," Proc. ACM WMuNeP’08, pp. 37-44, Vancouver, BC, Oct. 2008.
S. M. Amiri and I. V. Bajić, "A novel noncausal whole-frame concealment algorithm for video streaming," IEEE ISM’08, pp. 154-159, Berkeley, CA, Dec. 2008.
2007
I. V. Bajić and J. W. Woods, "Error concealment for scalable motion-compensated subband/wavelet video coders," IEEE Trans. Circuits Syst. Video Technol., vol. 17, no. 4, pp. 508-514, Apr. 2007. [IEEEXplore]
I. V. Bajić, "Efficient cross-layer error control for wireless video multicast," IEEE Trans. Broadcasting, vol. 53, no. 1, part 2, pp. 276-285, March 2007. (Special Issue on Mobile Multimedia Broadcasting) [IEEEXplore]
Y.-M. Chen and I. V. Bajić, "Predictive decoding for delay reduction in video communications," Proc. IEEE Globecom'07, pp. 2053-2057, Washington, DC, November 2007. [IEEEXplore]
I. V. Bajić, "The effects of channel correlation on the performance of some multiple description schemes," Proc. Canadian Workshop on Information Theory (CWIT'07), pp. 93-96, Edmonton, AB, Canada, June 2007. [IEEEXplore]
2006
I. V. Bajić, "Robust SWT video coding," Section 12.2 in Multidimensional Signal, Image and Video Processing and Coding, (J. W. Woods), pp. 447-457, Elsevier - Academic Press, 2006. ISBN 978-0120885169 [amazon].
I. V. Bajić, "Noncausal error control for video streaming over wireless packet networks," IEEE Trans. Multimedia, vol.8, no. 6, pp. 1263-1273, Dec. 2006. [IEEEXplore]
P. Luykx, I. V. Bajić, and S. Khuri, "NXSensor web tool for evaluating DNA for nucleosome exclusion sequences and accessibility to binding factors," Nucleic Acids Research, vol. 34, Web Server issue, pp. W560-W565, July 2006. [pdf]
I. V. Bajić, "Detection-theoretic analysis of MatInspector," IEEE Trans. Signal Processing, vol. 54, no. 6, part 2, pp. 2388-2393, June 2006. (Special Issue on Genomic Signal Processing) [IEEEXplore]
I. V. Bajić, "Adaptive MAP error concealment for dispersively packetized wavelet-coded images," IEEE Trans. Image Processing, vol. 15, no. 5, pp. 1226-1235, May 2006. [IEEEXplore]
I. V. Bajić, "Efficient error control for wireless video multicast," Proc. IEEE Workshop on Multimedia Signal Processing (MMSP’06), pp. 306-309, Victoria, BC, Canada, Oct. 2006.
I. V. Bajić, "Non-causal error control for wireless video streaming with noncoherent signaling," Proc. IEEE ISCAS'06, pp. 690-693, Kos Island, Greece, May 2006. [IEEEXplore]
2005
Y. Shan, I. V. Bajić, S. Kalyanaraman, and J. W. Woods, "Overlay multi-hop FEC scheme for video streaming," Signal Processing: Image Commun., vol. 20, no. 8, pp. 710-727, September 2005. (Special Issue on Video Networking) [pdf] (Among top 25 downloaded papers for this journal in the period July - September 2005.)
Y. Shan, S. Kalyanaraman, J. W. Woods, and I. V. Bajić, "Joint source-network error control coding for scalable overlay video streaming," Proc. IEEE ICIP'05, vol. 1, pp. 177-180, Genova, Italy, September 2005. [IEEEXplore]
X. Yu, J. W. Modestino, and I. V. Bajić, "Performance analysis of the efficacy of packet-level FEC in improving video transport over networks," Proc. IEEE ICIP'05, vol. 2, pp. 177-180, Genova, Italy, September 2005. [IEEEXplore]
X. Yu, J. W. Modestino, and I. V. Bajić, "Modeling and analysis of multipath video transport over lossy networks using packet-level FEC," Proc. DMS'05, pp. 265-270, Banff, AB, Canada, September 2005. [pdf]
I. V. Bajić, "Non-causal error control for video streaming over wireless packet networks," Proc. IEEE WirelessCom’05, pp. 1106-1111, Maui, HI, Jun. 2005.
I. V. Bajić, "Detection-theoretic analysis of MatInspector," Proc. IEEE Workshop on Genomic Signal Processing and Statistics (GENSIPS’05), New Port, RI, May 2005.
2004
V. B. Bajić and I. V. Bajić, "How neural networks find promoters using recognition of micro-structural promoter components," Chapter 5 in The Practical Bioinformatician, (L. Wong, Ed.), pp. 91-122, World Scientific, 2004. ISBN 9-812-38846-X [amazon].
Q. Qu, I. V. Bajić, X. Tian, and J. W. Modestino, "On the effects of path correlation in multi-path video communications over packet networks," Proc. IEEE Globecom'04, vol. 2, pp. 977-981, Dallas, TX, Nov.-Dec. 2004. [IEEEXplore]
Y. Shan, I. V. Bajić, S. Kalyanaraman, and J. W. Woods, "Overlay multi-hop FEC scheme for video streaming over peer-to-peer networks," Proc. IEEE ICIP’04, vol. 5, pp. 3133-3136, Singapore, Oct. 2004.
I. V. Bajić, "Optimal subsampling of circularly bandlimited images," Proc. IEEE ICASSP'04, vol. 3, pp. 313-316, Montreal, Canada, May 2004. [IEEEXplore]
I. V. Bajić, "Adaptive MAP error concealment for dispersively packetized images," Proc. IEEE Int. Symposium on Multimedia Software Engineering (MSE’04), pp. 52-59, Miami, FL, Dec. 2004.
2003
I. V. Bajić and J. W. Woods, "Domain-based multiple description coding of images and video," IEEE Trans. Image Processing, vol. 12, no. 10, pp. 1211-1225, October 2003. [IEEEXplore]
I. V. Bajić and J. W. Woods, "Maximum minimal distance partitioning of the Z2 lattice," IEEE Trans. Inform. Theory, vol. 49, no. 4, pp. 981-992, April 2003. [IEEEXplore]
I. V. Bajić, O. Tickoo, A. Balan, S. Kalyanaraman, and J. W. Woods, "Integrated end-to-end buffer management and congestion control for scalable video communications," Proc. IEEE ICIP'03, vol. III, pp. 257-260, Barcelona, Spain, Sep. 2003. (IBM Research Student Travel Grant)
I. V. Bajić and J. W. Woods, "EZBC video streaming with channel coding and error concealment," Proc. SPIE VCIP'03, vol. 5150, pp. 512 – 522, Lugano, Switzerland, Jul. 2003.
2002
I. V. Bajić and J. W. Woods, "Concatenated multiple description coding of frame-rate scalable video," Proc. IEEE ICIP'02, vol. II, pp. 193-196, Rochester, NY, Sep. 2002.
I. V. Bajić and J. W. Woods, "Domain-based multiple description coding of images and video," Proc. SPIE VCIP'02, pp. 124-135, San Jose, CA, Jan. 2002.
2000
I. V. Bajić, J. W. Woods, and A. M. Chaudry, "Robust transmission of packet video through dispersive packetization and error concealment," Proc. Packet Video Workshop (PV2000), Cagliari, Sardinia, Italy, May 2000.
Software
The software below is provided as is, without any warranty, expressed or implied. It is free for academic and non-commercial use. If you use the software in your research, please cite the corresponding references.
Adaptive hole filling for 3D point clouds - Implementation of exemplar-based hole filling from the SPL 2018 paper. Download.
C. Dinesh, I. V. Bajić, and G. Cheung, “Adaptive non-rigid inpainting of 3D point cloud geometry,” IEEE Signal Processing Letters, vol. 25, no. 6, pp. 878-882, Jun. 2018. [ResearchGate]
Exemplar-based hole filling for 3D point clouds - Implementation of exemplar-based hole filling from the VCIP 2017 paper. Download.
C. Dinesh, I. V. Bajić, and G. Cheung, “Exemplar-based framework for 3D point cloud hole filling,” Proc. IEEE VCIP'17, St. Petersburg, FL, Dec. 2017. [ResearchGate]
Color Gaussian jet features for image quality assessment - Implementation of Color Gaussian jet features for quality assessment of multiply-distorted images. Download.
H. Hadizadeh and I. V. Bajić, “Color Gaussian jet features for no-reference quality assessment of multiply-distorted images,” IEEE Signal Processing Letters, vol. 23, no. 12, pp. 1717-1721, Dec. 2016. [ResearchGate]
No-reference image quality assessment - A tool to evaluate image quality without a reference image. Download. (for password, please send an e-mail with your name and affiliation to hadi.sfu@gmail.com)
H. Hadizadeh and I. V. Bajić, “No-reference image quality assessment using statistical wavelet-packet features,” Pattern Recognition Letters, vol. 80, pp. 144–149, Sep. 2016. [pdf]
How many bits does it take for a stimulus to be salient? - Implementation of saliency estimation in video based on Operational Block Description Length (OBDL). Download.
S. H. Khatoonabadi, N. Vasconcelos, I. V. Bajić, and Y. Shan, “How many bits does it take for a stimulus to be salient?,” Proc. IEEE CVPR'15, pp. 5501-5510, Boston, MA, Jun. 2015. [pdf]
Attention retargeting by color manipulation - Implementation of an attention retargeting method based on color manipulation. Download.
V. A. Mateescu and I. V. Bajić, “Attention retargeting by color manipulation in images,” Proc. ACM Multimedia PIVP, pp. 15-20, Orlando, FL, Nov. 2014. [ACM DL]
Subliminal flicker - Experiments with subliminal flicker to guide attention in natural images. Download.
V. A. Mateescu and I. V. Bajić, “Can subliminal flicker guide attention in natural images?,” Proc. ACM Multimedia PIVP, pp. 33-34, Orlando, FL, Nov. 2014. [ACM DL]
Compressed-domain correlates of fixations in video - Implementation of visual saliency estimation methods for compressed video from the following two papers.
Download PIVP code.
Download MTAP code.
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Compressed-domain correlates of fixations in video,” Proc. ACM Multimedia PIVP, pp. 3-8, Orlando, FL, Nov. 2014. [ACM DL]
S. H. Khatoonabadi, I. V. Bajić, and Y. Shan, “Compressed-domain correlates of human fixations in dynamic scenes,” Multimedia Tools and Applications, vol. 74, no. 22, pp. 10057-10075, Nov. 2015. (Special Issue on Perception Inspired Video Processing) [ResearchGate]
Saliency-aware video compression - Implementation of saliency-aware video compression from the following paper. Download.
H. Hadizadeh and I. V. Bajić, “Saliency-aware video compression,” IEEE Trans. Image Processing, vol. 23, no. 1, pp. 19-33, Jan. 2014. [pdf]
Motion visualization in compressed video - Matlab code to reproduce the results from the following paper. Download.
S. H. Khatoonabadi and I. V. Bajić, “Still visualization of object motion in compressed video,” Proc. ICME'13 Workshops - MMIX, San Jose, CA, Jul. 2013. [pdf]
NDLT-based compressed-domain GME - Matlab code for compressed-domain Global Motion Estimation (GME) based on the Normalized Direct Linear Transform (NDLT) algorithm. Download.
S. H. Khatoonabadi and I. V. Bajić, “Compressed-domain global motion estimation based on the Normalized Direct Linear Transform algorithm,” presented at ITC-CSCC'13, Yeosu, Korea, Jul. 2013. [ResearchGate]
Compressed-domain tracking - Matlab code to reproduce the results from the following paper. Download.
S. H. Khatoonabadi and I. V. Bajić, "Video object tracking in the compressed domain using spatio-temporal Markov random fields," IEEE Trans. Image Processing, vol. 22, no. 1, pp. 300-313, Jan. 2013. [pdf]
Joint global motion estimation and motion segmentation - Matlab code to reproduce the results from the following paper. Download.
Y.-M. Chen and I. V. Bajić, "A joint approach to global motion estimation and motion segmentation from a coarsely sampled motion vector field," IEEE Trans. Circuits Syst. Video Technol., vol. 21, no. 9, pp. 1316-1328, Sep. 2011. [pdf]
Outlier removal for global motion estimation - Matlab code for removing motion vector (MV) outliers from the MV field prior to global motion estimation. Download.
Y.-M. Chen and I. V. Bajić, "Motion vector outlier rejection cascade for global motion estimation," IEEE Signal Processing Letters, vol. 17, no. 2, pp. 197-200, Feb. 2010. [pdf]
NAL-SIM - An interactive simulator of H.264/AVC video coding and transmission. Allows the user to encode a raw YUV video into H.264/AVC bitstream using a variety of options, analyze the bitstream structure (NAL units), simulate the loss of NAL units, and see the effects of loss on the decoded video quality. Download.
H. Hadizadeh and I. V. Bajić, "NAL-SIM: An interactive simulator for H.264/AVC video coding and transmission," Proc. IEEE CCNC'10, Las Vegas, NV, Jan. 2010. [pdf]
mcl.jit - A library of external objects for video coding, processing, and communication in Max/MSP/Jitter developed under the New Media Initiative grant funded by NSERC and CCA. A separate web page is maintained for it. Web.
Region-based predictive decoding of video - A Windows executable implementing Xvid MPEG-4 video encoding, and Region-Based Predictive Decoding (RBPD) of the resulting MPEG-4 video bitstreams. Download.
Y.-M. Chen and I. V. Bajić, "Region-based predictive decoding of video," IEEE Trans. Circuits Syst. Video Technol., vol. 20, no. 3, pp. 452-457, Mar. 2010. [pdf]
Error concealment for MC-EZBC - Microsoft Visual C/C++ code for motion-compensated error concealment for MC-EZBC. It includes an early version of MC-EZBC submitted to MPEG in 2002. Current versions of MC-EZBC are available on the CIPR website. Download.
I. V. Bajić and J. W. Woods, "Error concealment for scalable motion-compensated subband/wavelet video coders," IEEE Trans. Circuits Syst. Video Technol., vol. 17, no. 4, pp. 508-514, Apr. 2007. [pdf]
NXSensor - Nucleosome eXclusion Sequence sensor is a tool for finding regions of DNA sequences that are likely to be nucleosome-free. The basic idea behind NXSensor is that the DNA sequence which wraps around the nuclosome needs to have a certain degree of flexibility. DNA flexibility is a necessary (though not the only, and also not sufficient) condition for nucleosome formation. It is known that the intrinsic curvature of a piece of DNA depends on its sequence, and we use that knowledge to find DNA sequences that are fairly rigid. Regions of DNA that have several rigid sequences close to each other are likely to be nucleosome-free. Web.
P. Luykx, I. V. Bajić, and S. Khuri, "NXSensor web tool for evaluating DNA for nucleosome exclusion sequences and accessibility to binding factors," Nucleic Acids Research, vol. 34, Web Server issue, pp. W560-W565, July 2006. [pdf]
Maximum minimal distance lattice partitioning (MMDLP) - Matlab code for generating a partition matrix that solves the constrained sphere packing problem on the Z2 lattice. Download.
I. V. Bajić and J. W. Woods, "Maximum minimal distance partitioning of the Z2 lattice," IEEE Trans. Inform. Theory, vol. 49, no. 4, pp. 981-992, April 2003. [pdf]
Dispersive Packetization (DP) for images - Microsoft Visual C/C++ code for dispersive packetization of subband/wavelet coded images. Baseline coder is based on Geoff Davis' Kit, with the packetization and error concealment modules added. Download.
I. V. Bajić and J. W. Woods, "Domain-based multiple description coding of images and video," IEEE Trans. Image Processing, vol. 12, no. 10, pp. 1211-1225, October 2003. [pdf]
I. V. Bajić, "Adaptive MAP error concealment for dispersively packetized wavelet-coded images," IEEE Trans. Image Processing, vol. 15, no. 5, pp. 1226-1235, May 2006. [pdf]
Data
The datasets below are provided without any warranty, expressed or implied. They are free for academic and non-commercial use. If you use the data in your research, please cite the corresponding references.
SFU-HW-Tracks-v1 - This dataset is an extension of SFU-HW-Objects-v1, and contains unique object IDs for each annotated object in 13 raw HEVC v1 CTC sequences. This allows for benchmarking tracking algorithms and studying the relationship between video compression and tracking.
T. Tanaka, H. Choi, and I. V. Bajić, “Updating a dataset of labelled objects on raw video sequences with unique object IDs,” Data in Brief, vol. 41, article no. 107892, Apr. 2022. [DOI]
T. Tanaka, H. Choi, and I. V. Bajić, "SFU-HW-Tracks-v1: Object tracking dataset on raw video sequences," arXiv preprint arXiv:2112.14934, Dec. 2021. [arXiv]
SFU-HW-Objects - This dataset contains object annotations (bounding boxes and object classes) for raw HEVC v1 CTC sequences.
H. Choi, E. Hosseini, S. R. Alvar, R. A. Cohen, I. V. Bajić, A. Karabutov, Y. Zhao, and E. Alshina, "[VCM] Object labelled dataset on raw video sequences," ISO/IEC JTC1/SC29/WG11 MPEG2020/m54737, Jul. 2020. [doc]
H. Choi, E. Hosseini, S. R. Alvar, R. A. Cohen, I. V. Bajić, “A dataset of labelled objects on raw video sequences,” Data in Brief, vol. 34, article no. 106701, Feb. 2021. [DOI]
VOC-360 - This dataset includes a collection of images from from the VOC 2012 dataset that have been processed to look like fisheye images coming from a typical 360-degree camera. The dataset allows one to train models for object detection and segmentation on fisheye-looking images. The dataset includes images, object annotations, and segmentation masks.
J. Fu, I. V. Bajić, and R. G. Vaughan, "Datasets for face and object detection in fisheye images," Data in Brief, vol. 27, article no. 104752, Dec. 2019. [DOI]
Wider-360 - This dataset includes a collection of images from the Wider Face Detection Benchmark that have been processed to look like fisheye images coming from a typical 360-degree camera. The dataset allows one to train face detectors on fisheye-looking images. The dataset includes images and face annotations.
J. Fu, I. V. Bajić, and R. G. Vaughan, "Datasets for face and object detection in fisheye images," Data in Brief, vol. 27, article no. 104752, Dec. 2019. [DOI]
FDDB-360 - This dataset includes a collection of images from the Face Detection Data Set and Benchmark (FDDB) that haven been processed to look like fisheye images coming from a typical 360-degree camera. The dataset allows one to train face detectors on fisheye-looking images. The dataset includes images, face annotations, sample code to train and test a face detector, as well as a sample face detection model described in the paper below.
J. Fu, S. R. Alvar, I. V. Bajić, and R. G. Vaughan, "FDDB-360: Face detection in 360-degree fisheye images," Proc. IEEE MIPR'19, pp. 15-19, San Jose, CA, Mar. 2019. [arXiv]
Eye tracking database for standard video sequences - This dataset includes a database of gaze locations by 15 independent viewers on a set of 12 standard CIF video sequences: Foreman, Bus, City, Crew, Flower Garden, Mother and Daughter, Soccer, Stefan, Mobile Calendar, Harbor, and Tempete. Included are the gaze locations for the first and second viewing of each sequence, their visualizations, heat maps, and sample MATLAB demo files that show how to use the data.
H. Hadizadeh, M. J. Enriquez, and I. V. Bajić, "Eye-tracking database for a set of standard video sequences," IEEE Trans. Image Processing, vol. 21, no. 2, pp. 898-903, Feb. 2012. [pdf]
Segmented foreground objects - This dataset includes manually segmented foreground objects that we used as the ground truth in our moving region segmentation. Each set contains segmentation masks, segmented object(s), and original frames.
Y.-M. Chen, I. V. Bajić, and P. Saeedi, "Coarse-to-fine moving region segmentation in compressed video," Proc. IEEE WIAMIS'09, pp. 45-48, London, UK, May 2009. [pdf]
Y.-M. Chen and I. V. Bajić, "Compressed-domain moving region segmentation with pixel precision using motion integration," Proc. IEEE PacRim'09, pp. 442-447, Victoria, BC, August 2009. [pdf]
Openings
No openings at the moment.
Future openings will be announced here and on Twitter @IvanBajic