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Badrinath Roysam
Badri Roysam
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- affiliation: University of Houston, Department of Electrical Engineering, TX, USA
- affiliation: Rensselaer Polytechnic Institute, Troy, USA
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2020 – today
- 2024
- [j60]Son T. Ly
, Bai Lin, Hung Q. Vo
Cellular data extraction from multiplexed brain imaging data using self-supervised Dual-loss Adaptive Masked Autoencoder. Artif. Intell. Medicine 151: 102828 (2024) - [j59]Ryan Faulkenberry, Saurabh Prasad, Dragan Maric, Badrinath Roysam:
Visual Prompting Based Incremental Learning for Semantic Segmentation of Multiplex Immuno-Flourescence Microscopy Imagery. Neuroinformatics 22(2): 147-162 (2024) - 2023
- [j58]Kwan-Ling Wu, Melisa A. Martinez-Paniagua, Kate Reichel, Prashant Menon, Shravani Deo, Badrinath Roysam, Navin Varadarajan
Automated detection of apoptotic bodies and cells in label-free time-lapse high-throughput video microscopy using deep convolutional neural networks. Bioinform. 39(10) (2023) - [c37]Kwan-Ling Wu
Automated Focus Restoration for High-throughput Phase Contrast Time-lapse Microscopy with De-noising Diffusion Probabilistic Model. BCB 2023: 58:1 - 2022
- [i2]Son T. Ly, Bai Lin, Hung Q. Vo, Maric Dragan, Badri Roysam, Hien Van Nguyen:
Student Collaboration Improves Self-Supervised Learning: Dual-Loss Adaptive Masked Autoencoder for Brain Cell Image Analysis. CoRR abs/2205.05194 (2022) - 2020
- [j57]Aryan Mobiny
Automated Classification of Apoptosis in Phase Contrast Microscopy Using Capsule Network. IEEE Trans. Medical Imaging 39(1): 1-10 (2020) - [c36]Jaime S. Cardoso
Correction to: Interpretable and Annotation-Efficient Learning for Medical Image Computing. iMIMIC/MIL3ID/LABELS@MICCAI 2020: 1 - [c35]Jiabing Li, Camille Artur, Jason L. Eriksen
Segmenting Continuous but Sparsely-Labeled Structures in Super-Resolution Microscopy Using Perceptual Grouping. MICCAI (5) 2020: 141-150 - [c34]Pengyu Yuan, Aryan Mobiny, Jahandar Jahanipour, Xiaoyang Li, Pietro Antonio Cicalese, Badrinath Roysam, Vishal M. Patel, Maric Dragan, Hien Van Nguyen:
Few Is Enough: Task-Augmented Active Meta-learning for Brain Cell Classification. MICCAI (1) 2020: 367-377 - [e2]Jaime S. Cardoso
Interpretable and Annotation-Efficient Learning for Medical Image Computing - Third International Workshop, iMIMIC 2020, Second International Workshop, MIL3ID 2020, and 5th International Workshop, LABELS 2020, Held in Conjunction with MICCAI 2020, Lima, Peru, October 4-8, 2020, Proceedings. Lecture Notes in Computer Science 12446, Springer 2020, ISBN 978-3-030-61165-1 [contents] - [i1]Pengyu Yuan, Aryan Mobiny, Jahandar Jahanipour, Xiaoyang Li, Pietro Antonio Cicalese, Badrinath Roysam, Vishal M. Patel, Maric Dragan, Hien Van Nguyen:
Few Is Enough: Task-Augmented Active Meta-Learning for Brain Cell Classification. CoRR abs/2007.05009 (2020)
2010 – 2019
- 2019
- [j56]Hengyang Lu, Jiabing Li, Melisa A. Martinez-Paniagua, Irfan N. Bandey
TIMING 2.0: high-throughput single-cell profiling of dynamic cell-cell interactions by time-lapse imaging microscopy in nanowell grids. Bioinform. 35(4): 706-708 (2019) - [e1]Qian Wang, Fausto Milletari, Hien Van Nguyen, Shadi Albarqouni
Domain Adaptation and Representation Transfer and Medical Image Learning with Less Labels and Imperfect Data - First MICCAI Workshop, DART 2019, and First International Workshop, MIL3ID 2019, Shenzhen, Held in Conjunction with MICCAI 2019, Shenzhen, China, October 13 and 17, 2019, Proceedings. Lecture Notes in Computer Science 11795, Springer 2019, ISBN 978-3-030-33390-4 [contents] - 2018
- [j55]Heui-Chang Lee
Placing Sites on the Edge of Planar Silicon Microelectrodes Enhances Chronic Recording Functionality. IEEE Trans. Biomed. Eng. 65(6): 1245-1255 (2018) - 2017
- [j54]Murad Megjhani
Morphologically constrained spectral unmixing by dictionary learning for multiplex fluorescence microscopy. Bioinform. 33(14): 2182-2190 (2017) - 2016
- [j53]Yan Xu, Murad Megjhani
Unsupervised Profiling of Microglial Arbor Morphologies and Distribution Using a Nonparametric Bayesian Approach. IEEE J. Sel. Top. Signal Process. 10(1): 115-129 (2016) - [j52]Feiyan Zhang, Badri Roysam:
Blind Quality Metric for Multidistortion Images Based on Cartoon and Texture Decomposition. IEEE Signal Process. Lett. 23(9): 1265-1269 (2016) - 2015
- [j51]Murad Megjhani
Population-scale three-dimensional reconstruction and quantitative profiling of microglia arbors. Bioinform. 31(13): 2190-2198 (2015) - [j50]Amine Merouane, Nicolas Rey-Villamizar, Yanbin Lu, Ivan Liadi, Gabrielle Romain, Jennifer Lu, Harjeet Singh, Laurence J. N. Cooper, Navin Varadarajan
Automated profiling of individual cell-cell interactions from high-throughput time-lapse imaging microscopy in nanowell grids (TIMING). Bioinform. 31(19): 3189-3197 (2015) - [j49]Yanbin Lu, Lawrence Carin
Quantitative Arbor Analytics: Unsupervised Harmonic Co-Clustering of Populations of Brain Cell Arbors Based on L-Measure. Neuroinformatics 13(1): 47-63 (2015) - [j48]Yan Xu, Peng Qiu, Badrinath Roysam:
Unsupervised Discovery of Subspace Trends. IEEE Trans. Pattern Anal. Mach. Intell. 37(10): 2131-2145 (2015) - 2013
- [j47]Hanchuan Peng, Badrinath Roysam, Giorgio A. Ascoli:
Automated image computing reshapes computational neuroscience. BMC Bioinform. 14: 293 (2013) - [c33]Yan Xu, Michalis A. Savelonas, Peng Qiu, Kristen Trett, William Shain, Badrinath Roysam:
Unsupervised inference of arbor morphology progression for microglia from confocal microscope images. ISBI 2013: 1356-1359 - [c32]Yanbin Lu, Kristen Trett, William Shain, Lawrence Carin
Quantitative profiling of microglia populations using harmonic co-clustering of arbor morphology measurements. ISBI 2013: 1360-1363 - 2012
- [j46]David Mayerich
NetMets: software for quantifying and visualizing errors in biological network segmentation. BMC Bioinform. 13(S-8): S7 (2012) - [j45]Mark R. Winter
Axonal transport analysis using Multitemporal Association Tracking. Int. J. Comput. Biol. Drug Des. 5(1): 35-48 (2012) - [j44]Leidy P. Dorado-Muñoz, Miguel Velez-Reyes
A Vector SIFT Detector for Interest Point Detection in Hyperspectral Imagery. IEEE Trans. Geosci. Remote. Sens. 50(11): 4521-4533 (2012) - [c31]Arunachalam Narayanaswamy, Amine Merouane, Antonio Peixoto, Ena Ladi, Paul Herzmark, Ulrich Von Andrian
Multi-temporal Globally-Optimal Dense 3-D Cell Segmentation and Tracking from Multi-photon Time-Lapse Movies of Live Tissue Microenvironments. STIA 2012: 147-162 - 2011
- [j43]Amit Mukherjee, Brian Jenkins, Cheng Fang, Richard J. Radke
Automated kymograph analysis for profiling axonal transport of secretory granules. Medical Image Anal. 15(3): 354-367 (2011) - [j42]Dirk Ryan Padfield, Jens Rittscher
Coupled minimum-cost flow cell tracking for high-throughput quantitative analysis. Medical Image Anal. 15(4): 650-668 (2011) - [j41]Yu Wang, Arunachalam Narayanaswamy, Chia-Ling Tsai, Badrinath Roysam:
A Broadly Applicable 3-D Neuron Tracing Method Based on Open-Curve Snake. Neuroinformatics 9(2-3): 193-217 (2011) - [j40]Arunachalam Narayanaswamy, Yu Wang, Badrinath Roysam:
3-D Image Pre-processing Algorithms for Improved Automated Tracing of Neuronal Arbors. Neuroinformatics 9(2-3): 219-231 (2011) - [j39]Jonathan Luisi
The FARSIGHT Trace Editor: An Open Source Tool for 3-D Inspection and Efficient Pattern Analysis Aided Editing of Automated Neuronal Reconstructions. Neuroinformatics 9(2-3): 305-315 (2011) - [c30]David Mayerich, Christopher Björnsson, Jonothan Taylor, Badrinath Roysam:
Metrics for comparing explicit representations of interconnected biological networks. BioVis 2011: 79-86 - [c29]Yu Wang, Arunachalam Narayanaswamy, Badrinath Roysam:
Novel 4-D Open-Curve Active Contour and curve completion approach for automated tree structure extraction. CVPR 2011: 1105-1112 - [c28]Zhe Leng, Julie R. Korenberg, Badri Roysam, Tolga Tasdizen:
A rapid 2-D centerline extraction method based on tensor voting. ISBI 2011: 1000-1003 - [c27]Dirk Ryan Padfield, Jens Rittscher
Quantitative biological studies enabled by robust cell tracking. ISBI 2011: 1929-1934 - 2010
- [j38]Liang Xiao, Lili Huang, Badrinath Roysam:
Image Variational Denoising Using Gradient Fidelity on Curvelet Shrinkage. EURASIP J. Adv. Signal Process. 2010 (2010) - [j37]Yousef Al-Kofahi, Wiem Lassoued, William Lee, Badrinath Roysam:
Improved Automatic Detection and Segmentation of Cell Nuclei in Histopathology Images. IEEE Trans. Biomed. Eng. 57(4): 841-852 (2010) - [j36]Arunachalam Narayanaswamy, Saritha Dwarakapuram, Christopher Björnsson, Barbara Cutler, William Shain, Badrinath Roysam:
Robust Adaptive 3-D Segmentation of Vessel Laminae From Fluorescence Confocal Microscope Images and Parallel GPU Implementation. IEEE Trans. Medical Imaging 29(3): 583-597 (2010) - [c26]Yu Wang, Badrinath Roysam:
Joint tracking and locomotion state recognition of C. elegans from time-lapse image sequences. ISBI 2010: 540-543 - [c25]Arunachalam Narayanaswamy, Ena Ladi, Yousef Al-Kofahi, Ying Chen, Christopher D. Carothers, Ellen Robey, Badrinath Roysam:
5-D imaging and parallel automated analysis of cellular events in living immune tissue microenvironments. ISBI 2010: 1435-1438 - [c24]Liang Xiao, Xiaosong Yuan, Zack Galbreath, Badrinath Roysam:
Automatic and Reliable Extraction of Dendrite Backbone from Optical Microscopy Images. LSMS/ICSEE 2010: 100-112 - [c23]Leidy P. Dorado-Muñoz, Miguel Velez-Reyes
A vector SIFT operator for interest point detection in hyperspectral imagery. WHISPERS 2010: 1-4
2000 – 2009
- 2009
- [j35]Dirk Ryan Padfield, Jens Rittscher
Spatio-temporal cell cycle phase analysis using level sets and fast marching methods. Medical Image Anal. 13(1): 143-155 (2009) - [j34]Badrinath Roysam, William Shain, Giorgio A. Ascoli:
The Central Role of Neuroinformatics in the National Academy of Engineering's Grandest Challenge: Reverse Engineer the Brain. Neuroinformatics 7(1): 1-5 (2009) - [j33]Xiaosong Yuan, Joshua T. Trachtenberg, Steve M. Potter, Badrinath Roysam:
MDL Constrained 3-D Grayscale Skeletonization Algorithm for Automated Extraction of Dendrites and Spines from Fluorescence Confocal Images. Neuroinformatics 7(4): 213-232 (2009) - [j32]Andrew R. Cohen
Automatic Summarization of Changes in Biological Image Sequences Using Algorithmic Information Theory. IEEE Trans. Pattern Anal. Mach. Intell. 31(8): 1386-1403 (2009) - [j31]Amit Mukherjee, Miguel Velez-Reyes
Interest Points for Hyperspectral Image Data. IEEE Trans. Geosci. Remote. Sens. 47(3): 748-760 (2009) - [c22]Dirk Ryan Padfield, Jens Rittscher
Coupled Minimum-Cost Flow Cell Tracking. IPMI 2009: 374-385 - 2008
- [j30]Harihar Narasimha-Iyer, Vijay Mahadevan, James M. Beach, Badrinath Roysam:
Improved Detection of the Central Reflex in Retinal Vessels Using a Generalized Dual-Gaussian Model and Robust Hypothesis Testing. IEEE Trans. Inf. Technol. Biomed. 12(3): 406-410 (2008) - [j29]Chia-Ling Tsai, Benjamin Madore, Matthew J. Leotta, Michal Sofka, Gehua Yang
Automated Retinal Image Analysis Over the Internet. IEEE Trans. Inf. Technol. Biomed. 12(4): 480-487 (2008) - [c21]Dirk Ryan Padfield, Jens Rittscher
Methods for monitoring cellular motion and function. ACSCC 2008: 47-50 - [c20]Dirk Ryan Padfield, Jens Rittscher
Spatio-temporal cell segmentation and tracking for automated screening. ISBI 2008: 376-379 - [c19]Andrew R. Cohen
Automatic summarization of changes in image sequences using algorithmic information theory. ISBI 2008: 859-862 - 2007
- [j28]Harihar Narasimha-Iyer, James M. Beach, Bahram Khoobehi, Badrinath Roysam:
Automatic Identification of Retinal Arteries and Veins From Dual-Wavelength Images Using Structural and Functional Features. IEEE Trans. Biomed. Eng. 54(8): 1427-1435 (2007) - [j27]Harihar Narasimha-Iyer, Ali Can, Badrinath Roysam, Howard L. Tanenbaum, Anna Majerovics:
Integrated Analysis of Vascular and Nonvascular Changes From Color Retinal Fundus Image Sequences. IEEE Trans. Biomed. Eng. 54(8): 1436-1445 (2007) - [j26]Nicolas Roussel, Christine A. Morton, Fern P. Finger, Badrinath Roysam:
A Computational Model for C. elegans Locomotory Behavior: Application to Multiworm Tracking. IEEE Trans. Biomed. Eng. 54(10): 1786-1797 (2007) - [j25]James Alexander Tyrrell, Emmanuelle di Tomaso, Daniel Fuja
Robust 3-D Modeling of Vasculature Imagery Using Superellipsoids. IEEE Trans. Medical Imaging 26(2): 223-237 (2007) - [c18]Gang Lin, Yousef Al-Kofahi, James Alexander Tyrrell, Christopher Björnsson, William Shain, Badrinath Roysam:
Automated 3-D Quantification of Brain Tissue at tThe Cellular Scale from Multi-Parameter Confocal Microscopy Images. ISBI 2007: 1040-1043 - 2006
- [j24]Harihar Narasimha-Iyer, Ali Can, Badrinath Roysam, Charles V. Stewart, Howard L. Tanenbaum, Anna Majerovics, Hanumant Singh:
Robust detection and classification of longitudinal changes in color retinal fundus images for monitoring diabetic retinopathy. IEEE Trans. Biomed. Eng. 53(6): 1084-1098 (2006) - [j23]Omar Al-Kofahi, Richard J. Radke
Automated semantic analysis of changes in image sequences of neurons in culture. IEEE Trans. Biomed. Eng. 53(6): 1109-1123 (2006) - [c17]Harihar Narasimha-Iyer, Ali Can, Badrinath Roysam, Jeffrey Stern:
Automated Change Analysis From Fluorescein Angiograms for Monitoring Wet Macular Degeneration. EMBC 2006: 4714-4717 - [c16]James Alexander Tyrrell, Badrinath Roysam, Emmanuelle di Tomaso, Ricky Tong, Edward B. Brown, Rakesh K. Jain:
Robust 3-D modeling of tumor microvasculature using superellipsoids. ISBI 2006: 185-188 - [c15]Dirk Ryan Padfield, Jens Rittscher, Thomas Sebastian, Nick Thomas, Badrinath Roysam:
Spatio-temporal cell cycle analysis using 3D level set segmentation of unstained nuclei in line scan confocal fluorescence images. ISBI 2006: 1036-1039 - 2005
- [j22]Richard J. Radke
Image change detection algorithms: a systematic survey. IEEE Trans. Image Process. 14(3): 294-307 (2005) - [j21]Muhammad-Amri Abdul-Karim, Badrinath Roysam, Natalie M. Dowell-Mesfin, A. Jeromin, Murat Yuksel, Shivkumar Kalyanaraman:
Automatic Selection of Parameters for Vessel/Neurite Segmentation Algorithms. IEEE Trans. Image Process. 14(9): 1338-1350 (2005) - [c14]Vijay Mahadevan, James Alexander Tyrrell, Ricky T. Tong, Edward B. Brown, Rakesh K. Jain, Badrinath Roysam:
Complexity analysis of angiogenesis vasculature. Medical Imaging: Image Processing 2005 - 2004
- [j20]Gang Lin, Charles V. Stewart, Badrinath Roysam, Kenneth Fritzsche, Gehua Yang
Predictive scheduling algorithms for real-time feature extraction and spatial referencing: application to retinal image sequences. IEEE Trans. Biomed. Eng. 51(1): 115-125 (2004) - [j19]Chia-Ling Tsai, Charles V. Stewart, Howard L. Tanenbaum, Badrinath Roysam:
Model-Based Method for Improving the Accuracy and Repeatability of Estimating Vascular Bifurcations and Crossovers From Retinal Fundus Images. IEEE Trans. Inf. Technol. Biomed. 8(2): 122-130 (2004) - [j18]James Alexander Tyrrell, Justin M. LaPre, Christopher D. Carothers, Badrinath Roysam, Charles V. Stewart:
Efficient Migration of Complex Off-Line Computer Vision Software to Real-Time System Implementation on Generic Computer Hardware. IEEE Trans. Inf. Technol. Biomed. 8(2): 142-153 (2004) - [j17]Vijay Mahadevan, Harihar Narasimha-Iyer, Badrinath Roysam, Howard L. Tanenbaum:
Robust model-based vasculature detection in noisy biomedical images. IEEE Trans. Inf. Technol. Biomed. 8(3): 360-376 (2004) - 2003
- [j16]Hong Shen, Charles V. Stewart, Badrinath Roysam, Gang Lin, Howard L. Tanenbaum:
Frame-Rate Spatial Referencing Based on Invariant Indexing and Alignment with Application to Online Retinal Image Registration. IEEE Trans. Pattern Anal. Mach. Intell. 25(3): 379-384 (2003) - [j15]Khalid A. Al-Kofahi, Ali Can, Sharie Lasek, Donald H. Szarowski, Natalie M. Dowell-Mesfin, William Shain, James N. Turner, Badrinath Roysam:
Median-based robust algorithms for tracing neurons from noisy confocal microscope images. IEEE Trans. Inf. Technol. Biomed. 7(4): 302-317 (2003) - [j14]Charles V. Stewart, Chia-Ling Tsai, Badrinath Roysam:
The Dual Bootstrap Iterative Closest Point Algorithm with Application to Retinal Image Registration. IEEE Trans. Medical Imaging 22(11): 1379-1394 (2003) - [c13]Muhammad-Amri Abdul-Karim, Khalid A. Al-Kofahi, Badrinath Roysam, Natalie M. Dowell-Mesfin, Rifat J. Hussain, William Shain, James N. Turner:
Computer Vision Algorithms for Quantifying the Growth and Behavior of Neurons Cultured on Nanofabricated Surfaces. CVPR Workshops 2003: 20 - [c12]Chia-Ling Tsai, Anna Majerovics, Charles V. Stewart, Badrinath Roysam:
Disease-Oriented Evaluation of Dual-Bootstrap Retinal Image Registration. MICCAI (1) 2003: 754-761 - 2002
- [j13]Ali Can, Charles V. Stewart, Badrinath Roysam, Howard L. Tanenbaum:
A Feature-Based, Robust, Hierarchical Algorithm for Registering Pairs of Images of the Curved Human Retina. IEEE Trans. Pattern Anal. Mach. Intell. 24(3): 347-364 (2002) - [j12]Ali Can, Charles V. Stewart, Badrinath Roysam, Howard L. Tanenbaum:
A Feature-Based Technique for Joint Linear Estimation of High-Order Image-to-Mosaic Transformations: Mosaicing the Curved Human Retina. IEEE Trans. Pattern Anal. Mach. Intell. 24(3): 412-419 (2002) - [j11]Khalid A. Al-Kofahi, Sharie Lasek, Donald H. Szarowski, Christopher J. Pace, George Nagy
Rapid automated three-dimensional tracing of neurons from confocal image stacks. IEEE Trans. Inf. Technol. Biomed. 6(2): 171-187 (2002) - [c11]Chia-Ling Tsai, Charles V. Stewart, Badrinath Roysam, Howard L. Tanenbaum:
Covariance-driven retinal image registration initialized from small sets of landmark correspondences. ISBI 2002: 333-336 - 2001
- [j10]Hong Shen, Badrinath Roysam, Charles V. Stewart, James N. Turner, Howard L. Tanenbaum:
Optimal scheduling of tracing computations for real-time vascular landmark extraction from retinal fundus images. IEEE Trans. Inf. Technol. Biomed. 5(1): 77-91 (2001) - [c10]Hong Shen, Charles V. Stewart, Badrinath Roysam, Gang Lin, Howard L. Tanenbaum:
Frame-Rate Spatial Referencing Based on Invariant Indexing and Alignment with Application to Laser Retinal Surgery. CVPR (1) 2001: 79-86 - 2000
- [c9]Ali Can, Charles V. Stewart, Badrinath Roysam, Howard L. Tanenbaum:
A Feature-Based Technique for Joint, Linear Estimation of High-Order Image-to-Mosaic Transformations: Application to Mosaicing the Curved Human Retina. CVPR 2000: 2585-2591
1990 – 1999
- 1999
- [j9]Ali Can, Hong Shen, James N. Turner, Howard L. Tanenbaum, Badrinath Roysam:
Rapid automated tracing and feature extraction from retinal fundus images using direct exploratory algorithms. IEEE Trans. Inf. Technol. Biomed. 3(2): 125-138 (1999) - [c8]Charles V. Stewart, Badrinath Roysam, Ali Can:
Robust Hierarchical Algorithm for Constructing a Mosaic from Images of the Curved Human Retina. CVPR 1999: 2286-2293 - 1998
- [j8]Douglas E. Becker, Ali Can, James N. Turner, Howard L. Tanenbaum, Badrinath Roysam:
Image processing algorithms for retinal montage synthesis, mapping, and real-time location determination. IEEE Trans. Biomed. Eng. 45(1): 105-118 (1998) - 1997
- [j7]James N. Turner, Hakan Ancin, Douglas E. Becker, Donald H. Szarowski, Maria Holmes, Nate O'Connor, Michael Wang, Timothy Holmes, Badrinath Roysam:
Automated image analysis technologies for biological 3D light microscopy. Int. J. Imaging Syst. Technol. 8(3): 240-254 (1997) - 1995
- [c7]Robert W. Mackin Jr., Badrinath Roysam, James N. Turner:
Adaptive 3-D segmentation algorithms for microscope images using local in-focus, and contrast features: application to Pap smears. ICIP (3) 1995: 160-163 - [c6]Hakan Ancin, Thomas E. Dufresne, Gregg M. Ridder, James N. Turner, Badrinath Roysam:
An improved watershed algorithm for counting objects in noisy, anisotropic 3-D biological images. ICIP (3) 1995: 172-175 - [c5]Douglas E. Becker, James N. Turner, Howard L. Tanenbaum, Badrinath Roysam:
Real-time image processing algorithms for an automated retinal laser surgery system. ICIP 1995: 426-429 - 1994
- [j6]Anoop K. Bhattacharjya, Badrinath Roysam:
Joint solution of low, intermediate, and high-level vision tasks by evolutionary optimization: Application to computer vision at low SNR. IEEE Trans. Neural Networks 5(1): 83-95 (1994) - 1993
- [j5]Badrinath Roysam:
Computational Vision (Harry Wechsler). SIAM Rev. 35(1): 165-166 (1993) - [c4]Ronald K. McMurdy, Badrinath Roysam:
Improving RAID-5 Performance by Un-striping Moderate-Sized Files. ICPP (2) 1993: 279-282 - 1992
- [j4]Badrinath Roysam, Michael I. Miller:
Combining stochastic and syntactic processing with analog computation methods. Digit. Signal Process. 2(2): 48-64 (1992) - [j3]Anoop K. Bhattacharjya, Douglas E. Becker, Badrinath Roysam:
A genetic algorithm for intelligent imaging from quantum-limited data. Signal Process. 28(3): 335-348 (1992) - [j2]Badrinath Roysam, Anoop K. Bhattacharjya:
Hierarchically structured unit-simplex transformations for parallel distributed optimization problems. IEEE Trans. Neural Networks 3(1): 108-114 (1992) - 1991
- [j1]Michael I. Miller, Badrinath Roysam, Kurt R. Smith, Joseph A. O'Sullivan
Representing and computing regular languages on massively parallel networks. IEEE Trans. Neural Networks 2(1): 56-72 (1991) - 1990
- [c3]Badrinath Roysam, Michael I. Miller:
Stochastic representation of memoryless Boolean functions: application to boundary estimation at low contrast. ICASSP 1990: 2333-2336
1980 – 1989
- 1989
- [c2]Badrinath Roysam, Michael I. Miller:
A unified approach for hierarchical imaging based on joint hypothesis testing and parameter estimation. ICASSP 1989: 1779-1782 - 1988
- [c1]Badrinath Roysam, Jay A. Shrauner, Michael I. Miller:
Bayesian imaging using Good's roughness measure-implementation on a massively parallel processor. ICASSP 1988: 932-935
Coauthor Index
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