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Sreeraman Rajan
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2020 – today
- 2024
- [j60]Heba Nematallah, Sreeraman Rajan:
Adaptive Hierarchical Classification for Human Activity Recognition Using Inertial Measurement Unit (IMU) Time-Series Data. IEEE Access 12: 52127-52149 (2024) - [j59]Ebrahim Ali Nehary, Sreeraman Rajan, Carlos Rossa:
Metric-Based Frame Selection and Deep Learning Model With Multi-Head Self Attention for Classification of Ultrasound Lung Video Images. IEEE Access 12: 79297-79310 (2024) - [j58]Ebrahim Ali Nehary, Sreeraman Rajan:
Ultrasound Breast Image Classification Through Domain Knowledge Integration Into Deep Neural Networks. IEEE Access 12: 112966-112983 (2024) - [j57]Ankita Dey, Sreeraman Rajan:
Measurement Methodology: Breast Abnormality Detection using Thermography: An Engineer's Perspective. IEEE Instrum. Meas. Mag. 27(4): 13-21 (2024) - [j56]Mamoon Rashid, Christoph H. Gierull, Sreeraman Rajan:
Improved Vessel Detection via Quadratic Matched Filtering and Target Parameter Estimation for Dual and Compact Polarimetric SAR. IEEE Geosci. Remote. Sens. Lett. 21: 1-5 (2024) - [j55]Ganesha H. S, Rinki Gupta, Sindhu Hak Gupta, Sreeraman Rajan:
Few-shot transfer learning for wearable IMU-based human activity recognition. Neural Comput. Appl. 36(18): 10811-10823 (2024) - [j54]Heba Nematallah, Sreeraman Rajan:
Quantitative Analysis of Mother Wavelet Function Selection for Wearable Sensors-Based Human Activity Recognition. Sensors 24(7): 2119 (2024) - [j53]Ankita Dey, Sreeraman Rajan, George Xiao, Jianping Lu:
Radar-Based Human Activity Recognition Using Multidomain Multilevel Fused Patch-Based Learning. IEEE Trans. Instrum. Meas. 73: 1-14 (2024) - [j52]Ebrahim Ali Nehary, Sreeraman Rajan:
Phonocardiogram Classification by Learning From Positive and Unlabeled Examples. IEEE Trans. Instrum. Meas. 73: 1-14 (2024) - [c108]Ankita Dey, Sreeraman Rajan:
Unsupervised Learning for Breast Abnormality Detection using Thermograms. I2MTC 2024: 1-6 - [c107]Ebrahim Ali Nehary, Sreeraman Rajan, Bruno Andò:
Postural Sway Classification using Bispectrum. I2MTC 2024: 1-6 - [c106]Heba Nematallah, Sreeraman Rajan:
Hierarchical Classifier for Improved Human Activity Recognition using Wearable Sensors. I2MTC 2024: 1-6 - [c105]Ankita Dey, Sreeraman Rajan:
Comparison of Different Color Spaces for Abnormality Detection in Breast Thermograms. ICCE 2024: 1-6 - [c104]Ziaaddin Sharifisoraki, Marzieh Amini, Sreeraman Rajan:
Comparative Analysis of mmWave Radar-based Object Detection in Autonomous Vehicles. ICCE 2024: 1-6 - [c103]Ankita Dey, Sreeraman Rajan, Richard M. Dansereau:
Improved Detection of Abnormality in Grayscale Breast Thermal Images Using Binary Encoding. MeMeA 2024: 1-5 - [c102]Ebrahim Ali Nehary, Sreeraman Rajan:
Enhanced Phonocardiogram Classification Performance through Outlier Detection. MeMeA 2024: 1-6 - [c101]Omar Imran, Shikharesh Majumdar, Sreeraman Rajan:
Enhancing the Performance of Deep Learning Model Based Object Detection using Parallel Processing (Work In Progress Paper). ICPE (Companion) 2024: 7-13 - 2023
- [j51]Ziaaddin Sharifisoraki, Ankita Dey, Roger Selzler, Marzieh Amini, James R. Green, Sreeraman Rajan, F. A. Kwamena:
Monitoring Critical Infrastructure Using 3D LiDAR Point Clouds. IEEE Access 11: 314-336 (2023) - [j50]Ankita Dey, Sreeraman Rajan, Gaozhi Xiao, Jianping Lu:
Measurement Methodology. IEEE Instrum. Meas. Mag. 26(7): 12-19 (2023) - [c100]Ebrahim Ali Nehary, Sreeraman Rajan, Bruno Andò:
Postural Sway Classification using Modified Vision Transformer. BioCAS 2023: 1-5 - [c99]Bruno Andò, Salvatore Baglio, Valeria Finocchiaro, Vincenzo Marletta, Sreeraman Rajan, Ebrahim Ali Nehary, Valeria Dibilio, Giovanni Mostile, Mario Zappia:
Machine Learning Approach to Classify Postural Sway Instabilities. I2MTC 2023: 1-6 - [c98]Ian Lam, Shashank Pant, Max Manning, Michael Kubanski, Peter Fox, Sreeraman Rajan, Prakash Patnaik, Bhashyam Balaji:
Time-Frequency Analysis using V-band Radar for Drone Detection and Classification. I2MTC 2023: 1-6 - [c97]David Luong, Bhashyam Balaji, Sreeraman Rajan:
Speeding up Detection and Imaging Using Quantum Radars. ICASSP Workshops 2023: 1-5 - [c96]Hasan Abbasi, Ankita Dey, Ian Lam, Ziaaddin Sharifisoraki, Ebrahim Ali, Marzieh Amini, Sreeraman Rajan, James R. Green, Felix Kwamena:
A Step-By-Step Approach for Camera and Low-Resolution-3D-LiDAR Calibration. ICCE 2023: 1-5 - [c95]Ebrahim Ali Nehary, Ankita Dey, Sreeraman Rajan:
Comparison of Wearable Sensor-based Fall Event Detection by 1-D and 2-D Convolutional Neural Networks. ICCE 2023: 1-5 - [c94]Ziaaddin Sharifisoraki, Marzieh Amini, Sreeraman Rajan:
A Novel Face Recognition Using Specific Values from Deep Neural Network-based Landmarks. ICCE 2023: 1-6 - [c93]Peng Xu, Sreeraman Rajan:
Spectral Estimation from Actual Color Images based on Deep Neural Network. ICCE 2023: 1-4 - [c92]Ankita Dey, Yann Cabanes, Sreeraman Rajan, Bhashyam Balaji, Anthony Damini, Rajkumar Chanchlani:
Radar-Based Drone Detection Using Complex-Valued Convolutional Neural Network. SAS 2023: 1-5 - [c91]Rafik Goubran, Sreeraman Rajan, Alessandro Depari:
Welcome Message. SAS 2023: 1-18 - [c90]Ian Lam, David Luong, Bhashyam Balaji, Sreeraman Rajan:
Phase Estimation for an Experimental Noise Radar. SAS 2023: 1-5 - [c89]Ian Lam, Shashank Pant, Max Manning, Michael Kubanski, Peter Fox, Sreeraman Rajan, Prakash Patnaik, Bhashyam Balaji:
Studying the Effects of Clutter Using V-Band Radar for Drone Classification. SAS 2023: 1-5 - [c88]Ebrahim Ali Nehary, Ankita Dey, Sreeraman Rajan, Bhashyam Balaji, Anthony Damini, Rajkumar Chanchlani:
Synthetic Aperture Radar-Based Ship Classification Using CNN and Traditional Handcrafted Features. SAS 2023: 1-6 - [c87]Ebrahim Ali Nehary, Sreeraman Rajan, Carlos Rossa:
Lung Ultrasound Image Classification Using Deep Learning and Histogram of Oriented Gradients Features for COVID-19 Detection. SAS 2023: 1-6 - [c86]Ebrahim Ali Nehary, Sreeraman Rajan, Carlos Rossa:
Comparison of COVID-19 Classification via Imagenet-Based and RadImagenet-Based Transfer Learning Models with Random Frame Selection. SAS 2023: 1-6 - [c85]Ganesha H. S, Rinki Gupta, Sindhu Hak Gupta, Sreeraman Rajan:
Deep Learning Ensemble for Recognising Lower Limb Activity. SAS 2023: 1-5 - [c84]Hamidreza Sadreazami, Abhishek Khoyani, Marzieh Amini, Sreeraman Rajan, Miodrag Bolic:
Radar Based Fall Detection with Imbalance Data Handling and Data Augmentation. SAS 2023: 1-4 - [c83]Arka Singh, Sreeraman Rajan, Marzieh Amini, James R. Green, Kevin Dick:
Critical Electrical Infrastructure Segmentation in Arctic Conditions. SAS 2023: 1-6 - [c82]Feng Su, David Luong, Ian Lam, Sreeraman Rajan, Shulabh Gupta:
Machine Learning-Based Real-Time Metasurface Reconfiguration. SAS 2023: 1-6 - [c81]Samuel Lovett, Tyler Paquette, Brayden DeBoon, Sreeraman Rajan, Carlos Rossa:
Level Plane SLAM: Out-of-Plane Motion Compensation in a Globally Stabilized Coordinate Frame for 2D SLAM. SMC 2023: 3355-3360 - 2022
- [j49]David Luong, Bhashyam Balaji, Sreeraman Rajan:
Performance Prediction for Coherent Noise Radars Using the Correlation Coefficient. IEEE Access 10: 8627-8633 (2022) - [j48]Hadi Zanddizari, Sreeraman Rajan, Houman Zarrabi, Hassan Rabah:
Privacy Assured Recovery of Compressively Sensed ECG Signals. IEEE Access 10: 17122-17133 (2022) - [j47]Fereshteh Fakhar Firouzeh, John W. Chinneck, Sreeraman Rajan:
Faster Maximum Feasible Subsystem solutions for dense constraint matrices. Comput. Oper. Res. 139: 105633 (2022) - [j46]Sreeraman Rajan:
Guest Editorial. IEEE Instrum. Meas. Mag. 25(1): 3-4 (2022) - [j45]Shane Steinberg, Andy Huang, Yuu Ono, Sreeraman Rajan:
Continuous Artery Monitoring Using a Flexible and Wearable Single-Element Ultrasonic Sensor. IEEE Instrum. Meas. Mag. 25(1): 6-11 (2022) - [j44]Cristian Ciobanu, Katherine J. I. Ember, Balázs J. Nyíri, Sreeraman Rajan, Vinita Chauhan, Frédéric Leblond, Sangeeta Murugkar:
Potential of Raman Spectroscopy for Blood-Based Biopsy. IEEE Instrum. Meas. Mag. 25(1): 62-68 (2022) - [j43]David Luong, Bhashyam Balaji, Sreeraman Rajan:
A Likelihood Ratio Detector for QTMS Radar and Noise Radar. IEEE Trans. Aerosp. Electron. Syst. 58(4): 3011-3020 (2022) - [j42]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Signal Quality Assessment of Compressively Sensed Electrocardiogram. IEEE Trans. Biomed. Eng. 69(11): 3397-3406 (2022) - [j41]David Luong, Bhashyam Balaji, Sreeraman Rajan:
Structured Covariance Matrix Estimation for Noise-Type Radars. IEEE Trans. Geosci. Remote. Sens. 60: 1-13 (2022) - [c80]Khoa Tran, Sazedur Rahman, Yuu Ono, Sreeraman Rajan, Robert Arntfield:
Wearable Ultrasound Assessment of Lung Sliding in M-Mode: A Phantom Simulation-Based Study. BIBE 2022: 1-4 - [c79]David Luong, Anne Young, Bhashyam Balaji, Sreeraman Rajan:
Classifying Linear Frequency Modulated Radar Signals Using Matched Filters. CCECE 2022: 11-15 - [c78]Vanita Arora, Ravibabu Mulaveesala, Sreeraman Rajan, Bhashyam Balaji, Carlos Rossa:
Pulse Compression Favourable Thermal Wave Imaging Approach for Estimation of Osteoporosis: A Numerical Study. I2MTC 2022: 1-5 - [c77]Ian Lam, Andi Huang, Shashank Pant, Sreeraman Rajan, Prakash Patnaik, Bhashyam Balaji:
Drone Micro-Doppler Identification with Radar Calibration. I2MTC 2022: 1-6 - [c76]Ankita Dey, Sreeraman Rajan, George Xiao, Jianping Lu:
Fall Event Detection using Vision Transformer. IEEE SENSORS 2022: 1-4 - [c75]Ankita Dey, Sreeraman Rajan:
Red-plane Asymmetry Analysis of Breast Thermograms for Cancer Detection. MeMeA 2022: 1-6 - [c74]Ebrahim Ali Nehary, Sreeraman Rajan:
Classification of Ultrasound Breast Images Using Fused Ensemble of Deep Learning Classifiers. MeMeA 2022: 1-6 - [c73]Khoa Tran, Sreeraman Rajan, Yuu Ono:
Comparison of Particle Swarm Optimization and Genetic Algorithm for Ultrasound Estimation of Carotid Intima-Media Thickness Using Matching Pursuit. MeMeA 2022: 1-6 - [c72]Bruno Andò, Salvatore Baglio, Valeria Dibilio, Vincenzo Marletta, Michele Marella, Giovanni Mostile, Sreeraman Rajan, Mario Zappia:
A Neuro-Fuzzy Approach to Assess Postural Sway. SAS 2022: 1-6 - 2021
- [j40]Soroor Behbahani, Hamid Ahmadieh, Sreeraman Rajan:
Feature Extraction Methods for Electroretinogram Signal Analysis: A Review. IEEE Access 9: 116879-116897 (2021) - [j39]Hossein Chahrour, Richard M. Dansereau, Sreeraman Rajan, Bhashyam Balaji:
Target Detection Through Riemannian Geometric Approach With Application to Drone Detection. IEEE Access 9: 123950-123963 (2021) - [j38]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Automated Biosignal Quality Analysis of Electrocardiograms. IEEE Instrum. Meas. Mag. 24(2): 37-44 (2021) - [j37]Hamidreza Sadreazami, Miodrag Bolic, Sreeraman Rajan:
Contactless Fall Detection Using Time-Frequency Analysis and Convolutional Neural Networks. IEEE Trans. Ind. Informatics 17(10): 6842-6851 (2021) - [j36]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Detection of Atrial Fibrillation in Compressively Sensed Electrocardiogram Measurements. IEEE Trans. Instrum. Meas. 70: 1-9 (2021) - [c71]Hadi Zanddizari, Ankita Dey, Sreeraman Rajan:
Image Super-Resolution Through Compressive Sensing-based Recovery. EMBC 2021: 4006-4010 - [c70]Zachary Baird, Michael K. McDonald, Sreeraman Rajan, Simon J. Lee:
A Neyman-Pearson Criterion-Based Neural Network Detector for Maritime Radar. FUSION 2021: 1-8 - [c69]Ahmed Alzahrani, Jila Hosseinkhani, Sreeraman Rajan, Eranga Ukwatta:
Reducing Motion Impact on Video Magnification Using Wavelet Transform and Principal Component Analysis for Heart Rate Estimation. I2MTC 2021: 1-6 - [c68]Fereshteh Fakhar Firouzeh, Sreeraman Rajan, John W. Chinneck:
Recovery of Noisy Compressively Sensed Speech via Regularized Maximum Feasible Subsystem Algorithm. I2MTC 2021: 1-6 - [c67]Ebrahim Ali Nehary, Zaid Abduh, Sreeraman Rajan:
A Deep Convolutional Neural Network Classification of Heart Sounds using Fractional Fourier Transform. I2MTC 2021: 1-5 - [c66]Parichehreh Firoozi, Sreeraman Rajan, Ioannis Lambadaris:
Efficient Kronecker-based Sparse One-Time Sensing Matrix For Compressive Sensing Cryptosystem. MeditCom 2021: 354-359 - [c65]Satyake Bakshi, Sreeraman Rajan:
Few-shot Fall Detection using Shallow Siamese Network. MeMeA 2021: 1-5 - [c64]Soroor Behbahani, Sreeraman Rajan:
Non-Linear and Chaos-based Analysis of Electroretinogram. MeMeA 2021: 1-6 - [c63]Parichehreh Firoozi, Sreeraman Rajan, Ioannis Lambadaris:
Efficient Compressive Sensing of Biomedical Signals Using A Permuted Kronecker-based Sparse Measurement Matrix. MeMeA 2021: 1-5 - [c62]Fereshteh Fakhar Firouzeh, John W. Chinneck, Sreeraman Rajan:
Biological Data Classification via Faster MAXimum Feasible Subsystem Algorithm. MeMeA 2021: 1-5 - [i2]Hadi Zanddizari, Sreeraman Rajan, Hassan Rabah, Houman Zarrabi:
Privacy Assured Recovery of Compressively Sensed ECG signals. CoRR abs/2101.09416 (2021) - [i1]Fereshteh Fakhar Firouzeh, John W. Chinneck, Sreeraman Rajan:
Faster Maximum Feasible Subsystem Solutions for Dense Constraint Matrices. CoRR abs/2102.05744 (2021) - 2020
- [j35]Fereshteh Fakhar Firouzeh, John W. Chinneck, Sreeraman Rajan:
Maximum Feasible Subsystem Algorithms for Recovery of Compressively Sensed Speech. IEEE Access 8: 82539-82550 (2020) - [j34]Zachary Baird, Michael K. McDonald, Sreeraman Rajan, Simon J. Lee:
A CNN-LSTM Network for Augmenting Target Detection in Real Maritime Wide Area Surveillance Radar Data. IEEE Access 8: 179281-179294 (2020) - [j33]David Luong, Bhashyam Balaji, Sreeraman Rajan:
Quantum Two-Mode Squeezing Radar and Noise Radar: Correlation Coefficient and Integration Time. IEEE Access 8: 185544-185547 (2020) - [j32]Soojeong Lee, Hilmi R. Dajani, Sreeraman Rajan, Gangseong Lee, Voicu Z. Groza:
Uncertainty in Blood Pressure Measurement Estimated Using Ensemble-Based Recursive Methodology. Sensors 20(7): 2108 (2020) - [j31]Peter Klaer, Andi Huang, Pascale Sévigny, Sreeraman Rajan, Shashank Pant, Prakash Patnaik, Bhashyam Balaji:
An Investigation of Rotary Drone HERM Line Spectrum under Manoeuvering Conditions. Sensors 20(20): 5940 (2020) - [j30]Hamidreza Sadreazami, Miodrag Bolic, Sreeraman Rajan:
Fall Detection Using Standoff Radar-Based Sensing and Deep Convolutional Neural Network. IEEE Trans. Circuits Syst. II Express Briefs 67-II(1): 197-201 (2020) - [j29]Dipayan Mitra, Hadi Zanddizari, Sreeraman Rajan:
Investigation of Kronecker-Based Recovery of Compressed ECG Signal. IEEE Trans. Instrum. Meas. 69(6): 3642-3653 (2020) - [c61]Julio J. Valdés, Zachary Baird, Sreeraman Rajan, Miodrag Bolic:
Radar-based Noncontact Human Activity Classification Using Genetic Programming. CEC 2020: 1-8 - [c60]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Transfer Learning for Detection of Atrial Fibrillation in Deterministic Compressive Sensed ECG. EMBC 2020: 5398-5401 - [c59]Mohamed Abdelazez, Fereshteh Fakhar Firouzeh, Sreeraman Rajan, Adrian D. C. Chan:
Multi-Stage Detection of Atrial Fibrillation in Compressively Sensed Electrocardiogram. I2MTC 2020: 1-6 - [c58]Fereshteh Fakhar Firouzeh, Mohamed Abdelazez, Sina Salsabili, Sreeraman Rajan:
Improved Recovery of Compressive Sensed Speech. I2MTC 2020: 1-6 - [c57]Heba Nematallah, Sreeraman Rajan:
Comparative Study of Time Series-based Human Activity Recognition using Convolutional Neural Networks. I2MTC 2020: 1-6 - [c56]Andi Huang, Pascale Sévigny, Bhashyam Balaji, Sreeraman Rajan:
Radar Micro-Doppler-based Rotary Drone Detection using Parametric Spectral Estimation Methods. IEEE SENSORS 2020: 1-4 - [c55]Fereshteh Fakhar Firouzeh, Sreeraman Rajan, John W. Chinneck:
MAXimum Feasible Subsystem Recovery of Compressed ECG Signals. MeMeA 2020: 1-6 - [c54]Dipayan Mitra, Sreeraman Rajan:
Deterministic Compressed Domain Analysis of Multi-channel ECG Measurements. MeMeA 2020: 1-6 - [c53]Hadi Zanddizari, Dipayan Mitra, Sreeraman Rajan:
Blind Deterministic Compressive Sensing for Biomedical Images. MeMeA 2020: 1-5 - [c52]Hamidreza Sadreazami, Dipayan Mitra, Miodrag Bolic, Sreeraman Rajan:
Compressed Domain Contactless Fall Incident Detection using UWB Radar Signals. NEWCAS 2020: 90-93
2010 – 2019
- 2019
- [j28]Hamidreza Sadreazami, Miodrag Bolic, Sreeraman Rajan:
CapsFall: Fall Detection Using Ultra-Wideband Radar and Capsule Network. IEEE Access 7: 55336-55343 (2019) - [j27]Isar Nejadgholi, Hamidreza Sadreazami, Sreeraman Rajan, Miodrag Bolic:
Classification of Doppler radar reflections as preprocessing for breathing rate monitoring. IET Signal Process. 13(1): 21-28 (2019) - [c51]David Luong, Sreeraman Rajan, Bhashyam Balaji:
Estimating Correlation Coefficients for Quantum Radar and Noise Radar: A Simulation Study. GlobalSIP 2019: 1-5 - [c50]Heba Nematallah, Sreeraman Rajan, A.-M. Cret:
Logistic Model Tree for Human Activity Recognition Using Smartphone-Based Inertial Sensors. IEEE SENSORS 2019: 1-4 - [c49]Hamidreza Sadreazami, Miodrag Bolic, Sreeraman Rajan:
Residual Network-Based Supervised Learning of Remotely Sensed Fall Incidents using Ultra-Wideband Radar. ISCAS 2019: 1-4 - [c48]Hamidreza Sadreazami, Miodrag Bolic, Sreeraman Rajan:
TL-FALL: Contactless Indoor Fall Detection Using Transfer Learning from a Pretrained Model. MeMeA 2019: 1-5 - [c47]Harminder Singh, Sreeraman Rajan, Changcheng Huang, Gauravdeep Shami, Marc Lyonnais, Dmitri Fedorov, Rodney Wilson:
Analysis of lightwave system using negative dispersion fiber and high speed optical telemetry. PACRIM 2019: 1-6 - [c46]Dipayan Mitra, Sreeraman Rajan, Bhashyam Balaji:
A Deterministic Compressive Sensing Approach for Compressed Domain Image Analysis. SAS 2019: 1-6 - 2018
- [j26]Gurinderbeer Singh, Sreeraman Rajan, Shikharesh Majumdar:
A Fast-Iterative Data Association Technique for Multiple Object Tracking. Int. J. Semantic Comput. 12(2): 261-285 (2018) - [c45]Yiu-Tong Chan, François Chan, Sreeraman Rajan:
Estimation of Frequency of a Sinusoid from Compressive Sensing Measurements. CCECE 2018: 1-4 - [c44]Zachary Baird, Sreeraman Rajan, Miodrag Bolic:
Classification of Human Posture from Radar Returns Using Ultra-Wideband Radar. EMBC 2018: 3268-3271 - [c43]Mohamed Abdelazez, Shreyas Sreeraman, Sreeraman Rajan, Adrian D. C. Chan:
Effect of body posture on non-fiducial electrocardiogram based biometrie system. I2MTC 2018: 1-5 - [c42]Gurinderbeer Singh, Shikharesh Majumdar, Sreeraman Rajan:
Auto-Resource Provisioning for MapReduce-Based Multiple Object Tracking in Video. ICDCN 2018: 25:1-25:10 - [c41]Peter Carniglia, Bhashyam Balaji, Sreeraman Rajan:
Geolocation of Mobile Objects from Multiple UAV Optical Sensor Platforms. IEEE SENSORS 2018: 1-4 - [c40]Julio J. Valdés, Zachary Baird, Sreeraman Rajan, Miodrag Bolic:
Single Channel Continuous Wave Doppler Radar for Differentiating Types of Human Activity. IJCNN 2018: 1-8 - [c39]Dipayan Mitra, Hadi Zanddizari, Sreeraman Rajan:
Improvement of Recovery in Segmentation-Based Parallel Compressive Sensing. ISSPIT 2018: 141-146 - [c38]Dipayan Mitra, Hadi Zanddizari, Sreeraman Rajan:
Improvement of Recovery in Segmentation-Based Parallel Compressive Sensing. ISSPIT 2018: 501-506 - [c37]Dipayan Mitra, Sreeraman Rajan, Bhashyam Balaji:
A Deterministic Compressive Sensing Approach for Compressed Domain Image Analysis. ISSPIT 2018: 596-601 - [c36]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Detection of Noise Type in Electrocardiogram. MeMeA 2018: 1-6 - [c35]Mohamed Abdelazez, Sreeraman Rajan, Adrian D. C. Chan:
Detection of Abnormal Heartbeats in Compressed Electrocardiograms. MeMeA 2018: 1-5 - [c34]Dipayan Mitra, Hadi Zanddizari, Sreeraman Rajan:
Improvement of Signal Quality During Recovery of Compressively Sensed ECG Signals. MeMeA 2018: 1-5 - 2017
- [j25]Soojeong Lee, Sreeraman Rajan, Gwanggil Jeon, Joon-Hyuk Chang, Hilmi R. Dajani, Voicu Z. Groza:
Oscillometric blood pressure estimation by combining nonparametric bootstrap with Gaussian mixture model. Comput. Biol. Medicine 85: 112-124 (2017) - [j24]Bo Li, Liang Zhang, Thia Kirubarajan, Sreeraman Rajan:
Projection matrix design using prior information in compressive sensing. Signal Process. 135: 36-47 (2017) - [j23]Bo Li, Liang Zhang, Thia Kirubarajan, Sreeraman Rajan:
A projection matrix design method for MSE deduction in adaptive compressive sensing. Signal Process. 141: 16-27 (2017) - [j22]Soheil Salari, Il-Min Kim, François Chan, Sreeraman Rajan:
Blind Compressive-Sensing-Based Electronic Warfare Receiver. IEEE Trans. Aerosp. Electron. Syst. 53(4): 2014-2030 (2017) - [j21]Mohamad Forouzanfar, Mohamed Mabrouk, Sreeraman Rajan, Miodrag Bolic, Hilmi R. Dajani, Voicu Z. Groza:
Event Recognition for Contactless Activity Monitoring Using Phase-Modulated Continuous Wave Radar. IEEE Trans. Biomed. Eng. 64(2): 479-491 (2017) - [c33]Gurinderbeer Singh, Sreeraman Rajan, Shikharesh Majumdar:
A Greedy Data Association Technique for Multiple Object Tracking. BigMM 2017: 177-184 - [c32]Nikhilesh Pradhan, Sreeraman Rajan, Andy Adler, Calum Redpath:
Classification of the quality of wristband-based photoplethysmography signals. MeMeA 2017: 269-274 - [c31]Zachary Baird, Isuru Gunasekara, Miodrag Bolic, Sreeraman Rajan:
Principal component analysis-based occupancy detection with ultra wideband radar. MWSCAS 2017: 1573-1576 - [c30]Gurinderbeer Singh, Shikharesh Majumdar, Sreeraman Rajan:
MapReduce-based techniques for multiple object tracking in video analytics. SmartWorld/SCALCOM/UIC/ATC/CBDCom/IOP/SCI 2017: 1-8 - 2016
- [j20]Mohamed Mabrouk, Sreeraman Rajan, Miodrag Bolic, Mohamad Forouzanfar, Hilmi R. Dajani, Izmail Batkin:
Human Breathing Rate Estimation from Radar Returns Using Harmonically Related Filters. J. Sensors 2016: 9891852:1-9891852:7 (2016) - [j19]Xue Jiang, Sreeraman Rajan, Xingzhao Liu:
Wirtinger Flow Method With Optimal Stepsize for Phase Retrieval. IEEE Signal Process. Lett. 23(11): 1627-1631 (2016) - [j18]Yunfei Guo, Ratnasingham Tharmarasa, Sreeraman Rajan, Taek Lyul Song, Thia Kirubarajan:
Passive tracking in heavy clutter with sensor location uncertainty. IEEE Trans. Aerosp. Electron. Syst. 52(4): 1536-1554 (2016) - [c29]Isar Nejadgholi, Sreeraman Rajan, Miodrag Bolic:
Time-frequency based contactless estimation of vital signs of human while walking using PMCW radar. HealthCom 2016: 1-6 - [c28]David Abolarin, Mohamad Forouzanfar, Voicu Z. Groza, Sreeraman Rajan, Hilmi R. Dajani, Emil M. Petriu:
Model-based filtering and compression of oscillometric blood pressure pulses. MeMeA 2016: 1-5 - 2015
- [j17]Soojeong Lee, Sreeraman Rajan, Chee-Hyun Park, Joon-Hyuk Chang, Hilmi R. Dajani, Voicu Z. Groza:
Estimated confidence interval from single blood pressure measurement based on algorithmic fusion. Comput. Biol. Medicine 62: 154-163 (2015) - [j16]Bo Li, Yi Shen, Sreeraman Rajan, Thia Kirubarajan:
Theoretical results for sparse signal recovery with noises using generalized OMP algorithm. Signal Process. 117: 270-278 (2015) - [j15]Xue Jiang, Wen-Jun Zeng, Hing-Cheung So, Sreeraman Rajan, Thiagalingam Kirubarajan:
Robust Matched Filtering in ℓp-Space. IEEE Trans. Signal Process. 63(23): 6184-6199 (2015) - 2014
- [j14]Mohamad Forouzanfar, Hilmi R. Dajani, Voicu Z. Groza, Miodrag Bolic, Sreeraman Rajan, Izmail Batkin:
Ratio-Independent Blood Pressure Estimation by Modeling the Oscillometric Waveform Envelope. IEEE Trans. Instrum. Meas. 63(10): 2501-2503 (2014) - [c27]Mohamed Mabrouk, Sreeraman Rajan, Miodrag Bolic, Izmail Batkin, Hilmi R. Dajani, Voicu Z. Groza:
Model of human breathing reflected signal received by PN-UWB radar. EMBC 2014: 4559-4562 - 2013
- [j13]Soojeong Lee, Joon-Hyuk Chang, Sang Won Nam, Chungsoo Lim, Sreeraman Rajan, Hilmi R. Dajani, Voicu Z. Groza:
Oscillometric Blood Pressure Estimation Based on Maximum Amplitude Algorithm Employing Gaussian Mixture Regression. IEEE Trans. Instrum. Meas. 62(12): 3387-3389 (2013) - [j12]Qiyun Zhang, Octavia A. Dobre, Yahia A. Eldemerdash, Sreeraman Rajan, Robert J. Inkol:
Second-Order Cyclostationarity of BT-SCLD Signals: Theoretical Developments and Applications to Signal Classification and Blind Parameter Estimation. IEEE Trans. Wirel. Commun. 12(4): 1501-1511 (2013) - [c26]J. F. Rivest, Sreeraman Rajan:
Morphological detectors for Radar ELINT applications. I2MTC 2013: 1062-1067 - [c25]Sichun Wang, Brad R. Jackson, Sreeraman Rajan, François Patenaude:
Received Signal Strength-Based Emitter Geolocation Using an Iterative Maximum Likelihood Approach. MILCOM 2013: 68-72 - 2012
- [j11]Octavia A. Dobre, Menguc Oner, Sreeraman Rajan, Robert J. Inkol:
Cyclostationarity-Based Robust Algorithms for QAM Signal Identification. IEEE Commun. Lett. 16(1): 12-15 (2012) - [j10]Simon Henault, Yahia M. M. Antar, Sreeraman Rajan, Robert J. Inkol, Sichun Wang:
Effects of Mutual Coupling on the Accuracy of Adcock Direction Finding Systems. IEEE Trans. Aerosp. Electron. Syst. 48(4): 2990-3005 (2012) - [c24]Majid Mafi, Sreeraman Rajan, Miodrag Bolic, Voicu Z. Groza, Hilmi R. Dajani:
Blood pressure estimation using maximum slope of oscillometric pulses. EMBC 2012: 3239-3242 - [c23]Mohamad Forouzanfar, Balakumar Balasingam, Hilmi R. Dajani, Voicu Z. Groza, Miodrag Bolic, Sreeraman Rajan, Emil M. Petriu:
Mathematical modeling and parameter estimation of blood pressure oscillometric waveform. MeMeA 2012: 1-6 - 2011
- [j9]Silu Chen, Miodrag Bolic, Voicu Groza, Hilmi R. Dajani, Izmail Batkin, Sreeraman Rajan:
Extraction of Breathing Signal and Suppression of Its Effects in Oscillometric Blood Pressure Measurement. IEEE Trans. Instrum. Meas. 60(5): 1741-1750 (2011) - [j8]Mohamad Forouzanfar, Hilmi R. Dajani, Voicu Z. Groza, Miodrag Bolic, Sreeraman Rajan:
Feature-Based Neural Network Approach for Oscillometric Blood Pressure Estimation. IEEE Trans. Instrum. Meas. 60(8): 2786-2796 (2011) - [j7]Soojeong Lee, Miodrag Bolic, Voicu Z. Groza, Hilmi R. Dajani, Sreeraman Rajan:
Confidence Interval Estimation for Oscillometric Blood Pressure Measurements Using Bootstrap Approaches. IEEE Trans. Instrum. Meas. 60(10): 3405-3415 (2011) - [c22]Sichun Wang, Robert J. Inkol, François Patenaude, Sreeraman Rajan:
Numerical computation of the probability density of the phase error of the FFT-based digital interferometer. CCECE 2011: 130-135 - [c21]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
A comparison of the normalized detection threshold for the overlapped and non-overlapped FFT summation detectors. CCECE 2011: 136-141 - [c20]Majid Mafi, Sreeraman Rajan, Miodrag Bolic, Voicu Z. Groza, Hilmi R. Dajani:
Blood pressure estimation using oscillometric pulse morphology. EMBC 2011: 2492-2496 - [c19]Sichun Wang, Robert J. Inkol, François Patenaude, Sreeraman Rajan:
Computation of the normalized detection threshold for the FFT summation detector through eigenvalue sequence truncation. MILCOM 2011: 131-136 - 2010
- [j6]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
Detection of Narrow-Band Signals Through the FFT and Polyphase FFT Filter Banks: Noncoherent Versus Coherent Integration. IEEE Trans. Instrum. Meas. 59(5): 1424-1438 (2010) - [j5]Saif Ahmad, Miodrag Bolic, Hilmi R. Dajani, Voicu Groza, Izmail Batkin, Sreeraman Rajan:
Measurement of Heart Rate Variability Using an Oscillometric Blood Pressure Monitor. IEEE Trans. Instrum. Meas. 59(10): 2575-2590 (2010) - [j4]Anjana Punchihewa, Qiyun Zhang, Octavia A. Dobre, Chad M. Spooner, Sreeraman Rajan, Robert J. Inkol:
On the Cyclostationarity of OFDM and Single Carrier Linearly Digitally Modulated Signals in Time Dispersive Channels: Theoretical Developments and Application. IEEE Trans. Wirel. Commun. 9(8): 2588-2599 (2010) - [c18]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
Strategies for improving angle of arrival accuracy in direction finding systems. CCECE 2010: 1-6 - [c17]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
The Okamoto lower bound for the normalized detection threshold of the FFT filter bank-based summation detector. CCECE 2010: 1-6 - [c16]Qiyun Zhang, Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol, Erchin Serpedin:
Cyclostationarity Approach for the Recognition of Cyclically Prefixed Single Carrier Signals in Cognitive Radio. ICC 2010: 1-6
2000 – 2009
- 2009
- [j3]Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol:
Joint Signal Detection and Classification Based on First-Order Cyclostationarity For Cognitive Radios. EURASIP J. Adv. Signal Process. 2009 (2009) - [j2]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
On the Performance Gain of the FFT Filter-Bank-Based Summation and Majority CFAR Detectors. IEEE Trans. Instrum. Meas. 58(5): 1778-1788 (2009) - [c15]Qiyun Zhang, Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol:
On the second-order cyclostationarity for joint signal detection and classification in cognitive radio systems. CCECE 2009: 204-208 - [c14]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
Comparison of two angle of arrival averaging strategies. CCECE 2009: 1105-1110 - [c13]Simon Henault, Yahia M. M. Antar, Sreeraman Rajan, Robert J. Inkol, Sichun Wang:
Impact of a finite ground plane on the accuracy of conventional wideband direction finding systems for signals of unknown polarization. CCECE 2009: 1111-1116 - [c12]Sichun Wang, Robert J. Inkol, Sreeraman Rajan, François Patenaude:
Numerical computation of the normalized detection threshold for the FFT J-out-of-L detector. CCECE 2009: 1117-1122 - [c11]Simon Henault, Yahia M. M. Antar, Sreeraman Rajan, Robert J. Inkol, Sichun Wang:
Impact of experimental calibration on the performance of conventional direction finders. CCECE 2009: 1123-1128 - 2008
- [c10]Anjana Punchihewa, Octavia A. Dobre, Q. Zhang, Sreeraman Rajan, Robert J. Inkol:
The nth-order cyclostationarity of OFDM signals in time dispersive channels. ACSCC 2008: 574-580 - [c9]Octavia A. Dobre, Qiyun Zhang, Sreeraman Rajan, Robert J. Inkol:
Second-Order Cyclostationarity of Cyclically Prefixed Single Carrier Linear Digital Modulations with Applications to Signal Recognition. GLOBECOM 2008: 3513-3517 - [c8]Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol:
Exploitation of First-Order Cyclostationarity for Joint Signal Detection and Classification in Cognitive Radio. VTC Fall 2008: 1-5 - [c7]Octavia A. Dobre, Anjana Punchihewa, Sreeraman Rajan, Robert J. Inkol:
On the Cyclostationarity of OFDM and Single Carrier Linearly Digitally Modulated Signals in Time Dispersive Channels with Applications to Modulation Recognition. WCNC 2008: 1284-1289 - 2007
- [c6]Anjana Punchihewa, Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol:
Cyclostationarity-based Algorithm for Blind Recognition of OFDM and Single Carrier Linear Digital Modulations. PIMRC 2007: 1-5 - [c5]Octavia A. Dobre, Sreeraman Rajan, Robert J. Inkol:
A Novel Algorithm for Blind Recognition of M-ary Frequency Shift Keying Modulation. WCNC 2007: 520-524 - 2006
- [j1]Sreeraman Rajan, Sichun Wang, Robert J. Inkol, Alain Joyal:
Efficient approximations for the arctangent function. IEEE Signal Process. Mag. 23(3): 108-111 (2006) - [c4]Sichun Wang, Robert J. Inkol, Sreeraman Rajan:
Performance Comparison of the FFT Filter Bank-Based Majority and Median CFAR Detectors. CCECE 2006: 36-40 - [c3]Sreeraman Rajan, Sichun Wang, Robert J. Inkol:
Efficient Approximations for the Four-Quadrant Arctangent Function. CCECE 2006: 1043-1046 - [c2]Sreeraman Rajan, Erin Budd, Maryhelen Stevenson, Rajamani Doraiswami:
Unsupervised and Uncued Segmentation of the Fundamental Heart Sounds in Phonocardiograms Using a Time-Scale Representation. EMBC 2006: 3732-3735
1990 – 1999
- 1998
- [c1]Ram Balasubramanian, Sreeraman Rajan, Rajamani Doraiswami, Maryhelen Stevenson:
Using misclassified training samples to improve classification. SMC 1998: 4296-4300
Coauthor Index
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