Nome |
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Development of an EM Device for Cerebrovascular Diseases Imaging and Hardware Acceleration for Imaging Algorithms within the EMERALD Network, file e384c430-6bb3-d4b2-e053-9f05fe0a1d67
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77
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A Prototype Microwave System for 3D Brain Stroke Imaging, file e384c431-f24e-d4b2-e053-9f05fe0a1d67
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61
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Joint Position and Travel Path Optimization for Energy Efficient Wireless Data Gathering Using Unmanned Aerial Vehicles, file e384c431-c282-d4b2-e053-9f05fe0a1d67
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58
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Benchmark Head Phantoms for Microwave Imaging of Brain Strokes, file e384c432-1760-d4b2-e053-9f05fe0a1d67
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52
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Experimental Testing and Calibration Issues in the Realization of a Microwave Imaging Device for Brain Stroke Monitoring, file e384c432-299e-d4b2-e053-9f05fe0a1d67
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47
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Brick Shaped Antenna Module for Microwave Brain Imaging Systems, file e384c432-6a5d-d4b2-e053-9f05fe0a1d67
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47
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Experimental Validation of a Microwave System for Brain Stroke 3-D Imaging, file e384c433-adf5-d4b2-e053-9f05fe0a1d67
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37
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Microwave Imaging for Brain Stroke Monitoring, file e384c432-5e82-d4b2-e053-9f05fe0a1d67
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36
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Assessing a Microwave Imaging System for Brain Stroke Monitoring via High Fidelity Numerical Modelling, file e384c433-813c-d4b2-e053-9f05fe0a1d67
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30
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Experimental Imaging Issues of a 3-D Microwave Brain Scanner, file e384c433-ac36-d4b2-e053-9f05fe0a1d67
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28
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EM Device for Cerebrovascular Diseases Imaging, file e384c434-c67e-d4b2-e053-9f05fe0a1d67
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27
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High Fidelity Modelling of a Microwave Imaging Device for Brain Stroke Monitoring, file e384c432-28dc-d4b2-e053-9f05fe0a1d67
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24
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Realistic Numerical Modelling for 3-D brain stroke monitoring, file e384c432-6a5e-d4b2-e053-9f05fe0a1d67
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24
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Electromagnetic Virtual Prototyping of a Realistic 3-D Microwave Scanner for Brain Stroke Imaging, file e384c433-109b-d4b2-e053-9f05fe0a1d67
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18
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Microwave Brain Imaging System Validation via Realistic Experiments, file e384c433-b531-d4b2-e053-9f05fe0a1d67
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17
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Hybrid Simulation-Measurement Calibration Technique for Microwave Imaging Systems, file e384c433-5abf-d4b2-e053-9f05fe0a1d67
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15
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A Portable Microwave Scanner for Brain Stroke Monitoring: Design, Implementation and Experimental Validation, file e384c434-c810-d4b2-e053-9f05fe0a1d67
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15
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Hybrid Resolvent Kernel Calibration Technique for Microwave Imaging Systems, file e384c434-a44d-d4b2-e053-9f05fe0a1d67
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14
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EM Device for Cerebrovascular Diseases Imaging, file e384c434-e04d-d4b2-e053-9f05fe0a1d67
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13
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Intracranial hemorrhage imaging-based follow-up: experimental assessment using a microwave imaging scanner, file b290dcac-4937-4b43-8073-0d6fcb0abca4
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12
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Wearable Microwave Imaging System for Brain Stroke Imaging, file 36114e4b-4b1d-4b95-bcf7-b3c3d8d441f9
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11
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Experimental Assessment of Real-Time Brain Stroke Monitoring via a Microwave Imaging Scanner, file 8cd850d5-4694-4ff4-b558-512e298fe747
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10
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Benefits of Employing Metasurfaces on the Design of a Microwave Brain Imaging Scanner, file e384c434-1640-d4b2-e053-9f05fe0a1d67
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9
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Multi-shot Calibration Technique for Microwave Imaging Systems, file e384c434-8a87-d4b2-e053-9f05fe0a1d67
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9
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Hybrid Simulation-Measurement Calibration Technique for Microwave Imaging Systems, file e384c433-78b1-d4b2-e053-9f05fe0a1d67
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8
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Towards a microwave imaging device for cerebrovascular diseases monitoring: from numerical modeling to experimental testing, file 616853e3-f30e-4d78-883d-9647cbb09205
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6
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A microwave sensing system enhanced by a machine learning algorithm for Alzheimer’s disease early detection, file 64efbaca-5539-4021-ab87-abbc63d60e97
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6
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On numerical calibration-based techniques for microwave imaging devices, file 6c799e96-ecbf-4171-8315-9ef81659c236
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6
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Real-time 3D microwave tomography of brain stroke status using low-computing demand, file 6cd0cf4a-ef80-4e1d-9c19-421904ec58ce
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6
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Hybrid imaging kernel calibration applied on microwave scanner for brain stroke monitoring, file 9c739258-e88e-46d7-901c-6b40844993d8
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6
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Microwave antenna array calibration via simulated and measured S-parameters matching, file 3f0b89b5-3882-45d6-b1a9-b0e30e5055e8
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4
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Hybrid Simulation-Measurement Method for Broadband Dielectric Characterization of Synthetic Human Head Tissues, file d02c0df1-359a-4a0c-b549-23fc0e3f69bc
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4
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A Prototype Microwave System for 3D Brain Stroke Imaging, file e384c431-db78-d4b2-e053-9f05fe0a1d67
|
4
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Anthropomorphic multi-tissue head phantom for microwave imaging devices testing, file 0f5fbbcd-230b-40a2-8b3e-a774c0f6addf
|
3
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Towards a microwave imaging device for cerebrovascular diseases monitoring: from numerical modeling to experimental testing, file be3ad229-e06c-4984-a996-9d6fc212e808
|
3
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Microwave imaging device prototype for brain stroke 3D monitoring, file c9c1b176-caca-4bf8-931c-481149b9fb8c
|
3
|
Development of an EM Device for Cerebrovascular Diseases Imaging and Hardware Acceleration for Imaging Algorithms within the EMERALD Network, file e384c431-1d71-d4b2-e053-9f05fe0a1d67
|
3
|
Brick Shaped Antenna Module for Microwave Brain Imaging Systems, file e384c433-a309-d4b2-e053-9f05fe0a1d67
|
3
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Experimental Imaging Issues of a 3-D Microwave Brain Scanner, file e384c434-32dc-d4b2-e053-9f05fe0a1d67
|
3
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Benefits of Employing Metasurfaces on the Design of a Microwave Brain Imaging Scanner, file e384c434-37af-d4b2-e053-9f05fe0a1d67
|
3
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Experimental validation of a microwave scanner for brain stroke monitoring in realistic head models, file f4e380c1-026b-4702-a965-e2f7f5bc99ce
|
3
|
Microwave antenna array calibration via simulated and measured S-parameters matching, file 0ec98dbb-c032-4f70-a2af-72c757242195
|
2
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Experimental validation of a microwave scanner for brain stroke monitoring in realistic head models, file 193060d2-3411-4dfa-8099-b338c32b46a6
|
2
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A machine learning approach to microwave sensing for non-invasive alzheimer’s disease early detection, file 26fe2f01-c125-471e-bcb7-eeeb993f9591
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2
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Anthropomorphic multi-tissue head phantom for microwave imaging devices testing, file 57f7c6ba-d793-4bba-a767-9eddb5f33ee5
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2
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Moving Forward to Real-time Imaging-based Monitoring of Cerebrovascular Diseases Using a Microwave Device: Numerical and Experimental Validation, file 5959b7db-7bc4-4ecd-ac09-80f2cfe71c05
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2
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Experimental assessment of the effects of increasing illumination angles to maximise useful information in axillary microwave tomography, file 77bade79-ea7d-4697-b8d8-d38e2a554136
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2
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Microwave imaging device prototype for brain stroke 3D monitoring, file a3a6b57e-fbfa-41a3-b8de-deb8b04408bb
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2
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Hybrid imaging kernel calibration applied on microwave scanner for brain stroke monitoring, file ae4d6982-2c1d-4e1d-a88a-fe388aa5170d
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2
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On numerical calibration-based techniques for microwave imaging devices, file b237686e-931e-4856-9a70-0ed1f519e57f
|
2
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Experimental Assessment of Axillary Lymph Node Microwave Tomography Using Anthropomorphic Phantoms, file ca91f502-ce97-4e0f-8a26-96073a2a77ae
|
2
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Electromagnetic Virtual Prototyping of a Realistic 3-D Microwave Scanner for Brain Stroke Imaging, file e384c433-4624-d4b2-e053-9f05fe0a1d67
|
2
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Assessing a Microwave Imaging System for Brain Stroke Monitoring via High Fidelity Numerical Modelling, file e384c434-a725-d4b2-e053-9f05fe0a1d67
|
2
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A low-complexity microwave scanner for cerebrovascular diseases monitoring, file 285e4059-498d-4366-bdef-098bf9270968
|
1
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Moving Forward to Real-time Imaging-based Monitoring of Cerebrovascular Diseases Using a Microwave Device: Numerical and Experimental Validation, file 74e1323d-07b2-4996-838f-e2ee0003d495
|
1
|
Joint Position and Travel Path Optimization for Energy Efficient Wireless Data Gathering Using Unmanned Aerial Vehicles, file e384c431-a07f-d4b2-e053-9f05fe0a1d67
|
1
|
Totale |
792 |