Imaging Sensors and Applications

© 2022 by the authors; CC BY-NC-ND license

fluorescence LiDAR; laser-induced fluorescence; vegetation monitoring; classification discrimination; 3D measurement; fringe projection; 3D Fourier transform; phase unwrapping; phase measurement; ultrasound; photoacoustic imaging; photoacoustic microscopy; biomedical imaging; multifocal point transducer; wave patterns; analytical model; directivity pattern; guided wave (GW); non-destructive testing (NDT); macro-fiber composite (MFC); transducer; elastography; soft tissue; nonlinearity; viscoelasticity; acoustic emission; ultrasound; hydrogel; nanosilica; transcranial; skull bone; aberration; photoacoustic; distortion; brain imaging; balloon catheter; photoacoustic imaging; image guiding; medical diagnostic imaging; ultrasonic imaging; abdominal ultrasound; plane wave imaging; diverging wave imaging; synthetic focusing; back muscle stiffness; spine; elasticity; shear-wave elastography (SWE); tissue ultrasound palpation system (TUPS); reliability; Young’s modulus; carfilzomib; peripheral vasculature; photoacoustic microscopy; quantitative analysis; transrectal probe; optical lens; ultrasound imaging; photoacoustic imaging; prostate cancer; optical coherence tomography; quad-scanner scanning strategy; whole-directional scanning; full-directional imaging; IoT; remote control; remote operation; remote sharing economy; research equipment sharing; two-photon laser scanning microscopy; MQTT; deep learning; ensemble learning; brain tumor classification; machine learning; transfer learning; around view monitoring system; automatic camera calibration; vision-based advanced driver assistance systems; high-frequency ultrasound; ophthalmic imaging; synthetic aperture; convex array transducer; bandwidth expander; ultrasound transducer device; power amplifier; super-resolution; ultrasound imaging; deep learning; clinical applications; n/a