1 |
M. Aykin and S. Negahdaripour [Three-dimensional target reconstruction from multiple 2-D forward-scan sonar views by space carving, IEEE J. of Oceanic Eng.] (2017)
|
2 |
H. Cho, et al. [AUV-Based Underwater 3-D point cloud generation using acoustic lens-based multibeam sonar, IEEE J. of Oceanic Eng.] (2018)
|
3 |
H. Joe, et al. [3D Reconstruction using two sonar devices in a Monte-Carlo approach for AUV application, Int. J, of Control, Automation and Systems] (2020)
|
4 |
R. Fattal [Single image dehazing. ACM Transaction on Graphics] (2008)
|
5 |
J. Kim, et al. [3-D Reconstruction of underwater objects using image sequences from optical camera and imaging sonar, OCEANS Seattle] (2019)
|
6 |
J. Kim and S. Yu [Convolutional neural network-based real-time ROV detection using forward-looking sonar image, IEEE Autonomous Underwater Vehicles] (2016)
|
7 |
MBARI [Seafloor mapping AUV] (2005)
|
8 |
E. McCartney [Optics of the atmosphere: scattering by molecules and particles, NYJW] (1977)
|
9 |
Sound Metrics, http://www.soundmetrics.com/Products/DIDSON-Sonars
|
10 |
R. Malav, et al. [DHSGAN: an end to end dehazing network for fog, Asain Conf. on Computer Vision] (2018)
|
11 |
Teledyne Marine: http://www.teledynemarine.com/blueview
|
12 |
H. Cho, et al. [Acoustic beam profile-based rapid underwater object detection for an imaging sonar, J. of Marine Science and Technology] (2015)
|
13 |
N. Hurtos, et al. [Fourier‐based registration for robust forward‐looking sonar mosaicing in low‐visibility underwater environments, J. of Field Robotics] (2015)
|