Lidar

github neural
https://github.com/maudzung/RTM3D

https://github.com/maudzung/Super-Fast-Accurate-3D-Object-Detection

https://github.com/fangchangma/self-supervised-depth-completion This repo is the PyTorch implementation of our ICRA'19 paper on "Self-supervised Sparse-to-Dense: Self-supervised Depth Completion from LiDAR and Monocular Camera", developed by Fangchang Ma, Guilherme Venturelli Cavalheiro, and Sertac Karaman at MIT. A video demonstration is available on YouTube.

https://github.com/jingjing12110/object_detection_tracking

https://github.com/HKUST-Aerial-Robotics/A-LOAM

https://github.com/Reverie10/PointPillars_MultiHead_40FPS

Arduino
https://innovatorsguru.com/tf02-lidar/ tf02 from aliexpress for $150, range 22m. TF-Luna LiDAR Module Range Finder Sensor Single-Point Micro Ranging Module 5V UART IIC Interface with Cable with 8m range.

Osram
http://diydrones.com/profiles/blogs/osram-s-laser-chip-for-lidar The overall lidar system covers 120 degrees in the horizontal plane, with 0.1 degree of resolution, and 20 degrees in the vertical plane, with 0.5 degree of resolution. In the light of day, it should detect cars from at least 200 meters away, and pedestrians at 70 meters out. This is a very significant breakthrough, it is exactly what is needed to permit all kinds of autonomous vehicle and robot operation in our complex environment. We have primarily been doing autonomous operations with the absolute position control of GPS which does not take into account at all surrounding obstacles, but only provides a position on the surface of the Earth.

livox
https://diydrones.com/profiles/blogs/livox-mid-40-lidar-short-review

https://msadowski.github.io/livox-mid40-review/

https://www.livoxtech.com/mid-40-and-mid-100/downloads

https://acad.ro/sectii2002/proceedings/doc2018-1/08.pdf

Terabee
http://www.electronics-eetimes.com/news/light-centimetre-level-slam-drones

http://www.terabee.com/about/

http://www.teraranger.com/

https://github.com/Terabee/TeraRanger-Lidar-ROS-package

Lidar
http://diydrones.com/profiles/blogs/terrain-following-missions-using-lidar#comments The upcoming Copter-3.4 release will include terrain following support for mission commands using either Google earth altitude data or a Laser Range Finder. This is a demonstration video shot at a ski hill near my home in Karuizawa Japan of this new feature.

For this test I used a venerable 3DR IRIS with a PulsedLight Lidar Lite. This lidar is difficult to find but actually I recommend the sensors from Lightware (like the SF10) which, although they are quite a bit more expensive, are much more reliable and offer a greater range.

http://pulsedlight3d.com

http://ardupilot.org/copter/docs/common-rangefinder-lidarlite.html

http://www.lightware.co.za/shop/en/

http://ardupilot.org/copter/docs/common-lightware-sf10-lidar.html


 * http://diydrones.com/profiles/blogs/high-speed-scanning-laser-weighs-just-75g-and-measures-over-100m by http://www.lightware.co.za Laser scanning LIDAR and Slam.

http://diydrones.com/profiles/blogs/lidar-lite-360-degree-mirror-scanner, http://blog.trossenrobotics.com/2015/07/13/lidar-lite-360-mirror-scanner/  , http://forums.trossenrobotics.com/member.php?12669-r3n33

links
Arducam OAK ai module for distance and depth perception.

point cloud

https://www.getsurreal.com/product/xv-lidar-sensor-mount-package/ from articles by Fotache Pytorch and Slam

Image resolution

https://www.seeedstudio.com/RPLIDAR-360-degree-Laser-Scanner-Development-Kit-p-1823.html

https://velodynelidar.com/vlp-16.html

https://www.omron.com/media/press/2018/09/c0913_2.html