I think it is possible to use this instability, but it is probably better to avoid the elastic instabilities and just use higher velocity to slice through the skin instead of trying to make the robot unstable to release this high energy. Just my thought, but I guess if you figure out a way to consistently predict when the instability occurs, you could use it to its advantage.
Hello, does anyone know if the implementation of this network is published along with the paper? I did some searching, but could not find it. It'd be really helpful if someone could share the resource. Thanks.
Hello, Thanks for the good paper. I would like to watch this presentation with audio. Could you please let me know where can I find it? Thank and Regards, Harshkumar Borad
Very cool! I'm amazed that this is not more well-known. I think you might get more horizontal/lateral thrust and greater roll and pitch control if you replace the lower propeller with a cyclorotor. This cyclorotor would rotate in the same direction as the propeller it is replacing, and it would be helpful -- but not required -- if it could be given a similar torque/pitch coupling as the propeller.
Hi, Thank you for a great job. I have a deep interest in Multiple object tracking, I like your project, and I want to research to use your approach for Point clouds, can you please share your code?
Very interesting. I get a feeling this is not an open source project, sadly. Instead a teaser probably looking for funding. I wonder if there was any interest or further development. I guess RC hobby companies and many people would be interested in having more advanced controllers/gyros for acrobatics but probably not as rewarding financially as other industries :(
