This Domain Name Has Expired - Renewal Instructions.Rediscover the Magic of Flight with the Parrot AR. Drone tech toy introduces connected generation to flying fun. When was the last time technology grabbed you by surprise and wowed you? Was it the Rosetta comet landing? Perhaps an impromptu band rehearsal via Google+ Hangouts? If it's been a while, allow the Parrot AR.Drone 2.0 to lift your curiosity. As you can see in the above video, this is no ordinary toy quadcopter. Here's a pre-flight checklist of the AR. FLY – Using an app on your Android or iOS device, pilot the AR.Drone 2.0 at distances up to 165 feet. Embedded autopilot sensors hold it steady in the sky, making takeoff, navigation and landing easy. Battery life keeps you aloft for about 12 minutes and recharges in less time than it takes to watch Top Gun. RECORD – Two on-board cameras capture the action: one forward-facing (720p HD) and one downward-facing. Video is recorded and broadcast directly to your device in real-time.

SHARE – One-click lets you upload your aerial adventures to YouTube, Twitter, Facebook and Picasa. The product video showcases the AR.Drone 2.0’s capabilities and the tech specs look good on paper, but does it fly predictably? To pilot the AR.Drone 2.0, tap the Takeoff button on your smartphone or tablet and the Drone will automatically and assertively rise to a stable hover a few feet off the ground. ar drone 2 site officielTo navigate, press the virtual flight stick and tilt your device in the direction that you want to go. parrot ar drone switzerlandTo land, simply tap the Landing button.storm drone ff flying platform buyDrone 2.0 has something to offer for a variety of lifestyles. parrot ar drone increase range

Aspiring aviators and rocketeers are, of course, a natural fit. If you’re a gamer, swap your console controller for the virtual flight stick and test your skills in single player or head-to-head augmented reality apps such as AR.Race 2 and AR.Your family can enjoy an imaginative day together and you can share the bird's-eye-view video that you capture using the onboard video cameras. buy parrot ar drone south africaUpload your flight footage directly from your device to show friends and relatives.phantom 2 drone kopen Brian's Tips for Flying the AR. An open, grassy field is the ideal place to learn to fly. Confined areas with trees and obstacles will be tricky to navigate until you have a few flights under your belt. The protective indoor shell (the "foam clover" surrounding the propellers) cushions the drone during bumps and crashes indoors or outdoors.

To maneuver out of an unintended flight path, ease off the controls and let the AR.Drone 2.0 steady itself automatically. You can tap into the online community. Parrot's website and forums are buzzing with video tutorials and tips and offer replacement parts if needed.Following my tutorial on controlling the Sphero using the Leap Motion, I thought I would keep on converting my Node.js projects to Cylon.js and work on controlling an AR.Drone with Leap Motion. If you’ve had a look at my last tutorial, you probably noticed that using Cylon.js makes it really easy to program for hardware and connect multiple devices together. Below is the usual setup of any Cylon project: As you can see, you simply need to specify which devices you are using. The more interesting bit comes in the rest of the code: This code only makes the drone take off when the Leap Motion senses a hand over it and land after 5 seconds (just in case it decides to go crazy). Then, if you want to make it do more interesting things, you will have to play around with what Leap Motion has to offer;

different types of gestures, distance, hands, fingers, etc. The drone actions themselves are pretty straightforward: You can also make the drone rotate clockwise or counterclockwise, but what I found the most awesome thing is that the cylon-ardrone module makes the ‘flip’ movement really easy to execute. On a ‘keyTap’ for example, your drone could do a backflip! The code for that would look like this: If you wanna see the difference with Node.js, you can find my original Github repo here, otherwise here is the repo with more commands. If you have any question, don’t hesitate! Want to see more Leap Motion drone mashups? Check out some experimental flying videos or reach for the skies with our blog’s #drone tag. This package contains the implementation of a gazebo simulator for the Ardrone 2.0 and has been written by Hongrong Huang and Juergen Sturm of the Computer Vision Group at the Technical University of Munich. This package is based on the ROS package tu-darmstadt-ros-pkg by Johannes Meyer and Stefan Kohlbrecher and the Ardrone simulator which is provided by Matthias Nieuwenhuisen.

The simulator can simulate both the AR.Drone 1.0 and 2.0, the default parameters however are optimized for the AR.Drone 2.0 by now. You can fine more details on my report. The simulator is on the simulator_gazebo platform. Before using this simulator, it is recommended to get know more about the simulator by reading gazebo tutorials. Additionaly, you can get more information about flying robots and AR.Drone from the lecture visual navigation for flying robots. Real quadrocopter structure: The AR.Drone2.0 connects with a computer via WIFI, while the user manipulate a joystick which is via USB connecting with the same computer. ROS is running in this computer. Simulated quadrocopter manipulation: After the simulation is started. The user can use a joystick to manipulate the simulated quadrocopter. The botton functions of the joystick are the same as manipulating the real AR.Drone2.0. The following video shows an experiment about how the simulator works compared to the real AR. gazebo, ground_truth_to_tf, robot_state_publisher: The simulator program.

rviz: A 3d visualization environment for the simulated flying robots. joy_node, ardrone_joystick: They are the joystick driver and the command information translator for the Ardrone. Your computer should have ROS and simulator gazebo package installed. The ROS version should be fuerte and the Gazebo version of the ROS plugin (which is, for fuerte, 1.0.2). Be sure that rviz is also installed. 1. Install the following additional required packages in your ROS workspace. ardrone_autonomy package: This is the official driver for the real Ardrone flying robots. 2. Install tum_simulator package: You can start the simulator with one of the following flying scenario: You can manipulate the quadrocopter with joysticks after launching: For observation you can use following commands: OR using the rviz tool. If you get the following error message when you start the simulator, you should close all the other nodes which connect the simulator by some ROS topices. And try again to launch the simulator file.

Furtherm more, you can terminate your ROS master, even close all your terminal windows and restart the simulator again. - installing Gazebo 1.6.0 is not required (though its dependency libbullet might be), since launching gazebo via ROS will always use the Gazebo version of the ROS plugin (which is, for fuerte, 1.0.2) - Gazebo (and, by extension, the TUM simulator) is very picky about the installed graphics card; as far as we can tell at this time, only Nvidia cards really work (and only with the restricted Nvidia driver), ATI/AMD and Intel cards will not work, since the drivers do not have all the OpenGL/FireGL capabilities that Gazebo requires. In case of ATI drivers, we observed error messages about missing GL features, but with the Intel drivers, Gazebo simply segfaults (or rather, the Intel driver segfaults and Gazebo quits without any meaningful error message). Because of the limitation of the gazebo simulator, not all the AD.Drone sensors are 100% modeled in the simulation.