Date:13/12/16
“In this work, we address one of the main challenges towards autonomous drone flight in complex environments, which is flight through narrow gaps. Indeed, one day micro drones will be used to search and rescue people in the aftermath of an earthquake. In these situations, collapsed buildings cannot be accessed through conventional windows, so that small gaps may be the only way to get inside. What makes this problem challenging is that a gap can be very small, such that precise trajectory-following is required, and can have arbitrary orientations, such that the quadrotor cannot fly through it in near-hover conditions. This makes it necessary to execute an agile trajectory (i.e., with high velocity and angular accelerations) in order to align the vehicle to the gap orientation.
Previous works on aggressive flight through narrow gaps have focused solely on the control and planning problem and therefore used motion-capture systems for state estimation and external computing. Conversely, we focus on using only onboard sensors and computing. More specifically, we address the case where state estimation is done via gap detection through a single, forward-facing camera and show that this raises an interesting problem of coupled perception and planning: for the robot to localize with respect to the gap, a trajectory should be selected, which guarantees that the quadrotor always faces the gap (perception constraint) and should be replanned multiple times during its execution to cope with the varying uncertainty of the state estimate. Furthermore, during the traverse, the quadrotor should maximize the distance from the edges of the gap (geometric constraint) to avoid collisions and, at the same time, it should be able to do so without relying on any visual feedback (when the robot is very close to the gap, this exits from the camera field of view). Finally, the trajectory should be feasible with respect to the dynamic constraints of the vehicle. Our proposed trajectory generation approach is independent of the gap-detection algorithm being used; thus, to simplify the perception task, we used a gap with a simple black-and-white rectangular pattern.
We successfully evaluated our approach with gap orientations of up to 45 degrees vertically and up to 30 horizontally. Our vehicle weighs 830 grams and has a thrust-to-weight ratio of 2.5. Our trajectory generation formulation handles trajectories up to 90-degree gap orientations although the quadrotor used in these experiments is too heavy and the motors saturate for more than 45-degree gap orientations. The vehicle reaches speeds of up to 3 meters per second and angular velocities of up to 400 degrees per second, with accelerations of up to 1.5 g. We can pass through gaps 1.5 times the size of the quadrotor, with only 10 centimeters of tolerance. Our method does not require any prior knowledge about the position and the orientation of the gap. No external infrastructure, such as a motion-capture system, is needed. This is the first time that such an aggressive maneuver through narrow gaps has been done by fusing gap detection from a single onboard camera and IMU,” the scientists said.
Agile Drone Flight through Narrow Gaps with Onboard Sensing and Computing
German scientists have taught a quadrocopter perform aggressive manoeuvres, relying only on the testimony of its own gyro, accelerometer and camera.“In this work, we address one of the main challenges towards autonomous drone flight in complex environments, which is flight through narrow gaps. Indeed, one day micro drones will be used to search and rescue people in the aftermath of an earthquake. In these situations, collapsed buildings cannot be accessed through conventional windows, so that small gaps may be the only way to get inside. What makes this problem challenging is that a gap can be very small, such that precise trajectory-following is required, and can have arbitrary orientations, such that the quadrotor cannot fly through it in near-hover conditions. This makes it necessary to execute an agile trajectory (i.e., with high velocity and angular accelerations) in order to align the vehicle to the gap orientation.
Previous works on aggressive flight through narrow gaps have focused solely on the control and planning problem and therefore used motion-capture systems for state estimation and external computing. Conversely, we focus on using only onboard sensors and computing. More specifically, we address the case where state estimation is done via gap detection through a single, forward-facing camera and show that this raises an interesting problem of coupled perception and planning: for the robot to localize with respect to the gap, a trajectory should be selected, which guarantees that the quadrotor always faces the gap (perception constraint) and should be replanned multiple times during its execution to cope with the varying uncertainty of the state estimate. Furthermore, during the traverse, the quadrotor should maximize the distance from the edges of the gap (geometric constraint) to avoid collisions and, at the same time, it should be able to do so without relying on any visual feedback (when the robot is very close to the gap, this exits from the camera field of view). Finally, the trajectory should be feasible with respect to the dynamic constraints of the vehicle. Our proposed trajectory generation approach is independent of the gap-detection algorithm being used; thus, to simplify the perception task, we used a gap with a simple black-and-white rectangular pattern.
We successfully evaluated our approach with gap orientations of up to 45 degrees vertically and up to 30 horizontally. Our vehicle weighs 830 grams and has a thrust-to-weight ratio of 2.5. Our trajectory generation formulation handles trajectories up to 90-degree gap orientations although the quadrotor used in these experiments is too heavy and the motors saturate for more than 45-degree gap orientations. The vehicle reaches speeds of up to 3 meters per second and angular velocities of up to 400 degrees per second, with accelerations of up to 1.5 g. We can pass through gaps 1.5 times the size of the quadrotor, with only 10 centimeters of tolerance. Our method does not require any prior knowledge about the position and the orientation of the gap. No external infrastructure, such as a motion-capture system, is needed. This is the first time that such an aggressive maneuver through narrow gaps has been done by fusing gap detection from a single onboard camera and IMU,” the scientists said.
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