FLAP: FOV-Constrained Active Perception Planning for Prior-Map-Free 3D Navigation

Figure 1: Simulation results of the proposed method in a dense grid of metal pipes without prior mapping. The UAV starts from the ground, actively perceives unknown spaces using its onboard vision sensor, successfully avoids all obstacles and reaches the final position above the pipes.

Figure 7: Results of FLAP, SUPER, and FM in the horizontal narrow-space scenario. We use gradient colors to represent the UAV’s speed; the darker the color, the higher the speed. From top to bottom are the results with total vertical FOVs of 90 ∘ , 30 ∘ , 10 ∘ , and 0.2 ∘ . The small fan-shaped inset at the right of each row illustrates the corresponding vertical sensing range. The successful trajectory is shown only if the method succeeds in at least one trial. No trajectory is shown when all trials fail.

Figure 9: Results of FLAP and SUPER in the U-shaped maze scenario. (a) Trajectories of the two methods, where color gradients encode the UAV altitude; the right side shows representative close-up views at two locations. (b) Two types of U-shaped obstacles in the environment, where two colors distinguish obstacles attached to the floor and the ceiling, and the orange lines mark their intersections with the ground or ceiling.

Figure 14: Performance of FLAP and NBV in a cluttered environment with overlapping vertical obstacles. The UAV, equipped with a vision camera, must traverse a vertically constrained passage formed by these obstacles. The trajectory is color-coded by height. The left and right figures show the results of FLAP and NBV, respectively. For visualization clarity, the pipeline walls are omitted in the figure to reveal the internal obstacle layout and trajectories. The center top view compares the two trajectories and indicates the obstacle boundaries and the travel time from start to goal.

Figure 4: Two representative sensor configurations. (a) Asymmetric vertical angular coverage of the Livox Mid-360 LiDAR. (b) Symmetric vertical angular coverage of a typical depth camera.

Figure 5: Activation function \mathcal{L}_{a}(\mathcal{C}_{\mathrm{sd}}) and the resulting trajectory behaviors in a simplified 2D illustration, where the effect of orientation is ignored and the constraints are applied over the entire \boldsymbol{S}_{s} segment. (a) Safety-dominated case with \mathcal{L}_{a}(\mathcal{C}_{\mathrm{sd}})=0 . (b) Perception-dominated case with \mathcal{L}_{a}(\mathcal{C}_{\mathrm{sd}})=1 . (c) Proposed risk-aware active perception behavior.

Figure 6: Comparison of the proposed AP segment with other strategies. (a) Ignoring the safety distance and evaluating the safety and perception constraints over the terminal part of \boldsymbol{S}_{s} . (b) Considering the safety distance and evaluating the safety and perception constraints over the terminal part of \boldsymbol{S}_{s} . (c) The proposed AP segment, which can be interpreted as containing safety-dominated, coupling, and perception-dominated parts induced by the risk-aware activation.

Figure 8: Results of FLAP and SUPER in the overhead-obstacle scenario. The final point is set directly above the start point, and the UAV must actively observe the obstacle above to ensure safety.