A landing station guidance-and-security system can include an environmental cover and/or a guide-and-security bar. In some embodiments, the landing station guidance-and-security system is integrated into a parcel-receiving device. In some embodiments, the landing station guidance-and-security system is configured to attach to a parcel-receiving device. In some embodiments, the guide-and-security bar includes a precision rod. In some embodiments, a drone landing station includes: a magnetic centering mechanism configured to center a drone and/or a package; sliding dovetail doors; a plow bar; at least one roll-up door; a first storage locker; a second storage locker; and/or a solid rear door configured to block access to the second storage locker from the first storage locker when the first storage locker is being accessed by a user.

Disclosed are a system and method for aiming and/or guiding an interceptor Unmanned Aerial Vehicle to eliminate target Unmanned Aerial Vehicle, by holding the interceptor UAV to the direction of the target or by the use of a portable computer such as a table combined with the computer onboard camera and internal sensor to aim and guide the interceptor UAV toward the aerial threat by the operator. The UAV has a propulsion subsystem, imaging subsystem, flight sensors, and a computer processor that determine an intercept course for the UAV to the target using the sensors and the disable the target.

Disclosed are a system and method for aiming and/or guiding an interceptor Unmanned Aerial Vehicle to eliminate target Unmanned Aerial Vehicle, by holding the interceptor UAV to the direction of the target or by the use of a portable computer such as a table combined with the computer onboard camera and internal sensor to aim and guide the interceptor UAV toward the aerial threat by the operator. The UAV has a propulsion subsystem, imaging subsystem, flight sensors, and a computer processor that determine an intercept course for the UAV to the target using the sensors and the disable the target.

A device for the automated vertical take-off, vertical landing, and/or handling of an aerial vehicle with the aid of a robot, the device including a first connection module and a second connection module, each including a capture and/or release section that is active in a capture and/or release phase and a guide section that is active in a guide phase, and the first connection module and the second connection module being lockable in a holding position. An aerial vehicle capable of automatedly vertically taking off, vertically landing, or being handled with the aid of a robot, the aerial vehicle including a first connection module or a second connection module of such a device. An end effector for a robot for the automated vertical take-off, vertical landing, and/or handling of an aerial vehicle, the end effector including a second connection module or a first connection module of such a device.

An access management system includes a mobile device with a processor and a memory and a software platform including at least a processor and a memory. The software platform is configured to analyze data obtained from the mobile device and other devices connected to the software platform. Specifically, the software platform is operable to determine if an access key received, read, or captured by a mobile device matches an access key for an authorized account, object, device, or space for the mobile device, and to provide access to the mobile device if the access key received, read, or captured by the mobile device matches the authorized access key.

An access management system includes a mobile device with a processor and a memory and a software platform including at least a processor and a memory. The software platform is configured to analyze data obtained from the mobile device and other devices connected to the software platform. Specifically, the software platform is operable to determine if an access key received, read, or captured by a mobile device matches an access key for an authorized account, object, device, or space for the mobile device, and to provide access to the mobile device if the access key received, read, or captured by the mobile device matches the authorized access key.

A package unloading and conveying system including a landing platform and one or more container aligning linear rails. The container aligning linear rails for aligning, on or above the landing platform and a hold of an aerial vehicle placed in front of one of multiple conveyor belts. One or more package extracting tools adapted to push or pull the package out of the aligned hold into a container aligned with one of the multiple conveyor belts. The multiple rail arrangements each adapted to convey the container to one of the multiple building windows from one of the multiple conveyors.

An access management system includes a mobile device with a processor and a memory and a software platform including at least a processor and a memory. The software platform is configured to analyze data obtained from the mobile device and other devices connected to the software platform. Specifically, the software platform is operable to determine if an access key received, read, or captured by a mobile device matches an access key for an authorized account, object, device, or space for the mobile device, and to provide access to the mobile device if the access key received, read, or captured by the mobile device matches the authorized access key.

A vehicle includes, on its roof, a first autonomous driving sensor, a second autonomous driving sensor, and a takeoff and landing assist device. The first autonomous driving sensor is disposed adjacent to the front of the vehicle for sensing conditions ahead of the vehicle. The second autonomous driving sensor is disposed adjacent to the rear of the vehicle for sensing conditions behind the vehicle. The takeoff and landing assist device includes a takeoff and landing surface where a flying device takes off and lands. The takeoff and landing assist device is disposed between the first autonomous driving sensor and the second autonomous driving sensor.

A vehicle includes, on its roof, a first autonomous driving sensor, a second autonomous driving sensor, and a takeoff and landing assist device. The first autonomous driving sensor is disposed adjacent to the front of the vehicle for sensing conditions ahead of the vehicle. The second autonomous driving sensor is disposed adjacent to the rear of the vehicle for sensing conditions behind the vehicle. The takeoff and landing assist device includes a takeoff and landing surface where a flying device takes off and lands. The takeoff and landing assist device is disposed between the first autonomous driving sensor and the second autonomous driving sensor.