A drone comprising a camera and a controller. The camera is configured to output data representing an object within a field of view of the camera. The controller is configured to attempt to maintain a visual line of sight with the object. The controller is also configured to cause control equipment of an operator of the drone to notify the operator of the drone, visually, audibly and/or haptically, as to whether or not the object is being tracked by the drone.

Embodiments describe a computer-implemented method for generating a flight plan for a remote deployable transient sensory system using a coverage path planning system. The method includes generating, using the remote deployable transient sensory system, a first sensory dataset comprising sensory data associated with a plurality of building envelope features associated with a built environment, building a second sensory dataset comprising a 3-dimensional (3-D) point cloud model using the first sensory dataset and identifying, in the 3-D point cloud, via the processor, a plurality of virtual energy efficiency features associated with respective energy efficiency feature locations of the building. The system generates the flight plan based on a flight metric optimization scheme.

A system for providing a universal computing node for use in a smart self-healing node centric blockchain mesh network includes one or more programmable processing components, a communications network interface for communicating over the Internet, one or more local sensors, a blockchain ledger, a data store of useful data from the local sensors, AIML processing components, specific local functions to support one or more local hardware functions, and a local data store. The one or more programmable processing components execute a set of software components within the universal computing node that include a node controller for coordinating the interaction and processing of the set of software components when generating, storing, and retrieving blockchain data records, a web interface for transmitting and receiving data between the universal computing node and one or more additional universal computing nodes and one or more servers connected to the smart self-healing node centric blockchain mesh network, the blockchain processor for generating blockchain data records to be stored within the blockchain ledger, and a sensor interface for receiving data to be stored within one or more blockchain data records.

An environmental monitoring network has transportable, self-contained, environment sensing capsules, each capsule is water-proof, with first and second sections, the second section being hollow. Apertures in the capsule's housing enable fluid and gas entry wherein first sensor(s) disposed internal to the housing measure within the hollow, and second sensor(s) disposed external to the housing measure external to the housing. A controller and power system are connected to the first and second sensors and transmits measured data. An access entry way is on a side of the housing, enabling access to first sensors, controller system, power system, and the communication system. A central data server is configured to receive and analyze the measurement data sent from the capsules. There is a priority list of appropriate personnel for contact by the central data server in an event there is an emergency condition at a capsule location.

A computer receives a hotspot and a corresponding incentive, where the hotspot is a geolocation for collecting the weather data. The computer presents the received hotspot and the corresponding incentive to a user. The computer receives the weather data from the drone, transmits the weather data to a server, and updates a scorecard with the incentive corresponding to the hotspot based on determining that the drone reached the hotspot.

A Remote Drop Zone Atmospherics and Marking Platform provides wind speed and direction information to parachutists or operators who are using parachutes to deliver a parachutist or autonomous load to the ground.

A wind direction and a wind speed are readily and accurately estimated at a desired position without using a wind direction and velocity sensor. Movement instruction means of a wind estimation system instructs an unmanned aerial vehicle (UAV), which includes a sensor unit that detects information about a position change, to move. Fall control means causes the UAV to free fall after the UAV is moved according to the instruction of the movement instruction means. Estimation means estimates at least one of a wind direction and a wind speed at a fall position based on the information about the position change detected by the sensor unit during a fall of the UAV.

A method for calibrating a target gas sensor inside a drone comprises receiving air flow at the target sensor due to least one of diverted propeller air flow or diverted air flow caused by drone flight, measuring a concentration of the target gas, receiving equivalent air flow at a sensor of at least one reference gas having known atmospheric concentration positioned in or on the drone, measuring a concentration of the at least one reference gas, and calibrating the measured concentration of the target gas based on the measured concentration of the at least one reference gas.

The present disclosure relates to a system for generating a weather map. The system comprises a mobile device configured to move to first locations within an environment and obtain first weather data indicative of a weather condition at the first locations by using a sensor. Further, the system comprises a data processing circuitry configured to generate a weather map including a probability distribution of weather conditions between the first locations by applying a predetermined weather model to the first weather data. The data processing circuitry is further configured to determine second locations through a threshold comparison of the probability distribution. The mobile device is further configured to move to the second locations and obtain second weather data indicative of a weather condition at the second locations, by using the sensor, for increasing a confidence of the weather map using the second weather data.

Systems and methods of calculating a ballistic solution for a projectile are provided. A ballistic system may include an airborne device, a ballistic computer, a data interface, and a flight module, or any combination thereof. The airborne device (e.g., a drone) may be operable to gather wind data along or adjacent to a flight path of a projectile to a target. The ballistic computer may be in data communication with the airborne device to receive the wind data. The ballistic computer may be configured to calculate a ballistic solution for the projectile based on the wind data. The data interface may be in data communication with the ballistic computer to output the ballistic solution to a user. The flight module may be configured to calibrate a flight path of the airborne device.