The present disclosure provides for a device and system for aqueous wave measurement. The system may comprise at least one altimeter that may collect one or more measurements from a vertical orientation. The system may comprise at least one stabilization sensor that may interface with at least one positioning device. The stabilization sensor may, with fixed coordinates received from the positioning device, allow the drone to maintain a constant altitude above the variable, changing surface of water. The system may comprise one or more analytics that produce meaningful metrics from information received from the aqueous wave measurement device. The system may comprise at least one GUI that presents the analytics in an understandable way based on the expertise of a user viewing the analytics. The device may store collected measurements locally, or may transmit the measurements via at least one transmitting device, or both.

Disclosed is a method for assisting in the location of an engulfed element in a predetermined search zone, implemented by a location assistance system including at least a plurality of patrollers including at least one drone, the method including at least the following steps: arrival of the drone at the predetermined search zone; determination by the drone, of the topography of the predetermined search zone; division of the predetermined search zone into areas, by the drone, depending on the topography and the capabilities of each patroller, and assigning of each area to at least one patroller; searching for the engulfed element in each search zone by the at least one patroller assigned to the area; and periodic inter-patroller communication at least until the at least one engulfed element is located.

A detection system for detecting underwater conditions according to an embodiment or embodiments may include an aerial vehicle and a suspended device suspended from the aerial vehicle, wherein the suspended device includes a detecting section that performs an underwater detection operation, and a position information acquisition section that acquires position information.

The management server 2 acquires sensing information obtained by the UAV 1 sensing, from the sky, a scatter area where a colcothar is scattered on a mountain climbing route, identifies a state of the colcothar on the basis of the sensing information, and identifies a visual recognition difficult place on the basis of the state of the colcothar.

An imaging system can include a first and second camera configured to capture first and second sets of oblique images along first and second scan paths, respectively, on an object area. A drive is coupled to a scanning mirror structure, having at least one mirror surface, and configured to rotate the structure about a scan axis based on a scan angle. The first and second cameras each have an optical axis set at an oblique angle to the scan axis and include a respective lens to focus first and second imaging beams reflected from the mirror surface to an image sensor located in each of the cameras. The first and second imaging beams captured by their respective cameras can vary according to the scan angle. Each of the image sensors captures respective sets of oblique images by sampling the imaging beams at first and second values of the scan angle.

A system that combines aerial surveying and spraying services in a single remotely piloted aircraft (RPA) popularly known as Drone, in a multirotor configuration, with electric propulsion and power system with hybrid power supply (battery and motor-generator) and vertical take-off and landing (VTOL) system, wherein, the equipment allows, from the coupling of a set comprising aerial survey sensors such as a high definition camera and equipment aimed at spraying activities such as pumps and nozzles, aerial surveying practices, geoprocessing and spraying of chemical substances such as pesticide, herbicide, larvicide, fungicide and fertilizer, or other liquid agricultural products using a single vehicle a vehicle is also provided that is prepared to carry out the described system being a remotely piloted aircraft intended for aerial surveying and spraying activities.

An imaging system can include a first and second camera configured to capture first and second sets of oblique images along first and second scan paths, respectively, on an object area. A drive is coupled to a scanning mirror structure, having at least one mirror surface, and configured to rotate the structure about a scan axis based on a scan angle. The first and second cameras each have an optical axis set at an oblique angle to the scan axis and include a respective lens to focus first and second imaging beams reflected from the mirror surface to an image sensor located in each of the cameras. The first and second imaging beams captured by their respective cameras can vary according to the scan angle. Each of the image sensors captures respective sets of oblique images by sampling the imaging beams at first and second values of the scan angle.

A method includes determining current coordinates and a current elevation setting of a first unmanned aerial vehicle that is to be deployed to a candidate location for a microwave radio dish, receiving expected coordinates and an expected elevation setting of a second unmanned aerial vehicle that is deployed to a location of an existing cellular base station, calculating an angle necessary to direct a flash of light from the first unmanned aerial vehicle toward the expected coordinates and expected elevation setting of the second unmanned aerial vehicle, adjusting a current angle of an optical system of the first unmanned aerial vehicle to match the angle that is calculated, and sending a dataset to a centralized computing device, wherein the dataset includes at least an elevation setting of the first unmanned aerial vehicle at a time of capture of an image of the flash by the second unmanned aerial vehicle.

The present disclosure is directed to a camera configured to capture a set of oblique images along a scan path on an object area; a scanning mirror structure including at least one surface for receiving light from the object area, the at least one surface having at least one first mirror portion at least one second portion comprised of low reflective material arranged around a periphery of the first mirror portion, the low reflective material being less reflective than the first mirror portion; and a drive coupled to the scanning mirror structure and configured to rotate the scanning mirror structure about a rotation axis based on a scan angle. The at least one second portion can be configured to block light that would pass around the first mirror portion and be received by the camera at scan angles beyond the set of scan angles.

This disclosure is related to positioning one or more glass plates between an image sensor and lens of a camera in a scanning camera system; determining plate rotation rates and plate rotation angles based on one of characteristics of the camera, characteristics and positioning of the one or more glass plates, and relative dynamics of the camera and the object area; and rotating the one or more glass plates about one or more predetermined axes based on corresponding plate rotation rates and plate rotation angles.