Abstract: Suspension training systems include one or more bands, and one or more handles. The handles can be coupled to the bands, and transmit user-generated forces to the bands. The systems also include a force sensor that measures the user-generated forces acting on the bands, and a computing device that acquires and displays information relating to the exercise session. The systems can generate recommendations for future exercise sessions based on the acquired information, so that exercise sessions can be tailed to the specific needs and capabilities of the user.

Abstract: Interactive/smart resistance band training systems include one or more resistance bands connected to a force sensing unit that registers the force exerted by a user on handles connected to the bands. The sensing unit operates effectively regardless of whether the user is training with one handle individually, or with two handles being pulled in parallel or non-parallel directions. The systems may correct the force readings to account for non-alignment between the force-measurement axis of the force sensing unit and the directions in which the user applies force to the resistance bands. The systems may guide a user through exercise sessions tailored to the fitness level of the user; may display the force readings, calories burned, and other performance parameters and goals on a continuous, real-time basis; may summarize the result of the exercise session; and may recommend subsequent exercise sessions based on the performance of the user.

Abstract: The present invention relates to a body resistance physical exercise device with monitoring and fitness tracking capabilities, comprising: a) an electrical monitoring element configured to measure information relative to exercise parameters during repetitive motions performed with said device; and b) an elastomeric band adapted to enable the repetitive motions, wherein the resistance of the elastomeric band is capable of being adjusted.

Abstract: The present invention relates to a body resistance physical exercise device with monitoring and fitness tracking ties comprising: a) an electrical monitoring element configured to measure information relative to exercise parameters during repetitive motions performed with said device; and b) an elastomeric band adapted to enable the repetitive motions, wherein the resistance of the elastomeric band is capable of being adjusted.

Abstract: Example implementations associated with the aspects of the present invention include a low altitude aircraft identification system composed by three components: a small aircraft electronic identification box with an embedded logger, a ground identification equipment to automatically identify the aircraft just pointing at it, and an identification code database. The identification code can be transmitted by a visible light color sequence or by a radio frequency signal. The ground identification device is capable of recognizing both kinds of code.

Abstract: An indication of a detected security event is received. One or more sensors are selected based on the detected security event. The selected sensors are used to detect additional information associated with a protected airspace associated with the detected security event. A risk level assessment associated with the detected security event is determined based at least in part on the additional information detected using the selected sensors. A response is automatically invoked based on the determined risk level assessment.

Abstract: An aerial vehicle system comprises a radar system and a processor. The radar system is configured to transmit a radar signal. The transmitted radar signal is reflected off an object to produce a reflected radar signal. The radar system is configured to receive the reflected radar signal and provide a signature associated with the reflected radar signal. The signature has been adjusted based at least in part on a flight parameter of the aerial vehicle system. The processor is configured to classify the object as an unmanned aerial vehicle based on the adjusted signature and initiate an action based on a classification of the object.

Abstract: An aerial vehicle system includes a signal generator, a plurality of computing components, a plurality of communication antennas, a first structural component configured to at least in part block a noise signal generated by the signal generator from the plurality of computing components, and a second structural component configured to at least in part block the noise signal generated by the signal generator from the plurality of communication antennas, wherein the first structural component and the second structural component form a portion of a structural frame of the aerial vehicle system.

Abstract: An aerial vehicle system is comprised of a detector, a signal generator, and a transmitter. The detector is configured to detect a presence of a target unmanned aerial vehicle within a range of the aerial vehicle system. The signal generator is configured to generate a communication disruption signal. The transmitter is configured to trigger a transmission of the communication disruption signal based in part on the detected presence of the target unmanned aerial vehicle.

Abstract: A flight control operation of a reference aerial vehicle is performed. For example, an image captured by an image sensor of the reference aerial vehicle is received. A target is detected in the image. A three-dimensional relative location of the target with respect to the reference aerial vehicle is determined based on the image. The flight control operation is performed based on the three-dimensional relative location of the target with respect to the reference aerial vehicle.

Abstract: A spatio-temporal awareness engine combines a low-resolution tracking process and high resolution tracking process to employ an array of imaging sensors to track an object within the visual field. The system utilizes a low-resolution conversion through noise filtering and feature consolidation to load-balance the more computationally-intensive aspects of object tracking, allowing for a more robust system, while utilizing less computer resources. A process for target recovery and object path prediction in a robotic drone may include tracking targets using a combination of visual and acoustic multimodal sensors, operating a camera as a main tracking sensor of the multimodal sensors and feeding output of the camera to a spatiotemoral engine, complementing the main tracking sensor with non-visual, fast secondary sensors to assign rough directionality to a target tracking signal, and applying the rough directionality to prioritize visual scanning by the main tracking sensor.

Abstract: The present invention relates to a body resistance physical exercise device with monitoring and fitness tracking ties comprising: a) an electrical monitoring element configured to measure information relative to exercise parameters during repetitive motions performed with said device; and b) an elastomeric band adapted to enable the repetitive motions, wherein the resistance of the elastomeric band is capable of being adjusted.

Abstract: A spatio-temporal awareness engine combines a low-resolution tracking process and high resolution tracking process to employ an array of imaging sensors to track an object within the visual field. The system utilizes a low-resolution conversion through noise filtering and feature consolidation to load-balance the more computationally-intensive aspects of object tracking, allowing for a more robust system, while utilizing less computer resources. A process for target recovery and object path prediction in a robotic drone may include tracking targets using a combination of visual and acoustic multimodal sensors, operating a camera as a main tracking sensor of the multimodal sensors and feeding output of the camera to a spatiotemoral engine, complementing the main tracking sensor with non-visual, fast secondary sensors to assign rough directionality to a target tracking signal, and applying the rough directionality to prioritize visual scanning by the main tracking sensor.

Abstract: A wireless communication receiver is used to receive a wireless signal that identifies an identifier transmitted by an aircraft. A token value and a vehicle identifier are obtained from the received transmitted identifier. A secret corresponding to the vehicle identifier is obtained. A synchronized time value is obtained. A comparison token value is generated using the secret and the synchronized time value. The obtained token value and the generated comparison token value are compared to determine an authenticity of the received transmitted identifier.

Abstract: Example implementations associated with the aspects of the present invention include a low altitude aircraft identification system composed by three components: a small aircraft electronic identification box with an embedded logger, a ground identification equipment to automatically identify the aircraft just pointing at it, and an identification code database. The identification code can be transmitted by a visible light color sequence or by a radio frequency signal. The ground identification device is capable of recognizing both kinds of code.

Abstract: A system for identifying an unmanned aerial vehicle (UAV) detected in a location includes a reader device. The reader device includes a receiver configured to receive identification information transmitted from the UAV, and a transmitter configured to provide the received identification information to an identification server. The identification server includes a memory configured to store UAV registration information associated with the UAV, a receiver configured to receive the identification information provided by the reader device, and a processor configured to provide a verification of the identification information received by the reader based on the provided identification information and the stored UAV registration information.

Abstract: A touch pad system is disclosed. The system includes mapping the touch pad into native sensor coordinates. The system also includes producing native values of the native sensor coordinates when events occur on the touch pad. The system further includes filtering the native values of the native sensor coordinates based on the type of events that occur on the touch pad. The system additionally includes generating a control signal based on the native values of the native sensor coordinates when a desired event occurs on the touch pad.

Abstract: Example implementations associated with the aspects of the present invention include a low altitude aircraft identification system composed by three components: a small aircraft electronic identification box with an embedded logger, a ground identification equipment to automatically identify the aircraft just pointing at it, and an identification code database. The identification code can be transmitted by a visible light color sequence or by a radio frequency signal. The ground identification device is capable of recognizing both kinds of code.

Abstract: A flight control operation of a reference aerial vehicle is performed. For example, an image captured by an image sensor of the reference aerial vehicle is received. A target is detected in the image. A three-dimensional relative location of the target with respect to the reference aerial vehicle is determined based on the image. The flight control operation is performed based on the three-dimensional relative location of the target with respect to the reference aerial vehicle.

Abstract: Example implementations associated with the aspects of the present invention include a low altitude aircraft identification system composed by three components: a small aircraft electronic identification box with an embedded logger, a ground identification equipment to automatically identify the aircraft just pointing at it, and an identification code database. The identification code can be transmitted by a visible light color sequence or by a radio frequency signal. The ground identification device is capable of recognizing both kinds of code.