Abstract: A differential emissivity imaging device for measuring evaporable particle properties can include a heated plate, a thermal camera, a memory device, and an output interface. The heated plate can have an upper surface oriented to receive falling evaporable particles. The evaporable particles have a particle emissivity and the upper surface has a plate surface emissivity. The thermal camera can be oriented to produce a thermal image of the upper surface. A memory device can include instructions that cause the imaging device to calculate a mass of the individual evaporable particle via heat conduction using a calculated surface area and an evaporation time.

Abstract: A differential emissivity imaging device for measuring evaporable particle properties can include a heated plate, a thermal camera, a memory device, and an output interface. The heated plate can have an upper surface oriented to receive falling evaporable particles. The evaporable particles have a particle emissivity and the upper surface has a plate surface emissivity. The thermal camera can be oriented to produce a thermal image of the upper surface. A memory device can include instructions that cause the imaging device to calculate a mass of the individual evaporable particle via heat conduction using a calculated surface area and an evaporation time.

Abstract: An imaging system for capturing movement of an object can include a camera configured to capture image data. The system can also include a first motion sensor and a second motion sensor configured to detect an object; and transmit a motion detection signal to a motion sensor controller indicating the position of the object when it was detected by the first and second motion sensors. The system can further include a motion sensor controller configured to receive the motion detection signal, determine, based on the motion detection signal, whether the object has entered the target space; and generate a camera activation signal in response to determining that the object has entered the target space. The system can also include a camera activation engine configured to receive a camera activation signal from the motion sensor controller, and activate the camera to capture image data of the target space.

Abstract: A technology is described for identifying hydrometeors. A method includes receiving an image of a hydrometeor captured using a camera. The hydrometeor in the image can be identified and analyzed to determine characteristics associated with the hydrometeor. Environmental measurements recorded substantially contemporaneously with the image can be obtained from environmental sensors located in proximity to the camera. A feature vector can be constructed using the hydrometeor characteristics and the environmental measurements. The feature vector can be input to a classification model used to classify the hydrometeor, and the classification model can output a classification for the hydrometeor using the feature vector.

Abstract: A technology is described for identifying hydrometeors. A method includes receiving an image of a hydrometeor captured using a camera. The hydrometeor in the image can be identified and analyzed to determine characteristics associated with the hydrometeor. Environmental measurements recorded substantially contemporaneously with the image can be obtained from environmental sensors located in proximity to the camera. A feature vector can be constructed using the hydrometeor characteristics and the environmental measurements. The feature vector can be input to a classification model used to classify the hydrometeor, and the classification model can output a classification for the hydrometeor using the feature vector.

Abstract: Imaging of falling objects is described. Multiple images of a falling object can be captured substantially simultaneously using multiple cameras located at multiple angles around the falling object. An epipolar geometry of the captured images can be determined. The images can be rectified to parallelize epipolar lines of the epipolar geometry. Correspondence points between the images can be identified. At least a portion of the falling object can be digitally reconstructed using the identified correspondence points to create a digital reconstruction.

Abstract: Imaging of falling objects is described. Multiple images of a falling object can be captured substantially simultaneously using multiple cameras located at multiple angles around the falling object. An epipolar geometry of the captured images can be determined. The images can be rectified to parallelize epipolar lines of the epipolar geometry. Correspondence points between the images can be identified. At least a portion of the falling object can be digitally reconstructed using the identified correspondence points to create a digital reconstruction.