Systems and methods are disclosed for detecting crosswalk locations. Crosswalk locations can be detected by determining at least two painted lines on a road surface, and then combining the at least two painted lines on the road surface into a grouping of related elements. The grouping of related elements can be classified into a crosswalk (or in some embodiments a type of crosswalk) based on attributes of the grouping of related elements, where the attributes of the grouping of the elements includes a distance between the at least two painted lines, and an orientation of the grouping of related elements on the road surface.

Systems and methods are disclosed for detecting crosswalk locations. Crosswalk locations can be detected by determining at least two painted lines on a road surface, and then combining the at least two painted lines on the road surface into a grouping of related elements. The grouping of related elements can be classified into a crosswalk (or in some embodiments a type of crosswalk) based on attributes of the grouping of related elements, where the attributes of the grouping of the elements includes a distance between the at least two painted lines, and an orientation of the grouping of related elements on the road surface.

Systems and methods are disclosed for detecting crosswalk locations. Crosswalk locations can be detected by determining at least two painted lines on a road surface, and then combining the at least two painted lines on the road surface into a grouping of related elements. The grouping of related elements can be classified into a crosswalk (or in some embodiments a type of crosswalk) based on attributes of the grouping of related elements, where the attributes of the grouping of the elements includes a distance between the at least two painted lines, and an orientation of the grouping of related elements on the road surface.

Systems and methods are disclosed for detecting crosswalk locations. Crosswalk locations can be detected by determining at least two painted lines on a road surface, and then combining the at least two painted lines on the road surface into a grouping of related elements. The grouping of related elements can be classified into a crosswalk (or in some embodiments a type of crosswalk) based on attributes of the grouping of related elements, where the attributes of the grouping of the elements includes a distance between the at least two painted lines, and an orientation of the grouping of related elements on the road surface.

The present disclosure relates to a method, a device and a system for inspecting a moving object based on cosmic rays, pertaining to the field of radiation imaging and safety inspection techniques. The method includes: detecting whether a speed of the inspected moving object is within a preset range; recording a motion trajectory of the moving object with a monitoring device; acquiring information about charged particles in the cosmic rays with a position sensitive detector, the information about charged particles including track information of the charged particles; determining the moving object by matching positions of the motion trajectory and the track information; reconstructing the track of the charged particles according to the information about the charged particles; and recognizing the material inside the moving object based on the track reconstruction.

The present application relates to a method, apparatus and system for inspecting an object based on a cosmic ray, pertaining to the technical field of radiometric imaging and safety inspection. The method includes: recording a movement trajectory of an inspected object by using a monitoring device; acquiring information of charged particles in the cosmic ray by using a position-sensitive detector, the information of charged particles comprising trajectory information of the charged particles; performing position coincidence for the movement trajectory and the trajectory information to determine the object; performing trajectory remodeling for the charged particles according to the information of charged particles; and identifying a material inside the moving object according to the trajectory remodeling. According to the present disclosure, pedestrians who are walking and moving are inspected by using the cosmic ray, and nuclear materials, drugs and explosive materials and the like carried by human bodies may be detected.

A method and device for measuring the magnetic rigidity of penetrating charged particles uses an elongated transparent ionizable medium, surrounded by a reflective interface, extending along a helical path around a longitudinal axis. A magnet applies a magnetic field to the medium in a direction along the longitudinal axis. A single luminosity proportional photon detector is operationally associated with the medium and adapted to generate signals indicative of the number of photons transiting the medium. A controller is adapted to receive the signals and calculate a penetration depth of the ionizing particle through the medium based on the number of photons transiting the medium and a magnetic rigidity of the charged particle based upon the penetration depth.

A method and device for measuring the magnetic rigidity of penetrating charged particles uses an elongated transparent ionizable medium, surrounded by a reflective interface, extending along a helical path around a longitudinal axis. A magnet applies a magnetic field to the medium in a direction along the longitudinal axis. A single luminosity proportional photon detector is operationally associated with the medium and adapted to generate signals indicative of the number of photons transiting the medium. A controller is adapted to receive the signals and calculate a penetration depth of the ionizing particle through the medium based on the number of photons transiting the medium and a magnetic rigidity of the charged particle based upon the penetration depth.

Devices and methods for detecting radiation-induced cell damage by directly measuring DNA damage resulting from delivered radiation exposure is disclosed herein. The device can measure the rate of DNA double-strand break, which is the dominant factor for radiation induced cell damage. This approach enables more accurate measurements as compared to current exposure-based dosimetry. In embodiments, the device is comprised of magnetic streptavidin beads and strands of DNA configured with a biotin on one end and fluorescein on the other.

Devices and methods for detecting radiation-induced cell damage by directly measuring DNA damage resulting from delivered radiation exposure is disclosed herein. The device can measure the rate of DNA double-strand break, which is the dominant factor for radiation induced cell damage. This approach enables more accurate measurements as compared to current exposure-based dosimetry. In embodiments, the device is comprised of magnetic streptavidin beads and strands of DNA configured with a biotin on one end and fluorescein on the other.