Abstract: Radiation source localization systems and related techniques are provided to improve the operation of handheld or unmanned mobile sensor or survey platforms. A radiation source localization system includes a logic device configured to communicate with a communications module and a directional radiation detector, where the communications module is configured to establish a wireless communication link with a base station associated with the directional radiation detector and/or a mobile sensor platform, and the directional radiation detector includes a sensor assembly configured to provide directional radiation sensor data as the directional radiation detector is maneuvered within a survey area.

Abstract: Various techniques are disclosed for encoding and communicating detection results. In one example, a device includes a detector configured to capture measurement data in response to an external source. The device further includes one or more processors. The detection device further includes one or more memories including instructions stored therein, which when executed by the one or more processors, cause the one or more processors to perform operations. The operations include analyzing the measurement data to generate detection results. The operations further include generating a quick response (QR) code encoding at least a portion the detection results. The operations further include providing the QR code for access by an external device. Additional devices and related methods are also provided.

Abstract: Various techniques are provided to detect the direction and location of one or more radiation sources. In one example, a system includes a plurality of radiation detectors configured to receive radiation from a radiation source. A first one of the radiation detectors is positioned to at least partially occlude a second one of the radiation detectors to attenuate the radiation received by the second radiation detector. The system also includes a processor configured to receive detection information provided by the first and second radiation detectors in response to the radiation, and determine a direction of the radiation source using the detection information. A modular system including gamma radiation detectors and neutron radiation detectors and related methods are also provided. In some cases, radiation source type may be determined in addition to or separate from radiation source direction.

Abstract: Radiation source localization systems and related techniques are provided to improve the operation of handheld or unmanned mobile sensor or survey platforms. A radiation source localization system includes a logic device configured to communicate with a communications module and a directional radiation detector, where the communications module is configured to establish a wireless communication link with a base station associated with the directional radiation detector and/or a mobile sensor platform, and the directional radiation detector includes a sensor assembly configured to provide directional radiation sensor data as the directional radiation detector is maneuvered within a survey area.

Abstract: Various techniques are provided to detect the direction and location of one or more radiation sources. In one example, a system includes a plurality of radiation detectors configured to receive radiation from a radiation source. A first one of the radiation detectors is positioned to at least partially occlude a second one of the radiation detectors to attenuate the radiation received by the second radiation detector. The system also includes a processor configured to receive detection information provided by the first and second radiation detectors in response to the radiation, and determine a direction of the radiation source using the detection information. A modular system including gamma radiation detectors and neutron radiation detectors and related methods are also provided. In some cases, radiation source type may be determined in addition to or separate from radiation source direction.

Abstract: Various techniques are disclosed for encoding and communicating detection results. In one example, a device includes a detector configured to capture measurement data in response to an external source. The device further includes one or more processors. The detection device further includes one or more memories including instructions stored therein, which when executed by the one or more processors, cause the one or more processors to perform operations. The operations include analyzing the measurement data to generate detection results. The operations further include generating a quick response (QR) code encoding at least a portion the detection results. The operations further include providing the QR code for access by an external device. Additional devices and related methods are also provided.

Abstract: A method, and an apparatus to perform the method, of determining a location of a medical instrument in a patient during a medical procedure, the method including connecting at least a portion of the medical instrument to a first body region of the patient, propagating a plurality of signals at different frequencies along a conductive path of the medical instrument, measuring one or more feedback parameters corresponding to each of the plurality of signals at the first body region, determining an operational frequency from the different frequencies according to a comparison of the one or more feedback parameters, propagating a signal having the operational frequency along the conductive path as the medical instrument penetrates the body of the patient during the medical procedure, and measuring the one or more feedback parameters corresponding to the operational frequency to determine a penetration location of the medical instrument in the body of the patient.

Abstract: A light-diffusing safety cap for use with a light cable that couples an endoscope to a high intensity light source. The light-diffusing safety cap can be detachably or releasably coupled, in lieu of the endoscope, to the light cable, such that when the high intensity light source emits a high intensity light and the endoscope is not connected to the light cable, the light-diffusing safety cap reduces the intensity of the high intensity light emitted to the environment and provides an indication that the high intensity light source is activated when the endoscope is not connected to the light cable.

Abstract: A light-diffusing safety cap for use with a light cable that couples an endoscope to a high intensity light source. The light-diffusing safety cap can be detachably or releasably coupled, in lieu of the endoscope, to the light cable, such that when the high intensity light source emits a high intensity light and the endoscope is not connected to the light cable, the light-diffusing safety cap reduces the intensity of the high intensity light emitted to the environment and provides an indication that the high intensity light source is activated when the endoscope is not connected to the light cable.