A portable survey meter for measuring radiation, the portable survey meter comprising: a radiation detector configured to perform measurements of radiation; a range sensor configured to measure range data of distances from the portable survey meter to real world structures in at least two dimensions; and a processing unit configured to align the measured range data with reference range data so as to determine an instantaneous position of the portable survey meter in at least two dimensions relative to the real world structures as a fixed frame of reference, whereby each measurement is performed at a known position.

A portable survey meter for measuring radiation, the portable survey meter comprising: a radiation detector configured to perform measurements of radiation; a range sensor configured to measure range data of distances from the portable survey meter to real world structures in at least two dimensions; and a processing unit configured to align the measured range data with reference range data so as to determine an instantaneous position of the portable survey meter in at least two dimensions relative to the real world structures as a fixed frame of reference, whereby each measurement is performed at a known position.

An integrated monitoring system for radiological surveillance of groundwater and an operation method thereof are disclosed. The integrated monitoring system for radiological surveillance of groundwater around a nuclear facility according to an embodiment of the present disclosure may include a field monitoring system configured to monitor sectionally isolated groundwater characteristics by establishing a multiple packer system at each depth in groundwater around the nuclear facility, and measure whether or not radioactive contamination has occurred at each depth in groundwater pumped through an automatic branching apparatus connected to a sectional groundwater flow pipe isolatedly disposed at the each depth, and convert field measurement data acquired based on the measurement result into a DB and transmit the DB to a remote monitoring apparatus over a network, and the remote monitoring apparatus configured to remotely control the field monitoring system, and receive the DB-based field measurement data from the field monitoring system, and analyze the received field measurement data to predict a radioactive contaminant source, and provide a contaminant plume showing the distribution characteristics of contaminants in 3D graphic processing.

An integrated monitoring system for radiological surveillance of groundwater and an operation method thereof are disclosed. The integrated monitoring system for radiological surveillance of groundwater around a nuclear facility according to an embodiment of the present disclosure may include a field monitoring system configured to monitor sectionally isolated groundwater characteristics by establishing a multiple packer system at each depth in groundwater around the nuclear facility, and measure whether or not radioactive contamination has occurred at each depth in groundwater pumped through an automatic branching apparatus connected to a sectional groundwater flow pipe isolatedly disposed at the each depth, and convert field measurement data acquired based on the measurement result into a DB and transmit the DB to a remote monitoring apparatus over a network, and the remote monitoring apparatus configured to remotely control the field monitoring system, and receive the DB-based field measurement data from the field monitoring system, and analyze the received field measurement data to predict a radioactive contaminant source, and provide a contaminant plume showing the distribution characteristics of contaminants in 3D graphic processing.

Disclosed herein is an apparatus comprising an insertion tube; an image sensor inside the insertion tube; wherein the image sensor comprises an array of pixels; wherein the image sensor is configured to count numbers of particles of radiation incident on the pixels, within a period of time. Also disclosed herein is a method of using this apparatus.

Provided are an underwater radiation monitoring system and method. The monitoring system includes a plurality of sensors configured to measure a value of underwater radiation in a measurement area in which underwater radiation is to be measured, the plurality of sensors being installed in the measurement area by being arranged in a form which is set on the basis of information about the measurement area; and an electronic device configured to identify a value of underwater radiation in the measurement area on the basis of the values of underwater radiation measured by the plurality of sensors, wherein at least one first sensor among the plurality of sensors is connected to the electronic device to collect measured values obtained from the at least one first sensor and a plurality of second sensors excluding the at least one first sensor and to transmit the collected measured values to the electronic device.

Provided are an underwater radiation monitoring system and method. The monitoring system includes a plurality of sensors configured to measure a value of underwater radiation in a measurement area in which underwater radiation is to be measured, the plurality of sensors being installed in the measurement area by being arranged in a form which is set on the basis of information about the measurement area; and an electronic device configured to identify a value of underwater radiation in the measurement area on the basis of the values of underwater radiation measured by the plurality of sensors, wherein at least one first sensor among the plurality of sensors is connected to the electronic device to collect measured values obtained from the at least one first sensor and a plurality of second sensors excluding the at least one first sensor and to transmit the collected measured values to the electronic device.

An unmanned aerial vehicle may include a GPS configured to provide location coordinates for the unmanned aerial vehicle during flight and an ionization filter configured to trap radioactive particles. The unmanned aerial vehicle includes a radiation detector configured to measure radiation emitted from the trapped radioactive particles, and a memory device configured to store and associate the GPS coordinates and the measured radiation.

An unmanned aerial vehicle may include a GPS configured to provide location coordinates for the unmanned aerial vehicle during flight and an ionization filter configured to trap radioactive particles. The unmanned aerial vehicle includes a radiation detector configured to measure radiation emitted from the trapped radioactive particles, and a memory device configured to store and associate the GPS coordinates and the measured radiation.

A large-area directional radiation detection system may include a large number of slab-shaped detectors stacked side-by-side comprising alternate long and short detectors, where the long detectors are longitudinally longer than the short detectors. The long detectors may collimate or restrict the lateral field of view of the short detectors, so that a particular short detector that is aligned with the source has an unobstructed view of the source. By comparing detection distributions in the long and short detectors, a processor can determine the angular position and distance of a source. The high detection efficiency and large solid angle of the detector array may enable rapid detection of even well-shielded threat sources at substantial distances, while simultaneously determining the positions of any sources detected.