Abstract: An imaging system includes a platform having mounted thereon a coded-aperture imaging device and positioned to receive radiation over a baseline, and a computer configured to acquire a plurality of far-field datasets over the baseline, the plurality of far-field datasets comprising data received via the coded-aperture imaging device, form a first image from the plurality of far-field datasets, and form a second image if the first image indicates presence of a source, the second image formed from the plurality of far-field datasets using an estimated source location from the first image and thereby having a higher contrast than the first image.

Abstract: Systems, methods, and related computer program products for image-guided radiation treatment (IGRT) are described. Provided according to one preferred embodiment is an IGRT apparatus including a barrel-style rotatable gantry structure that provides high mechanical stability, versatility in radiation delivery, and versatility in target tracking. Methods for treatment radiation delivery using the IGRT apparatus include conical non-coplanar rotational arc therapy and cono-helical non-coplanar rotational arc therapy. A radiation treatment head (MV source) and a treatment guidance imaging system including a kV imaging source are mounted to and rotatable with a common barrel-style rotatable gantry structure, or alternatively the MV and kV sources are mounted to separate barrel-style rotatable gantry structures independently rotatable around a common axis of rotation.

Abstract: An electromagnetic-wave generation device including an emitter section including a first electrode, a collector section including a second electrode, a carrier-travel section placed between the emitter section and the collector section, a voltage-application unit configured to apply a voltage so that a potential of the second electrode becomes higher than a potential of the first electrode, and a light-irradiation unit configured to radiate light is provided, where the carrier-travel section includes a first semiconductor extending along a direction in which an electron carrier travels, and where the emitter section includes a second semiconductor that is formed in contact with the first semiconductor, and that achieves a potential barrier, and is configured so that the carrier goes beyond the potential barrier and is emitted to the carrier-travel section only when being irradiated with the light.

Abstract: One embodiment relates to a method for determining a concentration of a molecular species of interest. In this method, electromagnetic radiation is transmitted into a volume of gas within an output exhaust system. The transmitted electromagnetic radiation has a first intensity at a characteristic frequency that is associated with a transition of the molecular species of interest. Electromagnetic radiation is then received from the volume of gas at a second intensity. The method then correlates the first intensity to the second intensity to determine the concentration of the molecular species of interest within the volume of gas. Other methods and systems are also disclosed.

Abstract: A target for measuring an overlay error or a critical dimension of a substrate comprises a grating. In one example, lines of the grating are arranged at an angle of about 45° with respect to edges of the target.

Abstract: A sensor system comprises an entangled quantum generator operable to generate an entangled quanta signal including a plurality of entangled quanta. A carrier signal generator generates a carrier signal that includes electromagnetic field (EMF) pulses. The power of the carrier signal is less than the power required to ionize a propagating medium through which the carrier signal is traveling. A beam combiner is configured to output a combined signal that includes the entangled quanta signal in an EMF pulse of the carrier signal. A quantum detector is configured to detect a return signal based on the combined signal being reflected by a target.

Abstract: The invention provides a switchable photomultiplier switchable between a detecting state and a non-detecting state including a cathode upon which incident radiation is arranged to impinge. The photomultiplier also includes a series of dynodes arranged to amplify a current created at the cathode upon detection of photoradiation. The invention also provides a detection system arranged to detect radiation-emitting material in an object. The system includes a detector switchable between a detecting state in which the detector is arranged to detect radiation and a non-detecting state in which the detector is arranged to not detect radiation. The system further includes a controller arranged to control switching of the detector between the states such that the detector is switched to the non-detecting state whilst an external radiation source is irradiating the object.

Abstract: An apparatus for investigating a sample comprising: a source of beam radiation; a detector for detecting a beam of radiation reflected by the sample and an optical subsystem for manipulating the beam between source and detector wherein the optical subsystem comprises a first optical element arranged in use to angularly deflect the source beam within a given solid angle and a second optical element arranged to focus the beam from the first optical element onto a substantially flat image plane and wherein radiation reflected by the sample passes back through the first and second optical elements to the detector.

Abstract: A movable device for measuring physical quantities of nuclear materials contained in a shielded cell, which device can be brought up against the shielded cell and can be retracted therefrom, the device configured to carry out the measurement in the position in which it is against the shielded cell. The device includes a carriage, a support member placed on the carriage, and a shielded container placed on the support member. The shielded container includes a transfer container configured to store the nuclear material to be measured, and an opening configured to be aligned with an opening in one wall of the shielded cell. The support member is made of graphite and includes a housing accommodating a neutron emission module, a casing covering the shielded container, the casing being made of graphite, and a neutron measurement mechanism fastened to the casing.

Abstract: In an X ray imaging system, a rotational support device supports an X ray source in a rotatable manner, to adjust an orientation angle thereof. An angle detector is disposed on the X ray source removably, for detecting the orientation angle. A shift determiner operates when the X ray source is moved pivotally, and determines a shift amount for an FPD device to a position opposed to the X ray source according to the orientation angle from the angle detector and a distance between the X ray source and the FPD device. A pseudo signal generator generates a pseudo signal of a level irrespective of the shift amount by correcting a detection signal from a shift detector according to the shift amount from the shift determiner, and supplies a second moving device with the pseudo signal. Movement of the FPD device is controlled according to the shift amount.

Abstract: The present invention is a cargo inspection system, employing a radiation source, capable of scanning vehicles and/or cargo in a wide range of sizes, including conventional imaging areas as well as taller and bulkier enclosures at sufficiently optimal efficacy and overall throughput. In one embodiment, the present invention is a multiple pass inspection method for inspecting vehicles and their cargo, comprising a first pass scan, wherein said first pass scan includes moving a radiation source at a suitable scanning distance, rotating a radiation source at a suitable scanning angle, and moving said radiation source along an object under inspection.

Abstract: An angle-responsive sensor, comprising: a radiation detector adapted to detect ionizing radiation; at least one radiation absorbing element arranged to block radiation from reaching said detector in a manner dependent on a relative orientation of a radiation source, said detector and said element, said detector and said element defining an aim for said sensor; and circuitry coupled to said detector and which generates an output signal which varies as a function of said relative orientation, wherein said detector and said element are arranged to have a working volume of at least 10 cm in depth and having an angular width, such that said signal defines an accuracy of better than 3 mm within one standard deviation, over said working volume.

Abstract: A multi-touch and proximate object sensing apparatus using a sensing array is provided. The multi-touch and proximate object sensing apparatus may sense a touch image or a target image by sensing an invisible light which is projected to a diffuser through the sensing array. Also, the multi-touch and proximate object sensing apparatus may display an image on a display panel by controlling a location of the sensing array and a visible light source, without a backlight unit.

Abstract: A diagnostic imaging system and method using multiple types of imaging detectors are provided. The imaging system includes a gantry having a rotor and a stator and a pair of gamma detectors coupled to the rotor. The imaging system further includes a gamma detector coupled to the stator. The gamma detector coupled to the stator is different than the pair of gamma detectors coupled to the rotor.

Abstract: A radiation-based timer for use in an implantable medical device (IMD) includes a radiation source and a radiation detection circuit. The radiation source emits radiation particles during a process referred to as radioactive decay. The radiation detection circuit detects the radiation particles emitted during the decay process and tracks the number of radiation particles detected. When the number of radiation particles detected reaches a threshold value, a timer signal is generated. In this manner, the radiation-based timer generates a timer signal as a function of the radioactive decay of the radiation source. The timer signal may be used by one or more components of the IMD for any of a number of functions, including as a wakeup trigger for a communications and/or a sensor event.

Abstract: The present invention relates to an imaging apparatus for generating an image of a region of interest. The imaging apparatus comprises a radiation source (2), a detection unit (6) for generating detection data and a moving unit (1, 7, 8) for moving the radiation source (2) and the region of interest relative to each other, while the detection data are generated. The imaging apparatus further comprises an identification unit (13) for identifying in the detection data high density detection data and non-high density detection data. A density weighting unit (14) density weights the detection data, wherein at least a part of the high density detection data has a smaller density weight than the non-high density detection data, and a reconstruction unit (15) reconstructs an image of the region of interest from the weighted detection data.

Abstract: A ground-based system that provides quasi real-time measurement and collection of snow-water equivalent (SWE) data in remote settings is provided. The disclosed invention is significantly less expensive and easier to deploy than current methods and less susceptible to terrain and snow bridging effects. Embodiments of the invention include remote data recovery solutions. Compared to current infrastructure using existing SWE technology, the disclosed invention allows more SWE sites to be installed for similar cost and effort, in a greater variety of terrain; thus, enabling data collection at improved spatial resolutions. The invention integrates a novel computational architecture with new sensor technologies. The invention's computational architecture is based on wireless sensor networks, comprised of programmable, low-cost, low-powered nodes capable of sophisticated sensor control and remote data communication.

Abstract: A radiation imaging operation, wherein a radiation source irradiates radiation to an object, while the radiation source is being moved in one direction, is performed a plurality of times with the radiation source taking various different positions. A radiation detector is reciprocally moved within a period, during which the radiation source is moved in the one direction from a stage of beginning of the plurality of times of the radiation imaging operations to a stage of finishing of the plurality of times of the radiation imaging operations. The radiation detector is moved in a direction opposite to the one direction of the movement of the radiation source within each of radiation imaging operation periods.

Abstract: A sensor device, in particular for an image recorder for recording any desired radiation, in particular electromagnetic radiation, X-ray radiation, gamma radiation or some other particle radiation has a plurality of sensor layers which are arranged above one another and each have sensor elements. In each sensor layer, coefficients of a basic function are recorded by the sensor elements which are hard-wired and each directly provide a measured value, the magnitude of which corresponds to a coefficient of the basic function which may be a wavelet basic function. The sensor device provides a recorded image in compressed form and with simultaneously little complexity and can be used in a versatile manner, in particular in an image recorder or a digital camera or, in medicine, in an X-ray machine or a tomograph. Furthermore, the sensor device can be used in a satellite for distant reconnaissance or for the purposes of astrophysics.

Abstract: The method includes providing the volume of waste in a monitoring space; providing a support, the support being provided with a plurality of detectors for radioactive material; monitoring the volume of waste for radioactive material, in one or more parts, to give a monitoring results; and correcting the monitoring result for geometry and/or attenuation to give a corrected result using a correction factor. The correction factor is obtained by a method that includes providing a simulation of an equivalent volume of waste free of radioactive material in an equivalent monitoring space, with equivalent detectors; providing a known activity radioactive source at one or more positions in the volume of waste; determining the detector response to the source in a position, a comparison of the response and known activity contributing to a correction function for that equal volume, one or more such correction functions providing the correction factor.

Abstract: A radiographic image capturing apparatus of a radiographic image capturing system includes a radiation source for outputting a radiation, a cassette housing therein a radiation detector for detecting the radiation which is transmitted through a subject when the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into a radiographic image, a camera for capturing an image of at least the cassette, and a communication unit for sending the image of the cassette which is captured by the camera to an external circuit.

Abstract: A computerized system for locating a device including a sensor module and a processor. A radioactive source, associated with the device, produces a signal in the form of radioactive disintegrations. The sensor module includes a radiation detector capable of receiving a signal from the source attached to the device. The sensor module produces an output signal. The processor receives output signal(s) and translates output into information relating to a position of source.

Abstract: A radiographic image capturing apparatus includes a radiation source device housing therein a radiation source for outputting a radiation, a cassette housing therein a radiation detector for detecting the radiation which is transmitted through a subject when the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into a radiographic image, and a joining mechanism for selectively integrally joining the radiation source device and the cassette to each other and separating the radiation source device and the cassette from each other when the radiation source outputs the radiation.

Abstract: An apparatus and method for inspecting personnel or their effects. A first and second carriage each carries a source for producing a beam of penetrating radiation incident on a given subject. A positioner provides for relative motion of each beam vis-à-vis the subject in a motion, the vertical component of which is one-way. A detector receives radiation produced by at least one of the sources after the radiation interacts with the subject.

Abstract: A detector system adapted for monitoring a radiation treatment system comprising a pulsed beam radiation source for treating a body with a given beam intensity and beam configuration, with pulse times and intervals between pulses less than 100 milliseconds, using at least one monitoring radiation source located inside or outside the body, the detector system comprising; a) a detector designed to detect radiation from the monitoring source, and subject to interference radiation from the beam source; and b) control circuitry that creates a data record of radiation received by the detector, to provide information about the body; wherein, when the detector detects radiation in real time during operation of the beam, the data record selectively excludes data for radiation received by the detector during the pulses, as opposed to data for radiation received by the detector between pulses.

Abstract: A phase-contrast imaging apparatus for imaging an object, comprising a radiation source, a first diffracting optical element located to receive radiation from the source, a second diffracting optical element located after the first optical element, a spatially resolving detector for detecting radiation from the source that has propagated through the object and been diffracted sequentially by the first optical element and the second optical element and an actuator for providing a relative translation of the first and second optical elements with respect to and across a propagation direction of radiation transmitted from the source to the detector. The actuator provides the relative translations of the first and second optical element at respectively a first speed and a second speed that is the first speed times a magnification factor of the apparatus.

Abstract: A reference structure tomography device is provided which includes a reference structure configured to intercept and modulate energy in the form of waves or otherwise propagating from a source to a sensor, along longitudinal and traverse directions. The reference structure modulates or otherwise conditions the propagating wave to simplify an inversion process on the data set created by the interaction between the wave and the sensors. The reference structure can modulate a wave through multiple types of interactions with the wave including obscuring, defracting, defusing, scattering, and otherwise altering any characteristic of a portion of the wave. By selecting a reference structure that is compatible with the sensors, the number of measurements needed to resolve the source through the source wave is reduced. The reference structure can also increase the resolution of an imaging system.

Abstract: Devices and methods are disclosed which relate to the calibration and quality assurance of motion tracking enabled radiation therapy machines. A phantom, capable of mimicking human breathing through inflation and deflation of the lungs, houses an independently moving target (tumor) that detects the amount of radiation received from the radiation therapy machine. This amount can be compared with a desired amount to determine if adjustment or repositioning is necessary. The servo-mechanism(s) of the motion tracking enabled radiation therapy machine(s) are adjusted in comparison of detected versus programmed motion of the respiring phantom having incorporated independently moving target that incorporated radiation dose detector(s). In the invention, motion tracking and irradiation mechanisms of the radiation therapy machine are adjusted to calibrate with reference to performance specifications of the radiation therapy machine.

Abstract: The invention relates to an arrangement (10) and a method for detecting an object (18) arranged on a body (14). The arrangement comprises a vibration device (12), which sets the body (14) in a mechanical vibration of predetermined vibration frequency and predetermined vibration phase, an emission device (20) which emits in the direction of the body (14) a coherent electromagnetic detection radiation (26), the radiation frequency of which is selected such that it is reflected at least in part by the body (14) and the object (18) to be detected, a receiver device (30), which receives the radiation (28) reflected by the body (14) and the object (18), and an evaluation device (32) which filters out of the radiation (28) received the portions having the predetermined vibration frequency and evaluates them with respect to their vibration phase difference from the predetermined vibration phase.

Abstract: The subject matter described herein includes methods, systems, and computer program products for measuring the density of a sample construction material. According to one aspect, a nuclear density gauge is disclosed for measuring the density of a sample construction material. The material measurement gauge includes a radiation source positioned for emitting radiation into a sample construction material. A radiation detector is positioned apart from the radiation source and configured to detect radiation from the sample construction material and to produce a signal representing the detected radiation. A non-nuclear moisture property detector is configured to determine a moisture property of the sample construction material and to produce a signal representing the moisture property. A material property calculation function is configured to calculate a property value associated with the sample construction material based upon the signals representing the detected radiation and the moisture property.

Abstract: A diagnostic system for carcinogenicity diagnoses a risk of developing cancer due to a radioactive material deposited in a human body. The system includes a detecting apparatus that detects radiations emitted from the radioactive material; and a determining apparatus that obtains a dose of the radiations detected by the detecting apparatus and determines the risk based on the dose.

Abstract: A radiation detection, localization, and identification system uses a searching algorithm to identify hypothetical solutions to Compton scatter data. Model based representations of the physical data collection yield the identity and location of radiation sources when correct associations of gamma ray energies and locations are made with detected data events. The system's detector is an array of radiation detectors networked to act as a single detection system. This network has wide area of view and high sensitivity to radiation sources since no collimation is required.

Abstract: X-ray detector system with improved spatial resolution for a computed tomography systems is provided. The detector system may include pairs of first and second detector arrays, with each array containing detector elements of a different design. In one embodiment, the first array may comprise a first, relatively thin and continuous (i.e., monolithic) scintillation layer with an array of individual diodes positioned to receive light generated within the scintillation layer. The second array may comprise a second, relatively thick scintillation layer formed of separate scintillator elements. An array of diodes may be positioned to receive radiation from the scintillation layer such that each diode element is aligned to primarily receive radiation from one scintillator element in the layer. The structural arrangements of the detector system may also be adapted for applications involving direct conversion of x-ray energy.

Abstract: A radiographic image capturing system includes an image capturing apparatus for applying radiation to a subject, a radiation detecting apparatus for detecting radiation transmitted through the subject, a power feeder for supplying electric power contactlessly to a contactless power receiver of the radiation detecting apparatus, a feeding-state determining unit for determining whether power-feeding by the power feeder is being performed or not, and a signal generator for generating an image-capturing inhibition signal for inhibiting radiographic image-capturing by the image capturing apparatus if the feeding-state determining unit judges that the power-feeding is being performed.

Abstract: A radiation-detecting probe instrument has a forward working portion housing a radiation detector and a rearward user directed portion, and is in communication with a control assembly for processing and outputting signals received from the radiation detector correlative to a located radionuclide source emitting energy above about 80 KeV. The disclosed probe instrument forward portion has an annular housing having a radiation transparent tip. The radiation detector is disposed behind the radiation transparent tip. A K alpha radiation emitting wafer (e.g., Pb) wafer is disposed between the radiation transparent tip and the radiation detector. A radiation resistant (e.g., W) shield is disposed between the annular housing and the radiation detector and the Pb wafer. Radiation emitted from the radionuclide source strikes the Pb wafer causing the Pb wafer to emit K alpha radiation, which strikes the radiation detector for generating signals for communication the said control assembly.

Abstract: System including electromagnetic radiation source and electromagnetic radiation detector. Electromagnetic radiation source is configured to excite, with electromagnetic radiation having first source frequency, object configured for suppressing responsive emission of electromagnetic radiation having first source frequency. Electromagnetic radiation detector is configured to receive responsive emission of electromagnetic radiation from object. System is configured to detect presence of object. Method includes exciting, with electromagnetic radiation having first source frequency, object configured for suppressing responsive emission of electromagnetic radiation having first source frequency. Method includes receiving responsive emission of electromagnetic radiation from object and utilizing responsive emission to detect presence of object.

Abstract: An apparatus for identifying the position of defects (100) in bodies (2), comprises feed means (3) for moving the body (3) along a feed direction (A), an emitter (5) designed to direct towards the body (2) a plurality of beams (6?, 6?, 6??) of electromagnetic radiation lying in lying planes (P1, P2, P3) set at different angles to each other, and transversal to the feed direction (A), and a plurality of sensors (8?, 8?, 8??) each facing the emitter (5) for receiving a respective beam (6?, 6?, 6??) after the beam (6?, 6?, 6??) has passed through the body (2). The lying planes (P1, P2, P3) are positioned one after another along the feed direction (A), allowing each portion of the body (2) to be struck by successive beams (6?, 6?, 6??) as the body (2) is fed forward. A corresponding method is also claimed.

Abstract: A mammographic system as a radiation image capturing apparatus includes a radiation source for emitting radiation, a solid-state detector for detecting radiation emitted from the radiation source and generating a radiation image based on such radiation, AEC sensors for detecting a radiation dose emitted from the radiation source, a radiation source controller for controlling the dose emitted from the radiation source based on output signals from the AEC sensors, a reference output storage unit for storing reference output ranges defining respective ranges of reference output signals for the solid-state detector and the AEC sensors, and a malfunction detector for comparing output signals generated by the solid-state detector and the AEC sensors with the respective reference output ranges to detect a malfunction of the solid-state detector, the AEC sensors, or the radiation source.

Abstract: A radiation-based timer for use in an implantable medical device (IMD) includes a radiation source and a radiation detection circuit. The radiation source emits radiation particles during a process referred to as radioactive decay. The radiation detection circuit detects the radiation particles emitted during the decay process and tracks the number of radiation particles detected. When the number of radiation particles detected reaches a threshold value, a timer signal is generated. In this manner, the radiation-based timer generates a timer signal as a function of the radioactive decay of the radiation source. The timer signal may be used by one or more components of the IMD for any of a number of functions, including as a wakeup trigger for a communications and/or a sensor event.

Abstract: A tensiographic drophead comprises a quartz body 10 having a terminal surface 18 with a peripheral drop suspension edge 20. A liquid feed bore 14 extends through the body for supplying a liquid to the terminal surface to form a drop 32 whose outer edges are suspended from the suspension edge 20. At least two light guides 26, 28 extend through the body for respectively transmitting light into and collecting light reflected internally from the drop. The light guides terminate above the plane containing the suspension edge such that the intensity of the reflected light has a significant second order reflection peak.

Abstract: A judging section judges whether the operating portion provided on a device is being operated. A correcting section performs correction such that the values of signals S that indicate the intensities and directions of external forces applied to the operating portion, which are output from a detecting section while it is judged that the operating portion is not being operated, are included in a dead zone range with respect to control of a movement assisting section that assists manual movement of the device by urging the device. A control section controls the movement assisting section to assist movement in the directions of the external forces indicated by the signals output by the detecting section, and to not perform movement assistance in the case that the signal values are included in the dead zone range.

Abstract: An image displaying system includes an image processor and a display unit. The image processor moves and/or deforms a first radiographic image and a second radiographic image that has been captured after the first radiographic image such that the first radiographic image and the second radiographic image are aligned. The display unit displays the first radiographic image and the second radiographic image that have been aligned, allows one of the first and second radiographic image to be viewed by the right eye, and allows the other of the first and second radiographic image to be viewed by the left eye.

Abstract: A method of generating light is disclosed. The method comprises irradiating a substance with first optical field of a first frequency and second optical field of a second frequency. The second frequency being higher than a cutoff frequency of a harmonics generation spectrum characterizing the interaction of the substance with the first optical field.

Abstract: The object of the invention is to realize a light radiation-detecting apparatus including a step of preparing a matrix array including a substrate, an insulating layer arranged on the substrate, a plurality of pixels arranged on the insulating layer, wherein the pixel includes a conversion element converting an incident radiation into an electric signal, and connection electrode arranged at a periphery of the plurality of pixels, fixing a flexible supporting member for covering the plurality of pixels to the matrix array at a side opposite to the substrate, and releasing the substrate from the matrix array.

Abstract: An entangled quantum generator generates a signal including a plurality of entangled quanta. The wavelength of the signal is the sum of the wavelengths of the entangled quanta. A signal processor determines a characteristic of the target based on information derived from at least some of the entangled quanta in the return signal. The frequency of the signal is selected to propagate the signal through a medium and the frequencies of the entangled quanta are selected to provide sufficient data in the return signal to resolve the characteristic of the target.

Abstract: Systems, methods, and other modalities are described for (a) obtaining an indication relating to an emission module (which may be dangerous, e.g.) or its user (who may be untrained, e.g.) and for (b) configuring the module or causing an irradiation (for imaging, e.g.) in response to the indication.

Abstract: Systems, methods, and other modalities are described for (a) obtaining an indication relating to an emission module (which may be dangerous, e.g.) or its user (who may be untrained, e.g.) and for (b) configuring the module or causing an irradiation (for imaging, e.g.) in response to the indication.

Abstract: An apparatus includes an imaging unit configured to perform imaging by using a plurality of image capture elements for accumulating electric charges, a storage unit configured to store an offset correction image, a correction image generation unit configured, when capturing a radiation image through radiant-ray irradiation, to combine the offset correction image with an image captured by using a part of the plurality of image capture elements through the imaging unit without radiant-ray irradiation to update the offset correction image, and a correction processing unit configured to correct the captured radiation image, based on the offset correction image.

Abstract: This application relates to radiation detection, and more particularly, to a method and device for the remote detection and localization of nuclear materials in an unknown background. A method and apparatus for long range neutron and gamma ray detection and imaging is disclosed wherein a panel of thin walled tube detectors are rotated to enhance detection performance. The method and apparatus have particular applicability to portable monitoring and homeland security.

Abstract: An improved differential coat weight technique employs a novel algorithm for measuring the weight of a coating material that has been deposited onto a sheet of substrate. The invention employs dual x-ray or nuclear gauges such that, even though the downstream sensor is never exposed to uncoated sheet substrate, imparting the downstream sensor with the ability to predict results that it would have yielded when measuring the uncoated sheet substrate, leads to the development of a coat weight calibration protocol from which the basis weight of the coating can be ascertained directly from measurements from the upstream and downstream sensors. No subtraction of results is required. Moreover, the two sensors do not need to be re-calibrated whenever the relative proportions of the coating and base substrate change. The technique is particularly suited for applications where the coating material and substrate are made of substances that have very different atomic numbers.