Abstract: A proximity detection system is described among devices in a unified communications network. A narrow beam LED and a diffuse beam LED, both located near a first object, such as a computer monitor, provide a light illumination pattern detected by a narrow beam light detector and a broad beam light detector, both located near a second device, such as a headset. A processor calculates the ratio of measured intensity from the narrow beam LED compared to the broad beam LED as measured by the broad beam detector to provide an estimate for how far off axis the second object (e.g., a user of the headset) is with respect to the centerline in front of the second object (e.g., the computer monitor). The processor also calculates the ratio of measured intensity of the narrow IR beam detector to the broad IR beam detector to provide an estimate of the second object's orientation (e.g., the headset user's head) with respect to the first object to determine if the second object is facing the first object.

Abstract: A circuit for an image sensor pixel receives photogenerated information from an image sensor, such as infrared sensor. The circuit includes a single ended operational amplifier, they can have a simple circuit such as for example 4 transistors. An additional transistor is used in the pixel to regulate the voltage that is used to drive the operational amplifier, to maintain that voltage relative to a bias level. This prevents voltage fluctuations, which would otherwise be passed to the pixel output.

Abstract: Methods and systems for improving the accuracy of hitting a target are described. An apparatus includes a LIDAR unit, a storage device, an aim adjustment controller and an adjustment interface. The LIDAR unit is configured to measure at least one of wind profiles along a path between a shooting device and the target, and a range to the target. The storage device is configured to store ballistic information for at least one of ammunition types, shooting devices, and environmental conditions. The aim adjustment controller is configured to analyze at least one of the wind profile, the range to the target, and the ballistic information to determine a set of aiming parameters and the adjustment interface is configured to provide aiming instructions based on the set of aiming parameters, wherein the aiming instructions substantially improve the accuracy.

Abstract: The present invention relates to ellipsometer and polarimeter systems, and more particularly is an ellipsometer or polarimeter or the like system which operates in a frequency range between 300 GHz or lower and extending to higher than at least 1 Tera-hertz (THz), and preferably through the Infra-red (IR) range up to, and higher than 100 THz, including: a source such as a backward wave oscillator; a Smith-Purcell cell; a free electron laser, or an FTIR source and a solid state device; and a detector such as a Golay cell; a bolometer or a solid state detector; and preferably including a polarization state generator comprising: an odd bounce image rotating system and a polarizer, or two polarizers; and optionally including least one compensator and/or modulator, in addition to an analyzer.

Abstract: An electrode position detection device detects a relative positional relationship between a positive electrode and a negative electrode, when a packaged electrode having the positive electrode disposed inside a bag-shaped separator and the negative electrode are alternately stacked. The device includes a light source, a camera, and a detector. The light source projects light that penetrates the separator and is reflected by the electrodes. The camera receives the light reflected by the positive electrode when the packaged positive electrode is on the uppermost layer and receives the light reflected by the negative electrode when the negative electrode is on the uppermost layer. The detector detects the relative positional relationship between the electrodes based on the results of light reception by the camera when the packaged positive electrode is on the uppermost layer and the results of light reception by the camera when the negative electrode is on the uppermost layer.

Abstract: A millimeter and sub-millimeter wavelength receiver imaging apparatus and method which directly generates a time encoded digital signal for an imaging pixel in response to interoperation of a digital quench circuit, an envelope detector, and a regenerative oscillator coupled to an antenna. The device utilizes the fact that oscillator startup time in a regenerative oscillator is inversely proportional to injected pixel image power. A digital quench circuit, such as a latch, is coupled for activating and deactivating the regenerative oscillator in response to receiving an output from an envelope threshold circuit, and for generating a time encoded digital signal in response to pixel amplitude during millimeter and sub-millimeter wavelength imaging. Receiver embodiments are described for both fundamental frequency operation (DRR) and for multi-frequency imaging (IRR).

Abstract: An apparatus determines cooling characteristics of an operational cooling device used for transferring heat from an electronic device. The operational cooling device is thermally coupled to a heat pipe. The heat pipe has an exposed surface for selective application of heat thereon. Heat from a localized heat source is selectively applied to at least one region of the exposed surface. The heat source is preferably capable of being varied both positionally relative to the exposed surface and in heat intensity. A heat shield is preferably positioned around the exposed surface of the heat pipe to isolate the operational cooling device from the heat from the localized heat source. A temperature detector repeatedly measures a temperature distribution across the exposed surface while the cooling device is in a heat transfer mode. The temperature distribution is then used to thermally characterize the operational cooling device.

Abstract: Systems and methods are provided for mitigating optically aimed threats to an aircraft from the ground. A laser beam, having sufficient intensity to interfere with the vision of a human being, is projected from the aircraft over a defined scan pattern at ground level. At least one flight parameter is received. Each flight parameter represents one of a current orientation, position, and motion of the aircraft. The defined scan pattern is adjusted according to at least one flight parameter.

Abstract: Demultiplexing systems and methods are discussed which may be small and accurate without moving parts. In some cases, demultiplexing embodiments may include optical filter cavities that include filter baffles and support baffles which may be configured to minimize stray light signal detection and crosstalk. Some of the demultiplexing assembly embodiments may also be configured to efficiently detect U.V. light signals and at least partially compensate for variations in detector responsivity as a function of light signal wavelength.

Abstract: According to the embodiment of the present invention, an infrared sensor chip may be provided that includes: a CMOS circuit board comprised of an active matrix, a row line selector and an output multiplexer; and a bolometer which is stacked on the CMOS circuit board and is comprised of an active cell and a reference cell, wherein, for the purpose of a parametric test for the bolometer at a wafer or chip state, the row line selector selects a cell to which a voltage is applied in the bolometer, and wherein the output multiplexer outputs current characteristics according to the voltage application.

Abstract: An optical filter having a passband at least partially overlapping with a wavelength range of 800 nm to 1100 nm is provided. The optical filter includes a filter stack formed of hydrogenated silicon layers and lower-refractive index layers stacked in alternation. The hydrogenated silicon layers each have a refractive index of greater than 3 over the wavelength range of 800 nm to 1100 nm and an extinction coefficient of less than 0.0005 over the wavelength range of 800 nm to 1100 nm.

Abstract: A motion detector camera includes a housing, viewing electronics mounted within the housing, an IR emitter exposed on a surface of the housing, a motion detector exposed on a surface of the housing, and a controller operatively coupled to the viewing electronics, the IR emitter, and the motion detector, wherein the controller is adapted to send an activation signal to the IR emitter and to the viewing electronics when the controller receives a triggering signal from the motion detector

Abstract: A system includes a radiation detector array configured to direct a field of view toward multiple conduits within a fluid flow path from a turbine into a heat exchanger. The radiation detector array is configured to output a signal indicative of a multi-dimensional temperature profile of the fluid flow path based on thermal radiation emitted by the conduits. The system also includes a controller communicatively coupled to the radiation detector array. The controller is configured to determine a temperature variation across the fluid flow path based on the signal, and to compare the temperature variation to a threshold value.

Abstract: A spectrophotometer is provided, including a light source for irradiating light into a sample gas, a photodetector for detecting light transmitted through the sample gas, an optical filter, and an operation device for calculating a concentration of an actual gas to be measured, contained in the sample gas based on a detection signal value obtained from the photodetector. The operation device calculates the concentration of the actual gas based on function ? for associating a concentration of a substitute gas with the actual gas obtained from a reference instrument, function ? for associating a relation between a light absorption of the actual gas and the substitute gas in the reference instrument, with a relation between a light absorption of the actual gas the substitute gas in a calibration instrument, and a function indicating a relation between the concentration of the substitute gas and the detection signal value.

Abstract: Described are methods and systems for estimating a baseline of a proximity sensor on an electronic device comprising: collecting proximity sensor data at the electronic device using the proximity sensor; collecting second data using a second source at the electronic device; obtaining a sample of the proximity sensor data at the electronic device when it is determined that no object is proximal to a first face of the electronic device based on the proximity sensor data and based on the second data; and approximating the baseline of the proximity sensor using the obtained sample.

Abstract: Disclosed are methods and apparatus for determining an unknown degree of amorphicity in a bulk-solidifying amorphous alloy. A specimen can be prepared from the alloy, irradiated with passive radiation, imaged to provide a thermal image, and the image analyzed to assess the differences in emissivities in the image. The degree of amorphicity can be determined based on the differences in thermal emissivities.

Abstract: The calibration/verification system and method for gas imaging infrared cameras standardizes the procedures to objectively and consistently check performance of gas imaging infrared cameras. This system includes a background board maintaining a uniform temperature, a target cell filled with a target compound and disposed in front of the background board, a reference cell filled with a reference compound and disposed in front of the background board, and an analyzer coupled to the camera that captures images of the gas cell and the reference cell. The analyzer compares the intensity difference and the temperature difference of rays passing through the target cell and reference cell to a reference relationship data of a quality control chart to determine whether the camera is in a working condition. The method is further extended to provide a quantitative measurement of a hydrocarbon plume from a gas imaging infrared camera.

Abstract: A measuring device for analyzing a lubricant of a bearing. The measuring device has an electromagnetic radiation emitter, a receiving element and a test area that is arranged between the emitter and the receiving element. The measuring device allows for current information on the condition of the lubricant in the bearing to be obtained. At least some sections of the test area are inside the bearing and the receiving element supplies a spectrum of electromagnetic radiation captured by the test area. Also, a bearing and a seal for the bearing and a method for detecting and monitoring the condition of the lubricant of a bearing.

Abstract: Provided are thermo-sensitive and light-sensitive polymer compositions including poly(4-vinyl pyridine) and poly(4-vinyl pyridine-co-butyl methacrylate).

Abstract: An occupancy sensor has a body and a lens cover. The body includes an enclosure, a human movement sensing component and at least one multi-position rotary switch. The at least one multi-position rotary switch is configured through the enclosure of the body, has a plurality of switching positions and is rotatable between the switching positions. The lens cover is attached to the body and covers the human movement sensing component. With the above-mentioned structure, a user can easily and accurately rotate the multi-position rotary switch to adjust a function of the sensor because the multi-position rotary switch can be positioned in one of the switching positions, and thereby no excessive or deficient adjustment will be made.

Abstract: This disclosure provides methods to integrate heat generating nanoparticles to microelectromechanical (MEMs) and photonic devices such as microbolometers and thermopiles for better photodetection and electrical energy generation. Nanoparticles include noble metal and semiconductor nanocrystals of different shapes, as light sensing and heat generating materials.

Abstract: A mobile device including a source for emitting electromagnetic radiation, an enclosure having a side wall, and a detector for detecting electromagnetic radiation emitted by the source is described. At least a portion of the sidewall is adapted to transmit electromagnetic radiation from the source. The source and detector are positioned inside the enclosure. The detector is spaced from the source, and is arranged to detect electromagnetic radiation from the source that is reflected from an object outside the enclosure and passes through the portion of the side wall.

Abstract: An overhead occupancy sensor assembly includes a housing, a lens disposed in the housing, a sensing element disposed behind the lens and configured to detect light, and a light blocking element, the light blocking element being configured to block light from reaching the sensing element. The light blocking element is a re-shapeable filter element or a rejection pattern of the lens. A continuous range of motion extension adapter may be included to allow optimal positioning of the sensor device for improved detection.

Abstract: Method of determining a total HF concentration metric in an environment including measuring an uncorrected HF concentration metric in the environment based on a first infrared absorption measurement at a wavelength corresponding to a vibrational frequency of a non-hydrogen bonded gas phase HF molecule; determining an ambient H2O concentration metric in the environment available for reaction with the non-hydrogen bonded gas phase HF molecules at or about the time of obtaining the first infrared absorption measurement; calculating a HF hydrate concentration metric in the environment based on the uncorrected HF concentration metric, the ambient H2O concentration metric and a reaction equilibrium relationship between the non-hydrogen bonded gas phase HF molecule and the HF hydrate; and determining the total HF concentration metric in the environment based on the uncorrected HF concentration metric and an amount of HF determined by the HF hydrate concentration metric.

Abstract: A thickness monitoring device capable of performing thickness measurement of an object of measurement in real time even when using a relatively narrow band light source. This etching monitoring device (thickness monitoring device) includes a light source which produces measurement light having a predetermined wavelength bandwidth; an array detector which detects, for each wavelength, interference light of measurement light reflected from mask, whereof the thickness changes over time; and data processing unit which computes the thickness of the mask based on change over time of a plurality of single-wavelength components of the interference light detected by the array detector.

Abstract: An optical position detection device includes a first detection light source unit that outputs a detection light from one side to the other side in a first direction, a second detection light source unit that is separated from the first detection light source unit along a second direction crossing the first direction, and outputs a detection light from the one side to the other side in the first direction, a light detection unit having sensitivity toward the other side in the first direction, and a position detection unit that detects the position of the object based on the light reception in the light detection unit.

Abstract: There is provided a readout integrated circuit for an infrared signal that is able to operate at low power and reduce a pixel pitch without the use of a skimming capacitor.

Abstract: To provide a monochromatic wavelength variable terahertz wave generation/detection system that has high detection sensitivity at room temperature and that can quickly operate at the same time, excitation light of monochromatic wavelength generated from one excitation light source is inputted to a wavelength variable terahertz wave source and a nonlinear light conversion terahertz wave detector through an excitation light phase control optical system shown below.

Abstract: A device for radiation absorption measurements may include a radiation source emitting electromagnetic radiation having a wavelength in the interval 0.2 ?m-20 ?m, a detector detecting the electromagnetic radiation, when in a measurement mode at least a portion of the radiation has passed through a medium and been reflected by a surface at a distance from the radiation source, before reaching the detector. The device may further include a fluid calibration cell, which is adapted to be arranged in the path of the electromagnetic radiation between the radiation source and the detector. A method for calibrating a device for radiation absorption measurements may involve emitting electromagnetic radiation having a wavelength in the interval 0.2 to 20 ?m, directing at least a portion of the electromagnetic radiation through a fluid calibration cell, and detecting the electromagnetic radiation.

Abstract: A radiation source for emitting infrared electromagnetic radiation and having at least one source element. The radiation source is characterized by features including that: the source element is embodied in the form of a silicon carbide fiber; the source element is coated at least sectionally with a metal coating, via which the source element can be heated; and the metal coating heats the source element at least at times in such a manner that the source element emits infrared radiation at least at times. A method for the manufacture of a radiation source is likewise relevant.

Abstract: Pixel-level monolithic optical element configurations for uncooled infrared detectors and focal plane arrays in which a monolithically integrated or fabricated optical element may be suspended over a microbolometer pixel membrane structure of an uncooled infrared detector element A monolithic optical element may be, for example, a polarizing or spectral filter element, an optically active filter element, or a microlens element that is structurally attached by an insulating interconnect to the existing metal interconnects such that the installation of the optical element substantially does not impact the thermal mass or thermal time constant of the microbolometer pixel structure, and such that it requires little if any additional device real estate area beyond the area originally consumed by the microbolometer pixel structure interconnects.

Abstract: A thermal detector has a substrate, a thermal detector element having a light-absorbing film, and a support member. The support member has a mounting part mounting the thermal detector element, a first arm part having one end that is linked to one end of the mounting part and another end that is supported on the substrate, and a second arm part having one end that is linked to the other end of the mounting part and another end that is supported on the other end of the substrate. A plurality of wirings electrically connected with the thermal detector element are provided on the first arm part, and the length of the second arm part is shorter than the length of the first arm part.

Abstract: A system for diverting wide angle incident electromagnetic radiation to parallel to an optical axis of a wide FOV lens. The system includes a wide FOV lens system including at least one wide FOV lens and an electromagnetic radiation sensitive device. The wide FOV lens system includes at least one wide FOV lens, the wide FOV lens includes a smooth outer surface that is transparent to the incident electromagnetic radiation. The wide FOV lens system is superposed over an outer surface of the electromagnetic radiation sensitive device, the electromagnetic radiation sensitive device is capable of interacting with the incident electromagnetic radiation.

Abstract: An optical scanning system includes a frame having a central axis along which is mounted a first elevation mirror for receiving an incident light and reflecting the incident light along a first optical path, a telescope for receiving the reflected incident light and outputting an output light, a visible linear array imager for receiving the output light from the telescope, and a folding mirror positioned to receive part of the output light from the telescope and directing it to a linear array infrared imager. The optical scanning system scans large areas of sky using multiple linear sensors in order to detect, identify and track low and slow flying manned and unmanned aircraft as well as to surveil large areas of terrain.

Abstract: An apparatus for analyzing, identifying or imaging an target including first and second laser beams coupled to a pair of photoconductive switches to produce CW signals in one or more bands in a range of frequencies greater than 100 GHz focused on and transmitted through or reflected from the target; and a detector for acquiring spectral information from signals received from the target and using a multi-spectral heterodyne process to generate an electrical signal representative of some characteristics of the target. The lasers are tuned to different frequencies and a frequency shifter in the path of one laser beam allows the terahertz beam to be finely adjusted in one or more selected frequency bands.

Abstract: Proximity sensor devices are described that integrate a light emitting diode with a light sensor assembly in a single, compact package. The proximity sensor devices comprise a lead frame having a surface. The light emitting diode and light sensor assembly are mounted to the lead frame proximate to the surface. The light emitting diode is configured to emit electromagnetic radiation in a limited spectrum of wavelengths, while the light sensor assembly is configured to detect electromagnetic radiation in the limited spectrum of wavelengths emitted by the light emitting diode. An encapsulation layer is formed on the surface over the light emitting diode and light sensor assembly. A trench is formed in the encapsulation layer to receive electromagnetic radiation blocking material configured to block electromagnetic radiation in the limited spectrum of wavelengths to at least partially mitigate crosstalk between the light emitting diode and the light sensor assembly.

Abstract: A safety control method for a fan includes: capturing an image of an object next to the fan and gathering distances between a plurality of points on the object and a depth-sensing camera, obtaining the distance between the object in the scene and the fan, comparing the distance between the object and the fan against a first preset value, and cutting off power to the fan when the distance between the object and the fan is less than the first preset value.

Abstract: A radiation sensor (27) includes a radiation sensor chip (1) including first (7) and second (8) thermopile junctions connected to form a thermopile (7,8). The first thermopile junction is disposed in a floating portion of a dielectric membrane (3) thermally insulated from a silicon substrate (2) of the chip, and the second thermopile junction is disposed in the dielectric membrane directly adjacent to the substrate. Bump conductors (28) are bonded to corresponding bonding pads (28A) coupled to the thermopile (7,8) to physically and electrically connect the chip to conductors on a printed circuit board (23). The silicon substrate transmits infrared radiation to the thermopile while blocking visible light.

Abstract: The present invention provides a device for detecting foreign matter and a method for detecting foreign matter to detect a foreign matter on a surface of an object such as a film of an electrode mixture etc. or a foreign matter contained in the object, thereby to improve the reliability of the object. By irradiating an object with a terahertz illumination light 100 (wavelength of 4 ?m to 10 mm) and detecting a scattered light 660 from an electrode 10 as an example of the object by a scattered light detector 200, a foreign matter on a surface of the electrode 10 or contained in the electrode 10, for example, a metal foreign matter 720, is detected. The electrode 10 is one in which electrode mixture layers 700 each including an active material 701, conductive additive and a binder as components are coated on both surfaces of a collector 710. The scattered light 660 results from a part of a transmitted light 656 reflected by the metal foreign matter 720.

Abstract: A bolometric array detector for detecting electromagnetic radiation in a predetermined range of infrared wavelengths includes a substrate; an array of bolometric micro-plates for detecting the radiation suspended above the substrate by support arms; and metallic reflectors formed on the substrate underneath the micro-plates to reflect that portion of the radiation which has passed through said micro-plates without being absorbed by the latter. For each micro-plate, a corresponding reflector includes a first part located underneath the micro-plate which extends as a second part not positioned underneath the micro-plate. At least the second part has surface texturing in a repeating pattern for coupling a portion of incident radiation on the second part to a guided wave that propagates towards the first part of the reflector positioned underneath micro-plate.

Abstract: A detection device (10) includes an imaging unit (15) which images a wavelength region of infrared light, an irradiation unit (11) which irradiates first infrared light for detecting the tip part of an indication part on a detection target surface and second infrared light to be irradiated onto a region farther away from the detection target surface than the first infrared light, and a detection unit (19) which detects an orientation of the indication part on the basis of an image imaged by the imaging unit (15) by irradiating the first infrared light and the second infrared light, and detects a position of the tip part on the detection target surface on the basis of an image region of the tip part extracted on the basis of an image imaged by irradiating the first infrared light and the detected orientation of the indication part.

Abstract: A display device is applied to a light sensing system. The display device includes a display module and a pattern layer. The pattern layer is made of optical material capable of either fully or partially reflecting or absorbing invisible light of specific wavelength emitted from the display module, and is formatted on the display module, thus defining gaps through which invisible light can pass. A light sensor is utilized to sense the pre-determined pattern defined by the invisible light passing through the pattern layer. Based on the light sensing result, the light sensor can recognize the corresponding pattern. The optical material of the pattern layer may be arranged to incorporate locational varying invisible light transmittance to define the pre-determined pattern at a finer degree, thus further increasing sensing accuracy.

Abstract: A thermal infrared sensor is provided in a housing with optics and a chip with thermoelements on a membrane. The membrane spans a frame-shaped support body that is a good heat conductor, and the support body has vertical or approximately vertical walls. The thermopile sensor structure consists of a few long thermoelements per sensor cell. The thermoelements being arranged on connecting webs that connect together hot contacts on an absorber layer to cold contacts of the thermoelements. The membrane is suspended by one or more connecting webs and has, on both sides of the long thermoelements, narrow slits that separate the connecting webs from both the central region and also the support body. At least the central region is covered by the absorber layer.

Abstract: According to the present invention, the gas adsorption capability of a getter can be maintained while the characteristics of an infrared ray sensor element are prevented from being deteriorated. An infrared ray sensor package has an infrared ray sensor element, a base substrate, a housing, an infrared ray transmission window, and a getter. The infrared ray sensor element is vacuum-sealed in a space surrounded by the base substrate, the housing, and the infrared ray transmission window. A spacer is disposed between the infrared ray sensor element and the base substrate to form a gap between the infrared ray sensor element and the base substrate. The getter is arranged in the gap formed between the infrared ray sensor element and the base substrate. A heat shielding member is disposed between the infrared ray sensor element and the getter. The heat shielding member is a heater for heating the infrared ray sensor element or an element formed of alloy containing Ni or heat-resistant glass.

Abstract: A monitoring device includes a light source, an optical filter, and an optical detector. The monitoring device may monitor curing processes, such as ultraviolet (UV) curing processes to determine the progression of the level of cure of a light-activated material to a substrate. The light source emits light toward a light-activated material, such as a film, and/or a substrate. The optical filter is positioned so that a wavelength of the light is transmitted through the optical filter after the light is reflected off of the substrate and/or the film. The optical detector is positioned to detect the light that is transmitted through the optical filter.

Abstract: A method and system for determining a shape of an irradiance pulse to which a semiconductor wafer is to be exposed during a thermal cycle are disclosed. The method includes receiving, with a processor circuit, thermal cycle parameters specifying requirements of the thermal cycle, and determining, with the processor circuit, a shape of a heating portion of the irradiance pulse. Determining includes optimizing at least one parameter of a flux profile model of the heating portion of the irradiance pulse to satisfy the requirements while minimizing frequency-domain energy spectral densities of the flux profile model at resonant frequencies of the wafer, to minimize vibration of the wafer at the resonant frequencies when the wafer is exposed to the irradiance pulse.

Abstract: Passive IR sensor detection circuitry is provided that consumes eighty to ninety percent less power than conventional PIR sensor detection circuitry. Whereas prior art PIR sensor detection circuitry employs multiple amplification stages, to boost the power of the weak sensor signal, and a window comparator to determine whether an occupancy condition exists, the present invention uses, at most, a single amplification stage and no window comparator. In place of multiple amplification stages and a window comparators, the PIR sensor circuitry of the present invention uses a sensitive microcontroller to both detect and process the signal. A peak detector can be added just before the signal—whether amplified or not—is received by the microcontroller. Decay time of the peak detector is adjusted so that the signal will not substantially decay between measurements.

Abstract: An integrated Sensing package structure includes a substrate made of IR blocking material. The substrate has a first receiving compartment and a second receiving compartment concavely formed on the top surface thereof. The first receiving compartment has a reflective layer formed on the surface of the inner wall thereof. A LED unit is disposed in the bottom portion of the first receiving compartment. A plurality of first conducting lines is electrically connected to the LED unit and extends to an outer surface of the substrate. An IR sensing chip is disposed in the second receiving compartment. A plurality of second conducting lines is electrically connected to the IR sensing chip and extends to an outer surface of the substrate. An IR block cover is covered on the top surface of the substrate, forming at least one opening corresponding to the IR sensing chip.

Abstract: Techniques are provided for enhancing the visibility of objects located below the surface of a scattering medium such as tissue, water and smoke. Examples of such an object include a vein located below the skin, a mine located below the surface of the sea and a human in a location covered by smoke. The enhancement of the image contrast of a subsurface structure is based on the utilization of structured illumination. In the specific application of this invention to image the veins in the arm or other part of the body, the issue of how to control the intensity of the image of a metal object (such as a needle) that must be inserted into the vein is also addressed.

Abstract: According one embodiment, a non-heterodyne radiation imager includes a substrate having a ground plane layer. The radiation imager also includes a plurality of antenna elements operable to receive radiative input. Each support element of a plurality of support elements mechanically couples an antenna element of the plurality of antenna elements to the substrate. A plurality of energy detectors is operable to measure the radiative input received by the plurality of antenna elements.