Abstract: An optical fiber phosphor screen including a thin film phosphor layer and an optical fiber faceplate, allowing interfering light in a cladding of the optical fibers to be reduced. The phosphor screen includes an angular filter including at least one layer arranged between the thin film phosphor layer and the optical fiber faceplate.

Abstract: An electron multiplier for a system for detecting electromagnetic radiation or an ion flow is disclosed. The multiplier includes at least one active structure intended to receive a flow of incident electrons, and to emit in response a flow of electrons called secondary electrons. The active structure includes a substrate on which is positioned a thin nanodiamond layer formed from diamond particles the average size of which is less than or equal to about 100 nm.

Abstract: A photo cathode for use in a vacuum tube including a cathode layer, having an entrance face capable of absorbing photons impinging on the cathode layer, and an exit face for releasing electrons upon impinging of the photons, and an electron exit layer, in facing relationship with the exit face of the cathode layer for improving the releasing of the electrons, and a carbon containing layer, positioned between the exit face of the cathode layer and the electron exit layer, for bonding the electron exit layer to the cathode layer.

Abstract: An imaging device (100) for acquiring and displaying images in real-time, the imaging device comprising i) an imaging sensor (110) comprising a radiation sensitive array (120) for acquiring an image (142), ii) a readout circuit (140) connected to the radiation sensitive array for reading out the image, iii) a signal processor (160) for processing the image for obtaining a processed image (162), and iv) a display (180) for displaying the processed image, the radiation sensitive array being arranged in rows of sensor pixels and the display being arranged in rows of display pixels, and wherein the readout circuit is a rolling shutter circuit for sequentially reading out the rows of sensor pixels for sequentially providing subsets of pixels, the signal processor is configured for, on availability of one of the subsets of pixels, processing the subset of pixels for providing a processed subset of pixels, and the display is configured for, on availability of the processed subset of pixels, displaying the processed

Abstract: An electron multiplier for a system for detecting electromagnetic radiation or an ion flow is disclosed. The multiplier includes at least one active structure intended to receive a flow of incident electrons, and to emit in response a flow of electrons called secondary electrons. The active structure includes a substrate on which is positioned a thin nanodiamond layer formed from diamond particles the average size of which is less than or equal to about 100 nm.

Abstract: An optical fiber phosphor screen including a thin film phosphor layer and an optical fiber faceplate, allowing interfering light in a cladding of the optical fibers to be reduced. The phosphor screen includes an angular filter including at least one layer arranged between the thin film phosphor layer and the optical fiber faceplate.

Abstract: An electron multiplying structure for use in a vacuum tube using electron multiplying comprises an input face to be oriented in a facing relationship with an entrance window of the vacuum tube, an output face to be oriented in a facing relationship with a detection surface of the vacuum tube, as well as an ion barrier membrane for shielding off stray ions. The vacuum tube uses electron multiplying having a photocathode capable of releasing electrons into the vacuum chamber when exposed to light, electric field device for accelerating the released electrons from the photocathode towards an anode spaced apart from the photocathode in a facing relationship, as well as an electron multiplying structure. An ion barrier membrane is used in a vacuum tube and/or an electron multiplying structure. The ion barrier membrane is composed of at least one atomic layer containing graphene.

Abstract: A system for detecting electromagnetic radiation or an ion flow, including an input device for receiving the electronic radiation or the ion flow and emitting primary electrons in response, a multiplier of electrons in transmission, for receiving the primary electrons and emitting secondary electrons in response, and an output device for receiving the secondary electrons and emitting an output signal in response. The electron multiplier includes at least one nanocrystalline diamond layer doped with boron in a concentration of higher than 5·1019 cm?3.

Abstract: An electron multiplying structure for use in a vacuum tube using electron multiplying, the electron multiplying structure having an input face intended to be oriented in a facing relationship with an entrance window of the vacuum tube, an output face intended to be oriented in a facing relationship with a detection surface of the vacuum tube, wherein the electron multiplying structure at least is composed of a semi-conductor material layer adjacent the detection windows. Also disclosed is a vacuum tube using electron multiplying with an electron multiplying structure.

Abstract: A photo cathode for use in a vacuum tube including a cathode layer, having an entrance face capable of absorbing photons impinging on the cathode layer, and an exit face for releasing electrons upon impinging of the photons, and an electron exit layer, in facing relationship with the exit face of the cathode layer for improving the releasing of the electrons, and a carbon containing layer, positioned between the exit face of the cathode layer and the electron exit layer, for bonding the electron exit layer to the cathode layer.

Abstract: The invention relates to an image sensor array having multiple pixel sensor elements along the surface area of said image sensor and outputting at a specified video frame rate subsequent video frames corresponding to the image, characterized in that each multiple pixel sensor element is arranged for generating one or more video frame segments, said segments each having a time duration being a fraction of the time equivalent to the video frame rate, and composing a single video frame from the multiple of said video frame segments. The invention also relates to said pixel sensor element for use with an image intensifier or in an electron bombarded image sensor array device according to the invention.

Abstract: The invention relates to an electron bombarded image sensor array device comprising a vacuum chamber having a photocathode capable of releasing electrons into said vacuum chamber when exposed to light impinging on said photocathode, a photocathode capable of releasing electrons into said vacuum chamber when exposed to light impinging on said photocathode, electric field means for accelerating said released electrons from said photocathode towards an anode spaced apart from said photocathode in a facing relationship to receive an electron image from said photocathode, said anode being constructed as a back-thinned image sensor array having electric connecting pads distributed according to a pattern along the surface area of said sensor facing away from said photocathode, a carrier on which said image sensor array is mounted, said carrier having electric connecting pads distributed according to a pattern to feed electric signals from said image sensor array outside said vacuum chamber and electric connecting me

Abstract: An image intensifier tube and a night vision system fitted with such a tube. The tube body of the image intensifier tube includes a multilayer ceramic substrate fixed in a sealed manner to an input device and to an output device so as to assure leaktightness of a vacuum chamber delimited by the tube body. The multilayer substrate also maintains a microchannel plate arranged between a photocathode and a phosphorus screen, and supplies voltage to the photocathode, the plate, and the phosphorus screen.

Abstract: The present invention relates to a photo-detecting apparatus capable of obtaining the intensity distribution of incident light at the same timing even when the intensity distribution of incident light may change with time. The photo-detecting apparatus comprises a photo-detecting section in which plural pixels are arranged in a two-dimensional array, and a signal processing section. Each of plural pixels constituting the photo-detecting section has a first photodiode and a second photodiode, N first photodiodes included in the group of pixels constituting the m-th row of the two-dimensional array being electrically connected to each other through multiple lines, while M second photodiodes included in the group of pixels constituting the n-th column of the two-dimensional array being electrically connected to each other through other multiple lines.

Abstract: A single-channel photomultiplier tube having a sealed envelope, of which one wall includes an internal face having a concavity with a central axis, turned toward the inside of the tube, having a plane of symmetry and containing a photocathode, inlet optics including electrodes, an electron multiplier including a plurality of dynodes, an anode, and a mechanism connecting the dynodes, the photocathode, electrodes of the optics, and the anode, at their respective operating voltages. The electron multiplier is composed of parts physically distinct from one another, and having between them a symmetry of revolution with respect to the central axis of the concavity.

Abstract: The invention relates to an electron bombarded image sensor array device comprising a vacuum chamber having a photocathode capable of releasing electrons into said vacuum chamber when exposed to light impinging on said photocathode, a photocathode capable of releasing electrons into said vacuum chamber when exposed to light impinging on said photocathode, electric field means for accelerating said released electrons from said photocathode towards an anode spaced apart from said photocathode in a facing relationship to receive an electron image from said photocathode, said anode being constructed as a back-thinned image sensor array having electric connecting pads distributed according to a pattern along the surface area of said sensor facing away from said photocathode, a carrier on which said image sensor array is mounted, said carrier having electric connecting pads distributed according to a pattern to feed electric signals from said image sensor array outside said vacuum chamber and electric connecting me

Abstract: Single-channel photomultiplier tube (1) having a sealed envelope (4), of which one wall (5) comprises an internal face (7) having a concavity with a central axis (AA?), turned toward the inside of the tube, having a plane of symmetry and containing a photocathode (2), inlet optics (9) comprising electrodes, an electron multiplier (11) comprising a plurality of dynodes (30-39), an anode (16), means (12) for connecting the dynodes (30-39), the photocathode (2), electrodes (13, 15) of the optics (9), and the anode (16), at their respective operating voltages, characterised in that the electron multiplier is composed of parts (24, 26) physically distinct from one another, and having between them a symmetry of revolution with respect to the central axis of concavity.

Abstract: A glass planar waveguide structure, typically on a glass wafer or chip, has a core region, a contiguous narrow cladding region encompassing the core region, and an outer region practically extending over the rest of the wafer. The core region and the outer region are implanted with outside ions by ion diffusion, whereby the refractive index of the core and of the outer region are similar. The outer region forms an artificial waveguide to enhance the uniformity of physical properties of the wafer, e.g. stress, and reduce birefringence of the core.

Abstract: This invention relates to a photomultiplier tube including: a photocathode PK with a semi-transparent photo-sensitive layer provided to emit an electron flux towards the inside of the tube, focusing optics comprising a first dynode D1, concave on the side of the photocathode PK, and several Rajkman dynodes D3, . . . , D8 located on each side of a plane called the dynodes plane DP. According to the invention, the focusing optics also includes a second dynode D2 concave on the side of the re-emitting surface of the first dynode D1, the angle between the plane of the dynodes DP and the center line of the tube exceeding 45°, the concave side of the first Rajkman dynode D3 facing the re-emitting surface of the second dynode D2.