Abstract: An event synchronizing apparatus E for an image intensification camera system C for gathering image data includes an image intensifier 348 for amplifying received light 312. A relay optic assembly 316 is coupled between the image intensifier 348 and a digital image sensor 350, such as a CMOS or CCD device. Digital logic 352 is used to process or output an image or related data 334. An event detector 340 digitizes an input signal 342 from an illumination source 338 and generates an electrical output synchronization signal 346 in response to the input optical signal 342. The image intensifier camera C derives imaging and control information for the synchronization signal.

Abstract: A system (S) for mounting and aligning a detector (D) about an observation instrument (10) includes a first detector (12) movably coupled to the observation instrument (10) off an axis of observation centerline (14) for the observation instrument (10). A retainer (16) is mounted with the observation instrument (10) to secure the first detector (12) to the observation instrument (10). The retainer (16) permits rotatable movement of the first detector (12) about the axis of observation centerline (14). The retainer (16) also preferably includes an attachment point (20) for mounting the first detector (12) to the retainer (16). The first detector (12) should be adjustable at least about an axis (22) essentially perpendicular to the axis of the observation centerline (14) for the observation instrument (10).

Abstract: An InGaAs Image Intensifier (“I2”) Camera (C) detects and forms an image (310) to be viewed. An InGaAs photocathode Image Intensifier (312) is used to pass an amplified signal (316) from a screen (320). The InGaAs image intensification tube (312) is optically coupled (328) to an imaging device (322) for passing output light. The output light (316) from the InGaAs tube (312) is transformed by an electronic circuit (322) producing a desired signal output (324). The signal output (324) from the electronic circuit (322) may be further enhanced into an enhanced signal output (310). The enhanced signal output may be formatted into a form for viewing or may be saved.

Abstract: An image intensification camera system (C) for gathering image data includes an image intensifier (310) for amplifying received light (312). A relay optic assembly (316) is coupled between the image intensifier (310) and a digital image sensor (318), such as a CMOS or CCD device. Digital logic (322) is used to process or output an image or related data (334).

Abstract: A method and system for fusing image data includes an electronic circuit (L) for synchronizing image frames. An adaptive lookup table unit (302a, 302b) receives the image frame data sets and applies correction factors to individual pixels. The size of an image is then scaled or otherwise manipulated as desired by data formatting processors (312a and 312b). Multiple images communicated within parallel circuit branches (P1 and P2) are aligned and registered together with sub-pixel resolution.

Abstract: Synchronizing subsystems includes receiving an objective and constraints at a timing module from a processor. The constraints describe subsystems that include at least one sensor. An objective function is determined in response to the objective. The objective function includes a function of time variables, where a time variable is associated with a subsystem. The objective function is optimized in accordance with the constraints to determine a time value for each time variable, and the subsystems are synchronized according to the time values. Data is received from the synchronized subsystems at the processor, and an image is generated from the data.

Abstract: A system and method for gathering image data are disclosed. A first sensor (120) receives light directly from an aperture (114) and generates a first data set in response to the received light. A first reflective surface (130) receives light from the aperture (114) and reflects the received light. A second reflective surface (132) receives light reflected from the first reflective surface (130) and reflects the received light. A second sensor (134) receives light reflected from the second reflective surface (132) and generates a second data set in response to the received light. The second sensor (134) is substantially coaxial with the first sensor (120).

Abstract: A system (100) for gating a sensor (118) includes a detector (120) that detects light and outputs a signal (102) corresponding to the light. A control unit (134) receives the signal (104), adjusts a gating signal (112) in response to the signal (104), and outputs the adjusted gating signal (112) to gate a sensor (118) sensing the light.

Abstract: A system and method for gathering image data are disclosed. A first sensor (120) receives light directly from an aperture (114) and generates a first data set in response to the received light. A first reflective surface (130) receives light from the aperture (114) and reflects the received light. A second reflective surface (132) receives light reflected from the first reflective surface (130) and reflects the received light. A second sensor (134) receives light reflected from the second reflective surface (132) and generates a second data set in response to the received light. The second sensor (134) is substantially coaxial with the first sensor (120).

Abstract: A system (300) for gating a sensor (118) includes a detector (120) that detects light and outputs a signal (102) corresponding to the light. A control unit (334) receives the signal (106), and enables and disables a power supply (314) in response to the signal (106) to generate a gated power signal (316). The power supply (314) outputs the gated power signal (316) to a sensor (118) sensing the light.