A method for image colorization includes receiving, from a camera, an input image including a plurality of input image pixels. One or more input interest pixels of the plurality of input image pixels are classified as corresponding to an object of interest. A display image is generated having a plurality of display image pixels each having pixel values based on relative temperature values of objects in a real-world environment, the display image pixels including display interest pixels corresponding to the input interest pixels. The display interest pixels are colorized with a color selected based on a recognized class of the object of interest to give a colorized display image, the selected color being independent of the relative temperature values of the object of interest. The colorized display image is displayed with the display interest pixels colorized with the selected color.

Hidden camera detection systems and methods are disclosed herein. An example method includes illuminating a surface with infrared light, obtaining an image of the surface using an infrared camera, and determining the presence of a hidden camera associated with the surface by determining a difference in spectral reflectance between how the infrared light is reflected off of the hidden camera as compared to how the infrared light is reflected off of the surface.

Systems and methods for discriminating between malignant and benign pigmented skin lesions based on optical analysis using spatial distribution maps, morphological parameters, and additional diagnostic parameters derived from images of tissue lesions. A handheld optical transfer diagnosis device is disclosed capable of capturing a series of reflectance images of a skin lesion at a variety of angles of illumination and observation.

A head mounted display device, including a frame, a mask, at least one infrared (IR) transmitter, and at least one image capture device, is provided. The mask has a first light reflection layer on a first side. The IR transmitter is disposed in the frame and is used to emit an emitting light beam toward the first light reflection layer. The first light reflection layer reflects the emitting light beam to send a reflective light beam toward a target area. The image capture device is disposed in the frame and is used to capture a target area reflective image of the target area.

A monitoring camera includes an image-capturing element that has a plurality of pixels, and that is configured to acquire, for each of the pixels, a blue component signal, a red component signal, and a green component signal corresponding to light which is from a subject and which is incident through fog or haze, an optical filter that is disposed between the subject and the image-capturing element, and that is configured to transmit specific-wavelength light having a wavelength equal to or larger than a specific wavelength among light from the subject, and a processor that is configured to generate and output a captured image of the subject based on either a blue component signal, a red component signal and a green component signal for each of the pixels corresponding to the specific-wavelength light or a blue component signal for each of the pixels corresponding to the specific-wavelength light.

A system and method for the detection and identification of flaws on vehicle wheels is described. A preferred embodiment for the detection and identification of flaws on railroad wheels is specifically described, involving particular designs and approaches in imaging and analyzing images of said wheels.

Systems and methods disclosed herein provide for some embodiments infrared camera systems for maritime applications. For example in one embodiment, a watercraft includes a plurality of image capture components coupled to the watercraft to capture infrared images around at least a substantial portion of a perimeter of the watercraft; a memory component adapted to store the captured infrared images; a processing component adapted to process the captured infrared images according to a man overboard mode of operation to provide processed infrared images and determine if a person falls from the watercraft; and a display component adapted to display the processed infrared images.

A parking assistance system includes: a color/IR detector which detects, from a camera image captured with a camera, marker candidates that are areas in each of which an intensity of a color component or an infrared (IR) component exceeds a threshold; a marker position calculator which calculates positions of the marker candidates in the camera image; and a validity verifier which determines whether the marker candidates are valid as the markers, based on the positions of the marker candidates and a predetermined positional relationship of the markers.

A method and apparatus for processing images. A set of candidate targets is identified in a first image and in a second image that corresponds with the first image. A set of first scores is generated for the set of candidate targets using the first image. A set of second scores is generated for the set of candidate targets using the second image. A set of final scores is computed for the set of candidate targets using the set of first scores and the set of second scores. A determination is made as to which of the set of candidate targets is a target of interest based on the set of final scores.

An embodiment of a Wearable Computer with Natural User Interface apparatus includes a first portable unit for data gathering and communicating feedback and a second portable unit for processing the at least gathered data from the first unit. The first portable unit includes an eyeglass frame, at least one first optical unit disposed on the eyeglass frame for capturing at least one scene image corresponding to a field of view of a user, at least one second optical unit disposed on the eyeglass frame for capturing at least one eye image corresponding to at least a portion of at least one eye of the user, at least one microphone to allow the user to communicate via voice, at least one speaker to allow the user to receive feedback via voice, at least one visible light source to allow the user to receive feedback via light signals, at least one motion sensor to monitor the head movements of the user, and at least one first processor to at least receive data from the data gathering units in the first portable unit and at least manage the communication with the second portable unit. The second portable unit is in communication with the first portable unit and includes at least one second processor configured for receiving the at least data from the first processor and decoding a pre-defined command from the user and executing at least one command in response to the received command. At least one of the processors will determine a direction within the field of view to which the at least one eye is directed based upon the at least a history of one eye image, and generates a command or a subset of the at least one scene image based on the determined direction. At least one of the processors will provide a feedback to the user to acknowledge the user command received. In one embodiment, the Wearable Computer will function as a driver assistant and in another embodiment as a cameraman.