Patent application number | Description | Published |
20090273679 | APPARATUS AND METHOD FOR CALIBRATING IMAGE CAPTURE DEVICES - An apparatus and method are disclosed for calibrating image capture devices, such as the type used in electronic devices. In some embodiments, the electronic device may include at least one array of pixels and a memory coupled to the at least one array of pixels. The electronic device may further include a central processing unit (CPU) coupled to the memory and at least one color filter optically coupled to the at least one array of pixels. The memory may further include one or more storage locations that include a response of the at least one color filter to one or more predetermined wavelengths from a target test source, as well as, one or more storage locations that include a response of one or more baseline color filters. | 11-05-2009 |
20100073499 | IMAGE CAPTURE USING SEPARATE LUMINANCE AND CHROMINANCE SENSORS - Systems and methods are provided for capturing images using an image sensing device. In one embodiment, an image sensing device may include a first lens train for sensing a first image and a second lens train for sensing a second image. The image sensing device may also include a first image sensor for capturing the luminance portion of the first image and a second image sensor for capturing the chrominance portion of the second image. The image sensing device may also include an image processing module for combining the luminance portion captured by the first image sensor and the chrominance portion captured by the second image sensor to form a composite image. | 03-25-2010 |
20100079884 | DICHROIC APERTURE FOR ELECTRONIC IMAGING DEVICE - A dichroic filter that for use with an electronic imaging device, such as a camera. The dichroic filter is located in the main imaging lens, and may permit all light to pass through a first portion and be measured by a photosensor, while restricting at least some portions of visible light from passing through a second portion thereof. In this manner, only the non-restricted portions of visible light passing through the second portion may be measured by the associated pixels of the photosensor. The filter may be formed from a first aperture permitting a first set of wavelengths to pass therethrough and a second aperture adjacent the first aperture, the second aperture permitting only a subset of the first set of wavelengths to pass therethrough. The second aperture may be a dichroic mirror or it may be an optical filter of some other type. | 04-01-2010 |
20110115964 | DICHROIC APERTURE FOR ELECTRONIC IMAGING DEVICE - A dichroic filter that for use with an electronic imaging device, such as a camera. The dichroic filter is located in the main imaging lens, and may permit all light to pass through a first portion and be measured by a photosensor, while restricting at least some portions of visible light from passing through a second portion thereof. In this manner, only the non-restricted portions of visible light passing through the second portion may be measured by the associated pixels of the photosensor. The filter may be formed from a first aperture permitting a first set of wavelengths to pass therethrough and a second aperture adjacent the first aperture, the second aperture permitting only a subset of the first set of wavelengths to pass therethrough. The second aperture may be a dichroic mirror or it may be an optical filter of some other type. | 05-19-2011 |
20110116017 | SYSTEMS AND METHODS FOR ELECTRONICALLY CONTROLLING THE VIEWING ANGLE OF A DISPLAY - Systems and methods for electronically controlling the viewing angle of a display using liquid crystal optical elements are provided. Each liquid crystal optical element may be associated with a respective scattering module and may selectively steer a device generated light beam to one of two or more scattering regions of its associated scattering module. When a scattering region receives a steered light beam, the steered light beam may be scattered into a viewing cone having at least one viewing angle defined by a characteristic of that scatter region. Each liquid crystal optical element may be made from one or more suitable liquid crystal materials that can be controlled electronically to vary the effective index of refraction of one or more different regions of the liquid crystal optical element, thereby steering incoming light towards a particular one of two or more scattering regions of an associated scattering module. | 05-19-2011 |
20120044328 | IMAGE CAPTURE USING LUMINANCE AND CHROMINANCE SENSORS - Methods and apparatuses disclosed herein relate to image sensing devices. One embodiment may take the form of an image sensing device that includes a first image sensor for capturing a luminance image, a second image sensor for capturing a first chrominance, and a third image sensor for capturing a second chrominance image. The image sensing device may further include an image processing module for combining the luminance image captured by the first image sensor, the first chrominance image captured by the second image sensor, and the second chrominance image captured by the third image sensor, to form a composite image. | 02-23-2012 |
20120075432 | IMAGE CAPTURE USING THREE-DIMENSIONAL RECONSTRUCTION - Embodiments may take the form of three-dimensional image sensing devices configured to capture an image including one or more objects. In one embodiments, the three-dimensional image sensing device includes a first image device configured to capture a first image and extract depth information for the one or more objects. Additionally, the image sensing device includes a second imaging device configured to capture a second image and determine an orientation of a surface of the one or more objects. | 03-29-2012 |
20120109377 | AUTOFOCUS AND/OR AUTOSCALING IN TELESURGERY - Robotic, telerobotic, and/or telesurgical devices, systems, and methods take advantage of robotic structures and data to calculate changes in the focus of an image capture device in response to movement of the image capture device, a robotic end effector, or the like. As the size of an image of an object shown in the display device varies with changes in a separation distance between that object and the image capture device used to capture the image, a scale factor between a movement command input may be changed in response to moving an input device or a corresponding master/slave robotic movement command of the system. This may enhance the perceived correlation between the input commands and the robotic movements as they appear in the image presented to the system operator. | 05-03-2012 |
20130027548 | DEPTH PERCEPTION DEVICE AND SYSTEM - A system for determining a distance to a object or a depth of the object. The system includes a first image capturing device, which may include a lens and an image sensor. The system also includes a first laser source. The first laser source is configured to emit a fan shaped laser beam to intersect at least a portion of a field of view of the image capturing device. | 01-31-2013 |
20140253677 | SMALL FORM FACTOR HIGH-RESOLUTION CAMERA - A camera including a spherically curved photosensor and a lens system. Effective focal length f of the lens system is within about 20% of the radius of curvature of the photosensor. An image is formed by the lens system at a spherically curved image plane that substantially matches the concave surface of the photosensor. The camera is diffraction-limited with small spot size, allowing small pixels to be used in the photosensor. F/number may be 1.8 or less. The spherically curved image plane formed by the lens system at the photosensor follows f*θ image height law. Chief rays of the lens system are substantially normal to the concave surface of the photosensor. Total axial length of the camera may be 2.0 mm or less. The camera may be implemented in a small package size while still capturing sharp, high-resolution images, making the camera suitable for use in small devices. | 09-11-2014 |
20140296870 | AUTOFOCUS AND/OR AUTOSCALING IN TELESURGERY - Robotic, telerobotic, and/or telesurgical devices, systems, and methods take advantage of robotic structures and data to calculate changes in the focus of an image capture device in response to movement of the image capture device, a robotic end effector, or the like. As the size of an image of an object shown in the display device varies with changes in a separation distance between that object and the image capture device used to capture the image, a scale factor between a movement command input may be changed in response to moving an input device or a corresponding master/slave robotic movement command of the system. This may enhance the perceived correlation between the input commands and the robotic movements as they appear in the image presented to the system operator. | 10-02-2014 |