A system includes a surgical instrument configured to perform a laparoscopic surgical operation, a location sensor configured to identify a spatial relationship between an anatomical structure and the surgical instrument, and a processor configured to receive a graphical representation of a patient, determine proximity of the distal end portion of the surgical instrument with the anatomical structure of the patient based on the spatial relationship, and generate a warning based on the determination of proximity.

This application discloses a stand assembly that includes an upper portion for holding electronic components and a lower portion for supporting the upper portion. The lower portion including a base, a joint, and a second fastener structure configured to mate with a first fastener structure of the upper portion. The first fastener structure and the joint are configured to respectively provide a first degree of freedom of motion and a second degree of freedom of motion of the upper portion with respect to the lower portion. Movement of the upper portion at the first degree of freedom has substantially consistent resistance through first part of a first full range of motion associated with the first degree of freedom of motion. Movement of the upper portion at the second degree of freedom has substantially consistent resistance through a second full range of motion associated with the second degree of freedom.

A video processing apparatus includes a housing defining an interior space, the housing having first, second, third, and fourth sides and a back side extending between the first, second, third and fourth sides, the back side including a back wall having a main portion laying on a back plane, a recessed portion recessed from the back plane and defining a video connection recess, and a recessed wall extending from the main portion to the recessed portion, the recessed wall having a video connector opening, and the recessed portion having an angled surface lying at an angle of at least 5 degrees relative to the back plane; and a video output socket in the interior space and aligned with the video connector opening of the recessed wall, whereby the angled surface facilitates insertion of a video connector into the video output socket.

A vehicular imaging system includes an electronic control unit (ECU) and a camera device disposed at a body portion of the vehicle. The camera device includes structure that supports a camera and that is movable between a stowed position, where the structure and camera are within the body portion, and an extended position, where the structure and camera are extended outward from the body portion so that the camera is positioned with a field of view exterior of the vehicle. The structure includes a plurality of individually movable elements that are disposed adjacent one another and that cooperate to form the outer surface. The individually movable elements, when moved relative to the body portion of the vehicle, cooperate to extend and retract the camera. The camera, when the structure is in the extended position, captures image data and provides captured image data to the ECU.

The present invention includes computer vision based driver assistance devices, systems, methods and associated computer executable code (hereinafter collectively referred to as: “ADAS”). According to some embodiments, an ADAS may include one or more fixed image/video sensors and one or more adjustable or otherwise movable image/video sensors, characterized by different dimensions of fields of view. According to some embodiments of the present invention, an ADAS may include improved image processing. According to some embodiments, an ADAS may also include one or more sensors adapted to monitor/sense an interior of the vehicle and/or the persons within. An ADAS may include one or more sensors adapted to detect parameters relating to the driver of the vehicle and processing circuitry adapted to assess mental conditions/alertness of the driver and directions of driver gaze. These may be used to modify ADAS operation/thresholds.

System and method for improving the shaving experience by providing improved visibility of the skin shaving area. A digital camera is integrated with the electric shaver for close image capturing of shaving area, and displaying it on a display unit. The display unit can be integral part of the electric shaver casing, or housed in a separated device which receives the image via a communication channel. The communication channel can be wireless (using radio, audio or light) or wired, such as dedicated cabling or using powerline communication. A light source is used to better illuminate the shaving area. Video compression and digital image processing techniques are used for providing for improved shaving results. The wired communication medium can simultaneously be used also for carrying power from the electric shaver assembly to the display unit, or from the display unit to the electric shaver.

An endoscope having an operating handle including a handle housing arranged at a proximal end and an insertion tube extending from the handle towards a distal end of the endoscope and terminating in a steerable tip part at the distal end of the endoscope, the endoscope further including a control mechanism with a Bowden cable having an outer guide tube having a first length between a proximal end and a distal end of the outer guide tube and an inner pull-wire having a second length between a proximal end and a distal end of the inner pull-wire, the second length being longer than the first length, the proximal end of the outer guide tube is affixed to the operating handle by an adhesive.

Embodiments of the invention provide a method and system that allows parameters of a desired target image to be determined from hyperspectral imagery of scene. The parameters may be representative of various aspects of the scene being imaged, particularly representative of physical properties of the scene. For example, in some medical imaging contexts, the property being imaged may be blood perfusion or oxygenation saturation level information per pixel. In one embodiment the parameters are obtained by collecting lower temporal and spatial resolution hyperspectral imagery, and then building a virtual hypercube of the information having a higher spatial resolution using a spatiospectral aware demosaicking process, the virtual hypercube then being used for estimation of the desired parameters at the higher spatial resolution. Alternatively, in another embodiment, instead of building the virtual hypercube and then performing the estimation, a joint demosaicking and parameter estimation operation is performed to obtain the parameters. Various white level and spectral calibration operations may also be performed to improve the results obtained. While establishing functional and technical requirements of an intraoperative system for surgery, we present iHSI system embodiments that allows for real-time wide-field HSI and responsive surgical guidance in a highly constrained operating theatre. Two exemplar embodiments exploiting state-of-the-art industrial HSI cameras, respectively using linescan and snapshot imaging technology, were investigated by performing assessments against established design criteria and ex vivo tissue experiments. We further report the use of one real-time iHSI embodiment during an ethically-approved in-patient clinical feasibility case study as part of a spinal fusion surgery therefore successfully validating our assumptions that our invention can be seamlessly integrated into the operating theatre without interrupting the surgical workflow.

Stereo imaging systems and devices are disclosed. A stereo imaging system can include one or more stereo imaging modules and an image processing module connected to the one more stereo imaging modules by a coaxial cable that carries two-way communication signals and transfers electrical power from the image processing module to the stereo imaging modules. The stereo imaging modules each include a plurality of image sensors positioned to capture images of at least partially overlapping fields of view, and processing circuitry configured to transmit the captured images to the stereo imaging module via the coaxial cable. The processing module includes processing circuitry configured to receive and process the captured images, and power circuitry configured to provide electrical power to the stereo imaging module via the coaxial cable. The plurality of image sensors may be color image sensors configured to collect color images for stereo image processing.

An apparatus comprising a first part, the first part having: at least one camera configured to capture images, and at least two microphones configured to capture at least two audio signals; and a second part having at least one microphone configured to capture at least one audio signal, wherein one of the first part or the second part is configured to perform a move relative to the other part, wherein the apparatus is configured to: determine a parameter associated with the move; select at least one of: the at least two audio signals, or the at least one audio signal based, at least partially, on the determined parameter; and generate at least one output audio signal based on the parameter associated with the move and the selected at least one of: the at least two audio signals or, the at least one audio signal.