Patent application number | Description | Published |
20100013914 | IN-VIVO SENSING DEVICE AND METHOD FOR COMMUNICATING BETWEEN IMAGERS AND PROCESSOR THEREOF - An in-vivo sensing device having multiple imagers controlled by a single processor and a method for communicating between the processor and the imagers. The processor and imagers are connected via common data and control busses, instead of by direct separate conducting lines thereby reducing the number of pins on the processor and the corresponding number of conducting lines. | 01-21-2010 |
20100174141 | DEVICE AND METHOD FOR ASSEMBLING IN VIVO SENSING DEVICES - A sleeve for simple assembly of in-vivo devices, such as endoscopy capsules, is provided. The sleeve comprises grippers and leaf springs at either end to hold the rigid portions of a rigid-flex PCB (printed circuit board) in a folded configuration before the PCB is inserted into an in-vivo device's housing. A method of assembly of the rigid-flex PCB into the sleeve is provided. | 07-08-2010 |
20100326703 | IN VIVO SENSING DEVICE WITH A FLEXIBLE CIRCUIT BOARD AND METHOD OF ASSEMBLY THEREOF - A flexible circuit board for being inserted into an in-vivo imaging device is provided. The flexible circuit board may include a plurality of flexible installation units connected to one another through flexible connection units. The flexible installation units may be capable of having electrical components disposed thereon at a size suitable for being included in an in-vivo imaging device which may be inserted into a body lumen, e.g., a capsule endoscope. A method of assembling an in-vivo imaging device which may enclose such a full-flexible circuit board is also provided. | 12-30-2010 |
20110007203 | ASSEMBLY AND METHOD FOR ALIGNING AN OPTICAL SYSTEM - An assembly for aligning an optical system over an image sensor is described. The assembly may include a lens structure positioned over an image sensor and a lens holder positioned over the lens structure and secured onto a substrate. The lens structure may incorporate an optical section and a structural section extending from the optical section and may rest directly on an image sensor with one or more stoppers that may serve to elevate the optical system with respect to the image sensor at a distance corresponding to a near optimal focal length distance. A lip also included in the structural section of the lens structure may abut two or more opposing sides to secure the lens structure over the image sensor in a centered position with respect to the image sensor. | 01-13-2011 |
20120149981 | MAGNETICALLY MANEUVERABLE IN-VIVO DEVICE - An in-vivo device includes a magnetic steering unit (MSU) to maneuver it by an external electromagnetic field. The MSU may include a permanent magnets assembly to produce a magnetic force for navigating the device. The MSU may include a magnets carrying assembly (MCA) to accommodate the permanent magnet(s). The MCA may be designed to generate eddy currents, in response to AC magnetic field, to apply a repelling force. The in-vivo device may also include a multilayered imaging and sensing printed circuit board (MISP) to capture and transmit images. The MISP may include a sensing coil assembly (SCA) to sense electromagnetic fields to determine a location/orientation/angular position of the in-vivo device. Data representing location/orientation/angular position of the device may be used by a maneuvering system to generate a steering magnetic field to steer the in-vivo device from one location or state to another location or state. | 06-14-2012 |
20120271104 | SYSTEM AND METHOD FOR CONTROLLING POWER CONSUMPTION OF AN IN VIVO DEVICE - A method and device may control energy consumption of in an in vivo imaging device by determining or estimating an amount of energy needed to capture images at a frame rate until a complete passage of the device through a predetermined region of the gastrointestinal tract, and alter or limit the frame capture rate accordingly. | 10-25-2012 |
20130080119 | SYSTEMS AND METHODS FOR GENERATING ELECTROMAGNETIC INTERFERENCE FREE LOCALIZATION DATA FOR AN IN-VIVO DEVICE - An electromagnetic localization signal may be sensed by an electromagnetic field sensor in an in-vivo device with an electromagnetic field interference that is superimposed on the electromagnetic localization signal. The electromagnetic field interference may be filtered by outputting, by the electromagnetic field sensor, an alternating signal that represents, or in response to, the electromagnetic localization signal; sampling a first (e.g., positive) portion of the alternating signal during a first sampling window or period to obtain a first set of samples, sampling a second (e.g., negative) portion of the alternating signal during a second sampling window or period to obtain a second set of samples; and calculating a number, N | 03-28-2013 |
20130296650 | IN VIVO SENSING DEVICE WITH A FLEXIBLE CIRCUIT BOARD - A flexible circuit board for being inserted into an in-vivo imaging device is provided. The flexible circuit board may include a plurality of flexible installation units connected to one another through flexible connection units. The flexible installation units may be capable of having electrical components disposed thereon at a size suitable for being included in an in-vivo imaging device which may be inserted into a body lumen, e.g., a capsule endoscope. An in-vivo imaging device which may enclose such a full-flexible circuit board is also provided. | 11-07-2013 |
20130331649 | MAGNETICALLY MANEUVERABLE IN-VIVO DEVICE - An in-vivo device includes a magnetic steering unit (MSU) to maneuver it by an external electromagnetic field. The MSU may include a permanent magnets assembly to produce a magnetic force for navigating the device. The MSU may include a magnets carrying assembly (MCA) to accommodate the permanent magnet(s). The MCA may be designed to generate eddy currents, in response to AC magnetic field, to apply a repelling force. The in-vivo device may also include a multilayered imaging and sensing printed circuit board (MISP) to capture and transmit images. The MISP may include a sensing coil assembly (SCA) to sense electromagnetic fields to determine a location/orientation/angular position of the in-vivo device. Data representing location/orientation/angular position of the device may be used by a maneuvering system to generate a steering magnetic field to steer the in-vivo device from one location or state to another location or state. | 12-12-2013 |
20140003418 | SYSTEMS AND METHODS FOR SYNCHRONIZING BETWEEN AN IN-VIVO DEVICE AND A LOCALIZATION SYSTEM | 01-02-2014 |
20150073213 | SYSTEM AND METHOD FOR CONTROLLING POWER CONSUMPTION OF AN IN VIVO DEVICE - A method and device may control energy consumption of in an in vivo imaging device by determining or estimating an amount of energy needed to capture images at a frame rate until a complete passage of the device through a predetermined region of the gastrointestinal tract, and alter or limit the frame capture rate accordingly. | 03-12-2015 |