A Dynamic Connectivity System (DCS) comprising a patient module configured for communication with an in-vivo device and with at least one additional device; the DCS further comprises a gateway device configured for providing an access point for the patient module for accessing a network; the access point is configured for termination after an idle period of predetermined idle time, and the patient module is configured for uploading data to the network via the mobile device during a non-idle period of the gateway device; the patient module is also configured for sending, during the idle period, a pinging signal to the mobile device different from the data, the pinging signal having a period time shorter than the predetermined idle time, thereby interrupting the idle period and preventing termination of the access point.

An in-body image capturing device (camera unit) with high reliability is suggested. A camera unit (11) includes an image capturing unit that includes a lens (26) and a first illumination unit (27a) and is capable of being introduced into a body. The first illumination unit (27a) and the image capturing unit are housed in a casing (22) that is integrally molded with an integral light-transmitting body (22x) and an integral light shielding body (22y).

A system for propelling a magnetic robotic device through a human comprises a magnetic actuator device operable to generate a rotating magnetic field, and a magnetic robotic device comprising a compliant body and at least two permanent magnets supported by and spatially separated about the compliant body. A non-magnetic region can also be oriented between the at least two permanent magnets. The at least two permanent magnets can be alternating or non-alternating in polarity with each other. In response to application of the rotating magnetic field generated by the magnetic actuator device and that is situated proximate the magnetic robotic device, the rotating magnetic field effectuates undulatory locomotion of the magnetic robotic device to propel the magnetic robotic device through a human, such as through a natural lumen. Further, the magnetic robotic device can optionally be supported by a catheter or endoscope to assist with propelling a distal end through a human.

A method of examining digestive tract images is provided. The method of examining digestive tract images include: obtaining a basic image taken by a photographing apparatus; obtaining a set H of pixels with Hue in the range of D1 in the basic image; obtaining a set S of pixels with Saturation in the range of D2 in the basic image; obtaining a set of pixels with Value in the range of D3 in the basic image, and recording it as an effective pixel range; selecting all pixel sets of the set H and the set S in the effective pixel range to form a detection graph block; examining whether the basic image is an unclean image according to the detection graph block. The present invention further provides a method of examining the cleanliness of the digestive tract, a computer device, a computer-readable storage medium thereof.

A tethered imaging camera encapsulated in a shell lens element of such camera enables viewing from inside and imaging of a biological organ in/from a variety of directions. A portion of camera's optical system together with light source(s) and optical detector mutually cooperated by housing structure inside the shell are moveable/re-orientable within the shell to vary a desired view of the object space without interruption of imaging process. A tether carries electrical but not optical signals to and from the camera and controllable traction cords to move the camera, and a hand-control unit and/or electronic circuitry configured to operate the camera and power its movements. Method(s) of using optical, optoelectronic, and optoelectromechanical sub-systems of the camera.

Introduced here is an ingestible device comprising a capsule, a camera, an antenna, and a propulsion component. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

An imaging capsule, including a radiation source, a collimator that provides a collimated beam from the radiation source, a detector configured to detect particles resulting from X-ray fluorescence and/or Compton backscattering in response to the collimated beam, a motor to rotate the collimator and detector around an axle to scan a partial or full inner circumference of a user's colon with radiation, wherein the motor comprises a segmented commutator that is fed with a power signal via brush contacts; and wherein the motor provides a pulsed output signal based on mechanical switching of the segmented commutator on the brush contacts, providing an indication of the rotation angle of the motor as a function of time.

A patch configured for being applied to a patients skin, said patch comprising a contact area configured for being in direct contact with the patients skin when applied thereto, and a detector configured for detecting contact between the contact area and the patients skin.

The present technology relates to a solid-state image pickup element, electronic equipment, and a semiconductor apparatus that make it possible to reduce a surface reflection in an area in which a slit is formed and improve flare characteristics. A solid-state image pickup element includes a pixel area in which a plurality of pixels is two-dimensionally arranged in a matrix, a chip mounting area in which a chip is flip-chip mounted, and a dam area that is arranged around the chip mounting area and in which one or more slits that block an outflow of a resin are formed. In the dam area, the same OCL as that in the pixel area is formed. The present technology can be applied to a solid-state image pickup element etc. in which a chip is flip-chip mounted, for example.

A light-receiving device of an embodiment of the present disclosure includes a photoelectric conversion layer that includes a first compound semiconductor with a first conductivity type and absorbs a wavelength of an infrared region, a first semiconductor layer formed on the photoelectric conversion layer, and an insulation layer formed to surround the photoelectric conversion layer and the first semiconductor layer, the first semiconductor layer having a second conductivity-type region at a middle region excluding a periphery facing the photoelectric conversion layer.