A capsule endoscope device, system and method for dynamically adjusting a color illumination spectrum. A plurality of different color groups of LEDs may emit light, recorded by an image sensor, corresponding to a plurality of different respective wavelength subranges. A driving circuit may send a driving current to independently activate each different color group of LEDs during entirely or partially non-overlapping time pulses. A single color group of LEDs is independently activated at any one time, and the plurality of different color groups of LEDs are sequentially activated in successive time pulses to simulate a white light or multi-color illumination spectrum over a plurality of the time pulses. The activation pattern of the color groups of LEDs may be dynamically adjusted, in real-time, to achieve a flexible and customizable illumination spectrum ideal for imaging a variety of different environments e.g., in the GI tract.

A steerable assembly comprises an elongated body structure with an implement arranged at a distal end thereof, wherein a premagnetized material is arranged closer to the distal end than a proximal end, and is configured to enable steering of the implement through tissue of an animal body responsive to application of a magnetic field eternal to the body. A method for guiding passage of an implement through tissue includes altering strength and/or position of at least one magnetic field source external to an animal body to interact with and effectuate movement of a premagnetized material inserted into the animal body.

A capsule-type endoscope including a battery, a camera configured to capture internal organ images, a light source configured to irradiate light to capture the internal organ images, and a light source driving power line supplying power, stored in the battery, to the light source. The light source driving power line is a loop antenna coil for reception of a control signal from an external coupled loop antenna coil for transmission.

An automatic detection of surgical instruments with respect to a type and a location thereof is provided with a detection system, which includes at least two surgical instruments, which each include at least one cavity extending along a longitudinal axis of the instrument and a proximal entry region to the cavity. An angle of the proximal entry region in relation to the longitudinal extension of the cavity is different in the two instruments. A sensor unit includes two electromagnetic sensors and is insertable into the cavity. One of the sensors extends axially in the cavity, and the other sensor is arranged in the entry region. A field generator generates an electromagnetic field. An analysis unit analyzes signals transmitted by the sensors to the analysis unit in accordance with the location thereof in the field of the field generator.

A suspension device and a capsule endoscope magnetic control system are provided. The suspension device includes a base, including a pairing portion; a suspension member, at least part of the suspension member is disposed within the base; an intermediate member, which is disposed on an upper end of the suspension member; and an adsorption component, which is disposed above the intermediate member. When the adsorption component has no adsorption force, the intermediate member is pressed against the upper end of the suspension member so that at least part of the suspension member abuts against the pairing portion and the suspension member is locked. When the adsorption component has the adsorption force, the intermediate member is driven to move vertically so that at least part of the suspension member is separated from the pairing portion and a posture of the suspension member is appropriate for adjustment.

A magnetic control device and a capsule endoscope control system are provided. The magnetic control device comprises: a first support, a second support, a magnetic component, a first driving mechanism and a second driving mechanism. The magnetic component comprises a housing portion and a shaft portion connected to the housing portion, the housing portion is provided with a magnet and a drive fitting portion, and the shaft portion is rotatably connected to the second support. The first driving mechanism is disposed on the first support and is connected to the second support, the second driving mechanism is disposed on the second support and is connected to the magnetic component. The first driving mechanism drives the second support to drive the magnetic component to rotate around a first axis, the second driving mechanism drives the magnetic component to rotate around a second axis, the first axis intersects the second axis.

A magnetic control device comprises an upper support and a lower support, wherein the upper support comprises a first mounting space and a second mounting space; a magnetic component mounted on the lower support for driving the capsule endoscope; a first rotation assembly mounted on the lower support for driving the magnetic component to rotate around a first rotation axis, wherein the first rotation assembly comprises a first motor and at least part of the first motor is located in the second mounting space; a second rotation assembly mounted on the lower support and the upper support for driving the magnetic component and the first rotation assembly to rotate around a second rotation axis, the second rotation assembly comprises a second motor and at least part of the second motor is located in the first mounting space; the first rotation axis and the second rotation axis have an angle therebetween.

The present invention provides a magnetic control device and a magnetically controlled capsule endoscope system. The magnetic control device comprises a mounting base, a base, a magnetic component, a first motor and a second motor. The mounting base is for hoisting the magnetic control device, the base is connected to the mounting base, the magnetic component comprises a magnet for driving the capsule endoscope to rotate, the first motor drives the magnetic component to rotate around a first axis, and the first motor passes through the mounting base and is arranged on the base along a first direction, the second motor drives the magnetic component to rotate around a second axis, the second motor is arranged on the base, and the first axis intersects the second axis. By reasonably utilizing a mounting space of the magnetic control device, the structure is more compact, small and convenient to move.

The invention relates to a method of simultaneously calibrating magnetic actuation and sensing systems for a workspace, wherein the actuation system comprises a plurality of magnetic actuators and the sensing system comprises a plurality of magnetic sensors, wherein all the measured data is fed into a calibration model, wherein the calibration model is based on a sensor measurement model and a magnetic actuation model, and wherein a solution of the model parameters is found via a numerical solver order to calibrate both the actuation and sensing systems at the same time.

A micro-robot magnetic drive device and a control method based on double closed loop three-dimensional path tracking are disclosed. The method includes: inputting a desired tracking path, obtaining current pose information of a magnetic micro-robot through a camera, and then calculating a position of a center of mass, an actual axial direction, coordinates of a desired position point with the shortest distance from the center of mass on a desired tracking path, and a tangent direction of this point; calculating a horizontal distance, a vertical distance, a direction angle error, and a pitch angle error of the two points according to the actual axial direction, the tangent direction, and disturbance compensation; and obtaining a required rotating magnetic field according to a designed position closed loop controller.