An embodiment of the invention relates to a device for detecting an analyte in a sample. The device comprises a fluidic network and an integrated circuitry component. The fluidic network comprises a sample zone, a cleaning zone and a detection zone. The fluidic network contains a magnetic particle and/or a signal particle. A sample containing an analyte is introduced, and the analyte interacts with the magnetic particle and/or the signal particle through affinity agents. A microcoil array or a mechanically movable permanent magnet is functionally coupled to the fluidic network, which are activatable to generate a magnetic field within a portion of the fluidic network, and move the magnetic particle from the sample zone to the detection zone. A detection element is present which detects optical or electrical signals from the signal particle, thus indicating the presence of the analyte.

Provided is a conveyance device that conveys a conveyance object having a magnetic body, the conveyance device including: a plurality of coils configured to generate magnetic flux acting on the magnetic body; a coil driving unit configured to apply a voltage to each of the plurality of coils; and a calculation control unit including a current control unit and a position estimation unit. The current control unit determines the voltage. The position estimation unit estimates a position of the conveyance object based on a change in a current generated by applying a voltage pulse to the coils and switches, according to a position estimation value that indicates the position of the conveyance object estimated by the position estimation unit, between a speed control mode in which a speed of the conveyance object is controlled and a current control mode in which a current through the coils is controlled. Accordingly, in the conveyance device that has a function of estimating the position of the conveyance object based on information on the current flowing through winding wires of the coils, it is possible to implement stable conveyance speed control even in a section in which accuracy for estimating the position or speed of the conveyance object is low.

A novel, simple, inexpensive and universal device and method for manipulating a magnetic object with at least a portion thereof having a substantially prismatic shape with side surfaces and an end surface such as a fastener, bolt, nut, plug, screw, and the like is disclosed. One embodiment of the device includes a head assembly having a magnetic field. The head assembly includes a body and a magnetic pole piece. The body serves to support the magnetic pole piece and the magnetic pole piece is configured to contact no more than two side surfaces of the magnetic object. The magnetic pole piece is also constructed and arranged to concentrate and shape the magnetic field into the magnetic object. The head assembly is further configured to be spatially open opposite from the magnetic pole piece so as to receive and contact the magnetic object.

Disclosed is an electro-permanent magnet (EPM) including a structure. The structure includes at least one first magnet, at least one second magnet, at least one core associated with formation of a magnetic field within the structure, and a device configured to change a direction of a magnetic field of the at least one first magnet, wherein the core is arranged between the first magnet and the second magnet, and the first magnet and the second magnet are connected via the core.

In an interactive environment, a user action may dictate what type of action a base device performs using an entertainment object. In one embodiment, the base device includes a controllable electromagnet that uses magnetism to move one or more permanent magnetics mounted in or on the entertainment object. For example, the entertainment object may be a doll or character that jumps, vibrates, slides, or sways in response to a changing magnetic field generated by the electromagnet. Moreover, the user may wear headphones that determine the location of the base device (and the toy) relative to the user. Using this location, the headphones can output 3D positional audio that the user perceives as originating from the location of the entertainment object on the base device. The 3D positional audio can be outputted synchronously with the action performed by the entertainment object to further immerse the user in the interactive environment.

A magnetic manipulation and navigation system for moving a magnetic element through a body comprising at least six electromagnets with soft-magnetic cores arranged in a predetermined position to the body. One or more of the electromagnets operate in the non-linear regime of the magnetization curve of the cores. At least one magnetic field sensor is at one or more predetermined positions outside of the operating region. In the linear region, no feedback is required to set the magnetic field strength. In the non-linear region, feedback from the magnetic field sensors is used for closed-loop control. The system has an open loop mode operation in the linear regime for fast control signals, for stabilization during displacement of the magnetic element, and a closed-loop operation in the non-linear regime for higher field strengths, to apply forces and moments on the magnetic element while it is in contact with a surface.

A laboratory sample distribution system and to a laboratory automation system comprising a printed circuit board arrangement and a coil are presented. The printed circuit board arrangement and the coil are configured such that assembly and maintenance of the laboratory automation system are greatly simplified.

A transport device and a transport method efficiently increase a thrust to suppress power consumption. The transport device has a first magnetic body on a side of a to-be-transported object, a magnetic circuit with a core consisting of a second magnetic body, and a winding wound around an outside of the core, and a drive circuit supplying a current to the winding of the magnetic circuit. The magnetic circuit has first and second magnetic circuits, and in a case where the first magnetic body is located on a side of the second magnetic circuit relative to a first predetermined position between the first magnetic circuit and the second magnetic circuit, the drive circuit supplies a current to a winding of the first magnetic circuit in such a manner to cause an electromagnetic repulsive force to be generated between the first magnetic body and the first magnetic circuit.

A periodic arrangement of magnets are used to form structures that channel the potential energy that a magnet possesses into kinetic energy in a controlled fashion to perform some useful work or function. One function is to create a magnetic chute that converts the potential energy of a magnetic projectile into kinetic energy that is used to channel the projectile to follow a path achieving high velocities along a path. The path is formed by assembling magnets periodically along the path in a certain fashion to create a magnetic chute that allows the magnetic projectile to slide easily along the path since the projectile is confined by the shape of the magnetic chute.

Disclosed herein is a magnetic substance holding device that minimizes residual magnetism by way of employing structures for minimizing reluctance to magnetic flux flow.