Abstract: A hinge apparatus for a cover of an image forming apparatus has a hinge body with supporting brackets, movably inserted into a coupling hole positioned in a main body of the image forming apparatus, a hinge cam connected to the cover and pivotably connected to the supporting brackets, and a pressure device disposed at the hinge body to press the hinge cam. Accordingly, the hinge apparatus can be implemented with a simple and easy assembly operation, since it is not a complicated structural connection among the component parts of the hinge apparatus.

Abstract: Systems and methods are provided for digital transport of paramagnetic particles. The systems and methods may include providing a magnetic garnet film having a plurality of magnetic domain walls, disposing a liquid solution on a surface of the magnetic garnet film, wherein the liquid solution includes a plurality of paramagnetic particles, and applying an external field to transport at least a portion of the paramagnetic particles from a first magnetic domain wall to a second magnetic domain wall of the plurality of magnetic domain walls.

Abstract: A domain drag effect stripline pattern of conductive magnetic bubble material deposited upon a substrate is located in a magnetic bias field preferably normal to the plane of the stripline. Magnetic bubbles can be propagated through the stripline in response to passage of D.C. current pulses through the stripline. The width and cross-sectional area of the stripline is preferably substantially constant except at a switching area where it may be different, and preferably wider. There a coil is juxtaposed with the stripline to apply a magnetic field upon the switching area with the magnetic field varying above and below a critical value to switch the propagation of magnetic bubbles along the stripline on and off as a function of the current through the coil. Alternatively, the external magnetic bias field can be modulated to turn the stripline switch on and off.

Abstract: Two parallel conductors are positioned on top of a magnetic layer where bubble domains are to be coded. The two parallel conductors are positioned to form a gap therebetween of a particular size. An external in-plane magnetic field is applied to the magnetic layer. The size of the gap is selected such that when current is simultaneously applied in both conductors, a local in-plane field will be formed in the gap which is sufficient for coding bubble wall states and a vertical field will be formed in the gap sufficient to retain a bubble in the gap during the application of current to the conductors. The application of current in the one direction in the conductors codes a bubble with one pair (S = 0) of Bloch lines and the application of current in the opposite direction codes a bubble with no Bloch lines (S = 1).

Abstract: A device operating with the displacement of magnetic domain walls and comprising a layer of a magnetizable material having an easy axis of magnetization perpendicular to the plane of the layer, in which layer magnetic domain walls can be produced, maintained and moved, as well as a device to cause a magnetic propulsive field to act upon magnetic domains present in the layer so as to move them between previously determined positions. In order to obtain maximum speeds, the propulsive field acting upon a domain wall during the movement should at any instant have a value which is below the value for which a drop occurs in the function which characterizes the magnetizable material and which represents the relation between the propulsive field and the speed.

Abstract: The critical velocity at which magnetic bubbles can propagate within a matic material is increased by establishing an easy axis of magnetization within the material. This axis is either growth-induced or strain-induced. In one embodiment, the material has a curvature imparted to it which places it under a uniaxial strain and this induces the magnetic easy axis.