Abstract: A variable resistance device comprises a resistive member having a resistive resilient material. A first conductor is configured to be electrically coupled with the resistive member at a first contact location over a first contact area. A second conductor is configured to be electrically coupled with the resistance member at a second contact location over a second contact area. The first contact location and second contact location are spaced from one another by a distance. The resistance between the first conductor at the first contact location and the second conductor at the second contact location is equal to the sum of a straight resistance component and a parallel path resistance component. At least one of the first location, the second location, the first contact area, and the second contact area is changed to produce a change in resistance between the first conductor and the second conductor.

Abstract: A variable resistance device comprises a resistive member having a resistive resilient material. A first conductor is configured to be electrically coupled with the resistive member at a first contact location over a first contact area. A second conductor is configured to be electrically coupled with the resistance member at a second contact location over a second contact area. The first contact location and second contact location are spaced from one another by a distance. The resistance between the first conductor at the first contact location and the second conductor at the second contact location is equal to the sum of a straight resistance component and a parallel path resistance component. At least one of the first location, the second location, the first contact area, and the second contact area is changed to produce a change in resistance between the first conductor and the second conductor.

Abstract: A variable resistance device comprises a resistive member having a resistive resilient material. A first conductor is configured to be electrically coupled with the resistive member at a first contact location over a first contact area. A second conductor is configured to be electrically coupled with the resistance member at a second contact location over a second contact area. The first contact location and second contact location are spaced from one another by a distance. The resistance between the first conductor at the first contact location and the second conductor at the second contact location is equal to the sum of a straight resistance component and a parallel path resistance component. At least one of the first location, the second location, the first contact area, and the second contact area is changed to produce a change in resistance between the first conductor and the second conductor.

Abstract: A method of providing a variable resistance from a resistive member including a resistive resilient material comprises electrically coupling a first conductor with the resistive member at a first contact location over a first contact area; and electrically coupling a second conductor with the resistive member at a movable second contact location over a second contact area. The second contact location is movable relative to the resistive member to change the second contact location between the second conductor and the resistive member, the first contact location and the movable second contact location being spaced from one another by a distance.

Abstract: A windmill apparatus utilizing a base having a partition forming a chamber. Vanes are also included and possess means for pivoting the same. Each vane has a portion that moves along an arcuate path within the chamber. The base rotates around a central pivot by wind that enters the chamber and impinges on the vanes.

Abstract: A pointing device comprises a substrate with an electrically conductive surface (36) and a resilient return member (12). The return member resiliently supports a resistive surface (20) to contact the electrically conductive surface (36) in a pressed mode when a force (23) is applied to push and deform the return member against the electrically conductive surface. The return member (12) is made of a resistive rubber material. The resistive surface (20) has a voltage variance and is curved to be rocked on the electrically conductive surface (36) in the pressed mode. The voltage variance is detected on the electrically conductive (20) surface and a variable signal is generated and processed. In a specific embodiment, a dome switch is disposed between the resistive surface and the electrically conductive surface to provide a drag function.

Abstract: A pointing device comprises a substrate with an electrically conductive surface and a resilient boot. The resilient boot resiliently supports a resistive surface to contact the electrically conductive surface in a pressed mode when a force is applied to push and deform the resilient boot against the electrically conductive surface. The resilient boot is made of a resistive rubber material. The resistive surface has a voltage variance and is curved to be rocked on the electrically conductive surface in the pressed mode. The voltage variance is detected on the electrically conductive surface and a variable signal is generated and processed. At least one inner switch is provided near the center region of the electrically conductive surface and the inner switch is activated by the resistive surface in the pressed mode. When the force is removed, the resistive resilient boot returns to its undeformed state and the resistive surface is spaced from the electrically conductive surface in a rest mode.

Abstract: A variable resistance device comprises a resistive member having a resistive resilient material. A first conductor is configured to be electrically coupled with the resistive member at a first contact location over a first contact area. A second conductor is configured to be electrically coupled with the resistance member at a second contact location over a second contact area. The first contact location and second contact location are spaced from one another by a distance. The resistance between the first conductor at the first contact location and the second conductor at the second contact location is equal to the sum of a straight resistance component and a parallel path resistance component. At least one of the first location, the second location, the first contact area, and the second contact area is changed to produce a change in resistance between the first conductor and the second conductor.

Abstract: A variable resistance device comprises a resistive member having a resistive rubber material. A first conductor is configured to be electrically coupled with the resistive member at a first contact location over a first contact area. A second conductor is configured to be electrically coupled with the resistance member at a second contact location over a second contact area. The first contact location and second contact location are spaced from one another by a distance. The resistance between the first conductor at the first contact location and the second conductor at the second contact location is equal to the sum of a straight resistance component and a parallel path resistance component. At least one of the first location, the second location, the first contact area, and the second contact area is changed to produce a change in resistance between the first conductor and the second conductor.

Abstract: A pointing device comprises a stick coupled to a resilient return member which is supported on a substrate along an outer edge to move relative to an upper substrate surface of the substrate. The upper substrate surface has conductive lines and resistive coatings formed thereon or embedded therein. The return member has a conductive surface which is biased with a voltage and is normally spaced from the upper substrate surface. When an user applies an external force to the stick to move the return member toward the substrate, the conductive surface makes electrical contact with the substrate surface and generates a digital signal. The conductive surface is convex to provide rolling contact with the substrate surface to change the contact location. The conductive surface is deformable to allow the area of contact to increase with an increased external force for a change in resistance.

Abstract: An ergonomic pointing device comprises an orb controller coupled to a resilient return member which is supported on a substrate to move relative to an upper substrate surface of the substrate. The substrate surface has conductive lines and resistive coatings formed thereon or embedded therein. The return member has a conductive surface which is biased with a voltage and is spaced from the substrate surface at rest. When a user applies an external force to the orb controller to move the return member toward the substrate, the conductive surface makes electrical contact with the substrate surface and generates a digital signal. The conductive surface is convex to provide rolling contact with the substrate surface to change the contact location. The orb controller has a curved control surface which is contacted by a digit of a human hand to manipulate movement of the conductive surface relative to the substrate surface. The orb controller has a substantially smaller height than a joystick.

Abstract: A pointing device comprises a substrate with an electrically conductive surface and a resilient boot. The resilient boot resiliently supports a resistive surface to contact the electrically conductive surface in a pressed mode when a force is applied to push and deform the resilient boot against the electrically conductive surface. The resilient boot is made of a resistive rubber material. The resistive surface has a voltage variance and is curved to be rocked on the electrically conductive surface in the pressed mode. The voltage variance is detected on the electrically conductive surface and a variable signal is generated and processed. At least one inner switch is provided near the center region of the electrically conductive surface and the inner switch is activated by the resistive surface in the pressed mode. When the force is removed, the resistive resilient boot returns to its undeformed state and the resistive surface is spaced from the electrically conductive surface in a rest mode.

Abstract: Methods and devices for energy conservation to be retrofitted to refrigerated chambers or boxes of the type comprising an insulated chamber and an associated compression-type refrigeration system. The energy conservation devices disclosed are adapted to be mounted within the refrigerated chamber, on or within the evaporator, and connected to the thermostatic switch and the evaporator fans located within the refrigerated chamber.

Abstract: Methods and devices for energy conservation to be retrofitted to refrigerated chambers or boxes of the type comprising an insulated chamber and an associated compression-type refrigeration system. The energy conservation devices disclosed are adapted to be mounted within the refrigerated chamber, on or within the evaporator, and connected to the thermostatic switch and the evaporator fans located within the refrigerated chamber.