This invention is directed to a testing apparatus for testing a vehicle drive system by connecting load devices to the vehicle drive system, wherein the testing apparatus includes a handle operation amount input part for inputting a handle operation amount corresponding to a handle operation of a vehicle, an accelerator operation amount input part for inputting an accelerator operation amount corresponding to an accelerator operation of the vehicle, a brake operation amount input part for inputting a brake operation amount corresponding to a brake operation of the vehicle, and a control part for controlling the load devices based on the operation amounts simultaneously inputted by at least two of the handle operation amount input part, the accelerator operation amount input part and the brake operation amount input part.

A transfer case having a shift mechanism. The shift mechanism may include a shift rail, a range shift assembly, a mode shift assembly, and a sector cam. The sector cam may control movement of the range shift assembly and the mode shift assembly when the sector cam is rotated.

Inventive embodiments are directed to components, subassemblies, systems, and/or methods for continuously and infinitely variable transmissions (IVT). In one embodiment, a variator is adapted to receive a control system that cooperates with a shift nut to actuate a ratio change in an IVT. In another embodiment, a neutral lock-out mechanism is adapted to cooperate with the variator to, among other things, disengage an output shaft from a variator. Various inventive mechanical couplings, such as an output engagement mechanism, are provided to facilitate a change in the ratio of an IVT for maintaining a powered zero operating condition. In one embodiment, the output engagement mechanism selectively couples an output member of the variator to a ratio adjuster of the variator. Embodiments of a ratio adjuster cooperate with other components of the IVT to support operation and/or functionality of the IVT. Among other things, user control interfaces for an IVT are disclosed.

A continuously variable transmission includes a continuous gear-change mechanism, a gear-change operating section to which a gear-change operation is input, and a gear-change controlling section changing a gear ratio of the mechanism according to the gear-change operation that is input from the operating section. A first gear-change operation and a second gear-change operation, performed subsequently to the first operation, or an input from a second gear-change operating section can be input to the operating section. The e controlling section is provided with the plural gear ratios for plural gears and previously set, causes the mechanism to perform, according to the first operation, a gear-change operation to a gear ratio for a next gear, and to perform, according to the second operation, a gear-change operation to an intermediate gear ratio set between the gear ratio for the next gear and a gear ratio for a second next gear.

Inventive embodiments are directed to components, subassemblies, systems, and/or methods for continuously and infinitely variable transmissions (IVT). In one embodiment, a variator is adapted to receive a control system that cooperates with a shift nut to actuate a ratio change in an IVT. In another embodiment, a neutral lock-out mechanism is adapted to cooperate with the variator to, among other things, disengage an output shaft from a variator. Various inventive mechanical couplings, such as an output engagement mechanism, are provided to facilitate a change in the ratio of an IVT for maintaining a powered zero operating condition. In one embodiment, the output engagement mechanism selectively couples an output member of the variator to a ratio adjuster of the variator. Embodiments of a ratio adjuster cooperate with other components of the IVT to support operation and/or functionality of the IVT. Among other things, user control interfaces for an IVT are disclosed.

The invention refers to hydraulic rotation transmissions and can be used in power transmissions and transmissions where the stepless ratio variation is essential. It can also be used as stepless speed transmission for vehicles (FIG. 1). Getting any transmission ratio with higher performance factor is achieved by applying in the hydraulic transmission new scheme, including motionless and movable bodies containing two coupled rotors, composing of camshafts with pistons and separated by motionless wall. Transmission ratio varies from 0 to maximal value displacing the movable body in axial direction by means of overhanging control arm.

Inventive embodiments are directed to components, subassemblies, systems, and/or methods for continuously and infinitely variable transmissions (IVT). In one embodiment, a variator is adapted to receive a control system that cooperates with a shift nut to actuate a ratio change in an IVT. In another embodiment, a neutral lock-out mechanism is adapted to cooperate with the variator to, among other things, disengage an output shaft from a variator. Various inventive mechanical couplings, such as an output engagement mechanism, are provided to facilitate a change in the ratio of an IVT for maintaining a powered zero operating condition. In one embodiment, the output engagement mechanism selectively couples an output member of the variator to a ratio adjuster of the variator. Embodiments of a ratio adjuster cooperate with other components of the IVT to support operation and/or functionality of the IVT. Among other things, user control interfaces for an IVT are disclosed.

A force transmission transmits a force to a primary output gimbal plate and a secondary output gimbal plate. The secondary output gimbal plate supports the primary output gimbal plate. Each of three primary levers is supported by a primary pivot. Each primary lever is coupled to the primary output gimbal plate such that the three couplings are not collinear. Each of three secondary levers is supported by a secondary pivot. Each secondary lever is coupled to one of the primary levers by a force applying connector. Each secondary lever is coupled to the secondary output gimbal plate such that the three couplings are not collinear. The output gimbal plates may be coupled to the levers by flexible cables. The cables may be substantially contained within a tube. The output gimbal plates may be substantially smaller than the input gimbal plate.

A force transmission includes a gimbal plate having two degrees of freedom. Each of three lever arms is supported by a pivot between two ends of the lever arm. One end of each lever arm is coupled to the gimbal plate such that the three couplings are not collinear. An equalizer cable has two opposing ends, each end fixedly coupled to one of the lever arms. The equalizer cable is routed over a lever arm pulley pivotally coupled to another of the lever arms between the pivot and one end of the lever arm. The gimbal plate may be coupled to the three lever arms by flexible cables or by links that transmit compression forces but not tension forces. The cables may be substantially contained within a tube. The links may be electrically non-conductive. The force transmission may control a surgical end effector in a teleoperated surgical instrument.

A sensor device having at least one sensor element, such as a Hall sensor element, and at least one magnet element that can move in relation to the sensor element. The sensor element has a number of differently magnetized regions. The sensor element is configured to issue a sensor signal, which represents a condition defined by a magnetization of a region of the magnet element located in the measurement range of the sensor element. The sensor element determines the condition by means of one of at least three pre-defined sensor signal values.