Described are passenger seats (102) having a seat bottom (122) connected to the seat frame (108) at a hinge (130) at an aft portion of the seat bottom (122), and having a release mechanism (132) operably connected with the seat bottom (122) that, when actuated by a user, cause the seat bottom (122) to be released from a locked configuration to an unlocked configuration, whereby the seat bottom (122) is free to rotate downward, independent of a seat back (142), about the hinge (130) to a tilted position in order to increase a range of available angles between the seat bottom (122) and seat back (130).

A seat assembly includes a five-bar linkage for moving the seat assembly between a plurality of positions in an automotive vehicle. A first link is rotatably coupled to a seat back at a second pivot point disposed coaxial to a first pivot point, and to a seat base defining a fifth link at a third pivot point. A second link extends axially between the first and second pivot points. A third link is defined by a lower seat back portion and a seat cushion and extends between the first pivot point and a fifth pivot point disposed adjacent a front portion of the seat cushion. A fourth link is rotatably coupled to the third link at the fifth pivot point and the seat base at a fourth pivot point. The seat assembly is capable of moving to both a pitched easy entry position and a stow flat to floor position.

A control stand is disclosed for controlling a crane, an excavator, a crawler, or a similar construction machine having a seat, control elements actuable from the seat for inputting control commands, a display apparatus for displaying information, and a control unit for generating adjustment signals in dependence on input control commands and/or for providing information to the display apparatus. A crane is disclosed having such a control stand that can be configured in the form of a crane operator's cabin. The control elements and/or the display apparatus of the control stand and various further auxiliary units can be individually configurable. Personal pre-settings can be saved and can be reinvoked when the control stand or the crane is to be controlled by a certain machine operator.

A track assembly for a vehicle seating assembly includes a track that defines a lateral channel and a central channel. The lateral channel is in communication with the central channel. A plurality of contact strips are coupled with the track and are positioned within the lateral channel. A rail cartridge is positioned within the central channel and is slidable along the track. The lateral channel is at least partially enclosed by the track and the rail cartridge. A support is operably coupled with the rail cartridge and extends from the central channel into the lateral channel. A plurality of contacts are operably coupled with the support and are configured to engage the plurality of contact strips.

A technology disclosed in the present specification is a power supply device 10 configured to supply electric power to a seat S that can slide and rotate with respect to a floor part F of a vehicle. The power supply device 10 comprises: a power transmission unit 40 that is provided on the floor part F and extends along a sliding direction in which the seat S slides; and a power reception unit 70 that is provided on the seat S and receives electric power from the power transmission unit 40 in a contactless manner, wherein the power transmission unit 40 is provided such that the length dimension in the sliding direction is longer than the length dimension in a direction orthogonal to the sliding direction, and a portion of the power reception unit 70, which receives electric power from the power transmission unit 40, is disposed within an installation range of the power transmission unit 40 in a state of being close to the power transmission unit 40 while the seat S is sliding and rotating.

Systems and methods for using image analysis techniques to facilitate adjustments to vehicle components are disclosed. According to aspects, a computing device may access and analyze image data depicting an individual(s) within a vehicle, and in particular determine a positioning of the individual(s) within the vehicle. Based on the positioning, the computing device may determine how to adjust a vehicle component(s) to its optimal configuration, and may facilitate adjustment of the vehicle component(s) accordingly.

Systems and methods for automatically adjusting the interior cabin of an autonomous vehicle are provided. In one example embodiment, an autonomous vehicle can include a main body including a floor and a ceiling that at least partially define an interior cabin of the autonomous vehicle. The autonomous vehicle can include a partition wall that is movable within the interior cabin of the autonomous vehicle. The partition wall can extend between the floor to the ceiling of the main body. The autonomous vehicle can include a computing system configured to receive data indicative of one or more service assignments associated with the autonomous vehicle and to adjust a position of the partition wall within the interior cabin based at least in part on the one or more service assignments.

Systems and methods for reconfiguring seats of an autonomous vehicle is provided. The method includes obtaining service request data that includes a service selection and request characteristics. The method includes obtaining data describing an initial seat configuration for each of a plurality of seats of an autonomous vehicle assigned to the service request. The initial seat configuration can include a seat position and a seat orientation for each of the plurality of seats. The method includes generating, based on the initial cabin configuration and the service request data, seat adjustment instructions configured to adjust the initial seat configuration of at least one of the seats. The method includes providing the seat adjustment instructions to the autonomous vehicle assigned to the service request.

An electrical system may include a mounting surface, a component configured for connection with the mounting surface and configured to move relative to the mounting surface, and/or an orientation sensor configured to determining an orientation of the component relative to the mounting surface. The orientation sensor may include a first sensor (e.g., a magnetometer, an accelerometer, a gyroscope, etc.) connected, at least indirectly, to the mounting surface, and a second sensor (e.g., a magnetometer, an accelerometer, a gyroscope, etc.) connected to move with the component. The orientation sensor may include an electronic controller. The electronic controller may be configured to compare first information from the first sensor to second information from the second sensor to determine the orientation of the component relative to the mounting surface.

A method for controlling a vehicle seat valve, the piston thereof is actively displaced from a closed position into an open position or vice versa by an electrical voltage being applied to an electromagnetic drive means. The power of the drive means is regulated via an effective voltage which can be changed by means of pulse width modulation of an impulse voltage that has a constant frequency. In order to displace the piston from its closed position toward its open position, a duty cycle of the pulse width modulation is firstly increased from a rest duty cycle to a starting duty cycle of less than 100%, and the duty cycle is only raised to a final duty cycle when the piston has reached the open position and/or if a blockage impeding the displacement of the piston before it reaches its open position is identified.