Relative to a gaming system, a jackpot or game win processing device and server are configured to receive acknowledgement from a player regarding a gaming win award, such as input to the game win processing device of a signature by the player to gaming win forms. In response, the server is configured to generate at least one gaming win reporting form, such as a W2G, to generate a security code from at least two elements of personal information regarding the player, such as obtained from a casino player tracking server, to then secure the at the least one reporting form and then email the secure form to the player.

A header has a position controlled gauge wheel that is controlled using a position actuator. The position actuator is locked when the gauge wheel is in a selected position, relative to a mainframe of the header. An operator input, changing the position of the header, is detected and the position actuator is unlocked to accommodate movement of the header, based on the detected operator input signal.

An agricultural method for automatically controlling a position of a harvesting implement of an agricultural harvester, where the harvesting implement may be movably supported relative to a chassis of the agricultural harvester, and where a cab may be movably supported relative to the chassis, may include receiving inertial movement data from an implement-based inertial measurement unit (IMU) supported on the harvesting implement and inertial movement data from a vehicle-based IMU supported on at least one of the cab or the chassis of the agricultural harvester. The method may further include determining a relative movement parameter of the harvesting implement relative to the at least one of the cab or the chassis based at least in part on the inertial movement data. Additionally, the method may include controlling an operation of an implement actuator based at least in part on the relative movement parameter.

Systems, methods, and apparatuses for automatically controlling a position of a reel relative to wing of an agricultural header in response to movement of the wing are disclosed. In some instances, a position of the reel, such as a portion of the reel, is located at a different position relative to the wing based on an amount of articulation of the wing, such as an amount of angular displacement of the wing relative to a datum, such as a center frame of the header.

A control system for controlling pivoting of a header of an agricultural harvester. The control system includes first, second, and third header height sensors, each for mounting to a respective point on the header, each configured to provide a respective header height signal representing a respective measured header height of their respective point on the header above a ground plane. The control system further includes a header angle sensor configured to provide a header angle signal indicative of a pivot angle of the header about an axis; and a processor configured to: receive the signals; calculate an estimated first header height based on the pivot angle and the second and third header heights; determine a replacement first header height by selecting the smallest of the estimated and the measured first header height; and generate a control signal based at least on the replacement first header height.

An agricultural vehicle header suspension having a frame, a plurality of supports extending forward from the frame, an anchor plate, a frame pivot joining the frame to the anchor plate to be rotatable about a frame pivot axis, a frame actuator connected between the anchor plate and the frame and configured to resiliently hold the frame at a predetermined position relative to the anchor plate, and to allow the frame to move through a range of motion relative to the anchor plate, upon compression and/or extension of the frame actuator. The frame actuator may be, for example, at least one single-acting hydraulic actuator, mechanical spring, or a pneumatic cylinder.

A system for controlling harvesting implement height of an agricultural harvester may include a computing system configured to monitor the height of a harvesting implement of the harvester relative to a field surface based on the received sensor data. Additionally, the computing system may be configured to determine an implement height error signal by comparing the monitored height of the harvesting implement to a predetermined target height. Moreover, the computing system is configured to divide the determined implement height error signal into a first and second frequency portions, with the second frequency portion having a greater frequency than the first frequency portion. Furthermore, the computing system is configured to control the operation of first and second actuators of the harvester based on the first and second frequency portions of the implement height error signal, respectively.

In one aspect, a system for controlling the operation of harvesting implements configured for use with agricultural harvesters includes a harvesting implement configured to be supported relative to an agricultural harvester, and at least one user interface component supported on the harvesting implement. The user interface component(s) is configured to receive input commands associated with controlling an operation of the harvesting implement. The system also includes an implement-based controller supported on the harvesting implement and being communicatively coupled to the user interface element(s) such that the implement-based controller is configured to receive the input commands from the at least one user interface component.

An agricultural harvester including a header assembly, includes: a multicoupler storage assembly including: a multicoupler assembly including a plurality of at least one of hydraulic connectors and electrical connectors; and a cradle mechanism configured for storing the multicoupler assembly and for selectively pivoting between a receiving position associated with the cradle mechanism receiving the multicoupler assembly and a storage position associated with the cradle mechanism storing the multicoupler assembly.

An actuator assembly for moving an implement attached to an agricultural vehicle. The actuator assembly includes an actuator comprising a longitudinal axis, a cylinder extending along the longitudinal axis, and a piston rod extending from the cylinder along the longitudinal axis and that is configured to be attached to the implement at a connection point. A safety stop is pivotably attached at the connection point and is movable between a deployed position where the safety stop is configured to block retraction of the actuator, and a retracted position where the safety stop is not configured to block retraction of the actuator. The safety stop is configured to rotate with respect to the actuator about a first rotational axis that is orthogonal to the longitudinal axis, as well as a second rotational axis that is orthogonal to both the longitudinal axis and the first rotational axis.