A tractor includes an engine, a vehicle body, a rear PTO shaft, a central PTO shaft, a permission switch, and a control unit. The engine is configured to generate power. The vehicle body includes an operator's seat. The rear PTO shaft is configured to supply power generated by the engine to a rear work machine attached to a rear part of the vehicle body. The central PTO shaft is configured to supply power generated by the engine to a central work machine attached to a central part of the vehicle body. The permission switch is operable by an operator. The control unit indicates that the permission switch is operated as one of permission conditions for rotation of the rear PTO shaft after disembarkation, and indicates that the permission switch is operated as one of permission conditions for rotation of the central PTO shaft when moving backward.

The systems and methods described herein disclose regulation of vehicle access based on operator proficiency. The systems and methods for regulating vehicle access by an operator include determining, using driving capacity information, a driving capacity metric for an operator in a vehicle. A vehicle system of the vehicle can then be evaluated for a vehicle system proficiency. The driving capacity metric and the vehicle system proficiency can then be compared. Then, using the comparison, a proficiency level of the operator can be determined for the at least one vehicle system. Finally, access to the at least one vehicle system can be provided to the operator based on the proficiency level.

According to one embodiment, provisioning an amount of power for one or more vehicles can comprise receiving a request indicating a requirement for an amount of power for the one or more vehicles. The request can indicate the requirement for the amount of power for the one or more vehicles individually or in total. A set of management rules can be read from one or more databases. A set of service configuration information and a set of vehicle specific information for the one or more vehicles can also be read from one or more databases. One or more power sources to meet the requirement for the amount of power for the one or more vehicles can be determined based on applying the management rules and using the set of service configuration information and the set of vehicle information and an indication of the determined power sources can be provided.

Systems of a vehicle and the operations thereof are provided. The vehicle can associate sensitive information for a user of the vehicle. Then, the vehicle can automatically provide the sensitive information for either the driver and/or passenger to a third party in an interaction with the third party. As such, user employ the automated systems of the vehicle for interactions with third parties.

A method and system are provided for detecting a driver and passenger in a vehicle. The vehicle processor stores first and second sensitive information for the driver and passenger, respectively. In response to detecting the second presence of the passenger, provides a user interface for the passenger to enter the second sensitive information, receives and associates the second sensitive information with the vehicle and, while the vehicle is in motion, communicates with an external third party positioned along a selected route of the vehicle to perform a transaction on behalf of the passenger using the second sensitive information.

A vehicle is provided that comprises two or more radio frequency (RF) antennas and two or more RF transceivers to communicate wirelessly sensitive information associated with a user of the vehicle (the two or more RF antennas being at different physical locations on an exterior of the vehicle). The vehicle determines which one of the two or more RF antennas is receiving a strongest signal from a common signal source, selects a first RF transceiver associated with the RF antenna with the strongest signal to send the sensitive information associated with the user to the common signal source, and sends the sensitive information associated with the user to the first RF transceiver for transmission to the common signal source.

Controlling availability of features of a vehicle can be based on a set of initial parameters, with each parameter related to a feature of the vehicle and defining availability of the feature. The set of initial parameters can define at least one feature of the vehicle as unavailable but further define the unavailability of the at least one feature of the vehicle as overridable upon detection of an emergency condition by the control system of the vehicle. The control system of the vehicle can apply the set of initial parameters to operations of the vehicle to control. At another time, a set of updated parameters with at least one parameter having a different value than the initial set of parameters can be applied by the control system of the vehicle to control operations of the vehicle based on levels indicated by the set of updated parameters.

A device that controls the electrical connections to an accessory actuation solution, with integrated motion detection as an activation interlock, and diagnostic monitoring of the accessory. The device can use relays, or electronic drive solutions, to control electric or electro-hydraulic actuation devices. The device measures accelerations, rotations, voltages, currents, pressures, temperatures and other signals to provide diagnostic information about the accessory being controlled and vehicle to ensure safe operating conditions exist to activate the device. The device prohibits activation of the actuator if motion above a threshold is detected in more than one degree of freedom. The device connects with a dedicated remote control, or a third party device running a software application, either of which can control the actuation of the device and receive diagnostic information, The application collects and analyzes data, directly or indirectly via the dedicated remote, on the performance of the actuator for analysis.

A vehicle is provided that determines a need for communication with a third party vendor, retrieves a user rule from the memory (the user rule defines to which third party vendor the vehicle can send a first communication to address the need and defines a geographic location of the third party vendor relative to a current location of the vehicle, a monetary amount the vehicle can pay to a third party vendor for a product or service to address the need, and a time limit for the third party vendor to provide the product or service to address the need), based on the user rule, selects a third party vendor from among multiple possible third party vendors, and when determined by the user rule, automatically sends the first communication to the selected third party vendor to address the need. The first communication is associated with an order for the product or service, and the processor provides an authorization to the selected third party vendor to complete the order. The vehicle uses different antennas positioned at different physical locations on an exterior of the vehicle to provide the first communication and authorization to the selected third party vendor.

A vehicle includes an on board microprocessor that is programmed to receive and transmit multiple authentication factors or a key derived therefrom to a remote server to authenticate the vehicle or a vehicle occupant to a remote server. The multiple authentication factors comprise a plurality of an electronic address of a portable communication device of the occupant sensed by an on board sensor, a wireless remote signal description sensed by an on board sensor, a vehicle-related identifier, a vehicle parameter sensed by the on board processor, an environmental parameter sensed by the on board processor, and a passcode received by the microprocessor from the remote server.