Mowing systems include a mower and, optionally, a remote control unit such as a handheld unit, between which may be provided 1- or 2-way communications. Components and features are included in the mower, the remote control unit, or both to enhance the safety, functionality, or user experience of the system's user/operator. One aspect relates to monitoring a tilt angle of the mower, and defining or executing different system responses as a function of different first and second conditions that relate to the tilt angle. Another aspect relates to automatic adjustment of a speed setting of the mower's drive system as a function of a power takeoff (PTO) unit of the mower.

The present invention is related to a control system for controlling the movement of an aerial apparatus, in particular for controlling a turnable ladder of a firefighting vehicle, comprising a manually operable input device that is deflectable in at least one spatial direction by a deflecting force, an processing unit for converting the amount of deflection of the input device into a corresponding speed signal and an actuating unit for moving the aerial apparatus with a speed corresponding to the speed signal. The invention is characterized by determining means for determining a possible maximum speed and restricting means for counteracting or limiting the deflection of the input device according to the determined possible maximum speed.

The present disclosure includes a system, method, and device related to data collection and communication related to after-market and external vehicle systems, such as towing systems, cargo carrying systems, trailer breakaway systems, brake systems, braking control systems, and the like. Data is sensed, processed, shared, and further leveraged throughout the discrete components of the system, and possibly via internet and other communications' links, to effect various beneficial actions with minimal driver/user interaction or intervention. In the same manner, data from the system may be used for diagnostic reasons, safety controls, and other purposes.

An apparatus for protecting a passenger in a vehicle and a control method thereof. The apparatus includes a collision detection unit that detects a predicted collision state and a collision state of a vehicle; a seat belt driving unit that adjusts tension of a seat belt according to an operation mode; an airbag driving unit that deploys each of a plurality of airbags according to a driving signal; a capturing unit that captures images of an interior of the vehicle; an image processing unit that extracts passenger information by processing images inputted from the capturing unit; and a control unit that recognizes a passenger type and a seating position based on the passenger information, operates the seat belt driving unit by setting the operation mode, adjusts deployment time points of the plurality of airbags, and outputs the driving signal to the airbag driving unit.

An apparatus for protecting a passenger in a vehicle and a control method thereof. The apparatus includes a collision detection unit that detects a predicted collision state and a collision state of a vehicle; a seat belt driving unit that adjusts tension of a seat belt according to an operation mode; an airbag driving unit that deploys each of a plurality of airbags according to a driving signal; a capturing unit that captures images of an interior of the vehicle; an image processing unit that extracts passenger information by processing images inputted from the capturing unit; and a control unit that recognizes a passenger type and a seating position based on the passenger information, operates the seat belt driving unit by setting the operation mode, adjusts deployment time points of the plurality of airbags, and outputs the driving signal to the airbag driving unit.

Device (DMT) arranged to provide an additional voltage, when the heat engine starts up, for the electrical power supply of the rotating electrical machine (AD). This additional voltage is added to a rated voltage of the on-board electrical system (RB) provided by a battery (BAT). The device comprises a second voltage source (Ucap) and electronic switches (K1, K2), each comprising at least one MOSFET transistor. At least one MOSFET transistor (K2) of the switches, mounted in series with the second voltage source, is controlled in linear mode at the end of the startup of the heat engine. Advantageously, the device comprises current control loops for controlling the transistors in linear mode.

Safety device for a motor vehicle, having at least one sensor which is configured to detect an impending impact or an impending collision and possibly to generate a triggering signal, and having a control device which is configured to trigger a protective device if a triggering signal is present, wherein the safety device is configured to check whether the predicted impact or the collision has taken place within a predicted time period, and to transfer the motor vehicle into a safe state in the case of erroneous triggering.

A motor vehicle seatbelt restraint arrangement including a continuous seatbelt. When the occupant is seated the seatbelt buckle tongue is drawable across the body to engage the buckle providing firstly a pre-impact configuration of the seatbelt characterised by a lap belt portion resting on the hips or upper legs of the occupant, wherein the lap belt portion is rearward vertically offset relative to an underside belt portion of the continuous seatbelt across the seating surface of the seat, and secondly an impact configuration of the seatbelt characterised by the lap belt portion and the underside belt portion being less rearward vertically offset and substantially vertically aligned one with respect to the other to provide a more vertically aligned loop of the continuous seatbelt around the hips or upper legs of the occupant at impact preventing submarining of the occupant out from the motor vehicle seat during impact.

A method is described for ascertaining a group of at least two adjacently situated illumination units during the travel of a vehicle. The method includes a step of recognizing at least one first illumination unit and at least one second illumination unit in a detection range of a sensor and recognizing a subsequent departure of the first illumination unit from the detection range of the sensor. The method also includes a step of detecting a distance and/or a time which the vehicle travels after a departure of the first illumination unit from the detection range of the sensor up to a departure of the second illumination unit from the detection range of the sensor.

Obstructions in a path of a vehicle may be determined by recording a plurality of measurements while the vehicle is traveling through a geographic area. The plurality of measurements may involve a velocity of the vehicle, positions relative to the vehicle of a plurality of objects in the geographic area. Also, a path of a vehicle may be determined. An obstruction in the path may be detected as an object of the plurality of objects that is in the path. Also, the obstruction may be determined to be a stationary obstruction as a function of the velocity of the vehicle and multiple positions of the obstruction relative to the vehicle measured over time.