The disclosure provides a vehicle excitation advice. The vehicle excitation device that excites a vehicle having a plurality of wheels includes a plurality of excitation machine bodies on which the wheels are placed, respectively. The excitation machine body includes a front shaft and a rear shaft on which the wheels are placed at intervals in the in the front-rear direction of the vehicle, and an actuator (hydraulic actuator) that excites vibration to the wheels by moving at least one of the front shaft and the rear shaft in the front-rear direction. The front shaft is inclined such that the inner end portion of the front shaft in the left-right direction of the vehicle is located closer to the front of the vehicle than the outer end portion of the front shaft in the left-right direction of the vehicle.

A chassis dynamometer for motorcycles with a combustion engine, having a mounting unit, at least one fastening unit, an operating unit, a control unit and a roller for recording the peripheral speed of a motorcycle rear wheel is disclosed. The chassis dynamometer has a flow unit a drive unit, a diffuser and an outflow unit arranged downstream of the diffuser in the direction of flow where the diffuser and outflow unit form a flow channel carrying gas in the operating state, wherein the diffuser can be driven by the drive unit, where the control unit controls the drive unit as a function of the peripheral speed of the roller in such a way that a speed of the gas emerging from the outflow unit in the operating state is substantially equal to the peripheral speed at least from a peripheral speed of 150 km/h.

A method and apparatus for measuring the propulsive power required to overcome drag forces on a vehicle mounted within a wind tunnel. The apparatus includes a running belt platform driven by a dynamometer and supporting the vehicle placed inside a wind tunnel and controlled by a closed-loop servo control system, which maintains the vehicle centered on the running belt under varying operating speeds and headwind conditions. The power dissipated in drag is measured as the power transferred through ground contact with the wheels of the vehicle.

A chassis dynamometer that tests a two-wheel drive vehicle includes: a driving wheel side roller on which the driving wheels of the vehicle are placed; a driven wheel side roller on which the driven wheels of the vehicle are placed; a driving wheel side power absorbing part connected to the driving wheel side roller; a driven wheel side power absorbing part connected to the driven wheel side roller; a braking force measuring part that, via the driven wheel side power absorbing part, measures braking force exerted on the driven wheel side roller; and a control part that with use of the braking force measured by the braking force measuring part, sets the control target value of the power absorbing force of the driving wheel side power absorbing part to control the driving wheel side power absorbing part.

A motorcycle test stand comprises at least one dynamometer configured and arranged to be connected to a drivetrain of a motorcycle to be tested, and a receptacle configured and arranged for receiving a motorcycle frame, and a base fixing the dynamometer and the receptacle relative to one another. The receptable has first and second connecting points configured and arranged to be coupled to the motorcycle frame.

The disclosure provides a vehicle excitation advice. The vehicle excitation device that excites a vehicle having a plurality of wheels includes a plurality of excitation machine bodies on which the wheels are placed, respectively. The excitation machine body includes a front shaft and a rear shaft on which the wheels are placed at intervals in the in the front-rear direction of the vehicle, and an actuator (hydraulic actuator) that excites vibration to the wheels by moving at least one of the front shaft and the rear shaft in the front-rear direction. The front shaft is inclined such that the inner end portion of the front shaft in the left-right direction of the vehicle is located closer to the front of the vehicle than the outer end portion of the front shaft in the left-right direction of the vehicle.

A target vehicle, for example a two-wheeled vehicle, for mounting onto an ADAS (Advanced Driver Assistance System) testing platform is provided. The target vehicle comprises one or more sensors and an actuation assembly comprising an actuator. The sensors are arranged to measure a parameter relating to the dynamics of the target vehicle and may for example comprise accelerometers. The actuation assembly adjusts the tilt of the target vehicle in dependence on the output of the sensor(s), for example by means of a control unit. The tilting of the vehicle during cornering may thus be simulated. The measuring of such a parameter and the adjusting of the tilt may be conducted remotely from the testing platform. The sensor(s), control unit and actuator assembly may be self-contained within the target vehicle. A method of modeling a VRU (Vulnerable Road User) for ADAS testing is also provided.

Described are various embodiments of an aerodynamic drag monitoring system and method. In one embodiment, a system is described to comprise a motion sensor and an aerodynamic sensor operable to acquire respective sensor values each associated with a respective sensor noise variance, a digital data storage medium having stored thereon a digital motion dynamic model and preset initialization parameters, and a digital data processor operable to iteratively process measured sensor values against the model to output a predicted value for a predicted aerodynamic drag variable over time while accounting for each sensor noise variance.

A chassis dynamometer that tests a two-wheel drive vehicle includes: a driving wheel side roller on which the driving wheels of the vehicle are placed; a driven wheel side roller on which the driven wheels of the vehicle are placed; a driving wheel side power absorbing part connected to the driving wheel side roller; a driven wheel side power absorbing part connected to the driven wheel side roller; a braking force measuring part that, via the driven wheel side power absorbing part, measures braking force exerted on the driven wheel side roller; and a control part that with use of the braking force measured by the braking force measuring part, sets the control target value of the power absorbing force of the driving wheel side power absorbing part to control the driving wheel side power absorbing part.

A motorcycle test stand comprises at least one dynamometer configured and arranged to be connected to a drivetrain of a motorcycle to be tested, and a receptacle configured and arranged for receiving a motorcycle frame, and a base fixing the dynamometer and the receptacle relative to one another. The receptable has first and second connecting points configured and arranged to be coupled to the motorcycle frame.