Abstract: A method of controlling a motion support system (MSS) in a heavy commercial vehicle comprising repeatedly selecting a current drive mode; solving a quadratic programming (QP) problem related to optimal control of independently controlled MSS actuators in accordance with a current state of the vehicle and subject to constraints representing actuator limits, wherein the actuators include at least two electric motors at respective axles and a set of service brakes; and utilizing a solution of the QP problem for controlling the MSS. The selectable drive modes include a first drive mode, in which the QP problem represents a control allocation problem for the MSS, and a second drive mode, in which the QP problem minimizes power loss in the MSS. The QP problem in the second drive mode includes relationships between power loss and torque for at least two of the actuators, especially smooth approximate relationships.

Abstract: A method for controlling a technical system in real time, comprising: sensing a state of the technical system; with the sensed state, initiating independent executions of a plurality of optimization processes (P1, P2, P3, . . . ) configured to solve a predefined optimization problem related to optimal control of the technical system; after a predetermined delay, extracting a current solution vector (u1, u2, u3, . . . ) from each optimization process; computing differences (dij˜?ui?uj?) for pairs of the solution vectors; and on the basis of the differences, selecting at least one of the solution vectors for use in controlling the technical system.

Abstract: A control system for determining a reference side area for a vehicle entity. The vehicle entity is a vehicle or a vehicle trailer and having a nominal vehicle entity side area. The reference side area is adapted to be multiplied with a side force coefficient for determining a side force parameter proportional to a wind side force load imparted on the vehicle entity and/or to be multiplied with a lift coefficient for determining a lift parameter proportional to a wind lift load imparted on the vehicle entity and/or to be combined with a drag coefficient for determining a drag load imparted on the vehicle entity. The vehicle entity comprises a load surface adapted to receive a material load such that at least a portion of the material load can be exposed to wind loads. The load surface being associated with a load surface area and a load surface length.

Abstract: A control unit for controlling a heavy-duty vehicle, the control unit being arranged to receive ambient environment data from one or more environment sensors on the heavy-duty vehicle, and to predict an impact of the ambient environment on the motion of the heavy-duty vehicle, wherein the control unit is arranged to coordinate control of one or more motion support devices, MSDs, on the heavy-duty vehicle to compensate for the predicted impact of the ambient environment on the motion of the heavy-duty vehicle.

Abstract: A control system for a vehicle. The control system comprises a force determination controller adapted to determine external load characteristics of external loads that currently act or are predicted to act on the vehicle. The control system is adapted to determine a resulting force vector to be acting on the vehicle, using the external load characteristics, in order to obtain a requested vehicle operation behaviour. The control system is further adapted to issue control information to one or more motion support devices of the vehicle in order to control the one or more motion support devices so as to generate the resulting force vector on the vehicle. The control system further comprises a feedforward controller adapted to receive wind information representative of a wind currently acting or predicted to be acting on the vehicle.

Abstract: A control system for autonomous drive of a heavy-duty vehicle, comprising an autonomous drive, AD, controller configured with a trajectory tracking function arranged to track a desired vehicle trajectory is provided. A first vehicle model models a response by the vehicle to a requested steering angle. The AD controller generates a steering angle request based on the desired vehicle trajectory and on the first vehicle model. The control system includes a vehicle motion management, VMM, function arranged to receive the steering angle request from the AD controller, where the VMM function comprises a second vehicle model configured to be aligned with the first vehicle model, where the VMM function is arranged to obtain a desired vehicle behavior based on a response of the second vehicle model to the steering angle request, where the VMM function is arranged to determine motion support device control set points in dependence of the desired vehicle behavior.

Abstract: A steering assembly for a vehicle comprises first and second steering actuators, each configured to be actuated in accordance with at least one signal issued from a motion control system to control a steering angle of at least one steerable ground engaging member of the vehicle. The first and second steering actuators are associated with corresponding first and second nominal steering capabilities, each defining at least one limitation of at least one of the following: steering angle, steering angle rate and steering torque, for the at least one steerable ground engaging member. The motion control system is adapted to, upon detection of a malfunction associated with the first steering actuator, associate the second steering actuator with a second enhanced steering capability instead of the second nominal steering capability. The second enhanced steering capability is different from the second nominal steering capability.

Abstract: The present disclosure relates to an autonomous vehicle control system (100) for providing motion control of an autonomous vehicle (200), comprising: —a primary control unit (10) configured to perform longitudinal and lateral motion control of the vehicle during normal operation, —a secondary back-up control unit (20) configured to perform back-up longitudinal motion control when an emergency mode has been enabled, wherein the primary control unit is further configured to perform back-up lateral motion control when the emergency mode has been enabled. The invention further relates to a method for providing motion control of an autonomous vehicle and to an autonomous vehicle.

Abstract: The invention relates to a steering assembly (12) for a vehicle (10). The steering assembly (12) comprises a first steering actuator (14) and a second steering actuator (16). The first steering actuator (14) is adapted to be actuated in accordance with at least one signal issued from a motion control system (18) to control a steering angle of at least one steerable ground engaging member (20, 22) of the vehicle (10) to thereby control the steering of the vehicle (10). The first steering actuator (14) is associated with a first nominal steering capability, defining at least one limitation of at least one of the following: steering angle, steering angle rate and steering torque, for the at least one steerable ground engaging member (20, 22).

Abstract: A method of operating a vehicle comprising at least a first vehicle retarding subsystem controllable to retard the vehicle, and processing circuitry coupled to the at least first vehicle retarding subsystem, the method comprising the steps of: acquiring, by the processing circuitry from the first vehicle retarding subsystem, at least one value indicative of current energy accumulation by the first vehicle retarding subsystem; and determining, by the processing circuitry, a measure indicative of a retardation energy capacity currently available for retardation of the vehicle, based on: the acquired at least one value indicative of current energy accumulation by the first vehicle retarding subsystem; a predefined model of retardation energy accumulation by the first vehicle retarding subsystem; and a predefined limit indicative of a maximum allowed energy accumulation by the first vehicle retarding subsystem.

Abstract: The present disclosure relates to method for controlling a driving operation of an autonomously controlled vehicle. In particular, a navigation system is controlled to autonomously operate the vehicle in a direction from a position of loss of location to a first upcoming stop position; and to controlling the vehicle to a stand-still operation when the vehicle arrives at the stop position for calibration of a sensor arranged to measure an angular velocity of the vehicle.

Abstract: The present disclosure relates to a method for controlling a driving operation of an autonomously controlled vehicle, the vehicle comprising an angular velocity sensor for controlling the vehicle's lateral positioning along an operated road path during a loss of location situation, the method comprising: obtaining a signal indicative of a characteristics of a road path for operation of the vehicle determining an uncertainty parameter value of the angular velocity sensor for an upcoming position of the road path ahead of the vehicle; and controlling the vehicle to a stand-still operation at a stop position, prior to arrival at the upcoming position, along the road path for calibration of the angular velocity sensor when the uncertainty parameter value indicates an unacceptable uncertainty in lateral deviation of the vehicle at the upcoming position.

Abstract: The disclosure relates to a method for estimating a maximum safe articulation angle (?lim) to be used in reversing of a vehicle combination (1) comprising a towing vehicle (10) and at least one trailer (20), said method comprising: S1) providing a preset maximum safe articulation angle (?lim) for the towing vehicle (10) or the vehicle combination (1), S2) receiving a signal being indicative of an articulation angle (?) of the vehicle combination (1) during forward driving of the vehicle combination (1), and S3) updating the maximum safe articulation angle (?lim) when the articulation angle (?) of the vehicle combination (1) during forward driving is larger than the preset maximum safe articulation angle (?lim). The disclosure also relates to a method for reversing a vehicle combination (10), to a control unit (11), to a towing vehicle (10), to a computer program and to a computer readable medium.

Abstract: The disclosure relates to a method for reversing a vehicle combination (1) comprising a towing vehicle (10) and at least one trailer (20), said method comprising: (S10) reversing the vehicle combination, (S20) determining whether a jack-knifing condition (J) is about to occur by comparing a predicted future estimate of the articulation angle (?) with a maximum safe articulation angle (?lim), wherein the maximum safe articulation angle (?lim) is estimated according to the first aspect of the invention, and when it is determined that the jack-knifing condition (J) is about to occur, perform at least one of the following steps: (S30) issue a warning signal, and (S40) initiate a braking action for the vehicle combination, wherein the predicted future estimate of the articulation angle (?) is based on an estimated driver reaction time for initiating a braking action.

Abstract: A computer-implemented method for reducing a lateral drift of a heavy-duty vehicle due to a road bank angle, where the heavy-duty vehicle is associated with a non-zero understeer/oversteer gradient. The method comprises obtaining a road bank angle of a road section the heavy-duty vehicle is about to traverse; obtaining a vehicle model indicative of a vehicle motion response to the road bank angle, where the vehicle model includes the understeer/oversteer gradient; determining, based on the road bank angle and the vehicle model, a first compensation torque for reducing the lateral drift of the heavy-duty vehicle at the road section; and applying the first compensation torque across different wheels of the heavy-duty vehicle to reduce the lateral drift of the heavy-duty vehicle due to the road bank angle.

Abstract: A control arrangement for a vehicle motion system including a braking function, comprising motion actuators with one or more brake actuators pertaining to the braking function, a first vehicle motion management controller (VMM1) and a second vehicle motion management controller (VMM2), forming a redundant assembly to control the braking function, wherein, in riding conditions, the first vehicle motion management controller controls the brake actuators with a current nominal expected braking performance, while the second vehicle motion management controller (VMM2) is in a waiting-to-operate mode, the control arrangement comprising a hot swap functionality in which the second vehicle motion management controller (VMM2) is configured to take over control of the brake actuators from the first vehicle motion management controller, with the current nominal expected braking performance, in a short time period (SWT) less than one second, preferably less than 0.5 second, preferably less than 0.

Abstract: The present disclosure relates to an autonomous vehicle control system (100) for providing motion control of an autonomous vehicle (200), comprising: —a primary control unit (10) configured to perform longitudinal and lateral motion control of the vehicle during normal operation, —a secondary back-up control unit (20) configured to perform back-up longitudinal motion control when an emergency mode has been enabled, wherein the primary control unit is further configured to perform back-up lateral motion control when the emergency mode has been enabled. The invention further relates to a method for providing motion control of an autonomous vehicle and to an autonomous vehicle.

Abstract: The invention relates to a method of operating a vehicle (1) comprising at least a first vehicle retarding subsystem (3; 5; 13) controllable to retard the vehicle (1), and processing circuitry (15) coupled to the at least first vehicle retarding subsystem (3; 5; 13), the method comprising the steps of: acquiring (S10), by the processing circuitry (15) from the first vehicle retarding subsystem (3; 5; 13), at least one value indicative of current energy accumulation by the first vehicle retarding subsystem (3; 5; 13); and determining (S11), by the processing circuitry (15), a measure indicative of a retardation energy capacity currently available for retardation of the vehicle (1), based on: the acquired at least one value indicative of current energy accumulation by the first vehicle retarding subsystem (3; 5; 13); a predefined model of retardation energy accumulation by the first vehicle retarding subsystem (3; 5; 13); and a predefined limit indicative of a maximum allowed energy accumulation by the first ve

Abstract: The disclosure relates to a method for estimating a maximum safe articulation angle (?lim) to be used in reversing of a vehicle combination (1) comprising a towing vehicle (10) and at least one trailer (20), said method comprising: S1) providing a preset maximum safe articulation angle (?lim) for the towing vehicle (10) or the vehicle combination (1), S2) receiving a signal being indicative of an articulation angle (?) of the vehicle combination (1) during forward driving of the vehicle combination (1), and S3) updating the maximum safe articulation angle (Vim) when the articulation angle (?) of the vehicle combination (1) during forward driving is larger than the preset maximum safe articulation angle (?lim). The disclosure also relates to a method for reversing a vehicle combination (10), to a control unit (11), to a towing vehicle (10), to a computer program and to a computer readable medium.

Abstract: The invention relates to a steering assembly (12) for a vehicle (10). The steering assembly (12) comprises a first steering actuator (14) and a second steering actuator (16). The first steering actuator (14) is adapted to be actuated in accordance with at least one signal issued from a motion control system (18) to control a steering angle of at least one steerable ground engaging member (20, 22) of the vehicle (10) to thereby control the steering of the vehicle (10). The first steering actuator (14) is associated with a first nominal steering capability, defining at least one limitation of at least one of the following: steering angle, steering angle rate and steering torque, for the at least one steerable ground engaging member (20, 22).