Wheel slip boost function for a heavy-duty vehicle

The invention claimed is: 1 . A computer implemented method for controlling at least one driven and/or braked wheel of a heavy-duty vehicle, the method comprising: obtaining a motion request indicative of a desired longitudinal acceleration and/or a desired longitudinal force associated with the heavy-duty vehicle; configuring a wheel slip limit value at a nominal wheel slip limit value in dependence of an inverse tyre model, wherein the inverse tyre model represents a first relationship between wheel slip and wheel force at the wheel with a peak corresponding to maximum longitudinal force at an associated wheel slip value, wherein the wheel slip limit value is indicative of a maximum allowable wheel slip by the at least one driven and/or braked wheel, and wherein the nominal wheel slip limit value is determined with a margin to the peak of the inverse tyre model; and increasing a magnitude of the configured wheel slip limit value from the nominal wheel slip limit value to a boost wheel slip limit value in response to detecting a boost signal, thereby enabling operation in a non-linear region of the inverse tyre model and beyond the peak of the inverse tyre model, the method also comprising controlling the at least one driven and/or braked wheel in dependence of the motion request and subject to the configured wheel slip limit value, wherein said boost wheel slip limit value is greater than the nominal wheel slip limit value, and wherein said boost signal is generated in response to a determination that a wheel slip limit value beyond the nominal wheel slip limit value is desired. 2 . The method according to claim 1 , further comprising determining a target wheel slip value as a nominal target wheel slip value in dependence of the motion request and in dependence of the inverse tyre model, the inverse tyre model representing a relationship between wheel slip and longitudinal wheel force, increasing the target wheel slip value from the nominal target wheel slip value to a boost target wheel slip value in response to detecting the boost signal, and controlling the at least one driven and/or braked wheel in dependence of the target wheel slip value. 3 . The method according to claim 1 , comprising obtaining the motion request as function of an accelerator pedal position or a brake pedal position. 4 . The method according to claim 1 , comprising obtaining the motion request from a motion support device, MSD, coordination function of a vehicle motion management, VMM, system comprised in the heavy-duty vehicle. 5 . The method according to claim 1 , comprising obtaining the motion request from an autonomous or semi-autonomous drive function comprised in the heavy-duty vehicle. 6 . The method according to claim 1 , comprising determining the nominal wheel slip limit value based on the inverse tyre model, wherein the inverse tyre model is further representative of a second relationship between wheel slip and wheel force of the at least one driven and/or braked wheel. 7 . The method according to claim 1 , wherein the boost signal is triggered by an accelerator pedal position or brake pedal position exceeding a threshold value. 8 . The method according to claim 1 , wherein the boost signal is arranged to be manually triggered by operation of a trigger device. 9 . The method according to claim 1 , wherein the boost signal is conditioned on that the heavy-duty vehicle is operating at a velocity below a vehicle velocity acceptance threshold. 10 . The method according to claim 1 , wherein the boost signal is conditioned on that the heavy-duty vehicle is operating at a yaw motion below a vehicle yaw motion acceptance threshold. 11 . The method according to claim 1 , comprising determining a lateral force requirement of the at least driven and/or braked wheel, wherein the boost signal is conditioned on that the lateral force requirement is below a lateral force requirement threshold. 12 . The method according to claim 1 , comprising increasing the configured wheel slip limit value from the nominal wheel slip limit value to the boost wheel slip limit value only during a pre-determined time period. 13 . The method according to claim 1 , wherein the boost signal is triggered by an accelerator pedal position or brake pedal position exceeding a threshold value for a pre-determined time period. 14 . The method according to claim 1 , wherein the boost signal is arranged to be remotely triggered by operation of a remote-control trigger device. 15 . The method according to claim 1 , comprising updating the inverse tyre model associated with the at least one driven and/or braked wheel in response to detecting the boost signal. 16 . A non-transitory computer-readable medium storing a computer program for performing the method of claim 1 when the computer program is executed on a computer. 17 . A control unit for controlling at least one driven and/or braked wheel of a heavy-duty vehicle, the control unit comprising processing circuitry arranged to obtain a motion request indicative of a desired longitudinal acceleration and/or a desired longitudinal force associated with the heavy-duty vehicle, and configure a wheel slip limit value indicative of a maximum allowable wheel slip by the at least one driven and/or braked wheel at a nominal wheel slip limit value, and also increase the configured wheel slip limit value from the nominal wheel slip limit value to a boost wheel slip limit value in response to detecting a boost signal, thereby enabling operation in a non-linear region of the inverse tyre model and beyond the peak of the inverse tyre model and to control the at least one driven and/or braked wheel in dependence of the motion request and subject to the configured wheel slip limit value. 18 . A heavy-duty vehicle comprising: a control unit for controlling at least one driven and/or braked wheel of a heavy-duty vehicle, the control unit comprising processing circuitry arranged to obtain a motion request indicative of a desired longitudinal acceleration and/or a desired longitudinal force associated with the heavy-duty vehicle, and configure a wheel slip limit value indicative of a maximum allowable wheel slip by the at least one driven and/or braked wheel at a nominal wheel slip limit value, and also increase the configured wheel slip limit value from the nominal wheel slip limit value to a boost wheel slip limit value in response to detecting a boost signal, thereby enabling operation in a non-linear region of the inverse tyre model and beyond the peak of the inverse tyre model and to control the at least one driven and/or braked wheel in dependence of the motion request and subject to the configured wheel slip limit value.