Driver assistance system

What is claimed is: 1. A method for assistance to a driver of an ego-vehicle to avoid a vehicle collision, the ego-vehicle comprising an environmental sensor adapted to monitor the traffic environment around the ego-vehicle, a processor which receives data from the environmental sensor, and a control instrument configured to intervene in the directional or speed control of the ego-vehicle, the processor controlling the control instrument in response to information received from the environmental sensor; the method comprising: (1) monitoring the traffic environment around the ego-vehicle with the environmental sensor; (2) determining if the ego-vehicle is in danger of colliding with an object in front of the ego-vehicle by calculating a time to collision (TC) of the ego-vehicle with the object; (3) determining if the ego-vehicle is in a manual driving mode or an automated driving mode; (a) if the vehicle is in an automated driving mode, then planning a control intervention of a control instrument of the ego-vehicle based on the predicted time to collision (TC), said control intervention comprising: (i) determining if application of brakes of the vehicle at a first level of braking is sufficient to avoid collision with the object; and if so, controlling brakes to apply the brakes at the first level of braking to slow the ego-vehicle; and (ii) if braking at said first level of braking is not sufficient to avoid collision with the object, then determining if it is feasible to steer the ego-vehicle to swerve around the object; whereby, if it is feasible to steer around the object, the processor controls the control instrument to swerve around the object, and, if it is not feasible to steer around the object, the processor controls the brakes at a second level of braking greater than the first level of braking; and (b) if the vehicle is in a manual driving mode, then determining if the driver's hands are on the steering wheel or are likely on the steering wheel such that the driver is likely to execute a driver intervention; and if it is determined that the driver is not likely to execute a driver intervention, then planning a control intervention of a control instrument of the ego-vehicle based on predicted time to collision (TC), said control intervention comprising: (i) determining if application of brakes of the vehicle at a first level of braking is sufficient to avoid collision with the object; and if so, controlling brakes to slow the ego-vehicle and (ii) if braking at said first level of braking is not sufficient to avoid collision with the object, then determining if it is feasible to steer the ego-vehicle to swerve around the object; whereby, if it is feasible to steer around the object, the processor controls the control instrument to swerve around the object, and, if it is not feasible to steer around the object, the processor controls the brakes at a second level of braking greater than the first level of braking. 2. The method of claim 1 wherein, in manual driving mode, the method further includes the steps of: if it is determined the driver's hands are on the steering wheel or likely on the steering wheel, determining if the driver is executing an intervention; and determining if the driver intervention is sufficient to swerve around the assessed danger if the driver is executing an intervention, and providing supporting intervention in the same direction as the driver's intervention if the driver intervention may not avoid a collision; or, notifying the driver of the need to brake if it is determined the driver is not prepared to change lanes, and if a driver consent to braking is received, control braking of the ego-vehicle as necessary to avoid a collision or reduce a collision impact. 3. The method according to claim 1 , wherein the step of planning the control intervention comprises predicting a vehicle steering intervention having a maximum swerve not greater than a width of the vehicle for the driver of the ego-vehicle in reaction to the danger. 4. The method according to claim 1 , wherein the step of planning the control intervention comprises assessing a responsiveness of the driver and accounting for the responsiveness of the driver. 5. The method according to claim 4 , wherein the step of accounting for the responsiveness of the driver comprises responding to movement of the control instrument. 6. The method according to claim 1 , comprising a step of communicating the planned control intervention to the driver through a user interface. 7. The method according to claim 6 , wherein the user interface comprises an interface between the driver and the control instrument. 8. The method according to claim 7 , wherein the step of communicating the planned control intervention to the driver comprising signaling the driver to manipulate the control instrument without executing the planned control intervention. 9. The method according to claim 7 , wherein the control instrument comprises a steering wheel, wherein the step of communicating the planned control intervention to the driver comprises exercising a torque on the steering wheel in direction of the planned control intervention. 10. The method according to claim 1 , wherein the step of planning a control intervention further comprises predicting a vehicle braking intervention for the driver of the ego-vehicle in reaction to the danger. 11. The method according to claim 1 , wherein the step of planning a control intervention further comprises predicting a vehicle steering intervention having a maximum swerve not greater than a width of the vehicle for the driver of the ego-vehicle in reaction to the danger. 12. The method according to claim 1 , further comprising assessing the responsiveness of the driver with a sensor, wherein the step of planning the control intervention accounts for the responsiveness of the driver. 13. The method according to claim 1 , further comprising communicating the control intervention to the driver through a user interface.