Driver assistance system and method

What is claimed is: 1. A driver assistance system comprising: a first sensor installed at a vehicle and configured to have a field of view directed forward from the vehicle to acquire front image data; a second sensor selected from a group of radar and LIDAR sensors, installed at the vehicle, and configured to have a field of view directed forward from the vehicle to acquire front detection data; and a controller having a processor configured to process the front image data and the front detection data, wherein the controller is configured to: detect a lane, in which the vehicle is traveling, or detect a front object located in front of the vehicle, in response to the processing of the image data and the front detection data, determine a predetermined area which is narrower than an area having a width of the lane and a length of a distance between the vehicle and the front object, output a braking signal to a braking system of the vehicle to control the braking system to perform braking control, when a collision between the vehicle and the front object is expected at time t 0 , output a steering signal to a steering system of the vehicle to control the steering system to perform primary steering control until the vehicle is in the predetermined area and continue to output the braking signal to the braking system to continuously control the braking system to perform the braking control, when a collision between the vehicle and the front object is expected even with braking control at time t 1 after t 0 , and after the vehicle is in the predetermined area, output another steering signal to the steering system of the vehicle to control the steering system to perform secondary steering control to avoid a collision with the front object while keeping the vehicle in the lane. 2. The driver assistance system of claim 1 , wherein the controller is configured to, when a collision between the vehicle and the front object is expected, output the steering signal to the steering system of the vehicle in order for the vehicle to avoid the collision with the front object and stay in the lane, in which the vehicle is traveling. 3. The driver assistance system of claim 1 , wherein the controller is configured to calculate a yaw rate required for the vehicle to avoid a collision with the front object and stay in the lane, in which the vehicle is traveling. 4. The driver assistance system of claim 3 , wherein the controller is configured to output the steering signal to the steering system of the vehicle and output the braking signal to the braking system of the vehicle, in order for the vehicle to avoid a collision with the front object and stay in the predetermined area in the lane, in which the vehicle is traveling. 5. The driver assistance system of claim 1 , wherein the controller is configured to calculate a yaw rate in real time, the yaw rate being required for the vehicle to travel to stay in the predetermined area. 6. The driver assistance system of claim 5 , wherein the controller is configured to output the steering control signal changed according to the yaw rate calculated in real time to the steering system. 7. The driver assistance system of claim 6 , wherein the controller is configured to expect a collision between the vehicle and the front object based on a distance to the front object and relative speed of the front object. 8. A driver assistance method comprising: using a camera installed at a vehicle and having a field of view directed forward from the vehicle to acquire front image data of the vehicle; using a front radar installed at the vehicle and having a field of view directed forward from the vehicle to acquire front radar data of the vehicle; detecting a lane, in which the vehicle is traveling, or detecting a front object located in front of the vehicle, in response to processing of the image data and the front radar data; determining a predetermined area which is narrower than an area having a width of the lane and a length of a distance between the vehicle and the front object, putting a brake on the vehicle when a collision between the vehicle and the front object is expected at time t 0 ; performing primary steering control of the vehicle until the vehicle is in the predetermined area and continuing to put the brake on the vehicle, when a collision between the vehicle and the front object is expected even with the braking of the vehicle at time t 1 after t 0 ; and after the vehicle is in the predetermined area, performing secondary steering control of the vehicle to avoid a collision with the front object while keeping the vehicle in the lane. 9. The driver assistance method of claim 8 , further comprising: when a collision between the vehicle and the front object is expected, changing a traveling direction of the vehicle to avoid the collision with the front object and stay in the lane, in which the vehicle is traveling. 10. The driver assistance method of claim 8 , further comprising: calculating a yaw rate required for the vehicle to avoid a collision with the front object and stay in the lane, in which the vehicle is traveling. 11. The driver assistance method of claim 10 , further comprising: changing a traveling direction of the vehicle and putting the brake on the vehicle, in order for the vehicle to avoid a collision with the front object and stay in the predetermined area in the lane, in which the vehicle is traveling. 12. The driver assistance method of claim 11 , further comprising: calculating a yaw rate in real time, the yaw rate being required for the vehicle to travel to stay in the predetermined area. 13. The driver assistance method of claim 12 , further comprising: outputting a steering control signal changed according to the yaw rate calculated in real time to a steering system. 14. The driver assistance method of claim 13 , further comprising: expecting a collision between the vehicle and the front object based on a distance to the front object and relative speed of the front object. 15. A driver assistance system comprising: a first sensor installed at a vehicle and configured to have a field of view directed forward from the vehicle to acquire front image data; a second sensor selected from a group of radar and LIDAR sensors, installed at the vehicle, and configured to have a field of view directed forward from the vehicle to acquire front detection data; a processor configured to process the front image data and the front detection data; and a memory storing instructions which, when executed by the processor, cause the processor to: detect a lane, in which the vehicle is traveling, or detect a front object located in front of the vehicle, in response to the processing of the image data and the front detection data, determine a predetermined area which is narrower than an area having a width of the lane and a length of a distance between the vehicle and the front object, output a braking signal to a braking system of the vehicle to control the braking system to perform braking control, when a collision between the vehicle and the front object is expected at time t 0 , output a steering signal to a steering system of the vehicle to control the steering system to perform primary steering control until the vehicle is in the predetermined area and continue to output the braking signal to the braking system to continuously control the braking system to perform the braking control, when a collision between the vehicle and the front object is expected even with braking control at time t 1 after t 0 , after the vehicle is in the predetermined area, output another stee