ABS explained

ABS a significant safety feature

ABS helps an alert driver avoid a crash
Disc Brake Assembly

In my humble opinion ABS or Antilock Braking Systems are the most significant safety advance since the invention of the brake itself.

ABS requires no conscious thought, training or additional maintenance. Drivers simply have to react as they normally would in an emergency – jam on the brakes. But with ABS, they retain control of the steering. Without ABS, the front wheels lock up and the vehicle slides out of control directly into the object you were trying to avoid. ABS detects when a wheel is about to lock up under heavy braking and modulates brake pressure to individual wheels preventing them from doing so.

 ABS has its detractors, and there is a great deal of misinformation out there. But for the average driver, ABS will come to the rescue several times each year in normal driving conditions while airbags will be used once every 157 years! ABS is an active safety system – it requires action by the driver to help prevent a crash. Airbags, on the other hand are passive safety devices that require no action but do not come into effect until after a crash has occurred.

 Let’s address the naysayers and misinformation first:

1) ABS is no better than a fancy way to pump the brakes. Partially true – but radically different. When we pump the brakes in a non-ABS-equipped vehicle we apply brake pressure to all four wheels simultaneously. ABS deals with each wheel individually, allowing the others to go about their job.

 2) ABS reduces braking distances. Not necessarily. ABS simply allows the driver to retain control of steering during maximum braking. Properly applied braking in a non-ABS vehicle can bring a vehicle to a full stop just as quickly as an ABS-equipped vehicle.

 3) Statistics are proving that ABS-equipped vehicles are involved in more run-off-road crashes and result in more injuries and deaths than non-ABS-equipped vehicles. True – but with a proviso. Before ABS, drivers facing an emergency generally locked their brakes and slid into an object – usually another vehicle. With ABS they are doing the same thing but the vehicle is now responding to their steering input and turning – heading into the ditch or nearest offroad object because the driver doesn’t take the secondary action of actually steering to around the problem

 Traction control

 The same sensors that detect impending lockup, can be programmed to detect the opposite: wheel slippage or spinning. The control system then applies the brakes at that wheel to prevent it from spinning – voila – traction control. In more elaborate systems the sensors talk to the engine control computer telling it to reduce power until the wheel regains traction. Generally the lower cost, lower-speed systems apply the brakes to a spinning wheel at low speeds only since doing so at high speeds might cause stability problems.

Stability control

Stability control prevents the vehicle from spinning out by utilizing a combination of ABS , steering and yaw sensors to detect when a vehicle is not going in the desired direction. In such cases, individual brake pressure is applied to the appropriate wheels to bring it back in line.

Brake Assist

Brake assist is a method of maximizing the benefits of ABS. Studies have found that when drivers sense a problem, they do not immediately apply enough pressure to activate the ABS system. Instead the normal driver faced with an emergency will hit the brake pedal quickly and then assess the situation. Following this “assessment” they will either release the brakes or realize they need to apply more pressure.

This delay, while infinitesimal in terms of time – can prove deadly in terms of increased stopping distance. Brake assist monitors the speed and effort of the initial stab at the brake pedal. If it is judged to be a quick emergency-type application the system will apply full pressure and activate the ABS system immediately – while the driver is “assessing” the situation. If the driver lets off the brake pedal, the system will release pressure immediately. If, on the other hand the driver figures the scene ahead requires full braking, that will already have been done for him. The difference is amazing – tests indicate that from 50 km per hour brake assist can reduce braking distances by as much as 10 metres – almost two car lengths.

About Richard 166 Articles
At the age of five I was already obsessed with all things automotive being able to identify the make and model of car by just the sound of its engine going down the street in front of our house in the small town on the south shore of Nova Scotia. Although I have been covering and writing about the automotive scene for more than 40 years and the light still grows brightly.