Silver Bullet and Application of Newton's Laws There are millions of people who flock to amusement parks every year, and many are willing to wait in line for hours just to get on a ride that lasts just a few minutes. It may be the tendency to take risks or the adrenaline rush we feel when we subject ourselves to the force of such rushes that explain this phenomenon. The twists, turns, and loops of amusement park rides push and pull our bodies this way and that, yet this sensation is what we love about roller coasters. It's not every day that we find ourselves upside down. Newton's laws help us understand why we feel a certain way on an amusement park ride, and we'll focus on one ride in particular at Knott's Berry Farm: Silver Bullet, an inverted roller coaster that lasts 2 minutes and 10 seconds with a runway length of 3,125 feet and a top speed of 55 mph. Say no to plagiarism. Get a tailor-made essay on "Why Violent Video Games Shouldn't Be Banned"? Get Original Essay Newton's first law states that an object at rest stays at rest and an object in motion stays in motion unless external forces intervene. The roller coaster train does not move unless it is taken to the top of a ride. This law can be seen when my body continued to move forward while the running quickly stopped. This is why safety restrictions are necessary. Examples of such external forces are Silver Bullet inversions: loops, turns, rolls, twists. One of the six inversions was the vertical cycle. Thanks to inertia I could stay in my place while upside down. Roller coasters often change direction with the tracks and make us experience various sensations, but inertia tries to keep our bodies moving in a straight line. Newton's second law states that the acceleration of an object depends on its mass and the amount of applied force, this represented by F = ma. Returning to the vertical loop, the smaller the radius, the greater the acceleration. There was centripetal acceleration as I went around, which caused the train and passengers to move in a circular motion towards the center. During the climb I felt heavier as the normal force was greater than the force of gravity or my weight. I felt lighter during the ride because I was "falling" with the roller coaster train, my apparent weight seemed to be less than my actual weight. At the end of the ride, I felt heavier again, my apparent weight seemed to be greater than my actual weight. A zero gravity roll is another inversion, which causes the train to overturn. At this point, I felt like I was floating due to the artificial sensation of weightlessness. Newton's third law states that for every action there is an equal and opposite reaction. As the saying goes: “What goes up must come down.” This also applies to the fact that the roller coaster train also has to go back after having gone around. When the ride began, I leaned all the way back in my seat. For much of the ride, I felt my body pressed against the seat and the seat pressing against me. Along with the idea of ​​“equal and opposite,” the other side of centripetal force is centrifugal force (also known as “false” force). While the centripetal force pushed the train and passengers towards the center of the circuit, the centrifugal force created the sensation of being squeezed into the seat. Please note: this is just an example. Get a custom paper from our expert writers now. Get Custom Essay Now, when we head into that intimidating roller coaster, we can count on physics to.