acceleration problems\nuse the guess method to solve these problems. $a = \\frac{\\delta v}{t}$\ng - write…

acceleration problems\nuse the guess method to solve these problems. $a = \\frac{\\delta v}{t}$\ng - write down all \given\ information\nu - write down the \unknown\ you are looking for\ne - write down the \equation(s)\ you will used based on the g and u\ns - \substitute\ your numbers and compute the mathematical problem\ns - find a \solution\ with appropriate units\nsolve for acceleration\n1. a car starts from rest at a traffic light and accelerates uniformly to a speed of 20 m/s in 10 seconds. what is the cars acceleration?\n2. a cyclist is moving at a speed of 5 m/s when they begin to pedal harder and increase their speed to 12 m/s over a period of 4 seconds. what is the acceleration of the cyclist?\n3. an airplane accelerates down the runway, increasing its velocity from 15 m/s to 70 m/s in 30 seconds before takeoff. what is the airplanes acceleration?\n4. a train is traveling at 40 m/s and applies its brakes, slowing down to 10 m/s in 15 seconds. what is the acceleration of the train as it decelerates?\nsolve for time\n5. a sports car accelerates from 10 m/s to 50 m/s with an acceleration of 5 m/s². how much time does it take for the car?
Answer
Explanation:
Step1: Identify the acceleration formula
The formula for acceleration is $a=\frac{v - u}{t}$, where $v$ is final - velocity, $u$ is initial - velocity, and $t$ is time.
Step2: Solve problem 1
Given $u = 0\ m/s$ (starts from rest), $v = 20\ m/s$, $t = 10\ s$. $a=\frac{v - u}{t}=\frac{20 - 0}{10}=2\ m/s^{2}$
Step3: Solve problem 2
Given $u = 5\ m/s$, $v = 12\ m/s$, $t = 4\ s$. $a=\frac{v - u}{t}=\frac{12 - 5}{4}=1.75\ m/s^{2}$
Step4: Solve problem 3
Given $u = 15\ m/s$, $v = 70\ m/s$, $t = 30\ s$. $a=\frac{v - u}{t}=\frac{70 - 15}{30}=\frac{55}{30}\approx1.83\ m/s^{2}$
Step5: Solve problem 4
Given $u = 40\ m/s$, $v = 10\ m/s$, $t = 15\ s$. $a=\frac{v - u}{t}=\frac{10 - 40}{15}=\frac{- 30}{15}=-2\ m/s^{2}$
Step6: Solve problem 5
We use the formula $a=\frac{v - u}{t}$, and we need to solve for $t$. Rearranging gives $t=\frac{v - u}{a}$. Given $u = 10\ m/s$, $v = 50\ m/s$, $a = 5\ m/s^{2}$. $t=\frac{v - u}{a}=\frac{50 - 10}{5}=\frac{40}{5}=8\ s$
Answer:
- $2\ m/s^{2}$
- $1.75\ m/s^{2}$
- $\approx1.83\ m/s^{2}$
- $-2\ m/s^{2}$
- $8\ s$