Question

motion calculations

1. jane traveled from gaithersburg high school to new york by the quickest route. google maps says this trip should take 3.72 hours. what would her average speed be if google maps is right about the time?
2. if the car accelerates from 0 to 40 mph in 5 seconds, what is its acceleration?
3. if a person runs across a street at 10 mph then hits a pole and stops in ¼ second, what is their acceleration?
4. a football player catches the football at his own 30 yard line. forward is defined as the positive direction. if he runs with a velocity of +5 yards per second for 6 seconds, where will he be when he stops?
5. let’s say the football player starts at the 30 yard line, runs backward 10 yards in 4 seconds and then forward 30 yards in the following 6 seconds. what is his average velocity?
6. use this graph to find the velocity from…

a. …1 to 3 seconds
b. …3 to 4.5 seconds

Explanation:

Problem 1: Jane's Average Speed

Step1: Recall the formula for average speed

The formula for average speed \( v \) is \( v=\frac{d}{t} \), where \( d \) is the distance and \( t \) is the time. But we need to know the distance. From the map, the distance (quickest route) - let's assume the distance from Gaithersburg High School to New York via the quickest route is, for example, if we consider the time and we need to find speed, but maybe the distance is missing? Wait, maybe the map shows the distance? Wait, the user's image: the map has "4 h 33 min" and "3 h 42 min" - maybe the distance is, let's check typical distance from Gaithersburg (MD) to New York: about 240 miles (approximate). Let's assume the distance \( d = 240 \) miles (since it's a common distance). Time \( t=3.72 \) hours.

Step2: Calculate average speed

Using \( v=\frac{d}{t} \), substitute \( d = 240 \) miles and \( t = 3.72 \) hours.
\( v=\frac{240}{3.72}\approx64.52 \) miles per hour.

Step1: Recall acceleration formula

Acceleration \( a=\frac{\Delta v}{\Delta t} \), where \( \Delta v \) is change in velocity and \( \Delta t \) is change in time.

Step2: Identify values

Initial velocity \( v_i = 0 \) mph, final velocity \( v_f = 40 \) mph, time \( \Delta t = 5 \) seconds. First, convert time to hours or velocity to miles per second? Let's convert 5 seconds to hours: \( 5 \) seconds \(=\frac{5}{3600}\) hours \(=\frac{1}{720}\) hours. Or convert velocity to miles per second: \( 40 \) mph \(=\frac{40}{3600}\) miles per second \(=\frac{1}{90}\) miles per second.

Using \( a=\frac{v_f - v_i}{\Delta t} \), with \( v_f - v_i = 40 - 0 = 40 \) mph, \( \Delta t = 5 \) seconds \(=\frac{5}{3600}\) hours. So \( a=\frac{40}{\frac{5}{3600}} = 40\times\frac{3600}{5}= 28800 \) miles per hour squared. Or in miles per second squared: \( \Delta v = \frac{40}{3600} \) miles per second, \( \Delta t = 5 \) seconds, so \( a=\frac{\frac{40}{3600}}{5}=\frac{40}{3600\times5}=\frac{40}{18000}=\frac{1}{450}\approx0.00222 \) miles per second squared. Alternatively, convert to ft/s²: 40 mph = \( 40\times\frac{5280}{3600}=\frac{211200}{3600}\approx58.6667 \) ft/s. Time = 5 s. So \( a=\frac{58.6667 - 0}{5}\approx11.73 \) ft/s².

Step1: Acceleration formula

\( a=\frac{\Delta v}{\Delta t} \), where \( \Delta v = v_f - v_i \), \( v_i = 10 \) mph, \( v_f = 0 \) mph, \( \Delta t=\frac{1}{4} \) second.

Step2: Convert units

First, convert 10 mph to ft/s: \( 10\times\frac{5280}{3600}=\frac{52800}{3600}\approx14.6667 \) ft/s. \( \Delta t = 0.25 \) s. \( \Delta v = 0 - 14.6667=- 14.6667 \) ft/s.

Step3: Calculate acceleration

\( a=\frac{-14.6667}{0.25}=-58.6668 \) ft/s² (negative because it's deceleration).

Answer:

Approximately \( 64.52 \) mph (assuming distance is 240 miles; if distance is different, recalculate with actual distance).

Problem 2: Car's Acceleration