1.02 Descriptive modeling

Explain why the units on the axes cannot be meters and seconds.

We know from the problem that Qin is tracking his time and distance and that time is independent of distance.

If the time and distance were in meters and seconds, we would see that at 13.8 seconds, the distance would be 100 meters. This is not what we see on the graph.

Convert Qin's speed to miles per hour.

Starting with the rate at which Qin runs, we can choose appropriate conversion factors to multiply by. Then, dividing out common units in the conversion will simplify the rate.

Qin runs 16.30 miles per hour.

Determine if the axes on the treadmill's graph can be labeled in miles and hours.

The unit rate we converted to in part (b) was miles per hour. We can confirm that the graph matches the unit rate by matching points.

The graph begins at zero, and after 1 hour, we see the distance is marked around 16 miles. This matches the units converted to in the unit rate from part (b).

It is unlikely that Qin can maintain his sprint pace for hours, so the graph provided by the treadmill is not realistic.

Describe the quantities that should be considered if we want to maximize the amount of peaches we can purchase.

Consider what you know about how the cost of fruit, like peaches, is usually determined.

The quantities we want to measure are the peaches and their cost. The units we could use to measure them may be the number of peaches, their weight in pounds, ounces, kilograms, or grams, and the cost will likely be in dollars but could be measured in other units of value.

Suppose that the charges for the three bag sizes of peaches are as follows: a small bag at 2 \text{ lb} for \$5.40; a medium bag at 10 \text{ lb} for \$21.35; a large bag at 20 \text{ lb} for \$39.14. Use this information to determine the combination of bags that would weigh the most for \$100.

A comparison in cost per pound of peaches is useful in helping us decide how to combine bags.

For each of the bags, we can compare the cost per pound of peaches:

Small bag: \dfrac{\$5.40}{2 \text{ lb}}= \dfrac{\$2.70}{\text{lb}}

Medium bag: \dfrac{\$21.35}{10 \text{ lb}}= \dfrac{\$2.14}{\text{lb}}

Large bag: \dfrac{\$39.14}{20 \text{ lb}}= \dfrac{\$1.96}{\text{lb}}

The largest bag is the most expensive, but by comparing the rate for each, the largest bag offers the lowest price per pound of peaches. This means that we will get the most weight by purchasing more large bags than small ones.

The following combinations would cost \$100 or less:

• 36 \text{ lb} with 18 small bags
• 44 \text{ lb} with 4 medium bags and 2 small bags
• 48 \text{ lb} with 2 large bags and 4 small bags
• 50 \text{ lb} with 2 large bags and 1 medium bag

Since we know that the large bags of peaches are the best deal and the medium bags are the next best deal, we should buy the most large bags possible with the most medium bags to get the most peaches for \$100. The combination of 50 \text{ lb} with 2 large bags and 1 medium bag will be the most peaches.

When calculating the cost per pound for each bag, we rounded our rates for the medium bag from 2.135 to 2.14 and 1.957 to 1.96. Since these amounts are in dollars, rounding to the hundredths place is reasonable.

Describe appropriate independent and dependent variables of the relationship.

The owner is attempting to determine how busy the cafe could be during certain times. The times could be measured in minutes or hours. How busy the cafe is could be measured by the amount of money the cafe brings in, the number of meals they sell, or the number of customers in the cafe.

The independent variable could be time in hours. The dependent variable could be the number of customers in the cafe.

The graph below shows the comparison between lunch on the weekends versus weekdays. Choose appropriate scales and unit labels for the axes. Justify your reasoning.

Consider the independent and dependent variables from part (a) and determine if they are reasonable with the given graph.

The independent variable is time in hours. The x-axis scale could be by 1, showing a total of 4 hours for a cafe's lunch crowd.

The dependent variable of customers in the cafe could be reasonable with this graph. If the scale on the y-axis is also 1, it looks like there are about 8 guests each hour in the cafe for the flatter graph and more for the steeper graph.

The dependent variable could also be measured in the number of meals or the amount of money the cafe is making each hour. The scale for the amount of money could be by 5 or 10 or another dollar amount that makes sense aligned to the cost of items in the cafe.

Round 461\,585 to three significant figures.

When rounding to n significant figures, we count (n+1) digits starting with the first nonzero digit from the left and round the nth digit up or down according to the (n+1) \text{th} digit. Then replace all other digits with zeros.

462\,000

Round 0.006\,377\,36 to two significant figures.

0.0064

We started counting two digits from the first nonzero digit, 6, and then determined what to round 3 to based on the 7 to its right. We rounded up the digit from 3 to 4, leaving us with the rounded number 0.0064 at two significant figures.

What is the absolute error of the measuring tape?

The absolute error of a measuring tool is equal to \dfrac{1}{2} the smallest measurement of that tool. We are given that the measuring tape has markings every 20 \text{ cm,} so the smallest measurement of the measuring tape will be 20 \text{ cm.}The absolute error will be equal to half this amount.

The absolute error of the measuring tape is 10 \text{ cm}.

The length of an object is measured as 120 \text{ cm} by the measuring tape. A second measurement is then taken, measuring its length to the nearest centimeter. What is the range we should expect this second measurement to lie within?

We can express the range of values as \text{Range of values} = \text{Marking value } \pm \text{ Absolute error}

The second measurement should lie within 110 \text{ cm} and 130 \text{ cm.}