1.5: Percents

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Leah Griffith, Veronica Holbrook, Johnny Johnson & Nancy Garcia
Rio Hondo College

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1.5 Learning Objectives

Find what percent one number is of another
Change fractions to percents
Rewrite decimals as percents
Find a percent of a number
Solve applications involving percents

In the 2004 vice-presidential debates, Edwards's claimed that US forces have suffered "90% of the coalition casualties" in Iraq. Cheney disputed this, saying that in fact Iraqi security forces and coalition allies "have taken almost 50 percent" of the casualties[1]. Who is correct? How can we make sense of these numbers?

Percent literally means “per 100,” or “parts per hundred.” When we write 40%, this is equivalent to the fraction $\frac{40}{100}$ or the decimal 0.40. Notice that 80 out of 200 and 10 out of 25 are also 40%, since $\dfrac{80}{200}=\dfrac{10}{25}=\dfrac{40}{100}$.

Example 1

243 people out of 400 state that they like dogs. What percent is this?

Solution

$\dfrac{243}{400}=0.6075=\dfrac{60.75}{100}$. This is 60.75%.

Notice that the percent can be found from the equivalent decimal by moving the decimal point two places to the right.

Example 2

Write each as a percent: a) $\dfrac{1}{4}$ b) 0.02 c) 2.35

Solution

a) $\dfrac{1}{4}=0.25=25 \%$ b) $0.02=2 \%$ c) $2.35=235 \%$

Percents

If we have a part that is some percent of a whole, then

$\text{percent }=\dfrac{\text { part }}{\text { whole }}$, or equivalently, $\text{part }=\text{percent} \cdot \text{whole}$

To do the calculations, we write the percent as a decimal.

Notice that the equation translated to English would be "part is percent of the whole." So direct multiplication is used.

In some cases the question will ask for the percent off the whole, which is different.

If we have a part that is some percent off a whole, then

$\text{part }=\left ( 100\% - \text{percent}\right) \cdot \text{whole}$

Since the statement is the percent off, to find the correct value for the part, the percent must be subtracted from 100% first.

Example 3

The sales tax in a town is 9.4%. How much tax will you pay on a $140 purchase?

Solution

Here, $140 is the whole, and we want to find 9.4% of $140. We start by writing the percent as a decimal by moving the decimal point two places to the left (which is equivalent to dividing by 100). We can then compute:

$\operatorname{tax}=0.094(140)=\$ 13.16$ in tax.

Example 4

In the news, you hear “tuition is expected to increase by 7% next year.” If tuition this year was $1200 per quarter, what will it be next year?

Solution

The tuition next year will be the current tuition plus an additional 7%, so it will be 107% of this year’s tuition:

$\$ 1200(1.07)=\$ 1284$.

Alternatively, we could have first calculated 7% of $1200: $\$ 1200(0.07)=\$ 84$.

Notice this is not the expected tuition for next year (we could only wish). Instead, this is the expected increase, so to calculate the expected tuition, we’ll need to add this change to the previous year’s tuition:

$\$ 1200+\$ 84=\$ 1284$.

Try it Now 1

A TV originally priced at $799 is on sale for 30% off. There is then a 9.2% sales tax. Find the price after including the discount and sales tax.

Answer: The sale price is $\$799(1-0.30) = \$799(0.70)=\$559.30$. After tax, the price is $\$559.30(1.092) = \$610.76$.

Example 5

The value of a car dropped from $7400 to $6800 over the last year. What percent decrease is this?

Solution

To compute the percent change, we first need to find the dollar value change: $\$ 6800-\$ 7400=-\$ 600$ Often we will take the absolute value of this amount, which is called the absolute change: $|-600|=600$.

Since we are computing the decrease relative to the starting value, we compute this percent out of $\$7400$:

$\frac{600}{7400}=0.081=8.1 \%$ decrease. This is called a relative change.

Absolute and Relative Change

Given two quantities,

Absolute change = $|\text{ending quantity }-\text{ starting quantity}|$

Relative change: $\dfrac{\text { absolute change }}{\text { starting quantity }}$

Absolute change has the same units as the original quantity.

Relative change gives a percent change.

The starting quantity is called the base of the percent change.

The base of a percent is very important. For example, while Nixon was president, it was argued that marijuana was a “gateway” drug, claiming that 80% of marijuana smokers went on to use harder drugs like cocaine. The problem is, this isn’t true. The true claim is that 80% of harder drug users first smoked marijuana. The difference is one of base: 80% of marijuana smokers using hard drugs, vs. 80% of hard drug users having smoked marijuana. These numbers are not equivalent. As it turns out, only one in 2,400 marijuana users actually go on to use harder drugs[2].

Example 6

There are about 75 QFC supermarkets in the U.S. Albertsons has about 215 stores. Compare the size of the two companies.

Solution

When we make comparisons, we must ask first whether an absolute or relative comparison. The absolute difference is $215 – 75 = 140$. From this, we could say “Albertsons has 140 more stores than QFC.” However, if you wrote this in an article or paper, that number does not mean much. The relative difference may be more meaningful. There are two different relative changes we could calculate, depending on which store we use as the base:

Using QFC as the base, $\dfrac{140}{75}=1.867$.

This tells us Albertsons is 186.7% larger than QFC.

Using Albertsons as the base, $\dfrac{140}{215}=0.651$.

This tells us QFC is 65.1% smaller than Albertsons.

Notice both of these are showing percent differences.

We could also calculate the size of Albertsons relative to QFC: 215/75, which means Albertsons is 2.867 or 286.7% times the size of QFC. Likewise, we could calculate the size of QFC relative to Albertsons: 75/215, which tells us that QFC is 34.9% of the size of Albertsons.

Example 7

Suppose a stock drops in value by 60% one week, then increases in value the next week by 75%. Is the value higher or lower than where it started?

Solution

To answer this question, suppose the value started at $100. After one week, the value dropped by 60%:

$\$ 100-\$ 100(0.60)=\$ 100-\$ 60=\$ 40$.

In the next week, notice that base of the percent has changed to the new value, $40. Computing the 75% increase:

$\$ 40+\$ 40(0.75)=\$ 40+\$ 30=\$ 70$.

In the end, the stock is still $30 lower, or $\dfrac{\$ 30}{\$ 100}=30 \%$ lower, valued than it started.

Try it Now 2

The U.S. federal debt at the end of 2001 was $5.77 trillion, and grew to $6.20 trillion by the end of 2002. At the end of 2005 it was $7.91 trillion, and grew to $8.45 trillion by the end of 2006[3]. Calculate the absolute and relative increase for 2001-2002 and 2005-2006. Which year saw a larger increase in federal debt?

Answer

2001-2002: Absolute change: $0.43 trillion. Relative change: 7.45%

2005-2006: Absolute change: $0.54 trillion. Relative change: 6.83%

2005-2006 saw a larger absolute increase, but a smaller relative increase.

Example 8

A Seattle Times article on high school graduation rates reported “The number of schools graduating 60 percent or fewer students in four years – sometimes referred to as “dropout factories” – decreased by 17 during that time period. The number of kids attending schools with such low graduation rates was cut in half.”

a) Is the “decrease by 17” number a useful comparison?

b) Considering the last sentence, can we conclude that the number of “dropout factories” was originally 34?

Solution

a) This number is hard to evaluate, since we have no basis for judging whether this is a large or small change relative to the number of such schools. If the number of “dropout factories” dropped from 20 to 3, that would be a very significant change, but if the number dropped from 217 to 200, that would be less of an improvement.

b) The last sentence provides relative change which helps put the first sentence in perspective. We can estimate that the number of “dropout factories” was probably previously around 34. However, it’s possible that students simply moved schools rather than the school improving, so that estimate might not be fully accurate.

Example 9

Solution

Without more information, it is hard for us to judge who is correct, but we can easily conclude that these two percents are talking about different things, so one does not necessarily contradict the other. Edward’s claim was a percent with coalition forces as the base of the percent, while Cheney’s claim was a percent with both coalition and Iraqi security forces as the base of the percent. It turns out both statistics are in fact fairly accurate.

Try it Now 3

In the 2012 presidential elections, one candidate argued that “the president’s plan will cut $716 billion from Medicare, leading to fewer services for seniors,” while the other candidate rebuts that “our plan does not cut current spending and actually expands benefits for seniors, while implementing cost saving measures.” Are these claims in conflict, in agreement, or not comparable because they’re talking about different things?

Answer: Without more information, it is hard to judge these arguments. This is compounded by the complexity of Medicare. As it turns out, the $716 billion is not a cut in current spending, but a cut in future increases in spending, largely reducing future growth in health care payments. In this case, at least the numerical claims in both statements could be considered at least partially true. Here is one source of more information if you’re interested: http://factcheck.org/2012/08/a-campaign-full-of-mediscare/

We’ll wrap up our review of percents with a few cautions.

First, when talking about a change in quantities that are already measured in percents, we have to be careful in how we describe the change.

Example 10

A politician’s support increases from 40% of voters to 50% of voters. Describe the change.

Solution

We could describe this using an absolute change: $|50 \%-40 \%|=10 \%$. Notice that since the original quantities were percents, this change also has the units of percent. In this case, it is best to describe this as an increase of 10 percentage points.

In contrast, we could compute the percent change: $\dfrac{10 \%}{40 \%}=0.25=25 \%$ increase. This is the relative change, and we’d say the politician’s support has increased by 25%.

Second, pay attention to shifting base values.

Example 11

An employer asks his employee to take a temporary 10% pay cut for 6 months because the company has hit some hard times. At the end of the 6 months the employer will give the employee a 10% raise. Will the employee make more, less, or the same amount as before the pay cut? Is that fair?

Solution

Suppose the employee makes $4500 per month. The employer is proposing to take 10% off the current salary.

$\text{part}=\$4500\left (1-0.10\right )=\$4500\left (0.90\right )=\$4050$

After 6 months pass the employer promises to give a 10% raise on the salary. The employee will retain 100% of what they have plus 10%.

$\text{part}=\$4050\left (1+0.10\right )=\$4050\left (1.10\right )=\$4455$

Since the value that the percent is based on has changed the employee would not be restored to their original salary in this scenario.

Last, beware of averaging percents.

Example 12

A basketball player scores on 40% of 2-point field goal attempts, and on 30% of 3-point of field goal attempts. Find the player’s overall field goal percentage.

Solution

It is very tempting to average these values, and claim the overall average is 35%, but this is likely not correct, since most players make many more 2-point attempts than 3-point attempts. We don’t actually have enough information to answer the question. Suppose the player attempted 200 2-point field goals and 100 3-point field goals. Then they made 200(0.40) = 80 2-point shots and $100(0.30) = 30$ 3-point shots. Overall, they made 110 shots out of 300, for a $\dfrac{110}{300}=0.367=36.7 \%$ overall field goal percentage.

[1] www.factcheck.org/cheney_edwards_mangle_facts.html

[2] http://tvtropes.org/pmwiki/pmwiki.php/Main/LiesDamnedLiesAndStatistics

[3] www.whitehouse.gov/sites/defa...s/hist07z1.xls