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Example Questions
Example Question #2 : Interpreting Graphs
The chart below maps how scientists view others' work (left) and how they suspect others will view their own work (right) if the researcher (the scientist or another, depending on the focus) admitted to engaging in questionable research practices.
Adapted from Fetterman & Sassenberg, "The Reputational Consequences of Failed Replications and Wrongness Admission among Scientists." December 9, 2015, PLOS One.
Which of the following is best supported by the graph?
Scientists believed that others would view them as much less honest if they admitted to wrongness.
Scientists were slightly less likely to view others as honest if they did not admit to wrongness.
Scientists were slightly more likely to view others as honest if they did admit to wrongness.
Scientists were much more likely to view others as honest if they admitted to wrongness.
Scientists believed that others would view them as much less honest if they admitted to wrongness.
Scientists viewed others who admitted to wrongdoing with less suspicion than they viewed people who did not admit to wrongdoing. However, scientists believed that others would view them as less trustworthy if they admitted to wrongdoing. This matches "scientists believed that others would view them as much less honest if they admitted to wrongness."
The other choices can all be eliminated because they make the claim that there is some sort of relationship that can be drawn between scientists in one group and the other. Because you don't have scientist- by-scientist data, however, you can't make any conclusions linking individual scientists in each survey group.
Example Question #1 : Interpreting Graphs
The following graph plots the average wind speed by time of day for a windmill farm outside of Toronto. Time of day is given in military time (0 hours to 2400 hours).
Which of the following best summarizes the data in the graph?
The average wind speed is highest between 20:00 and 22:00.
The average wind speed increases steadily between 5:00 am and midnight.
The average wind speed is lowest between 3:00 and 5:00.
The average wind speed more than doubles from 18:00 to 22:00.
The average wind speed is highest between 20:00 and 22:00.
Very often with line graphs, the SAT will ask you to describe a trend evident from the graph. In these cases, it’s helpful to get a quick glance at the graph to notice extremes (Where is the line the highest? Where is it the lowest? Are there any places where it stays flat for multiple increments?), but ultimately you’ll need to utilize Process of Elimination with the answer choices. We cannot conclude that “Average wind speed increases steadily between 5:00 am and midnight” because the graph clearly shows periods where the line goes down after 5:00 but before 24:00. Therefore the average wind speed does not increase steadily; in some instances, it decreases. We are also unable to conclude that “Average wind speed is lowest between 3:00 and 5:00.” Although the period between 3:00 and 5:00 marks one of the lower points on the graph, the line dips even lower below the 6.6 line at 18:00.
We also want to be sure to check the scale on graph problems! The entire y-axis for this graph only spans 6.5 to 7.2 meters per second, so although the line jumps up sharply it only represents a small percentage increase. Thus, we can eliminate “Average wind speed more than doubles from 18:00 to 22:00. This leaves us with “Average wind speed is highest between 20:00 and 22:00,” our correct answer. The highest point on the line is at 21:00, between the stated times of 20:00 and 22:00.
Example Question #2 : Interpreting Graphs
The following scatter plot displays the world record time, in seconds, for the men’s 100-meter dash from 1910 through 2010. The line of best fit displays what the expected world record time would be at each point along the years 1900 to 2100.
Which of the following best summarizes information displayed in the scatter plot above?
The world records set between 1980 and 1995 were all faster than what the line of best fit predicts.
The world records set between 2000 and 2010 were all faster than what the line of best fit predicts.
The world record time in 2050, in seconds, is predicted by the line of best fit to be less than half what it was in 1910.
Since 1900, the world record has never gone more than 15 years without being lowered.
The world records set between 2000 and 2010 were all faster than what the line of best fit predicts.
Notice that 3 of the 4 answer choices include the term “line of best fit” with regard to a prediction. With scatter plots, the line of best fit can serve as a tool to predict where new data points will fall. In this case, the line of best fit represents where one would expect the world record to be at any given point between 1900 and 2100. Remember that a faster time will be a lower number (running the 100 meters in 9 seconds is faster than running it in 10 seconds). So, “The world records set between 1980 and 1995 were all faster than what the line of best fit predicts” is incorrect, as the data points from 1980 to 1995 are above the line of best fit, so slower than what would have been predicted. Additionally, each data point represents a new world record – a point in time at which the world record was broken. So you can look at the horizontal space between each data point to see how long the duration was in between. And between approximately 1930 and just after 1950 there are no data points, so you can conclude that the world record was not broken for a period of approximately 20 years. Thus, “Since 1900, the world record has never gone more than 15 years without being lowered” is incorrect.
“The world record time in 2050, in seconds, is predicted by the line of best fit to be less than half what it was in 1910” is also incorrect, and brings up another point critical to your work with graphs: look at the scale! Even though the line of best fit is much, much lower at 2050 than it was in 1910, the total scale goes from 9.4 seconds at the bottom to 10.8 seconds at the top. So there’s no chance for one data point to be half of another: half of 10.8 (the top data point) would be 5.4, and the graph doesn’t go that low. It’s quite common for the lines or bars on a graph to appear to have a much greater difference in size than is actually true, so always check the scale when answering questions dealing with percent change. However, because the data points between 2000 and 2010 are all below the line of best fit, those times were all faster than would have been predicted. Thus, “The world records set between 2000 and 2010 were all faster than what the line of best fit predicts” is our correct answer.
Example Question #1 : Interpreting Graphs
The scatter plot below displays the daily sales figures for a beachfront ice cream shop for the month of June, with each data point representing the sales totals and the high temperature for the day.
The scatter plot above offers evidence that the ice cream store will:
typically sell more ice cream on weekends than on weekdays.
not sell any ice cream on a day for which the high temperature is below 55 degrees.
usually sell less ice cream on days with lower temperatures than on days with higher temperatures.
sell over $2,100 in ice cream on a day for which the high temperature is over 90 degrees.
usually sell less ice cream on days with lower temperatures than on days with higher temperatures.
Sometimes the SAT will ask you a question about what the graph suggests will happen in the future. Here, you won’t always be able to find the exact answer simply by looking at the graph, but will instead have to pay attention – as always – to trends in the graph and to precision in wording in the answer choices.
“Not sell any” is a very strong statement, particularly when the bottom of the graph shows $700 worth of ice cream and you have data points near 55 degrees that are well above that line. It’s not likely (even though it’s technically possible) that sales would fall off the graph entirely with just a slight move leftward on the x-axis (temperature axis), so “not sell any ice cream on a day for which the high temperature is below 55 degrees” is incorrect.
Similarly, over $2,100 in sales would jump above the highest gridline on the graph, and the trend shows that the two closest data points to 90 degrees retreat slightly toward lower sales. Such a jump to over $2,100 is possible, but not entirely likely. Thus, we can eliminate “sell over $2,100 in ice cream on a day for which the high temperature is over 90 degrees.” The answer choice, “typically sell more ice cream on weekends than on weekdays” uses softer wording, but is problematic in its contents. The graph only shows information regarding temperature and sales, not about the day of week and sales, so even though this might very well be true, the graph gives no evidence to make this prediction.
“Usually sell less ice cream on days with lower temperatures than on days with higher temperatures” uses softer language than the previous two choices, something you should notice given that precision in wording matters quite a bit on graph problems. “Usually” is a bit easier to prove than “will,” and the general trend in the data supports this – the trend in the data points is from lower left (lower temperature, less sales revenue) to upper right (higher temperature, more sales revenue), so we’ve found our correct answer.
Example Question #1 : Interpreting Graphs
The following is excerpted from a textbook addressing the breakdown and landmass of the earth. (2018)
Which of the following conclusions cannot be drawn from the graph above?
Asia is approximately 50% larger, based on landmass, than Africa.
Half of the earth’s surface area is covered by Asia and Africa.
The landmass of Africa is approximately the same size as the combined landmass of Antarctica, Europe, and Australia.
The two Americas account for a combined 29% of the world’s landmass.
Half of the earth’s surface area is covered by Asia and Africa.
When breaking down graphs and tables, it’s important to pay close attention to often overlooked details such as scale, labels, and titles. Here, we’re told what this pie graph is measuring right in the title - it’s a graph of world landmass by continent. We can do the math to identify that “Asia is approximately 50% larger, based on landmass than Africa,” that “The landmass of Africa is approximately the same size as the combined landmass of Antarctica, Europe, and Australia,” and that “The two Americas account for a combined 29% of the world’s landmass.” However, we do not know that “Half of the earth’s surface area is covered by Asia and Africa.” If we attempt to draw this conclusion, we’ve made a critical mistake in reading - we’ve forgotten about the water! There’s a drastic difference between “world landmass” and “world surface area,” since the former is looking only to the land, and the latter includes all surface area, even the portion covered by the deep blue! It’s critical that we pay close attention to what the data is measuring when interpreting graphs and tables, because convincing wrong answers - and in this case, our answer to an “except” question - will often draw us in with options that sound on-topic but address different data from the data we were presented within the figure.
Example Question #2 : Interpreting Graphs
The following is excerpted from a 2010 study concerning patterns of enrollment and graduation at Ivy League schools. (2010)
Which of the following conclusions is supported by the bar graph above?
More students graduated from Cornell in 2010 than from any other Ivy League school.
In 2010, Dartmouth had the lowest graduation rate out of any ivy league school.
The total enrollment for Ivy League schools in 2010 was greater than 40,000 students.
There was a greater difference between the 2010 graduating classes of Dartmouth and Harvard than there was between those of Princeton and Yale.
The total enrollment for Ivy League schools in 2010 was greater than 40,000 students.
When breaking down graphs and tables, it’s important to pay close attention to often overlooked details such as scale, labels, and titles. Here, the bar graph we’ve been given represents undergraduate enrollment. So, we can only feasibly draw conclusions about the enrollment of the schools in question. So, answers that address graduation rates or compare them cannot be concluded based on the bar graph alone. Only our correct answer “The total enrollment for Ivy League schools in 2010 was greater than 40,000 students,” can be confidently concluded based on the information, and we can get there efficiently using rounding and estimation, as the total is well over the 40,000 mark.
Example Question #1 : Interpreting Graphs
The following graph is excerpted from a study on the part-time work of high school seniors. The graph depicts the average hours worked per week by a sampled group of seniors in 2018, the year before the study was conducted. (2019)
Which of the following conclusions is supported by the line graph above?
The sample’s average hours worked per week increase each month from January to July.
The sample’s total hours worked in May through August were greater than the total hours worked for the rest of the year.
The sample’s average hours worked per week decrease each month from July to December.
The sample’s total hours worked per month increase each month from January to December.
The sample’s total hours worked in May through August were greater than the total hours worked for the rest of the year.
In this example, we can use process of elimination and a bit of rounding to arrive at our correct answer efficiently. We can conclude that the sample’s total hours worked per month did not increase each month from January to December, or even from January to July, as there is a clear decrease from February to March, as well as several more decreases later in the year. We also cannot conclude that hours worked decreased each month from July to December, as we can see a clear increase from October to November, and again from November to December. We can, however, conclude that “The sample’s total hours worked in May through August were greater than the total hours worked for the rest of the year.” Even if we apply a bit of rounding, the roughly 15+20+40+36 gives us around 110 for the months in question. (and yes, we’d want to keep in mind that these are weekly figures and that the *actual* values would depend on the weeks in the month and the number of participants in the sample group. That said, this change will be proportional, so we can simplify by looking to the weekly and average amounts.) This roughly 110 far surpasses the sum for the remainder of the months, even if we round up, as most are at or below roughly 10. Keep in mind, graph questions on the SAT are never meant to be an eye exam - so if it seems as though the numbers are “too close to call,” you’re probably missing something along the way!
Example Question #1 : Interpreting Graphs
Which of the following best describes the information in the graph?
As the level of education increases, the unemployment rate and the median weekly income are positively correlated.
The average holder of any type of college degree is less than half as likely to be unemployed as is the average person who has not completed high school.
The median holder of an associate’s degree earns more than twice as much per week as the median person who has not completed high school.
For every level of education, as education increases the unemployment rate decreases.
The average holder of any type of college degree is less than half as likely to be unemployed as is the average person who has not completed high school.
When you’re selecting an answer choice that describes the graph, it’s important that the entire answer choice be true. For example, consider the answer choice that reads “For every level of education, as education increases the unemployment rate decreases.” For almost every level of education, as the level of education increases the unemployment rate decreases. So, choice B is almost true. But that last level – doctoral degree – has an unemployment rate just higher than the level before it (professional degree), so “every level” isn’t quite true. Make sure you read each choice critically and are careful with words that are hard to prove (every, all, always, never, none, etc.). “As the level of education increases, the unemployment rate and the median weekly income are positively correlated” is incorrect, again for just one word: the unemployment rate and the median weekly income are indeed correlated, but as income goes up the unemployment rate goes down. This is a negative – not positive – correlation.
“The median holder of an associate’s degree earns more than twice as much per week as the median person who has not completed high school” is also incorrect. The Associate’s Degree median is $768 while the median for no high school degree is $451. Since $768 is not quite twice as much as $451, this answer can be eliminated.
However, the first level of college degree listed is an Associate’s Degree, with an unemployment rate of 6.8%, and all other degrees listed have unemployment rates less than that. Since the unemployment rate for those without high school degrees is 14.1%, you can conclude that this rate is more than double the rate for any college degree, meaning that any college degree will have a rate of less than half the rate for no high school degree. This makes “The average holder of any type of college degree is less than half as likely to be unemployed as is the average person who has not completed high school” our correct answer.
Example Question #3 : Interpreting Graphs
The following graph displays, for several major categories of public transportation, the share of total trips taken via public transportation in the United States over a year.
What statement is best supported by the data in the figure above?
Over half of all users of public transportation are bus riders.
45% of all miles traveled on public transportation are traveled by rail of some kind.
More people travel via paratransit than via ferry.
Over 40% of all public transportation trips are taken by rail of some kind.
Over 40% of all public transportation trips are taken by rail of some kind.
Perhaps the easiest way to miss a graph-based question is to answer based only on the image without consideration of the words that accompany it. So make sure you always take note of what, specifically, the graph is displaying. Here it’s the percentages of trips taken, which is critical. It may seem convincing that “Over half of all users of public transportation are bus riders” at first (“more than half” certainly applies to “bus”), but the units matter! You can’t conclude that more than half of all users are bus riders, just that more than half of all trips taken were by bus. Suppose, for example, that people who take the bus take it twice per day, but people who use heavy rail only use it once per week. Each user of the bus would then take 10 trips for every one trip that a heavy rail user takes, and in that case, you’d need a lot more heavy rail users than bus users to have 35% of all trips be taken by heavy rail. “45% of all miles traveled on public transportation are traveled by rail of some kind” is also incorrect, because we’re once again facing a units problem. You don’t know about the percentage of miles traveled via each public transportation service; you only know about the percentage of trips taken. “More people travel via paratransit than via ferry” makes the same mistake: it draws a conclusion about the percentage of people when the information you have is about the percentage of trips taken. This leaves us with our correct answer: “Over 40% of all public transportation trips are taken by rail of some kind.” This option correctly makes an inference about the percentage of trips taken, and if you check the actual numbers you’ll see that the three categories of rail add up to 45% of all trips taken. Therefore, it is true that rail accounts for more than 40% of all trips taken.
Example Question #21 : Graphs And Tables
The passage is adapted from Ngonghala CN, et. al’s “Poverty, Disease, and the Ecology of Complex Systems” © 2014 Ngonghala et al.
In his landmark treatise, An Essay on the Principle of Population, Reverend Thomas Robert Malthus argued that population growth will necessarily exceed the growth rate of the means of subsistence, making poverty inevitable. The system of feedbacks that Malthus posited creates a situation similar to what social scientists now term a “poverty trap”: i.e., a self-reinforcing mechanism that causes poverty to persist. Malthus’s erroneous assumptions, which did not account for rapid technological progress, rendered his core prediction wrong: the world has enjoyed unprecedented economic development in theensuing two centuries due to technology-driven productivity growth.
Nonetheless, for the billion people who still languish in chronic extreme poverty, Malthus’s ideas about the importance of biophysical and biosocial feedback (e.g., interactions between human behavior and resource availability) to the dynamics of economic systems still ring true. Indeed, while they were based on observations of human populations, Malthus's ideas had reverberations throughout the life sciences. His insights were based on important underlying processes that provided inspiration to both Darwin and Wallace as they independently derived the theory of evolution by natural selection. Likewise, these principles underlie standard models of population biology, including logistic population growth models, predator-prey models, and the epidemiology of host-pathogen dynamics.
The economics literature on poverty traps, where extreme poverty of some populations persists alongside economic prosperity among others, has a history in various schools of thought. The most Malthusian of models were advanced later by Leibenstein and Nelson, who argued that interactions between economic, capital, and population growth can create a subsistence-level equilibrium. Today, the most common models of poverty traps are rooted in neoclassical growth theory, which is the dominant foundational framework for modeling economic growth. Though sometimes controversial, poverty trap concepts have been integral to some of the most sweeping efforts to catalyze economic development, such as those manifest in the Millennium Development Goals.
The modern economics literature on poverty traps, however, is strikingly silent about the role of feedbacks from biophysical and biosocial processes. Two overwhelming characteristics of under-developed economies and the poorest, mostly rural, subpopulations in those countries are (i) the dominant role of resource-dependent primary production—from soils, fisheries, forests, and wildlife—as the root source of income and (ii) the high rates of morbidity and mortality due to parasitic and infectious diseases. For basic subsistence, the extremely poor rely on human capital that is directly generated from their ability to obtain resources, and thus critically influenced by climate and soil that determine the success of food production. These resources in turn influence the nutrition and health of individuals, but can also be influenced by a variety of other biophysical processes. For example, infectious and parasitic diseases effectively steal human resources for their own survival and transmission. Yet scientists rarely integrate even the most rudimentary frameworks for understanding these ecological processes into models of economic growth and poverty.
This gap in the literature represents a major missed opportunity to advance our understanding of coupled ecological-economic systems. Through feedbacks between lower-level localized behavior and the higher-level processes that they drive, ecological systems are known to demonstrate complex emergent properties that can be sensitive to initial conditions. A large range of ecological systems—as revealed in processes like desertification, soil degradation, coral reef bleaching, and epidemic disease—have been characterized by multiple stable states, with direct consequences for the livelihoods of the poor. These multiple stable states, which arise from nonlinear positive feedbacks, imply sensitivity to initial conditions.
While Malthus’s original arguments about the relationship between population growth and resource availability were overly simplistic (resulting in only one stable state of subsistence poverty), they led to more sophisticated characterizations of complex ecological processes. In this light, we suggest that breakthroughs in understanding poverty can still benefit from two of his enduring contributions to science: (i) models that are true to underlying mechanisms can lead to critical insights, particularly of complex emergent properties, that are not possible from pure phenomenological models; and (ii) there are significant implications for models that connect human economic behavior to biological constraints.
World Population, 1990-2015
YEAR |
NUMBER OF PEOPLE (in billions) |
1990 |
5.3 |
1993 |
5.5 |
1996 |
5.8 |
1999 |
6.1 |
2002 |
6.3 |
2005 |
6.4 |
2008 |
6.6 |
2010 |
6.8 |
2015 |
7.3 |
The above table plots the world population, in billions of people, from 1990 through 2015
Percent of Population Living in Extreme Poverty
1990 |
1993 |
1996 |
1999 |
2002 |
2005 |
2008 |
2010 |
2015 |
|
Europe and Central Asia |
2 |
3 |
4 |
4 |
2 |
2 |
1 |
3 |
1 |
Middle East |
8 |
6 |
5 |
5 |
5 |
5 |
5 |
6 |
5 |
Latin American and Caribbean |
11 |
10 |
10 |
12 |
14 |
9 |
5 |
5 |
4 |
East Asia and Pacific |
55 |
52 |
37 |
37 |
30 |
18 |
16 |
13 |
8 |
South Asia |
53 |
53 |
49 |
45 |
45 |
38 |
36 |
32 |
22 |
Sub-Saharan African |
57 |
60 |
48 |
59 |
57 |
51 |
48 |
47 |
42 |
The table above shows the percentage of people in each region that lived in extreme poverty, as defined by the World Bank, for each of the years plotted. The seventh region, North America, is not shown, as its extreme poverty rate fell below the minimum rate for tracking in this study.
Which of the following conclusions is best supported by the two tables?
In 1999, there were more people living in extreme poverty in South Asia than in East Asia and the Pacific.
Extreme poverty is not a major concern in Europe & Central Asia.
As of 2015, less than 3.5 billion people in the world lived in extreme poverty.
Fewer people in Latin America & the Caribbean lived in poverty in 2008 than in 2002.
As of 2015, less than 3.5 billion people in the world lived in extreme poverty.
To answer this question, we need to compare the answer options to the two tables. When you are looking at the answer options, keep in mind that the correct answer must be supported by both tables, not just one. Let’s start with “in 1999, there were more people living in extreme poverty in South Asia than in East Asia and the Pacific”. Note that the table that compares regions only deals with percents (percentage of people in that region living in poverty) but not with actual numbers of people. Without an idea of how many people live in each region, we can’t compare total numbers. Next, “fewer people in Latin America & the Caribbean lived in poverty in 2008 than in 2002” has the same problem - without knowing how many people are in each region, we can’t draw conclusions about the total number of people (for example, if one region has one billion people and another has one hundred, you could take the same percentage of each region and get wildly different actual numbers). Answer choice “extreme poverty is not a major concern in Europe & Central Asia” is interesting in that it offers a value judgment - from the numbers you might think “only 1% of people in this region live in extreme poverty, and 1% isn’t a big number” but ask yourself: if it’s 1% of 500 million people, isn’t it possibly a major concern to those 5 million people? Value judgments like this are very hard to prove, and when you’re asked to draw a conclusion on the SAT you need to be able to prove your answer. This leaves us with, “as of 2015, less than 3.5 billion people in the world lived in extreme poverty”. Without even having to go back and reference the tables you should notice that this choice mentions a population size- which is discussed in the first table- and poverty level- which is covered in the second table. To double check, we can look at the first table and see that is 2015 there are 7.3 billion people in the world- which makes 3.5 billion people about half of the population. Looking at the second table in 2015 we can see that all poverty rates are substantially below 50%, so we can draw this conclusion.