1.

Errors in Graphs

Given the complexities involved in graphing large data sets, there are many ways for errors to creep in. Still, I was very surprised to read in a study by William S. Cleveland that 30% of all graphs published in volume 207 of Science (1980) contained errors.³ The error types he found were classified as mistakes of construction (mislabels, wrong tick marks or scales, missing items: 6% of graphs), poor reproduction (with some aspect of the graph missing as a result: 6% of graphs), poor discrimination (items such as symbol types and line styles could not be distinguished: 10% of graphs), and poor explanation (something on the graph is not explained, neither in the caption nor the text: 15% of graphs). This total, by the way, only included graphs with actual errors, not graphs that were merely poor at performing the function of communication (of which there were many more, according to Cleveland).

Since 1980, a lot about the process of producing graphs has changed. It is likely that ubiquitous computing and graphing software has diminished the frequency of some error types. But while such tools can make producing quality graphs much faster and easier, they also make it easier to produce bad graphs. Since the most common type of error, incomplete explanation of what is on the graph, is outside the technical process of producing the graph itself, it is doubtful that our software tools have helped much with this error type. Unfortunately, I am forced to admit that Cleveland’s 30% error rate is probably not too different from today’s performance.

2.

Graphical Integrity

As with every aspect of science writing, integrity plays a key role in designing and executing figures and tables. A graph is a powerful tool for communicating, and one must choose to communicate truth rather than falsehood. Tufte suggests these questions as a test for graphical integrity:⁷

To these I would add three more:

This last question is part of the overriding ethic of scientific publishing: For a result to be scientific, and contribute to the body of scientific knowledge, it must be described sufficiently so that it could be reproduced by others. As a straightforward example, any graph that does not numerically label its axes cannot be published (and unfortunately, we sometimes get those graphs submitted to JM³).

Working to ensure both graphical integrity and low error rates in the execution of a graph will greatly enhance the ability of the graph to meet its goals and the goals of the paper. A well-written paper with poor graphs will never be remembered as a well-written paper.

3.

A Few Guidelines

Graphs come in an extremely wide variety of types, a testament to the innovations from the last two centuries of chart making. Still, rapid communication is generally best served using one of several familiar chart types, since familiarity speeds cognition. The overriding principles of design should be to seek clarity and avoid clutter.⁸ With that in mind, here are some miscellaneous guidelines for good graphics that might prove useful on different occasions:

I’m sure that there are many more tidbits of advice that would be valuable to share, but these are the first that come to mind. I’d be interested in hearing from the readers of JM³ about their experiences, good and bad, with graphs.

4.

Figures and Tables in JM³

How are graphs used in our journal, JM³? The table below shows my counts of figures and tables found in the 2012 issues of JM³. The graph types I used are somewhat arbitrary (as all categories are), but hopefully useful. JM³ papers in 2012 had an average of 19 figures and one table per paper, attesting to the importance of figures in our field. About 20% of the figures were used to explain the theory or experimental setup, and the rest showed results. By far the most common figure was the ubiquitous x-y plot, accounting for 1/3 of all figures and tables. Results micrographs (optical and scanning electron micrographs, as well as atomic force microscope renderings) made up 25% of the figures. Contour and 3-D plots were used about 10% of the time, with other types of charts filling in the remainder.

While I made no attempt to rate or judge the quality of the figures, it was clear to me from my survey that there were many excellent examples of figures and tables in all categories. There were some poor ones as well. I hope this editorial will spur attention to the difficult process of building quality graphs and that the JM³ figure quality will improve over time.

Table 1

Figure and table counts for JM3 papers published in 2012.

As an exercise, I rendered the data from the “Results” figures of the above table into a variety of bar charts (see Figure 1). Most of them fail the test of staying “on message.” The first four draw attention to the variations between issues, either in actual numbers or in percentages, though the per-issue variation is not important to my story here. The last two correctly keep the emphasis on the relative frequency of each figure type. But then, they don’t do a better job of conveying the message compared to the table, and the table is far more rich and dense with information (and has the added benefit of documenting the data better). This conclusion is quite frequently true of bar charts: a table would be better.

Fig. 1

A comparison of six different bar charts based on the data from the “Results” section of the table. (a)–(d) are “off-message,” emphasizing the per-issue variation. (e) and (f) have the proper emphasis but are not very data-dense.

5.

Conclusions

They say a picture is worth a thousand words. In a scientific journal, each figure occupies the space of anywhere from 150 to 500 words. So at the very least, a figure should convey more information than the words it displaces. Otherwise, valuable space has been wasted. A good graph can certainly do that, though not all figures do. As the abstract artist Ad Reinhardt so aptly put it, “As for a picture, if it isn’t worth a thousand words, the hell with it.”

Next time I’ll focus on how to make the most of one specific graph type: the ever-popular x-y scatter plot.