I agree with the OP, the presentation is seriously flawed.

brief explanation first:

- The measured variable in each case is neither discrete nor
continuous -- it's
*ordinal*; yet ordinal variables have characteristics of
both discrete and continuous.
- Ordinal variables are like discrete variables in that they are not
numeric (the choice of values {1,2,3,4,5} is pure artifact;
{a,b,C,d,e} is an equally valid way to encode an ordinal variable of
cardinality 5.
- But ordinal variables encode information that discrete variables do
not --
*ranking*, in particular; perhaps analogous to transitivity: if
1 < 2 and 2 < 3, then 1 < 3; in this sense they are like continuous
variables.
- Rank isn't a necessary condition for a discrete variable -- eg, for the
variable Sex which has two values Male and Female, Male > Female or
Female > Male has no useful meaning.
- Finally, ordinal and discrete are similar in that even simple
arithmetic is undefined -- eg, the average of New York and California
isn't Nebraska.

But why then, in the cases the OP raised, when the person who created the survey plots, attempted to calculate the mean from each set of responses, was a valid result returned (eg, 4.15)?

Because a human chose to encode the values comprising the variable as sequential integers (1 - 5); this mapping -- i.e., {"strongly disagree" -> 1, "strongly agree" -> 5, ...} -- is arbitrary. In other words, *A through E* would have sufficed for the mapping just as well as the symbols *1 through 5*

But because integers were chosen for the mapping, and integers have a bunch of well-defined arithmetic operations, such as average, minimum, maximum, etc., it's tempting to go to just hog wild.

In this instance, calculating the mean of the mapped responses is full of assumptions, not the least of which is that the values are separated by an equal interval (another is usually referred to as *paired-comparison intransitivity*, which if I had correctly learned the first time around, I would never have had the privilege of taking Advanced Probability Theory a second time).

Anyway, here's how i'd do it:

choose a representation that removes the dependency on all of these assumptions by *avoiding the mapping step* altogether (other than as a plot-annotation convenience, eg, "1" means "Strongly Disagree"). This way, i have no contrived symbols that look like integers which trick me into thinking they are integers that I then mistakenly do arithmetic on.

Display the results of each question like so,

a *standardized distribution* of response counts

Won't a separate bar plot for each question make the viewport too cluttered?

If done right, it'll look very clean, what's more, this is a fairly routine technique to plot data of this sort. A plotting library based on Tufte sparklines would do the job nicely. What's more, displaying these in a *single column* (e. g., immediately following the question) and standardizing the counts, would allow quick visual comparison among question responses by the reader.