A leading bicycle company has engineered a revolutionary lightweight

carbon fiber frame for its new racing bicycle, but is concerned that the main tube (called the

‘down tube’) might bend too much under strong pedaling forces. Too much, according to the

bicycle company’s specification, is more than a 10-degree bend when applying 600 newtons of

force—that’s more than twice the force that most racing cyclists can produce. Carbon fiber is

laid by hand, so some variation is expected. The bicycle company’s engineers predict that the

new frame design can be manufactured to meet the bending specification only 85% of the time.

However, the company’s favored manufacturer has historically made carbon fiber frames that

meet the bending specification 95% of the time. The bicycle company asked this manufacturer

to supply 12 frames with the new lightweight design in a range of sizes. Let the random

variable X be the number of frames in the sample of 12 that meet the bending specification.

a. Assume that the engineers are right about the probability of manufacturing to

specification, what is the expected number of frames that meet the specification?

b. Assuming again that the engineers are right about the probability of manufacturing to

specification, what is the probability that all 12 of the frames meet the specification?

c. Assume now that the favored manufacturer’s historical probability of making to

specification is right, what is the probability that all 12 of the frames meet the

specification?

d. Assuming again that the manufacturer’s historical probability of making to

specification is right, what is the probability that more than 10 frames meet the

specification?

e. If all 12 of the frames supplied by the manufacturer are found to meet the bending

specification, what if anything can we say about whether the engineers’ predicted

probability or the manufacturer’s historical probability is more likely to be right for the

new frame design?