I am reading through "Mythical Man-Month" and near the end in the updates for the 20th anniversary edition it talks a bit about Boehm's model and the optimal time to delivery based upon the exected effort in man-months of a project.

His statement, when discussing Boehm's model, is:

His results solidly confirm The MM-M’s assertion that the trade-off between men and months is far from linear, that the man-month is indeed mythical as a measure of productivity. In particular, he finds:[16]

• There is a cost-optimum schedule time to first shipment, T = 2.5MM

^{1/3}. That is, the optimum time in months goes as the cube root of the expected effort in man-months, a figure derived from the size estimate and other factors in his model. An optimum staffing curve is a corollary.• The cost curve rises slowly as the planned schedule gets longer than the optimum. People with more time take more time.

• The cost curve rises sharply as the planned schedule gets shorter than the optimum.

• Hardly any projects succeed in less than 3/4 of the calculated optimum schedule, regardless of the number of people applied! This quotable result gives the software manager solid ammunition when higher management is demanding impossible schedule commitments

I am having a bit of difficulty in applying this statement practically, I wonder if anyone has any insight as to how this would inform software estimates? I am particually trying to interpret the estimate formula, as plotted here: cost-optimum schedule time plot

This seems to indicate that, for a project with 1 man-month of work, there is an cost-optimal time-to-delivery of 2.5 months. This makes sense, however, if you then assume that there is a project with 5 man-months of work, the plot suggests that the cost-optimal time-to-delivers is 4 months!

Does this suggest that more man-power should be allocate to deliver within this time frame, or that the estimates are too large?

Also, how can you estimate optimum staffing levels from this model? Thanks

1more comment