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:
• There is a cost-optimum schedule time to first shipment, T = 2.5MM1/3. 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