Go to CCP Homepage Go to Materials Page Go to Linear Algebra Materials Go to Table of Contents
Go Back One Page Go Forward One Page

Harvesting an Age-Distributed Population

Part 3: Optimal harvesting

We have now considered two sustainable harvesting policies: harvesting the same fraction from every age group, and harvesting only from the youngest age group. The latter probably produces a much smaller harvest in pounds of meat, but possibly a more valuable harvest for the sheep farmer. We now ask: What sustainable harvesting policy would produce the largest possible harvest in terms of numbers of animals? Another way to ask the question: What combination of harvesting fractions h1, h2, ..., h12 results in the largest fraction of the total population being harvested -- while still maintaining sustainability?

On the face of it, this is a very difficult question. However, there is a theorem from linear programming theory that simplifies the question considerably:

Optimal Sustainable Yield
If a sustainable harvesting policy is optimal, it harvests only from one or two age classes. If two age classes are harvested, then the older class is completely harvested.
[C. Rorres, ``Optimal Sustainable Yield of a Renewable Resource,'' Biometrics, Vol. 32, 1976, pages 945-948.]
  1. For the New Zealand sheep population, it can be shown (by techniques beyond the level of this course) that the optimal yield is achieved when h1 = 0.522, h9 = 1, and all the other h's are zero. Find the sustainable age distribution for this policy, both before and after growth.

  2. What fraction of the total population is harvested each year? How does this compare with uniform harvesting and with lambs-only harvesting?

Go to CCP Homepage Go to Materials Page Go to Linear Algebra Materials Go to Table of Contents
Go Back One Page Go Forward One Page

modules at math.duke.edu