Joseph M. Mahaffy SDSU
Math 124: Calculus for the Life Sciences Spring 2017
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Computer Lab Help 5


This page is designed to provide helpful information about the laboratory questions. You will find more details in the Lab Manual that accompanies this course. Begin this lab and every lab by introducing yourself to your partner. Determine the times when you can meet together during the week before the lab is due at your next Lab session. You should start this lab and each lab by typing the name of each team member and your computer number on the Lab Cover Page (or a copy of it).

The first WeBWorK problem asks questions about this help page and appropriate lecture material. This should help you work through the Lab more smoothly. The first problem of the main WeBWorK lab study continues your study of discrete population models. The problem examines the population of a country in the twentieth century by fitting it with a discrete Malthusian growth model, a Malthusian growth model with immigration, and a logistic growth model. These models are compared for accuracy and used to project future behavior of the population. The second problem explores relationships between age, height, and weight of children. Data on the growth of girls is presented. Allometric modeling compares the relationship between height and weight, then a growth curve is created. The concept of growth is very important in connecting biological problems to Calculus.

Problem 1: This question introduces you to the material for linear discrete dynamical systems. The lecture notes (Linear Discrete) have most of the material that you will need to help you through this problem. In Part a, you begin by using the formula to calculate q, then you simply iterate the discrete model as you did in the previous lab problem. You will want to perform 40-50 iterations (which is very easy in Excel) to get far enough out to answer the question about how many breaths it takes to reduce the level of Ar to 0.01. Part c requires that you use some of your skills in algebra (or skills in Maple to let it do the algebra). You are given c0 and c1, which you use in the formula for the model as cn and cn+1, respectively. You know g and Vi also, so you are only lacking Vr, which you must solve for. After you have Vr, the problem is very much like Part a.

Problem 2: This problem is another examination of census data for some country. Part a is very similar to problems you have done before with simple Malthusian growth. Rather than actually using the solution of the discrete Malthusian growth model, you simulate the model with your named parameters for growth rate, r, and initial population, P0. You use Excel's Solver to find the best fitting (least sum of square errors) parameters growth rate, r, and initial population, P0. In Part b, the discrete Malthusian growth model adds a term for immigration, m. Once again, you name the 3 parameters in this model (use unique names with initial guesses suggested in the question), then simulate the discrete linear model of population growth with immigration. You should find Excel very good at simulating the model by entering the equation in the line below the initial population and filling down. Again, you use Excel's Solver to find the best fitting parameters for this model by letting it compute the least sum of square errors. The third model in this question uses a logistic growth model to simulate the census data. This is performed just like the immigration model, but uses the logistic growth equation given in your Lab question with its 3 parameters (with reasonable initial guesses for the parameters). Again Excel's Solver will find the parameters for this model that give you the least sum of square errors. If you want to be safe with your answer from Solver, then run Solver twice. The second run should leave an answer that is very close to your first execution of Solver.

The last part of the question with the logistic growth model asks for equilibria. These are found by substituting Pe for Pn and Pn+1 in the logistic growth equation, then solving for Pe. Since this is a quadratic equation, it should be easy for you to find the equilibria. One of the equilibria should be obvious from what you know should be true of population models.

Problem 3: This problem is meant to help motivate the idea of a derivative, which we will be studying over most of the rest of this course. The first part of this problem gives you more experience with allometric modeling using heights and weights of children. The remainder of the problem is designed to build intuition on the rate of gain of height or weight, which is a derivative. The lecture notes have details on computing the average rate of change in height, and this lab problem repeats a very similar calculation and adds the calculations for the average rate of gain of weight.

 

Copyright © 2015 Joseph M. Mahaffy.