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Oscillating Example for Algebra II, Using STELLA
Author(s): Diana M. Fisher Subject: Math
  From CC-STADUS. Demonstrates existing conditions, involves predator-prey relationship, explores (pulse-started) oscillation.
  PDF
Oscillations 1 Background Information on Simulation Created for Lesson 1: Springs Everywhere: Exploring Spring-Mass Dynamics
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  This lesson is a precursor to the Oscillation curriculum created for the Complex Systems Project. Experimenting with a virtual spring will help students gain an intuitive understanding for why a spring oscillates. This knowledge will be reinforced in other lessons in this series.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF
Oscillations 1C Springs Everywhere: Exploring Spring-Mass Dynamics
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  The spring simulation allows students to experiment with a virtual spring-mass system. They can change settings, run the simulation, and compare results. The default simulation behavior is equilibrium, as the spring is initially at rest. By changing the settings, a variety of oscillatory behaviors are generated. This model is intended as an introduction for this series of oscillatory models, although it also aligns with specific math and science curricular standards.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF

Link to the simulation: http://www.clexchange.org/curriculum/complexsystems/oscillation/Oscillation_SpringC.asp
Oscillations 2 Background Information on Simulation Created for Lesson 2: Romeo and Juliet: In Rapturous Oscillation?
Author(s): Jennifer Andersen, Anne LaVigne, & in collaboration with the CLE Subject: Cross-Curricular
  The model used in this lesson is structurally similar to the spring-mass simulation (Lesson 1) and is intended to follow it. It challenges students to apply what they have learned about springs to intangible subject matter. For example, “resistance” from the spring simulation gets recast as “fatigue” to show what happens when one party in a relationship gets tired of the up-and-down dynamic. Students should recognize that their own personal relationships include themselves as part of the system; therefore, they do have the opportunity to influence an unwanted dynamic.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF
Oscillations 3 Background Information on Simulation Created for Lesson 3: Rabbits, Rabbits and More Rabbits: Logistic Growth in Animal Populations
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  Lesson 3 is an important precursor to Lesson 4: Waves of Change: Predator and Prey Dynamics. Population dynamics are taught in a mini-series of three lessons. We recommend starting with this lesson, logistic growth, and teaching these lessons in order because they clearly show the progression of structure needed to simulate S-shaped and cyclic behavior patterns.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF
Oscillations 3A Too Many Animals?
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  Students see animals all around them, often pets in their home or birds and other wildlife in their neighborhood. This lesson allows students to explore how populations can grow and decline over time. Students can use the information in the simulation to input settings, such as how long a particular animal lives, on average. An additional option is to have students research, explore, and compare additional populations.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF

Link to the simulation: http://www.clexchange.org/curriculum/complexsystems/oscillation/Oscillation_PopulationA.asp
Oscillations 3B Why Are There Not More Elephants?: Population Dynamics
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  This lesson explores how animal populations can grow and decline over time through use of a simulation. This very simple model allows students to impact the birth and death rates based on input for different animals. The simulation displays what happens to the different populations over time. Students can compare the resulting trends for different animals and consider why those trends occur. Students may also research additional animal data in order to create their own runs.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF

Link to the simulation: http://www.clexchange.org/curriculum/complexsystems/oscillation/Oscillation_PopulationB.asp
Oscillations 3C: Rabbits, Rabbits, and More Rabbits: Logistic Growth in Animal Populations
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  This simple population model explores a variety of animals limited only by their own population densities. Students can change various settings for each population, including birth factor, lifespan, and habitat area. Each of the populations does (or would eventually) level off as it reaches a carrying capacity.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF

Link to the simulation: http://www.clexchange.org/curriculum/complexsystems/oscillation/Oscillation_PopulationC.asp
Oscillations 4 Background Information on Simulation Created for Lesson 4: Waves of Change: Predator and Prey Dynamics
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  This lesson builds on Lesson 3 – Rabbits, Rabbits, and More Rabbits: Logistic Growth in Animal Populations within the Oscillation curriculum created for the Complex Systems Project. Lessons 3 - 5 work together to show how a population in isolation can experience growth or decline, but not oscillation (Lesson 3). Further, it is only when considering a population in relation to a wider system boundary, either interacting with another population (Lesson 4) and/or a food supply (Lesson 5), that we have the structure necessary to produce cyclic behavior.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF
Oscillations 4A Up and Down in the Wild: Predator and Prey
Author(s): Anne LaVigne, Jennifer Andersen, & in collaboration with the CLE Subject: Cross-Curricular
  This lesson allows students to explore the interactions of two animal populations (wolves and moose) within an ecosystem. One animal in the simulation is a predator. The other animal is its prey. Their populations rise and fall (oscillate) over time as they interact and impact one another.

Complex Systems Connection: Cause within System. Five interdisciplinary areas are covered in a series of lessons, utilizing a family of models that all generate oscillation. Oscillation in real-world systems is often considered problematic rather than a consequence of system structure. This progression of lessons will help students understand that undesirable behavior can be a consequence of system structure and not a result of outside, uncontrollable influences. In other words, a system that oscillates does so because it has an inherent tendency to do so.
  PDF

Link to the simulation: http://www.clexchange.org/curriculum/complexsystems/oscillation/Oscillation_PredPreyA.asp
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