Next Generation Science Standards
(NGSS)
Systems Association of Fish and Wildlife
Agencies
Sustainable Tomorrow: A Teachers’ Guidebook for Applying Systems
Thinking to Environmental Education Curricula
Educators
Prior to working through this presentation:
• Download Sustainable Tomorrow: A Teachers’ Guidebook for Applying Systems Thinking to Environmental Education Curricula from the Moodle site.
• Download and Print:
Educators are required to include the study of Systems
(NGSS Framework)
Dimensions of the
Framework
–Scientific and Engineering Practices
–Crosscutting Concepts
–Disciplinary Core Ideas
Educators: Systems is one of 7 Crosscutting Concepts (NGSS)
1. Patterns
2. Cause & effect: Mechanism & explanation
3. Scale, proportion, & quantity
4. Systems & system models
5. Energy & matter: Flows, cycles, & conservation
6. Structure & function
7. Stability and change
Value of Using Systems as a Crosscutting Concept
Educators: Below are excepts describing the value of “Systems and System Models” in NGSS (2011) that will guide the development of state science standards.
Using systems to understand complexity: The natural and designed world is
complex; it is too large and complicated to investigate and comprehend all at once. Scientists and students learn to define small portions for the convenience of investigations. The units of investigations can be referred to as ‘systems’ (National Science Education Standards).
Using systems to model or mathematically represent complexity: A model
of a system under study is a useful tool for representing the complexity of the system, gaining an understanding and communicating that understanding of a system to others.
Using system models to examine complexity: Models are useful for
predicting a system’s behavior or in diagnosing problems in the functioning of the system
NGSS – K12 Framework
General Definition: A system is an organized group of related objects or components that form a whole. Systems can consist, for example, of organisms, machines, fundamental particles, galaxies, ideas and numbers. Systems have boundaries, components, resources, flow, and feedback (NGSS-K12SES: 4-7)
Educators: The NGSS systems definition requires learners to address boundaries, components (variables), resources (stocks) flow (inputs and outputs) and feedback (negative/balance and positive/causal) found in the AFWA ‘Sustainable Tomorrow” guide.
Educators: Another resource for educators on how systems can be integrated into science learning:
System Definition: from *Art Sussman’s Guide to Science
A system exists whenever parts combine or connect with each other to form a whole. The whole is QUALITATIVELY more than the sum of its parts (*Page 23). Questions to ask about systems (*Page 35): 1.What are the parts of the system? 2.How does the system function as a whole? 3.How is the system part of larger system? 4.Does the system do anything when given input? *Dr Art’s guide to Science: Connecting Atoms, Galaxies and Everything in Between. Art Sussman 2006. Jossey-Bass, San Francisco, CA www.guidetoscience.net
KEY SYSTEMS SCIENCE PRINCIPLES
• A system is a group of interacting parts that functions as a whole.
• Systems change over time.
• Changes in systems can be short, slow, or cyclic.
• Interactions within a system may not always be obvious.
• Systems have boundaries.
• Scientists do not yet know enough about Earth systems to determine which elements are essential and which are not.
• Systems are parts of larger systems, which are parts of still larger systems.
• Systems are made up of subsystems, which in turn are made up of still smaller subsystems.
• Systems have inputs and outputs.
Cary Sneider, Richard Golden, Katherine Barrett A New World View http://www.lhs.berkeley.edu/GSS/
Educators:
Which of the following are
systems or parts of
systems. Why or why
not? Use the Systems
Science Principles to
justify your answer.
•Battery
•Box of staples
•Lungs
•Leaf
KEY SYSTEMS SCIENCE PRINCIPLES
• A system is a group of interacting parts that functions as a whole.
• Systems change over time.
• Changes in systems can be short, slow, or cyclic.
• Interactions within a system may not always be obvious.
• Systems have boundaries.
• Scientists do not yet know enough about Earth systems to determine which elements are essential and which are not.
• Systems are parts of larger systems, which are parts of still larger systems.
• Systems are made up of subsystems, which in turn are made up of still smaller subsystems.
• Systems have inputs and outputs.
Cary Sneider, Richard Golden, Katherine Barrett A New World View http://www.lhs.berkeley.edu/GSS/
Educators:
Which of the following are
systems or parts of
systems. Why or why
not? Use the Systems
Science Principles to
justify your answer.
•Battery
•Box of staples
•Lungs
•Leaf
The Battery, lungs and leaf
are all systems. The box
of staples is not a system
because it does not have
interacting parts that
function as a whole.
9-12
6-8
3-5
K-2
Educators: Learners are expected to progress in their depth of understanding of systems at each grade band
Systems: A Progression of Explanatory Ideas
Inputs, Outputs, Boundaries & Flows:
Complex Systems:
Part – Whole Relationships:
Predictability and Feedback:
Systems
Why use Systems Thinking?
Systems is a crosscutting concept in NGSS
Which Systems?
Physical Systems
Earth/Space Systems
Living Systems
Big Idea:
Systems thinking makes it possible to analyze and
understand complex phenomena.
Systems-Speak K-3
Parts & Wholes
Function of the Part
Predict
Systems-Speak 4-5
Subsystems & System
Inputs & Outputs
Functions & Predictions
Systems-Speak 6-8
Inputs & Outputs Boundaries & Flow
Open and Closed Systems
Systems-Speak 9-12
Positive Feedback
Negative Feedback
Equilibrium
Educators: Here is another representation systems understanding for of learners at each grade band
Courtesy: Mark Watrin, Education Service District 112 Science Coordinator , Washington State
Making the system visible
• NGSS Chapter 4-7: Models can be valuable in predicting a system’s behavior or in diagnosing problems in its functioning. A good system model for use in developing scientific explanations or engineering designs must specify not only the parts or subsystems, of the system but how they interact with one another. It must also specify the boundary of the system being modeled. In complex systems it is important to ask what interactions are occurring –like predator-prey relationships in an ecosystem – and to recognize that they all involve transfers of energy, matter, and sometimes information among parts of the system.
Model the systems
• Students can model their system through diagrams, words and mathematical relationships (NGSS-K12SES 4-8).
• The systems models provide a graphical representation indicating the mathematical relationships between the parts of the system.
• NGSS: (page 4-8). Students models should incorporate a
range of mathematical relationships among variables and some analysis of the patterns of those relationships.
Make the system visible
• Represent the interactions between the parts of the system through the following systems models
Behavior over time graphs (page 10)
Causal loop diagrams (page11- 14)
Input/output diagrams (page 15)
Iceberg Model (page 19- 22)
Educators: Each of the systems models will be described next.
Make the system visible
• Represent the interactions between the parts of the system through the following systems models
Behavior over time graphs (page 10)
Causal loop diagrams (page11- 14)
Input/output diagrams (page 15)
Iceberg Model (page 19- 22)
Educators: Check the Behavior Over Time systems model on page 10 and identify the mathematical trend (increase, decrease or equilibrium)
Educators: Look at the behavior over time graph which demonstrates
the mathematical trends observed by scientists: read an explanation
on page 10 and page 17 of Sustainable Tomorrow
Mule Deer Population
1950----------------------------2012
Educators: For example the Washington Department of Fish and Wildlife scientists study why Mule Deer Populations have declined over the past decades. The Behavior over time graph is a mathematical representation of the system trend.
Modeling the system is important in engineering (including natural
resource management) to support developing design (and management)
ideas, and sharing, testing and refining them (NGSS 2011)
Go to the SYSTEMS MODELING ACTIVITY PAGE:
ACTIVITY 1: Represent at least one study that your state
fish and wildlife agency currently conducts that can be
explained by a Behavior Over Time graph. What are the
parts of the system (variables) focused on by your state
agency that change over time & needs to be managed?
Make the system visible
• Represent the interactions between the parts of the system through the following systems models
Behavior over time graphs (page 10)
Causal loop diagrams (page11- 14)
Input/output diagrams (page 15)
Iceberg Model (page 19- 22)
Educators: Check the Causal Loop/Feedback systems model on pages 11-14 and identify the mathematical relationship (increase, decrease, positive & negative feedback)
A system is changing when one variable in the system is changing in the same (s) direction (increase or decrease) as another variable. This is a self reinforcing (R) or positive causal feedback loop
Input/Event: Wildlife Population ↑
Simplified positive reinforcing causal loop:
Output: Wildlife Births ↑
A system is in balance (B) or equilibrium when one part of the system is increasing ↑ while another part is decreasing ↓. This is a balancing loop (page 14), typical of Predator Prey relationships
Make the system visible
• Represent the interactions between the parts of the system through the following systems models
Behavior over time graphs (page 10)
Causal loop diagrams (page11- 14)
Input/output diagrams (page 15)
Iceberg Model (page 19- 22)
Educators: Check the Input/Output systems model on the page 15 and identify the mathematical relationship (increase, decrease)
Model for System Flow with Inputs & Outputs
Input Output
↓ ↓
[Deer Births] → {Number of Deer} → [Deer Deaths]→
Go to the SYSTEMS MODELING ACTIVITY PAGE :
ACTIVITY 2: Represent the system you modeled
with the Behavior Over Time Graph by using a
system flow model that shows inputs and outputs.
The trends are made more visible by modeling the input and output
flow of the system (Pages18).
Make the system visible
• Represent the interactions between the parts of the system through the following systems models
Behavior over time graphs (page 10)
Causal loop diagrams (page11- 14)
Input/output diagrams (page 15)
Iceberg Model (page 19- 22)
Educators: Check the Iceberg Model on pages 19-22, linking system events, with system patterns, system structures and mental models.
Mental Model: We need to regulate fishing to ensure future generations have fish
Structure: State agencies manage populations: hunting & fishing regulations
Pattern: Ecosystem Balance – carrying capacity stable
Events: People catching and releasing fish at local pond Observable behaviors
Recurring events over time
Elements in a system that drive behavior
Held beliefs & assumptions that give rise to structures & behaviors
Story of State Fish and Wildlife Agencies and Programs
Observable behaviors: What we see
Recurring events over time: What we see over time
Elements in a system that drive behavior: What supports what we see
Held beliefs & assumptions that give rise to structures & behaviors: What we believe.
Mental Model:
Structure:
Pattern:
Events:
Go to the SYSTEMS MODELING ACTIVITY PAGE :
ACTIVITY 3: Create an iceberg model representing some concern you are dealing with in your professional situation.
Systems Analysis in 6 Steps
Look at issues in your professional situation through the lens of systems.
Use the 6 steps for Systems Analysis described in Sustainable Tomorrow pages 8-21
Practice Systems Analysis using your environmental & sustainability education lessons. These lesson typically include both science and social science disciplines
Inputs & Outputs
The parts of the system that change over time
Relationship between parts of the system
Educators: You can apply the 6 steps of systems analysis to issues
you address through your profession.
Conclusion
• The Next Generation Science Standards (NGSS) expects STEM education to include the study of systems and applying systems analysis to problem solving.
• Biologists and natural resource managers apply systems understanding and systems analysis in their role as professionals for agencies, business and industry.