1.7 Part 1 · Theory

System Behavior & Dynamics

By Tom Bosschaert August 1, 2019 SiD Documentation

What Are System Dynamics?

Systems consist of objects and their interrelations. They are dynamic, respond to internal and external influences, and exhibit behaviors whose causes cannot be reduced to any single object or connection. These complex emerging behaviors are system dynamics.

Because real-world system dynamics cannot be accurately predicted, the most useful goal is intuitive fluency: after encountering enough cases, patterns emerge naturally and you can detect opportunities and problems at the system level.

The Nature of Complex Systems

Before examining specific dynamics, it helps to understand the inherent properties of complex systems that give rise to these behaviors. Complex systems share twelve fundamental characteristics:

They are numerous in their components, with all components influencing each other, exhibiting non-linear emergent behavior.

They can be understood but not predicted. Any action upon them may have unpredictable side-effects. Prepare for resilience, not prediction.

They grow like organisms and perish like them. No complex system exists for eternity.

They require increasing resources per added unit of complexity. There are always limits to growth.

They change rapidly in revolution-like jumps as well as in slow evolutionary progression.

They do not necessarily behave the same way given the same conditions.

They are always dynamic, never sit still, and are never entirely in balance.

They may exhibit survival or seemingly cognitive behavior.

They require incubation periods for changes to be registered and acted upon.

They can best be understood by human brains, as they are also organic complex systems.

They interact beyond their chosen system boundary.

They always offer hidden system dynamics that can have beneficial or destructive effects.

These properties explain why the behaviors below emerge so consistently across vastly different systems, from ecosystems to economies to cities.

The System Behaviors Zoo

Below are common behaviors you may encounter in the wild. Recognizing them helps you work with complex systems rather than against them.

From Masters of Beautiful Achievement with Alexander Prinsen · Full episode

Tom on how resilience, autonomy, and harmony influence each other: increased autonomy can decrease resilience, and why no country can be fully autonomous. (0:57)

Catastrophic Shift

Every complex system stabilizes itself in an equilibrium (attractor state). When pressures reach a threshold, the system may suddenly switch to a different attractor state without warning. Earth formation, social revolutions, and financial crashes all follow this pattern. Big systems are not slow — once triggered, they change very fast.

Rebound Effect

An intended improvement triggers secondary effects that counteract it. Reducing the cost of driving by improving fuel efficiency leads to more driving, partially or fully offsetting the gain. This is a primary reason why incremental efficiency improvements alone will not create significant reductions in resource use.

In 2000, a car with ~20% environmental improvements saw a rebound: environmentally-inclined buyers felt less guilty and drove more, resulting in higher total impact than the efficiency gains achieved.

Exponential Effects

When one parameter influences multiple others, which in turn multiply, the system responds exponentially. Biological growth, climate tipping points (melting land ice accelerating further melting), and viral spread all follow this curve.

"The greatest shortcoming of the human race is our inability to understand the exponential function." — Albert Allen Bartlett, Physicist

Law of Diminishing Marginal Returns

For each additional unit of production, return drops slightly below the previous one. Systems hit an efficiency ceiling beyond which overhead grows until the system collapses. Archaeologist Joseph Tainter argues in The Collapse of Complex Societies that all societal collapse follows this curve.

"Anyone who believes exponential growth can go on forever in a finite world is either a madman or an economist." — Kenneth Boulding

80-20 Rule (Pareto Principle)

Roughly 80% of effects are caused by 20% of causes. Named after Vilfredo Pareto's observation that 80% of Italian land was owned by 20% of the people. In projects, 80% of time typically lies in the final 20% of work — the tweaking stage.

Historical Momentum

Even when all preconditions for change are present and public will exists, complex systems can change very slowly due to ingrained collective memory. To overcome it, find positive exponential drivers to accelerate transition, or apply a short "transition boost" — a period of concentrated impulse.

Tragedy of the Commons

Named after Garrett Hardin's 1968 essay: a shared resource gets depleted even when each member of the group knows depletion works against their interests. The effect strengthens as populations grow and is a reason why some degree of centralized management is necessary in any system.

The Cobra Effect

British India offered rewards for captured cobras; locals started breeding them. When the program ended, breeders released their snakes, increasing the population beyond the original level. An attempted solution that makes the problem worse through unintended consequences.

Working with System Dynamics

Understanding these behaviors does not allow you to predict complex systems, but it does let you prepare for them, design for resilience, and find leverage points for change. SiD's network parameters help identify exponential patterns between individual parameters — particularly relevant when scaling sustainable systems, since RAH indicators often respond nonlinearly to changes in complexity.

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