Differences
This shows you the differences between two versions of the page.
| Both sides previous revision Previous revision Next revision | Previous revision | ||
|
basic_fundamentals [2019/08/30 16:35] argemiro |
basic_fundamentals [2020/02/18 00:22] (current) argemiro |
||
|---|---|---|---|
| Line 1: | Line 1: | ||
| {{ :logo_guidebook1.jpg?400 |}} | {{ :logo_guidebook1.jpg?400 |}} | ||
| \\ | \\ | ||
| - | =====Basic Modeling questions in Environmental Systems Models==== | ||
| \\ | \\ | ||
| + | =====Basic Modeling Questions in Environmental Systems Models==== | ||
| \\ | \\ | ||
| - | Modelling environmental dynamics is critical to understanding and predicting the evolution of the environment in response to the large number of influences including urbanisation, climate change and deforestation. Simulation and modelling provide support for decision making in environmental management. This lesson introduces terminology and provides an overview of methodological modelling approaches which may be applied to environmental and complex dynamics. Based on this introduction this book illustrates various models applied to a large variety of themes: deforestation in tropical regions, fire risk, natural reforestation in European mountains, agriculture, biodiversity, urbanism, climate change and land management for decision support, etc. These case studies, provided by a large international spectrum of researchers and presented in a uniform structure, focus particularly on methods and model validation so that this book is not only aimed at researchers and graduates but also at professionals. | + | Modelling environmental dynamics is critical to understanding and predicting the evolution of the environment in response to the large number of influences including urbanisation, climate change and deforestation. Simulation and modelling provide support for decision making in environmental management. This lesson introduces terminology and provides an overview of methodological modelling approaches which may be applied to environmental and complex dynamics. |
| + | \\ | ||
| + | \\ | ||
| + | In accordance with this, the guidebook illustrates various models applied to a large variety of themes: deforestation in tropical regions, fire risk, natural reforestation in European mountains, agriculture, biodiversity, urbanism, climate change and land management for decision support, etc. These case studies, provided by a large international spectrum of researchers and presented in a uniform structure, focus particularly on methods and model validation so that this guidebook is not only aimed at researchers and graduates but also at professionals. | ||
| \\ | \\ | ||
| - | |||
| ---- | ---- | ||
| + | \\ | ||
| ===What are models?=== | ===What are models?=== | ||
| - | * Simple representations of realty according to a specific vision | + | \\ |
| - | + | As stated by the Merriam-Webster dictionary, a model is a system of postulates, data, and inferences presented as a mathematical description of an entity or state of affairs. Simply put, a model is a simplified representation of reality according to the specific vision of the modeller. | |
| + | \\ | ||
| ---- | ---- | ||
| - | + | \\ | |
| - | ====What are Spatially explicit models?==== | + | ===What are spatially explicit models?=== |
| - | * Spatially explicit models simulate the dynamics of an environmental system, reproducing the way its spatial patterns evolve, to project the probable ecological and socioeconomic consequences from the system dynamics. | + | \\ |
| - | + | Spatially explicit models simulate an environmental system, reproducing the way its spatial patterns evolve, projecting the nature and likelihood of ecological and socioeconomic consequences from the system dynamics. | |
| + | \\ | ||
| ---- | ---- | ||
| - | + | \\ | |
| - | ====Discrete and Continuous Maps - What's the Difference?==== | + | ===Discrete and continuous maps - What's the difference?=== |
| - | * **Discrete map** contains finite values that have nothing in-between. So, in other words discrete map refers to the type of map that contain quantitative data that relies on counts. It contains only finite values, whose subdivision is not possible. It includes only those values that can only be counted in whole numbers or integers and are separate which means the data cannot be broken down into fraction or decimal. | + | \\ |
| - | + | * A **Discrete Map** holds a finite array of integer values. Otherwise stated, a discrete map includes only those values that can only be counted in whole numbers or integers and are separate, which means the data cannot be broken down into a fraction or decimal representation. | |
| - | * **Continuous map** is described as a map unbroken set of observations; that can be measured on a scale. It can take any numeric value, within a finite or infinite range of possible value. Statistically, range refers to the difference between highest and lowest observation. The continuous data can be broken down into fractions and decimal, i.e. it can be meaningfully subdivided into smaller parts according to the measurement precision. | + | \\ |
| - | + | * A **Continuous Map** is described as an unbroken set of observations that can be measured on a scale. It can take any numeric value, within a finite or infinite range of possible values. Statistically, range refers to the difference between the highest and lowest observations. The continuous data can be broken down into a fraction and decimal representation , i.e. it can be meaningfully subdivided into smaller parts according to the measurement precision. | |
| - | * Hence, Discrete map expects a certain number data of isolated values. In contrast to continuous map, which expects any value from a given range (without any breaks), and is related to physical measurement. | + | \\ |
| - | + | Hence, discrete maps expect a certain number data of isolated values. On the other hand, continuous maps expect any value from a given range (without any breaks), and is related to a physical measurement. | |
| + | \\ | ||
| ---- | ---- | ||
| - | + | \\ | |
| - | ====What are the ways of representing data? Raster and Vector Data - What's the Difference? === | + | ===How can data be represented? Raster and Vector Data - What's the Difference? === |
| - | + | \\ | |
| - | * **Vector Data** is a representation of the world using points, lines, and polygons. These data are created by digitizing the base data. They store information in x, y coordinates. Vectors models are used to store data, which have discrete boundaries like country borders, land parcels and roads. Vector models are useful for storing data that has discrete boundaries, such as country borders, land parcels, and streets. \\ \\ | + | * **Vector Data** is a representation of the world using points, lines, and polygons. These data are created by digitising the base data and they store information in X, Y coordinates. Vector models are useful for storing data that has discrete boundaries, such as country borders, land parcels, and streets. |
| - | * **Raster Data** stores information of features in cell-based manner. Satellite images, photogrammetry and scanned maps are all raster-based data. Raster models are used to store data, which varies continuously as in aerial photography, a satellite image or elevation values. A raster consists of a matrix of cells (or pixels) organized into rows and columns. | + | \\ |
| - | + | * **Raster Data** stores information of features in cell-based manner. Satellite images, photogrammetry and scanned maps are all raster-based data. Raster models are used to store data, which varies continuously as in aerial photography, a satellite image or elevation values. A raster consists of a matrix of cells (or pixels) organised into rows and columns. | |
| + | \\ | ||
| ---- | ---- | ||
| - | + | \\ | |
| - | ====Why model land change?==== | + | ===Why model land change?=== |
| - | * Land Change Models support science and decision making | + | \\ |
| + | * Land Change Models provides scientific background for decision making | ||
| * Predict and project (What if we choose policy A or B?) | * Predict and project (What if we choose policy A or B?) | ||
| * Explain and learn (What are some potential unintended consequences of choosing policy A?) | * Explain and learn (What are some potential unintended consequences of choosing policy A?) | ||
| - | + | \\ | |
| ---- | ---- | ||
| - | + | \\ | |
| - | ====What is a feedback?==== | + | ===What is a feedback?=== |
| - | * A feedback loop in a dynamic system can be defined as a closed-loop circleof cause and effect in which "conditions" in one part of the system cause "results" elsewhere in the system, which in turn act on the original "conditions" to change them. There are two types of feedback loops that can occur.These are **(1)positive feedback** (also called reinforcing feedback) and **(2) negative feedback** (also called counteracting feedback). | + | \\ |
| + | A feedback loop in a dynamic system can be defined as a closed-loop or a circle of cause and effect in which "conditions" in one part of the system cause "results" elsewhere in the system, which in turn act on the original "conditions" to change them. There are two types of feedback loops that can occur. These are **positive feedback** loops (also called reinforcing feedback) and **negative feedback** loops (also called counteracting feedback). | ||
| + | \\ | ||
| + | \\ | ||
| + | ---- | ||
| + | \\ | ||
| + | ☞[[lesson_1|Next Lesson]] | ||
| + | \\ | ||
| + | ☞[[:guidebook_start| Back to Guidebook Start]] | ||