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Cookbook for Common Codes for StarLogo Nova 1.0 and StarLogo Nova 2.0

The links below include explanations and screen shots for common codes in both versions of StarLogo Nova, including setting up the world, creating and renaming breeds, using default traits and creating custom traits, random and wiggle walks, coordinates and using 3-D view, using keyboard controls, using widgets including sliders, data boxes, charts and line graphs, terrain color, using collisions, creating a stop code, and teaching agents to chase or run away from other agents.

Image of slider from www.thenounproject.com

What are the chances?

An off-line activity to introduce students to concepts of randomness and how to program percent chance using a slider in StarLogo Nova.

Image from Project GUTS instructions showing grid

Battleship activity in StarLogo Nova

This activity uses the idea of the classic "battleship" game to review x and y coordinates in StarLogo Nova. Students do a pen and paper simulation of the game, and then use a base model in StarLogo Nova to review the coordinates.

Decoding a model

Decoding a model is an on computer activity in which students are challenged to decode a model.

Photo of presentation from larryferrlazzo.edublogs.org

Student Activity Guide: Preparing Presentations

A list of guidelines for students to follow in preparing to present a completed model (Day 5 activity in Modules 2, 2A, 3, and 4 in CS in Science Modules).

Libro de recetas de StarLogo NOVA

Este documento incluye explicaciones y capturas de pantalla para los códigos comunes en StarLogo Nova, incluyendo la creación del mundo, la creación y el cambio de nombre de razas, el uso de rasgos por defecto y la creación de rasgos personalizados, movimientos aleatorios, coordenadas y el uso de la vista 3D, cajas de datos y gráficos de línea, el color del terreno, el uso de colisiones, la creación de un código para detener la ejecución, y cómo perseguir o huir de otros agentes.

Formulario de diseño experimental

Una copia imprimible del formulario de diseño experimental, utilizada en los Módulos Científicos de Project GUTS, para que los estudiantes planifiquen un experimento, incluyendo la identificación de variables, la planificación de la recopilación y el análisis de datos y la interpretación. Traducción del original en Inglés.

Pioneros (Trailblazers)

Pioneros (Trailblazers) es una actividad divertida con lápiz y papel donde los estudiantes escriben instrucciones sencillas para que otro estudiante navegue por un laberinto. Las instrucciones se dibujan en el laberinto como comandos (si el cuadrado es rojo, gire a la derecha, etc.) y luego los estudiantes intercambian papeles para navegar por el laberinto siguiendo solamente los comandos. Esta es una actividad preliminar para la actividad de codificación de las tortugas chocadoras.

image of battleship by https://www.vectorstock.com

Battle of the Agents

A take on the classic board game Battleship, this paper and pencil activity is a fun way to help students understand the use of x and y coordinates in StarLogo Nova. After the activity, students can use the StarLogo Nova model to experiment with x and y locations in a game-like context.

Daisy world

A model demonstrating the albedo effect of black or white surfaces. Use as a part of the Climate Change and Agriculture Project GUTS Curricular Unit, or as a stand-alone model, activity, and video.

Diagram of x and y coordinates in StarLogo Nova

Math Basics for StarLogo Nova

This handout explains left and right degrees, x and y coordinates, and headings in StarLogo Nova.

Code.org and SLNova Computer Science Concepts

This is a 4 week unit for a Computer Technology class in a middle school. Students are introduced to computer science concepts through lessons in Code.org's Course 3. Students then apply those concepts in SLNova projects.

Maze

Students struggle understanding proportional relationships and scaling shapes. This module allows students to scale one shape and transfer it to 3 different environments. Students will create a game online (SL Nova) and program a Sphero (robot) while learning the math standards.

https://www.youtube.com/watch?v=Utb1plCyyb0

Exploring the Wiggle Walk and Collisions via a Kinesthetic Activity

This activity teaches the Wiggle Walk blocks (random right by ___ degrees, random left by___ degrees), through a kinesthetic activity and explores when a programmer would want to code agents to move this way. It avoids the statical analysis of the random probabilities found in Module One, Lesson 4 Activity 1: Probability with Dice and Data and Colliding Turtles, while still addressing the end goals of the Module One Lesson 4.

Decoding a Model - Dissolving of NaCl in Water

Start of a lesson on dissolving a solid in water by decoding on a model.

Scientific Practices and Computational Thinking in Modeling & Simulation

This document is a handout used to reflect on the scientific practices and computational thinking involved in a Project GUTS module or lesson.

Screen shot of blocks and concepts guide

Code Blocks for CS in Science Module 1: Intro to Computer Science & Simulation

Here are links to the Code Blocks for CS in Science Module 1, for StarLogo Nova 1.0 (Flash version), and the Code Blocks for CS in Science Module 1 for StarLogo Nova 2.0 (HTML5/JavaScript version). This is not the one-page Blocks and Drawers Guide for StarLogo Nova (those documents are linked below).

Guides, Common Forms, and Activity Sheets for CS in Science Modules

This 56-page pdf includes printable copies of the Student Activity Guides, Common Forms, Blocks Guides, CS Concepts, and Progress Monitors for Modules 1-4 of CS in Science. This version was created in 2015, for StarLogo Nova 1.0. If using StarLogo Nova 2.0, search for the Blocks guides attached to each module.

Model Observation Form

This form is used to capture a learner's thinking while observing a model.

Rock Paper Scissors

The classic game of Rock Paper Scissors is known to all students. This common experience can then be used to encourage students to think about Complex Adaptive Systems in terms of unpredictability, which comes from the simple rules of agents. The off-line activity gives students a set of rules that will then be programmed into their computer model using Boolean logic and collisions.

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