The solar system is made up of the Sun, the planets that orbit the Sun, their satellites, dwarf planets and many, many small objects, like asteroids and comets. All of these objects move and we can see these movements. We notice the Sun rises in the eastern sky in the morning and sets in the western sky in the evening. We observe different stars in the sky at different times of the year. When ancient people made these observations, they imagined that the sky was actually moving while the Earth stood still. The Moon is a natural satellite of the Earth, meaning that it orbits around the Earth.It is the only place outside of the Earth that humans have ever been! We can often see the Moon on a clear night, but it does appear to change shape during the 29 days it takes to orbit the Earth.

The course aims is to understand the relation between urban design and planning and the aspects of: - sun, energy and plants - wind, sound and noise - water, traffic and other networks - earth, soil and site preparation - life, ecology and nature preservation - living, human density, economy and environment These themes in sustainable urban engineering are related to legends for design, described in a wide variety of lecture papers (720 pages, 1000 figures, 200 references, 5000 key words, 400 questions), accompanied by interactive Excel computer programmes to get quantitative insight. The assignment is an evaluation of an own earlier and future design work integrating sun, plantation, wind, noise, water, traffic, earth, land preparation, cables and pipes, life, natural differentiation, living, density, environment and proposing new legends for design. Study Goals The student: - is able to link urban interventions to urban development technology and within that interrelate urban designers to relevant technical specialists - is able to integrating sun, plantation, wind, noise, water, traffic, earth, land preparation, cables and pipes, life, natural differentiation, living, density, environment - is able to develop new legends for design from the perspective of sustainable urban engineering

Interpret properties of the landscape using topographic maps of well-known national parks. Direct link on ArcGIs. THE EARTH SCIENCE GEOINQUIRY COLLECTIONhttp://www.esri.com/geoinquiriesThe Earth Science GeoInquiry collection contains 15 free, web-mapping activities that correspond and extend map-based concepts in leading middle school Earth science textbooks. The activities use a standard inquiry-based instructional model, require only 15 minutes for a teacher to deliver, and are device agnostic.  The activities harmonize with the Next Generation Science Standards. Activity topics include:•                 Topographic maps•                 Remote sensing•                 Minerals / Mining•                 Rock Types•                 Landforms•                 Plate tectonics•                 Earthquakes•                 Volcanoes•                 Mountain building•                 Fresh water•                 Ocean features•                 Ground wind and temperature patterns•                 Weather•                 Storms•                 Climate change

Students learn about tornadoes - their basic characteristics, damage and occurrence. Students are introduced to the ways that engineers consider strong winds, specifically tornadoes, in their design of structures. Also, students learn how tornadoes are rated, and learn some basics of tornado safety.

Students learn about tornadoes, the damage they cause, and how to rate tornadoes. Specifically, students investigate the Enhanced Fujita Damage Scale of tornado intensity, and use it to complete a mock engineering analysis of damage caused by a tornado. Additional consideration is given to tornado warning systems and how these systems can be improved to be safer. Lastly, students learn basic tornado safety procedures.

Students will analyze data of tornadoes throughout the United States. They will create a bar graph of the number of tornadoes for the top ten states in the country and then calculate the median and the mode of the data.

Students apply their knowledge about mountains and rocks to transportation engineering, with the task of developing a model mountain tunnel that simulates the principles behind real-life engineering design. Student teams design and create model tunnels through a clay mountain, working within design constraints and testing for success; the tunnels must meet specific design requirements and withstand a certain load.

In this seminar you will learn all about the water cycle that we have on Earth. You will use the habit of mind known as gathering data through all senses to explore each stage of the water cycle. You will explain why the water cycle is essential for humans, animals, and plants on Earth. Finally, you will get to explain how the water cycle works through an informational project.Standards3.2.4.A5MODELSUse models to demonstrate the physical change as water goes from liquid to ice and from liquid to vapor.

During this activity, students learn how oil is formed and where in the Earth we find it. Students take a core sample to look for oil in a model of the Earth. They analyze their sample and make an informed decision as to whether or not they should "drill for oil" in a specific location.

The Apollo 11 mission to the moon in 1969 introduced The Lunar Laser Ranging Interplanetary Experiment led by Hildreth (Hal) Walker Jr. This ongoing experiment measures Earth's distance from the Moon

In this animated video segment adapted from NASA, astronomer Doris Daou explains how the forces of speed and gravity keep the Moon in a constant orbit around Earth.

Students will learn the difference between global, prevailing and local winds. In this activity, students will make a wind vane out of paper, a straw and a soda bottle and use it to measure wind direction over time. Finally, they will analyze their data to draw conclusions about the prevailing winds in their area.

Students learn about wind energy by making a pinwheel to model a wind turbine. Just like engineers, they decide where and how their turbine works best by testing it in different areas of the playground.

In this activity, students will learn about how tornadoes are formed and what they look like. By creating a water vortex in a soda bottle, they will get a first-hand look at tornadoes.

In this activity, learners use basic measurements of the Earth and pieces of rock and iron to estimate the mass of the Earth. Learners will calculate mass, volume, and density, convert units, and employ the water displacement method. To calculate an even more accurate estimate of the mass of the Earth, this resource includes optional instructions on how to measure the iron core mass.