With encouragement and ideas from his family, Papa, based on the real-life inventor Lodner Phillips, builds a working submarine that takes his family on a ride to the bottom of Lake Michigan. The resource includes a lesson plan/book card, a design challenge, and copy of a design thinking journal that provide guidance on using the book to inspire students' curiosity for design thinking. Maker Challenge: Students will use materials on hand to design a solution to a problem they see in their school or at home. The invention should meet the needs of fellow students, teachers, bus drivers, principals, siblings, friends, or even parents.

A document is included in the resources folder that lists the complete standards-alignment for this book activity.

Test prep/review sheets for students for the following topics: Cells; Reproduction; Separating mixtures; Rocks; Light and Sound; Electricity

New York City in the 1860s was a mess: crowded, disgusting, filled with garbage. You see, way back in 1860, there were no subways, just cobblestone streets. That is, until Alfred Ely Beach had the idea for a fan-powered train that would travel underground. On February 26, 1870, after fifty-eight days of drilling and painting and plastering, Beach unveiled his masterpiece—and throngs of visitors took turns swooshing down the track. The resource includes a lesson plan/book card, a design challenge, and copy of a design thinking journal that provide guidance on using the book to inspire students' curiosity for design thinking. Maker Challenge: Think about the way most people in your community travel. Invent a new way of traveling around your community that takes into account the following: helpful to the community, economical to those who use it, convenient for users. What would your new travel system look like? Sketch a new design, and then create a physical prototype of the new design to scale. Keep in mind: Where the system travels, how it is powered, why it is helpful to the community, and any features that make it special.

A document is included in the resources folder that lists the complete standards-alignment for this book activity.

Students learn the connections between the science of sound waves and engineering design for sound environments. Through three lessons, students come to better understand sound waves, including how they change with distance, travel through different mediums, and are enhanced or mitigated in designed sound environments. They are introduced to audio engineers who use their expert scientific knowledge to manipulate sound for music and film production. They see how the invention of the telephone pioneered communications engineering, leading to today's long-range communication industry and its worldwide impact. Students analyze materials for sound properties suitable for acoustic design, learning about the varied environments created by acoustical engineers. Hands-on activities include modeling the placement of microphones to create a specific musical image, modeling and analyzing a string telephone, and applyling what they've learned about sound waves and materials to model a controlled sound room.

This simulation lets you see sound waves. Adjust the frequency or volume and you can see and hear how the wave changes. Move the listener around and hear what she hears.

In this lesson, students are introduced to communications engineers as people who enable long-range communication. In the lesson demonstration, students discuss the tendency of sound to diminish with distance and model this phenomenon using a slinky. Finally, Alexander Graham Bell is introduced as the inventor of the telephone and a pioneer in communications engineering.

In this simulation, students adjust the slider to increase or decrease the pitch of a sound. They can also manipulate the time scale. This is used in Lesson 5 of Unit 8.2 of the OpenSciEd curriculum.

In this simulation, students adjust the slider to increase or decrease the loudness of a sound. They can also manipulate the time scale. This is used in Lesson 4 of Unit 8.2 of the OpenSciEd curriculum.

Music can loosely be defined as organized sound. The lesson objectives, understanding sound is a form of energy, understanding pitch, understanding sound traveling through a medium, and being able to separate music from sound, can provide a good knowledge base as to how sound, math, and music are related. Sound exists everywhere in the world; typically objects cause waves of pressure in the air which are perceived by people as sound. Among the sounds that exist in everyday life, a few of them produce a definite pitch. For example, blowing air over half full glass bottles, tapping a glass with a spoon, and tapping long steel rods against a hard surface all produce a definite pitch because a certain component of the object vibrates in a periodic fashion. The pitch produced by an object can be changed by the length or the volume of the portion that vibrates. For example, by gradually filling a bottle while blowing across the top, higher pitches can be generated. By organizing a few of these sounds with a clearer pitch, the sounds become closer to music. The very first musical instruments involved using various objects (e.g. bells) that have different pitches, which are played in sequence. The organization of the pitches is what transforms sounds into music. Since the first instruments, the ability to control pitch has greatly improved as illustrated by more modern instruments such as guitars, violins, pianos, and more. Music is comprised of organized sound, which is made of specific frequencies. This lesson will help define and elaborate on the connections between sound and music.

With this free online tone generator, students enter their desired frequency and press play. The tone generator plays four different waveforms. This is used in Lesson 12 of Unit 8.2 of the OpenSciEd curriculum.

This simulation demonstrates a slow-motion version of what it would look like if you could see particles in a medium vibrating. The wave-like diagram underneath the air particle representation is a graph of the motion of the sound source. Only the particle diagram is a representation of the sound wave. This is used in Lesson 10 of Unit 8.2 in the OpenSciEd curriculum.

Watch a string vibrate in slow motion. Wiggle the end of the string and make waves, or adjust the frequency and amplitude of an oscillator. Adjust the damping and tension. The end can be fixed, loose, or open.

Emma Lilian Todd was a self-taught engineer who tackled one of the greatest challenges of the early 1900s: designing an airplane. As an adult, typing up patents at the U.S. Patent Office, Lilian built inventions in her mind, including many designs for flying machines. However, they all seemed too impractical. Lilian knew she could design one that worked. She took inspiration from both nature and her many failures, driving herself to perfect the design that would eventually successfully fly. The resource includes a lesson plan/book card, a design challenge, and copy of a design thinking journal that provide guidance on using the book to inspire students' curiosity for design thinking. Maker Challenge: Design a new mode of transportation (air, sea, or ground) or select a current mode of transportation and improve it then use household items to create a prototype of your new or updated invention.

A document is included in the resources folder that lists the complete standards-alignment for this book activity.