Voyager & Ozobot: A STEM Team to Study Circular Motion

Submitted by Rich on Wed, 07/26/2017 - 15:44

Ozobot “Evo” ( is a tiny one-inch diameter robot that can be quickly programmed to follow lines using a Google Blockly dialect known as OzoBlockly (  This lesson combines the ability to program Ozobot to follow a circle at constant speed with Voyager’s ability to sense the resulting motion through its angular velocity sensor.  The purpose of this project is to show that if speed is kept constant and the same fo

Is Global Warming FAKE NEWS? Creating a Bottle Ecosystem

Submitted by DaveBakker on Tue, 07/25/2017 - 22:56

Can you devise an experiment to see whether increased CO2 (carbon dioxide) in the atmosphere contributes to warming? We found a teacher who tweeted exactly what you need! @MontessoriMicky  shared with us his lesson plan on a Bottle Ecosystem and had his class run an experiment using PocketLab to measure the heat absorption of a glass bottle filled with CO2 vs normal air as a control.

Voyager & Ozobot: A STEM Team to Determine the Dimensions of a Cardboard Box

Submitted by Rich on Mon, 07/24/2017 - 15:34

Ozobot “Evo” ( is a tiny one-inch diameter robot that can be quickly programmed using a Google Blockly dialect known as OzoBlockly (  Combining the ability to program Ozobot to rotate precisely as desired with Voyager’s ability to sense the resulting motion through its collection of sensors, the possibility of a seemingly endless variety of STEM projects becomes a reality.

PocketLab Voyager: A Study of Rolling Resistance

Submitted by Rich on Fri, 07/21/2017 - 17:19

In this experiment a coasting cart on a flat surface gradually slows down and stops due to rolling resistance.  Two very different surfaces are compared—a carpeted floor and a wood floor.  The purpose of this experiment is three-fold:  (1) to determine the force of rolling resistance, (2) to determine the coefficient of rolling resistance between the cart the surface on which it rolls, and (3) to gain a practical understanding of the meaning of this coefficient.  Voyager's range finder is used to collect data.

PocketLab Voyager: The Effect of Area on Terminal Velocity of a Falling Object

Submitted by Rich on Tue, 07/18/2017 - 18:10

The effect of mass on the terminal velocity of an object falling in air is commonly done using basket coffee filters.  But how could we study the effect of area on the terminal velocity of a falling object?  One way to do this is to use PocketLab Voyager and its range finder along with a single piece of cardstock as the object to be dropped.  In this lesson, students discover a relationship between area and terminal velocity and compare their results to a common model of air resistance (aka drag).  

PocketLab Voyager: Polarization and Malus's Law

Submitted by Rich on Sun, 07/16/2017 - 16:14

One of the most well-known physical laws related to polarization is Malus’s Law.  This law states that the intensity of plane-polarized light passing through a rotatable polarizer analyzer varies as the square of the cosine of the angle through which the analyzer is rotated from the position giving maximum intensity.  The lesson described here allows you to verify Malus’s Law using PocketLab Voyager and one of the light polarizers contained in the PocketLab Scientist Kit.

PocketLab Voyager: How to Discover an Exoplanet

Submitted by Rich on Thu, 07/13/2017 - 00:53

Over the past twenty years, scientists have discovered hundreds of what are known as exoplanets—planets that orbit stars outside of our own solar system.   Different groups of scientists worldwide have used a variety of methods to detect these planets.  In this lesson we will investigate a method that has been quite fruitful in finding exoplanets as a result of the Kepler Mission, launched by NASA in 2009.  Another similar mission is CoRoT, led by the French Space Agency.  These missions identify exoplanets by a method called transit, in which the b