Motion and force

  • #403 Gizmo Image

    Fan Cart Physics

    Gain an understanding of Newton's Laws by experimenting with a cart (on which up to three fans are placed) on a linear track. The cart has a mass, as does each fan. The fans exert a constant force when switched on, and the direction of the fans can be altered as the position, velocity, and acceleration of the cart are measured.

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    Free-Fall Laboratory

    Investigate the motion of an object as it falls to the ground. A variety of objects can be compared, and their motion can be observed in a vacuum, in normal air, and in denser air. The position, velocity, and acceleration are measured over time, and the forces on the object can be displayed. Using the manual settings, the mass, radius, height, and initial velocity of the object can be adjusted, as can the air density and wind.

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    Golf Range

    Try to get a hole in one by adjusting the velocity and launch angle of a golf ball. Explore the physics of projectile motion in a frictional or ideal setting. Horizontal and vertical velocity vectors can be displayed, as well as the path of the ball. The height of the golfer and the force of gravity are also adjustable.

  • #609 Gizmo Image

    Shoot the Monkey

    Fire a banana cannon at a monkey in a tree. The monkey drops from the tree at the moment the banana is fired from the cannon. Determine where to aim the cannon so the monkey catches the banana. The position of the cannon, launch angle and initial velocity of the banana can be varied. Students can observe the velocity vectors and the paths of the monkey and banana.

  • #405 Gizmo Image

    Roller Coaster Physics

    Adjust the hills on a toy-car roller coaster and watch what happens as the car careens toward an egg (that can be broken) at the end of the track. The heights of three hills can be manipulated, along with the mass of the car and the friction of the track. A graph of various variables of motion can be viewed as the car travels, including potential, kinetic, and total energies, and the x- and y- components of position, velocity, and acceleration.

  • #604 Gizmo Image

    Inclined Plane - Simple Machine

    Investigate how an inclined plane redirects and reduces the force pulling a brick downward, with or without friction. A toy car can apply a variable upward force on the brick, and the mechanical advantage and efficiency of the plane can be determined. A graph of force versus distance illustrates the concept of work.

  • #27 Gizmo Image

    Inclined Plane - Sliding Objects

    Investigate the energy and motion of a block sliding down an inclined plane, with or without friction. The ramp angle can be varied and a variety of materials for the block and ramp can be used. Potential and kinetic energy are reported as the block slides down the ramp. Two experiments can be run simultaneously to compare results as factors are varied.

  • #587 Gizmo Image

    Inclined Plane - Rolling Objects

    Observe and compare objects of different shapes as they roll or slide down an inclined plane. Compare the percentages of translational and rotational kinetic energy for each object, and see how this affects how quickly each object moves. The slope of each ramp can be adjusted, and a variety of materials can be used for the objects and ramp.

  • #605 Gizmo Image

    Moment of Inertia

    Place masses on a circular table and see how fast it spins when struck by a piston. Discover the relationships between angular velocity, mass, radius and moment of inertia for collections of point-masses, rings, disks, and more complex shapes.

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    Torque and Moment of Inertia

    One of the simplest machines is a see-saw lever. Place up to eight objects on the lever at different locations and try to balance it. Calculate net torque and moment of inertia based on the positions of the objects and the mass of the bar. The mass of each object can be changed, and the fulcrum position can be shifted as well.

  • #12 Gizmo Image

    Air Track

    Adjust the mass and velocity of two gliders on a frictionless air track. Measure the velocity, momentum, and kinetic energy of each glider as they approach each other and collide. Collisions can be elastic or inelastic.

  • #586 Gizmo Image

    Orbital Motion - Kepler's Laws

    Learn Kepler's three laws of planetary motion by examining the orbit of a planet around a star. The initial position, velocity, and mass of the planet can be varied as well as the mass of the star.

  • #603 Gizmo Image

    Archimedes' Principle

    Place weights into a boat and see how far the boat sinks into a tank of liquid. The depth of the boat can be measured, as well as the amount of liquid displaced. The dimensions of the boat and the density of the liquid can be adjusted. See how much weight the boat can hold before it sinks to the bottom!

  • #523 Gizmo Image

    Atwood Machine

    Measure the height and velocity of two objects connected by a massless rope over a pulley. Observe the forces acting on each mass throughout the simulation. Calculate the acceleration of the objects, and relate these calculations to Newton's Laws of Motion. The mass of each object can be manipulated, as well as the mass and radius of the pulley.

  • #260 Gizmo Image

    Distance-Time Graphs

    Create a graph of a runner's position versus time and watch the runner complete a 40-yard dash based on the graph you made. Notice the connection between the slope of the line and the speed of the runner. What will the runner do if the slope of the line is zero? What if the slope is negative? Add a second runner (a second graph) and connect real-world meaning to the intersection of two graphs.

  • #301 Gizmo Image

    Distance-Time and Velocity-Time Graphs

    Create a graph of a runner's position versus time and watch the runner run a 40-yard dash based on the graph you made. Notice the connection between the slope of the line and the velocity of the runner. Add a second runner (a second graph) and connect real-world meaning to the intersection of two graphs. Also experiment with a graph of velocity versus time for the runners, and also distance traveled versus time.

  • #572 Gizmo Image

    Pulley Lab

    Use a pulley system to lift a heavy weight to a certain height. Measure the force required to lift the weight using up to three fixed and three movable pulleys. The weight to be lifted and the efficiency of the pulley system can be adjusted, and the height of the weight and the total input distance are reported.

  • #415 Gizmo Image

    Vectors

    Manipulate the magnitude and direction of two vectors to generate a sum and learn vector addition. The x and y components can be displayed, along with the dot product of the two vectors.

  • #361 Gizmo Image

    2D Collisions

    Investigate elastic collisions in two dimensions using two frictionless pucks. The mass, velocity, and initial position of each puck can be modified to create a broad array of scenarios.

  • #423 Gizmo Image

    Uniform Circular Motion

    Measure the position, velocity, and acceleration (both components and magnitude) of an object undergoing circular motion. The radius and velocity of the object can be controlled, along with the mass of the object. The forces acting on the object can also be recorded.

  • #391 Gizmo Image

    Period of a Pendulum

    Perform experiments with a pendulum to gain an understanding of the period during simple harmonic motion. The gravity, length and mass of the pendulum can be adjusted, and data can be collected by measuring the time between swings of the pendulum.

  • #454 Gizmo Image

    Period of a Pendulum - Large Angle

    Perform experiments with a pendulum to gain an understanding of the period and the dependence on the angular range of the swing. The gravity, the length and mass of the pendulum, along with the initial angle (which can be very large) can be adjusted, and data can be collected by measuring the time between pendulum swings.

  • #390 Gizmo Image

    Energy of a Pendulum

    Perform experiments with a pendulum to gain an understanding of energy conservation in simple harmonic motion. The gravity, length and mass of the pendulum can be adjusted, as well as the initial starting angle of the pendulum. Data (tables, bar chart, and graphs) of the potential and kinetic energies are shown as the pendulum oscillates.

  • #421 Gizmo Image

    Period of Mass on a Spring

    Perform experiments with a mass on the end of a spring to gain an understanding of the period during simple harmonic motion. The gravity, spring constant, and mass hanging from the spring can be adjusted, and data can be collected by measuring the time between oscillations of the mass.

  • #428 Gizmo Image

    Determining a Spring Constant

    Place a pan on the end of a hanging spring, and continue to add additional objects with mass to the pan. As the string stretches the length of the spring can be measured. Using the data points, a best-fit line can be used to find the spring constant.

  • #606 Gizmo Image

    Center of Mass

    Drag blocks onto a two-dimensional surface and observe the effects on the center of mass. Use a grid to calculate the coordinates of the center of mass. Investigate predefined shapes or your own arrangements of blocks.

  • #411 Gizmo Image

    Gravitational Force

    Drag two objects around and observe the gravitational force between them as the positions change. The mass of each object can be adjusted, and the gravitational force is displayed both vectorially and numerically as the distance between the objects is altered.

  • #44 Gizmo Image

    Simple Harmonic Motion

    Observe two different forms of simple harmonic motion: a pendulum and a spring supporting a mass. Use a stopwatch to measure the period of each as you adjust the gravity, spring constant, mass hanging from the spring, length of the pendulum, and mass of the pendulum.

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