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Disc: $23.00 This interactive curriculum matrix was created to make it easier to see how standards on different topics covered in different grades can work together. Using an accordion style layout allows the matrix to highlight the alignments between content and grade levels while collapsing unneeded standards and temporarily hiding them from view. Flash allows the matrix to be fully interactive with selectable text and allows the matrix to be web accessible to teachers, parents, advisors, and administrators.
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Print: $12.75 It takes a lot to prepare for the AP Physics Exams. The Grade Level Expectations in Delaware's Science Standards outline a path that helps with this preparation. This booklet aligns Delaware's Grade Level Expectations with the Advanced Placement Physics Learning Objectives.
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Download: $12.50 This is the Strobe Vehicle Mechanics Assessment. This assessment uses strobe images of cars to guage understanding of motion, forces, momentum and energy.
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SUV IllustrationSUV Illustration (multimedia download)
Download: $1.00 These illustrations show two perspectives of an SUV in microsoft word
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Car IllustrationCar Illustration (multimedia download)
Download: $1.00 These illustrations show two perspectives of a small car drawn in microsoft word.
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Disc: $20.00 These physics drawing objects were created with the Drawing toolbar in Microsoft Word. In this format, they allow users to select and delete individual lines or grouped shapes, resize, distort or rotate the object, move portions of selected lines or grouped shapes, and add or change shading or coloring. Any of these changes will have no effect on the objects' final print quality like pixel based images. Since all drawing objects were created in Word, they are compatible with all Microsoft Office programs and are particularly effective in Power Point.
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Download: $10.00 The Physics Ancillary was originally created by Judson Wagner to serve the needs of students taking Advanced Placement Physics. The result was a valuable companion that continued to assist these students well into their first years of college physics. Like the printed version, this flash edition of the ancillary was intended to compliment the standard college text by providing what the college text cannot. It is affordable and compact. The ancillary is fully equipped with quick reference reminders, illustrations, and equations on topics which include mechanics, E&M, waves, optics, thermodynamics, and modern physics.
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Download: $1.00 This animation shows the relationship between the normal force and the weight of a person on a moving elevator. A scale on the elevator, position vs time and velocity vs time graphs, strobe dots, and a reacting figure illustrate how motion effects the normal force.
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Download: $1.00 This animation shows the path of a projectile with velocity vectors and illustrates the constant change in velocity.
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Download: $1.00 This animation shows boats crossing a river with a current. Velocity vectors are used to indicate resultant motion.
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Download: $1.00 This animation shows a car moving while showing strobe dots for the position of the car at equal time intervals, the effect on the acceleration on the driver, vectors representing velocity and acceleration, a position vs time graph and velocity vs time graph.
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Download: $1.00 This animation shows a car moving while showing strobe dots for the position of the car at equal time intervals, the effect on the acceleration on the driver, vectors representing velocity and acceleration, a position vs time graph and velocity vs time graph.
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Download: $1.00 This animation shows an object in circular motion with a velocity vector and illustrates the direction of the change in velocity over long and short increments of time.
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Download: $1.00 This animation shows an object in circular motion with a velocity vector and illustrates the direction of the change in velocity over long and short increments of time.
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Download: $1.00 This animation shows how the motion of a car going around a curve effects the driver of the car. Velocity (blue) and acceleration (green) vectors, a hanging ball, and a reacting figure illustrate this relationship.
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Download: $1.00 This animation shows how the motion of a car going around a curve effects the driver of the car. Velocity (blue) and acceleration (green) vectors, a hanging ball, and a reacting figure illustrate this relationship.
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Download: $1.00 This animation shows a car going around a curve when friction is present and when friction is removed. Strobe dots, blue velocity vectors and green acceleration vectors are used to illustrate the resulting motion.
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Download: $1.00 This animation shows a car going around a curve when friction is present and when friction is removed. Strobe dots, blue velocity vectors and green acceleration vectors are used to illustrate the resulting motion.
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Download: $1.00 This animation shows a car going around a banked curve. Red vectors are used to show the forces acting on the car and a yellow vector is used to illustrate the centripetal component of the normal force that gives the car its curved motion.
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Download: $1.00 This animation shows a car going around a banked curve. Red vectors are used to show the forces acting on the car and a yellow vector is used to illustrate the centripetal component of the normal force that gives the car its curved motion.
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Download: $1.00 This animation shows a two dimensional glancing collision. Strobe images are used to illustrate both path and speeds. Perspectives are used to show that momentum is still conserved when viewed as a one dimensional collision horizontally and vertically.
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Download: $1.00 This animation shows a two dimensional glancing collision. Strobe images are used to illustrate both path and speeds. Perspectives are used to show that momentum is still conserved when viewed as a one dimensional collision horizontally and vertically.
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Download: $1.00 This animation shows the collisions between balls of various mass and speeds. Larger balls are used to indicate larger masses.
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Download: $1.00 This animation shows the collisions between balls of various mass and speeds. Larger balls are used to indicate larger masses.
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Download: $1.00 This animation shows the impulse needed to stop a running boy. A force vs time graph is used once when the boy uses his face to stop himself, and again when he used his arms.
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Download: $1.00 This animation shows the impulse needed to stop a running boy. A force vs time graph is used once when the boy uses his face to stop himself, and again when he used his arms.
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Download: $1.00 This animation shows an exploding projectile and the effects of the explosion on the projectile's center of mass. The projectile is shown once from the perspective of a stationary observer, once with strobe images to illustrate the path of the center of mass, and once from the perspective of an observer moving with the center of mass.
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Download: $1.00 This animation shows an exploding projectile and the effects of the explosion on the projectile's center of mass. The projectile is shown once from the perspective of a stationary observer, once with strobe images to illustrate the path of the center of mass, and once from the perspective of an observer moving with the center of mass.
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Download: $1.00 This animation shows the Compton effect. Yellow vectors are used to represent the momentum of an incident photon and the scattered electron and photon.
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Download: $1.00 This animation shows the Compton effect. Yellow vectors are used to represent the momentum of an incident photon and the scattered electron and photon.
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Download: $1.00 This animation shows Hertz's photoelectric effect as explained by Einstein. Light of increasing frequencies is used to free electrons from a metal surface. First, a galvanometer is used to show what light produces a current. Second, an energy vs frequency graph is used to show the photoelectric equation as a linear relationship.
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Download: $1.00 This animation shows Hertz's photoelectric effect as explained by Einstein. Light of increasing frequencies is used to free electrons from a metal surface. First, a galvanometer is used to show what light produces a current. Second, an energy vs frequency graph is used to show the photoelectric equation as a linear relationship.
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Download: $1.00 This animation illustrates Plank's blackbody radiation by a heated object. An intensity versus wavelength graph is used to show the conditions on the object throughout the heating.
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Download: $1.00 This animation uses ray tracing to illustrate the characteristics of a refracted image.
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Download: $1.00 This animation uses ray tracing to illustrate the characteristics of a refracted image.
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Download: $1.00 This animation illustrates Plank's blackbody radiation by a heated object. An intensity versus wavelength graph is used to show the conditions on the object throughout the heating.
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Download: $1.00 This animation shows a simple circuit involving batteries and bulbs. As the animations shows combinations of bulbs in parallel, series and both parallel and series, bar graphs of dissipated power, potential differences, current and resistance are shown for each bulb and for the entire circuit. The bulbs also change brightness in agreement with the power dissipation.
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Download: $1.00 This animation shows a few models that explain the space between to objects with opposite charge. Field lines are shown as white lines and lines of equal potential are yellow. A rotated contour plot is used to illustrate the high and low potentials as will as the space between the charges.
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Download: $1.00 This animation shows a few models that explain the space between to objects with opposite charge. Field lines are shown as white lines and lines of equal potential are yellow. A rotated contour plot is used to illustrate the high and low potentials as will as the space between the charges.
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Download: $1.00 This animation is used to show the refraction of light through a denser medium. First, monochromatic light enters at various angles to show internal reflection. Second, light at various wavelengths is used to illustrate dispersion.
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Download: $1.00 This animation shows a moving charge in a uniform magnetic field and the resulting circular motion according to the right hand rule. The blue vector represents the charge's velocity (vo), the red vector is the centripetal force (F) and the yellow vector shows the magnetic field (B) coming out of the screen. The path is rotated to show the helical path that results when the velocity is not perpendicular to the magnetic field.
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Download: $1.00 This animation shows a moving charge in a uniform magnetic field and the resulting circular motion according to the right hand rule. The blue vector represents the charge's velocity (vo), the red vector is the centripetal force (F) and the yellow vector shows the magnetic field (B) coming out of the screen. The path is rotated to show the helical path that results when the velocity is not perpendicular to the magnetic field.
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Download: $1.00 This animation illustrates Rutherford's gold foil experiment. As alpha particles approach the gold nucleus, their kinetic energy is transformed into electric potential energy.
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Download: $1.00 This animation illustrates Rutherford's gold foil experiment. As alpha particles approach the gold nucleus, their kinetic energy is transformed into electric potential energy.
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Download: $1.00 This animation is used to show the refraction of light through a denser medium. First, monochromatic light enters at various angles to show internal reflection. Second, light at various wavelengths is used to illustrate dispersion.
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Download: $1.00 This animation shows the effect of a changing magnetic field on a coiled wire according to Faraday's law and Lentz's law. A galvanometer and yellow vectors are used to show the magnitude and direction of the induced currents.
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Download: $1.00 This animation shows the effect of a changing magnetic field on a coiled wire according to Faraday's law and Lentz's law. A galvanometer and yellow vectors are used to show the magnitude and direction of the induced currents.
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Download: $1.00 This animation shows a simple circuit involving batteries and bulbs. As the animations shows combinations of bulbs in parallel, series and both parallel and series, bar graphs of dissipated power, potential differences, current and resistance are shown for each bulb and for the entire circuit. The bulbs also change brightness in agreement with the power dissipation.
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Download: $1.00 This animation shows the reflections caused by a curved surface. First, the significance of the focal point is shown with straight and circular wave fronts. Second, ray tracing is illustrated to show the characteristics of a reflected image.
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Download: $1.00 This animation shows the reflections caused by a curved surface. First, the significance of the focal point is shown with straight and circular wave fronts. Second, ray tracing is illustrated to show the characteristics of a reflected image.
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Download: $1.00 This animation illustrates Bohr's hydrogen model. The energy levels of the electron are shown.
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Download: $1.00 This animation illustrates Bohr's hydrogen model. The energy levels of the electron are shown.
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Download: $1.00 This animation shows a ball being thrown straight up while showing strobe dots for the position of the ball at equal time intervals, the effect on the acceleration on its motion, vectors representing velocity and acceleration, a position vs time graph and velocity vs time graph.
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Download: $1.00 This animation shows a ball being thrown straight up while showing strobe dots for the position of the ball at equal time intervals, the effect on the acceleration on its motion, vectors representing velocity and acceleration, a position vs time graph and velocity vs time graph.
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Download: $1.00 This animation illustrates the idea of field by highlighting the similarities between electrical and gravitational fields. Yellow vectors represent the field lines and the red vectors represent the forces.
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Download: $1.00 This animation illustrates the idea of field by highlighting the similarities between electrical and gravitational fields. Yellow vectors represent the field lines and the red vectors represent the forces.
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Download: $1.00 This animation shows electrostatic interactions. Plus signs (+) are used to represent concentrations of positive charges and minus signs (-) are used for concentrations of negative charge.
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Download: $1.00 This animation shows electrostatic interactions. Plus signs (+) are used to represent concentrations of positive charges and minus signs (-) are used for concentrations of negative charge.
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Download: $1.00 This animation shows a gas in a piston throughout the Carnot cycle. A pressure vs volume graph is used to show the conditions on the gas throughout the cycle.
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Download: $1.00 This animation shows a gas in a piston throughout the Carnot cycle. A pressure vs volume graph is used to show the conditions on the gas throughout the cycle.
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Download: $1.00 This animation illustrates the Ideal Gas Law and Kinetic Molecular Theory. Red balls are used to represent moving gas molecules, circular plates are used to represent pressure, and a flame is used to represent a heat source.
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Download: $1.00 This animation illustrates the Ideal Gas Law and Kinetic Molecular Theory. Red balls are used to represent moving gas molecules, circular plates are used to represent pressure, and a flame is used to represent a heat source.
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Download: $1.00 This animation shows a fluid moving through a pipe to demonstrate Bernoulli's principal. A cut-away of the pipe shows objects moving with the fluid. Analogue guages are used to show changes in the internal pressure. A stacked bar graph is used to show the conservation of energy.
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Download: $1.00 This animation shows a source of circular waves. The Doppler effect is demonstrated, as the source moves. Each successive wave crest is given a different color and the object is shown moving slower, at the same speed and faster than the waves it creates.
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Download: $1.00 This animation shows a source of circular waves. The Doppler effect is demonstrated, as the source moves. Each successive wave crest is given a different color and the object is shown moving slower, at the same speed and faster than the waves it creates.
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Download: $1.00 This animation shows a fluid moving through a pipe to demonstrate Bernoulli's principal. A cut-away of the pipe shows objects moving with the fluid. Analogue guages are used to show changes in the internal pressure. A stacked bar graph is used to show the conservation of energy.
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Download: $1.00 This animation shows a box sliding down a frictionless incline. A stacked bar graph is used to illustrate the relationship between the box's potential energy (blue) and kinetic energy (red). The box is dropped twice to illustrate how the amounts of energy are related to the box's position and when the energy is determined.
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Download: $1.00 This animation shows a box sliding down a frictionless incline. A stacked bar graph is used to illustrate the relationship between the box's potential energy (blue) and kinetic energy (red). The box is dropped twice to illustrate how the amounts of energy are related to the box's position and when the energy is determined.
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Download: $1.00 This animation shows a drifting spacecraft before and after its rocket is ignited. Strobe points are used to illustrate motion and path.
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Download: $1.00 This animation shows a drifting spacecraft before and after its rocket is ignited. Strobe points are used to illustrate motion and path.
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Download: $1.00 This animation shows the motion of four projectiles. One is shot at a high angle, one is shot at 45 degrees, and two are shot at complimentary angles. All four are shown with strobe dots to illustrate path.
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Download: $1.00 This animation shows the motion of four projectiles. One is shot at a high angle, one is shot at 45 degrees, and two are shot at complimentary angles. All four are shown with strobe dots to illustrate path.
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Download: $1.00 This animation shows the path of a projectile using strobe images. The images are rotated once to illustrate vertical motion and again to illustrate horizontal motion.
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Download: $1.00 This animation shows the path of a projectile using strobe images. The images are rotated once to illustrate vertical motion and again to illustrate horizontal motion.
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Download: $1.00 This animation shows how a projectile should be aimed directly at a falling object since both the falling object and the projectile are falling at the same rate.
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Download: $1.00 This animation shows how a projectile should be aimed directly at a falling object since both the falling object and the projectile are falling at the same rate.
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Download: $1.00 This animation shows the path of a projectile with velocity vectors and illustrates the constant change in velocity.
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Download: $1.00 This animation shows the relationship between the normal force and the weight of a person on a moving elevator. A scale on the elevator, position vs time and velocity vs time graphs, strobe dots, and a reacting figure illustrate how motion effects the normal force.
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Download: $1.00 This animation shows boats crossing a river with a current. Velocity vectors are used to indicate resultant motion.
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Download: $1.00 This animation shows standing waves in a tube. One model uses dots to represent the compression and rarefaction of air in the form of a longitudinal wave and the other model uses transverse waves to represent regions of high and low pressure. Various harmonics are illustrated with opened and closed ends.
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Download: $1.00 This animation shows standing waves in a tube. One model uses dots to represent the compression and rarefaction of air in the form of a longitudinal wave and the other model uses transverse waves to represent regions of high and low pressure. Various harmonics are illustrated with opened and closed ends.
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Download: $1.00 This animation shows the super position of two waves. The blue wave remains stationary while the yellow wave changes phase. The green wave is the resultant wave.
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Download: $1.00 This animation shows the super position of two waves. The blue wave remains stationary while the yellow wave changes phase. The green wave is the resultant wave.
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Download: $1.00 This animation shows a pulse wave traveling on a string. The string is segmented to show how the motion of each segment is perpendicular to the direction of energy movement. A stacked energy bar graph is used to illustrate the relationship between the segment's kinetic and potential energy. The pulse is also shown interacting with a a point where the linear density of the string changes.
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Download: $1.00 This animation shows a pulse wave traveling on a string. The string is segmented to show how the motion of each segment is perpendicular to the direction of energy movement. A stacked energy bar graph is used to illustrate the relationship between the segment's kinetic and potential energy. The pulse is also shown interacting with a a point where the linear density of the string changes.
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Download: $1.00 This animation shows Newton's illustration of a cannon on the top of a very large mountain and the paths of cannon balls shot at various speeds. Strobe dots are used to show how these paths support Kepler's laws of planetary motion.
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Download: $1.00 This animation shows Newton's illustration of a cannon on the top of a very large mountain and the paths of cannon balls shot at various speeds. Strobe dots are used to show how these paths support Kepler's laws of planetary motion.
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Download: $1.00 This animation shows a planet in orbit around a star with a space-time model, strobe positions at equal time intervals, and changing velocity and force vectors throughout.
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Download: $1.00 This animation shows a planet in orbit around a star with a space-time model, strobe positions at equal time intervals, and changing velocity and force vectors throughout.
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Download: $1.00 This animation shows a bead sliding on a string with a pie chart illustrating the bead's potential energy (red) and kinetic energy (green).
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Download: $1.00 This animation shows a bead sliding on a string with a pie chart illustrating the bead's potential energy (red) and kinetic energy (green).
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Disc: $20.00 The physics animations on this CD illustrate physical situations using Flash based interactive contols including play, pause, step forward or backwards, play forwards or backwards with a slider bar and keyboard controls.
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Disc: $20.00 Physics Animations in the form of image sequences can be placed on any MP3 player that can display photos. By scrubbing through a sequence of images, motion is simulated just like a cartoon flip book. As the user scrubs clockwise, time moves forward.
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Disc: $12.00 Reflective Formative Assessment Spreadsheets are a series of Excel spreadsheets that
use cell referencing capabilities to collect large amounts of data from students, and
graphing capabilities to display this data in a way that can quickly be used by teachers.
These spreadsheets were created and developed with the following objectives in mind.
1. Serve the reflective practitioner.
2. Foster learning through formative assessment.
3. Allow the development of understanding through social interaction.
4. Allow students to exercise those skills necessary to engage in inquiry.
5. Play a key role in professional learning communities.
A detailed Template Instructions book is available at www.lulu.com/content/604251
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Download: $10.00 Reflective Formative Assessment Spreadsheets are a series of Excel spreadsheets that
use cell referencing capabilities to collect large amounts of data from students, and
graphing capabilities to display this data in a way that can quickly be used by teachers.
These spreadsheets were created and developed with the following objectives in mind.
1. Serve the reflective practitioner.
2. Foster learning through formative assessment.
3. Allow the development of understanding through social interaction.
4. Allow students to exercise those skills necessary to engage in inquiry.
5. Play a key role in professional learning communities.
These files are available on CD at www.lulu.com/content/605869 and a detailed Template Instructions book is available at www.lulu.com/content/604251
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Print: $17.55 Download: $6.25 Reflective Formative Assessment Spreadsheets are a series of Excel spreadsheets that
use cell referencing capabilities to collect large amounts of data from students, and
graphing capabilities to display this data in a way that can quickly be used by teachers.
These spreadsheets were created and developed with the following objectives in mind:
1. Serve the reflective practitioner.
2. Foster learning through formative assessment.
3. Allow the development of understanding through social interaction.
4. Allow students to exercise those skills necessary to engage in inquiry.
5. Play a key role in professional learning communities.
The files that this book refers to are available for download at www.lulu.com/content/605859 or or on a CD at www.lulu.com/content/605869.
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