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  • A stroboscopic image of a trebuchet launching a ball.  The trebuchet uses the potential energy of a weight falling to project a yellow ball.  A trebuchet is a type of catapult that was used as a siege engine in the Middle Ages. It is sometimes called a counterweight trebuchet or counterpoise trebuchet, to distinguish it from an earlier weapon called the traction trebuchet, which employed pulling men working the mechanism.  The counterweight trebuchet appeared in both Christian and Muslim lands around the Mediterranean in the 12th century. It could fling projectiles weighing up to 350 pounds (160 kg) at or into enemy fortifications. Its use continued into the 15th century, well after the introduction of gunpowder.
    K14-trebuchet0126.jpg
  • A stroboscopic image of a trebuchet launching a ball.  The trebuchet uses the potential energy of a weight falling to project a yellow ball.  A trebuchet is a type of catapult that was used as a siege engine in the Middle Ages. It is sometimes called a counterweight trebuchet or counterpoise trebuchet, to distinguish it from an earlier weapon called the traction trebuchet, which employed pulling men working the mechanism.  The counterweight trebuchet appeared in both Christian and Muslim lands around the Mediterranean in the 12th century. It could fling projectiles weighing up to 350 pounds (160 kg) at or into enemy fortifications. Its use continued into the 15th century, well after the introduction of gunpowder.
    K14-trebuchet0127.jpg
  • A .22 caliber bullet is fired from a rifle.  The schlieren optical system images different air pressures with different colors of light.  The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound.  The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-22quickshot_4400.jpg
  • The supersonic shockwave that exits the barrel a .22 caliber rifle in front of the bullet.  This pressure wave is responsible for the loud sound of the gun.  The schlieren optical system images different air pressures with different colors of light.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-22quicksho4416.jpg
  • An X-ray of a toy gun. This gun shoots sponge darts out the front when the trigger is pulled.
    nerfgun1neg.jpg
  • X-Ray of a Paintball Gun. A paintball gun is a gun that shoots round balls of paint using high pressure carbon dioxide gas.  The gas cylinder is shown in the picture, as are the paint balls.  Paintball is now a sport.
    K07x07painball1FC.jpg
  • An X-ray of a squirt gun. This gun shoots water out the front when the trigger is pulled. This is a false color x-ray.
    gun6fixFC.jpg
  • A .45 caliber bullet exiting the gun. This image is part of a series taken 1/1,000,000th of a second apart.  The gunpowder still has velocity and will travel up to 20 feet from the point of discharge.  This gunpowder can be detected on clothing and skin to determine the location of individuals at the scene of a crime.  The schlieren optical system images different air pressures with different colors of light.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-45auto-sequence1.jpg
  • A boy holds a gun in a bag.  This image is part of a series showing the identical scene in far infrared light.  The comparison of image in the series show the power of far infrared light to see through materials like the plastic bag teh boy is holding.
    ir07-192visible.jpg
  • A .22 caliber bullet is fired from a rifle. The pullet is passing through a thin sheet of glass. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0046.jpg
  • A .22 caliber bullet is fired from a rifle. The pullet is passing through a thin sheet of glass. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second. The origional colors have been changed in Photoshop.
    K20-polint-bullet_0030X.jpg
  • An X-ray of a squirt gun. This gun shoots water out the front when the trigger is pulled.
    squrtgun1sfpk.jpg
  • An X-ray of a toy gun. This gun shoots sponge darts out the front when the trigger is pulled.
    nerfgun1negFC.jpg
  • An X-ray of a confetti gun. This gun shoots streamers of confetti at a party.  The shell of confetti can be seen above the trigger.
    gun2fix8x10FC.jpg
  • A .45 caliber handgun firing a bullet.  This image freezes the motion by using a high speed flash with a duration of   1/2,000,000th of a second.  The sparks are from gunpowder that was still burring as it left the barrel behind the bullet.
    K0845calB_3822B.jpg
  • A .45 caliber bullet exiting the gun. This image is part of a series taken 1/1,000,000th of a second apart.  The gunpowder still has velocity and will travel up to 20 feet from the point of discharge.  This gunpowder can be detected on clothing and skin to determine the location of individuals at the scene of a crime.  The schlieren optical system images different air pressures with different colors of light.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-45auto-sequence2.jpg
  • A .357 caliber bullet is fired from a hand gun.  The schlieren optical system images different air pressures with different colors of light.  The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound.  The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-357magt4426.jpg
  • A .22 caliber bullet is fired from a rifle.  The schlieren optical system images different air pressures with different colors of light.  The lack of a bow wave in front of the bullets shows that the bullet is moving slower than the speed of sound.  This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.  .
    K08-22subsonic_4411.jpg
  • A .45 caliber bullet exiting the spent gunpowder.  This event takes place approximately 6 inches in front of the gun.  The gunpowder still has velocity and will travel up to 20 feet from the point of discharge.  This gunpowder can be detected on clothing and skin to determine the location of individuals at the scene of a crime.  The schlieren optical system images different air pressures with different colors of light.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-22quicksho4424.jpg
  • A Thermogram of a boy with a squirt gun.  The different colors represent different temperatures on the object. The lightest colors are the hottest temperatures, while the darker colors represent a cooler temperature.  Thermography uses special cameras that can detect light in the far-infrared range of the electromagnetic spectrum (900?14,000 nanometers or 0.9?14 µm) and creates an  image of the objects temperature..
    ir07-1665.jpg
  • A .22 caliber bullet is fired from a rifle. The pullet is passing through a thin sheet of glass. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second. The origional colors have been changed in Photoshop.
    K20-polint-bullet_0046X.jpg
  • A .22 caliber bullet is fired from a rifle. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0015.jpg
  • A .22 caliber bullet is fired from a rifle. The pullet is passing through a thin sheet of glass. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second. The origional colors have been changed in Photoshop.
    K20-polint-bullet_0046X.jpg
  • A .22 caliber bullet is fired from a rifle. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0028.jpg
  • A .22 caliber bullet is fired from a rifle. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0015.jpg
  • X-Ray of a Paintball Gun. A paintball gun is a gun that shoots round balls of paint using high pressure carbon dioxide gas.  The gas cylinder is shown in the picture, as are the paint balls.  Paintball is now a sport.
    K07x07painball1FC2.jpg
  • An X-ray of a toy gun. This gun has a number of motors to turn different parts, the gun also has a noise making system.
    gun5fullFC-18inch.jpg
  • A .45 caliber handgun firing a bullet.  This image freezes the motion by using a high speed flash with a duration of   1/2,000,000th of a second.  The sparks are from gunpowder that was still burring as it left the barrel behind the bullet.
    K0845calB_3822B2.jpg
  • A .22 caliber bullet is fired from a rifle.  The schlieren optical system images different air pressures with different colors of light.  The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound.  The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-22quickshot_4398.jpg
  • A .22 caliber bullet is fired from a rifle. The pullet is passing through a thin sheet of glass. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0030A.jpg
  • An X-ray of a squirt gun. This gun shoots water when the trigger is pulled.
    gun7fix10FC.jpg
  • A .45 caliber handgun firing a bullet.  This image freezes the motion by using a high speed flash with a duration of   1/2,000,000th of a second.  The sparks are from gunpowder that was still burring as it left the barrel behind the bullet.
    K0845calA_3822.jpg
  • A .45 caliber bullet exiting the gun. This image is part of a series taken 1/1,000,000th of a second apart.  The gunpowder still has velocity and will travel up to 20 feet from the point of discharge.  This gunpowder can be detected on clothing and skin to determine the location of individuals at the scene of a crime.  The schlieren optical system images different air pressures with different colors of light.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-45autot_4439.jpg
  • A .22 caliber bullet is fired from a rifle.  The schlieren optical system images different air pressures with different colors of light.  The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound.  The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle.   This image freezes the motion by using a high speed flash with a duration of  1/2,000,000th of a second.
    K08-22quickshot_4398blue.jpg
  • A .22 caliber bullet is fired from a rifle. Here the bullet is seen in a polarizing interferometer. The different colors of light represent different air pressures. The clear bow wave in front of the bullets shows that the bullet is moving faster than the speed of sound. The exact velocity of this supersonic bullet can be calculated from measurements of the bow wake angle. This image freezes the motion by using a high speed flash with a duration of 1/2,000,000th of a second.
    K20-polint-bullet_0028.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 45 degrees to the horizontal.
    bloodsplatter-20cm-45deg_0202.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-20cm_0208.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-21cm_0188.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-21cm_0186.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 75 degrees to the horizontal.
    bloodsplatter-20cm-75deg_0199.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 45 degrees to the horizontal.
    bloodsplatter-20cm-45deg_0201.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-100cm_0196.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a flat paper surface.
    bloodsplatter-20cm_0193.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell differnent heights.  The height of the drops on the bottom row were 5 cm, second row from the bottom is 15 cm, third row from the bottom is 20, the top row is 30 cm.  There drops all fell onto a flat paper surface.
    bloodsplatter-20cm-calibration_0216.jpg
  • Blood droplet. In forensic science, the pattern created by projected blood is analyzed to determine information about the origin on the body, the weapon used and the number of blows, the relative position of the victim and assailant, and the sequence of events. This is a single drop that fell 20 cm onto a paper surface angled at 80 degrees to the horizontal.
    bloodsplatter-20cm-80deg_0204.jpg
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Ted Kinsman

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