Convex mirror changing curvature1970-01-01T00:00:00+00:00Simulation of parallel beams of light striking a convex parabolic mirror whose curvature varies over time. Notice how the light striking the mirror radiates outwards creating a virtual focus behind the mirror. Compare with its inverse the parabolic con...PT8Shttps://d3e1m60ptf1oym.cloudfront.net/9229449a-de7a-474f-86b0-e46d6d8f898c/CONVEX-MIRROR-varying-curvature-coloured-lights-FHD-Russell-Kightley_xlarge.jpghttps://d3e1m60ptf1oym.cloudfront.net/9229449a-de7a-474f-86b0-e46d6d8f898c/CONVEX-MIRROR-varying-curvature-coloured-lights-FHD-Russell-Kightley_mp4_hd_video.mp4https://www.scientific.pictures/-/galleries/optics/-/medias/9229449a-de7a-474f-86b0-e46d6d8f898c/pricehttps://www.scientific.pictures/-/galleries/optics/-/medias/9229449a-de7a-474f-86b0-e46d6d8f898c/price
FIBRE OPTIC
FIBRE OPTIC: Animation of fibre optic transmission of light. The light source to the left beams light into the slender glass fibre. The light bounces off the interface of the glass and external layer as a result of total internal reflection. In this way, the light can follow the course of the fibre as it bends progressively through the animation. Effectively, the light can travel around corners. Huge amounts of information can be carried by such systems. See our Critical Angle Calculator. Because of their huge capacity to carry data, fibre optics are the method chosen for the Australian National Broadband Network.
Animation ID: FIBRE-OPTIC-animation-FHD-H-Russell-Kightley
Duration: 00:12
copyright Russell Kightley
Animation resolution: 1920x1080 pixels @ 30.0 fps, ~53.9 Mbits/s
Animation keywords: data transmission, fiber optics, fibre optic, light, optics, physics, total internal reflection
FIBRE OPTIC2020-08-12T07:39:28ZFIBRE OPTIC: Animation of fibre optic transmission of light. The light source to the left beams light into the slender glass fibre. The light bounces off the interface of the glass and external layer as a result of total internal reflection. In this wa...PT12Shttps://d3e1m60ptf1oym.cloudfront.net/908162c2-3e69-45ff-b79c-b212cdf9ac8a/FIBRE-OPTIC-animation-FHD-H-Russell-Kightley_xlarge.jpghttps://d3e1m60ptf1oym.cloudfront.net/908162c2-3e69-45ff-b79c-b212cdf9ac8a/FIBRE-OPTIC-animation-FHD-H-Russell-Kightley_mp4_hd_video.mp4https://www.scientific.pictures/-/galleries/optics/-/medias/908162c2-3e69-45ff-b79c-b212cdf9ac8a/pricehttps://www.scientific.pictures/-/galleries/optics/-/medias/908162c2-3e69-45ff-b79c-b212cdf9ac8a/price
LASER1970-01-01T00:00:00+00:00LASERS: the stimulated emission of photons.
LASER BEAM: Three atoms are shown in a line in a highly simplified diagram of a laser. The zigzag at the bottom represents an energy source. When energy is added to the laser (the bright flash) electrons in ...PT10Shttps://d3e1m60ptf1oym.cloudfront.net/73ac1edb-605d-4bb3-8231-48db60aa7e07/LASER-FHD-Russell-Kightley_xlarge.jpghttps://d3e1m60ptf1oym.cloudfront.net/73ac1edb-605d-4bb3-8231-48db60aa7e07/LASER-FHD-Russell-Kightley_mp4_hd_video.mp4https://www.scientific.pictures/-/galleries/optics/-/medias/73ac1edb-605d-4bb3-8231-48db60aa7e07/pricehttps://www.scientific.pictures/-/galleries/optics/-/medias/73ac1edb-605d-4bb3-8231-48db60aa7e07/price