Flip-disc display

A flip-dot destination sign on a LACMTA New Flyer D40LF bus A Fok Gyem flip dots display on a RATB Ikarus 415T trolleybus An O-Pelled flip dots display detail Flip-disc display elements (close up). The disc rotates on the shaft that is carried in the two triangular posts. The magnet that powers the rotation can be seen embedded in the disc. Under the disc is the driving solenoid; when powered, a field is induced into the two posts, flipping the discs. Rotation stops when the disc hits the post. The flip-disc display (or flip-dot display) is an electromechanical dot matrix display technology used for large outdoor signs, normally those that will be exposed to direct sunlight. Flip-disc technology has been used on buses across North America and Europe. It has also been used extensively on public information displays.1 A few game shows have also used flip-disc displays, most notably the Richard Dawson and Ray Combs versions of Family Feud. Contents 1 Design 2 History 3 Alternative technologies 4 See also 5 External links 6 References // Design The flip-disc display consists of a grid of small metal discs that are black on one side and a bright color on the other (typically white or day-glo yellow), set into a black background. With power applied, the disc flips to show the other side. Once flipped, the discs will remain in position without power. The disc is attached to an axle which also carries a small permanent magnet. Positioned close to the magnet is a solenoid. By pulsing the solenoid coil with the appropriate electrical polarity, the permanent magnet on the axle will align itself with the magnetic field, also turning the disc. Another style uses a magnet embedded in the disc itself, with separate solenoids arranged at the ends or side to flip it. A computerized driver system reads data, typically characters, and flips the appropriate discs to produce the desired display. Some displays use the other end of the solenoid to actuate a reed switch, which controls an LED array behind the disc, resulting in a display that is visible at night but requires no extra drive electronics. Various driving schemes are in use. Their basic purpose is to reduce the amount of wiring and electronics needed to drive the solenoids. All common methods connect the solenoids in some sort of matrix. One driving method is similar to that of core memory: the solenoids are connected in a simple matrix. Those solenoids at the crossing point of two powered wires are driven with enough current to flip their discs; those powered on only the vertical or horizontal line see only 1/4 of the required force (as flux is proportional to current, which in turn is proportional to the square of the voltage). Those on unpowered lines also do not flip. Typically, the driving scheme works its way from top to bottom, powering each horizontal line "on" and then powering the needed vertical lines to set up that row. The whole process takes a few seconds, during which time the sound of the discs being flipped over is quite distinctive. Other driving schemes use diodes to isolate non-driven solenoids, which allows only the discs whose state need changing to be flipped. This uses less power, and may be more robust. History The flip-disc display was developed by Kenyon Taylor at Ferranti-Packard at the request of Trans-Canada Airlines (today's Air Canada). By the time the system had been patented in 1961, TCA had already lost interest and Ferranti's management didn't consider the project very interesting. The first big opportunity for this system came in 1961 when the Montreal Stock Exchange decided to modernize its method of displaying trading information.1 Ferranti-Packard and Westinghouse both bid on the project, Westinghouse using an electro-luminescent technology. Ferranti won the contract after demonstrating the system with a mock-up they built in a disused warehouse across the street from the exchange's new offices, using hand-painted dots moved by hand to show how the system would work. The dots were slowly replaced with operating modules as they became available. The $700,000 system (US$4,964,772 in 2009 dollars) was beset by delays and technical problems, but once it became fully operational it was considered very reliable. The systems were relatively expensive because of their manual construction, typically completed by women who "sewed" the displays in a fashion very similar to the construction of core memory. Worse, Ferranti signed maintenance contracts that were, by 1971, losing $12,000 a month.1 A re-organization of the engineering and maintenance department addressed the problems, and prices started to fall. By 1977 the system had won sales with half the world's major stock exchanges. As prices fell, they were soon found in wider roles, notably that of highway signs and information systems for public transport. In Europe they became popular for displaying prices at gasoline stations. In 1974 Ferranti started a project to build smaller versions for the front of buses and trains, and by 1977 revenue from these had already surpassed that from other lines of business.1 The displays often required minor maintenance to free up "stuck" discs. Alternative technologies DOT-LED display of a bus Irisbus Citybus 18M (made 2004) is changing the text. Flip-disc systems are still widespread but are not often found in new installations. Their place has been filled by LED-based products, which use a small amount of power constantly rather than each time the message changes, but are easily visible in light and darkness and, having no moving parts, require little maintenance. Some producers offer combined displays which use flip-dot and LED technologies together (every dot-disc has its own LED) and thereby they combine their advantages. For example, the Czech company BUSE from Blansko supplies self-patented DOT-LED displays (only DOT and only LED as well) in Central and East Europe.2 This combined technology was used for outside displays of most of new trams, buses and trams. See also Display examples External links U.S. Patent 3,303,494 Wikimedia Commons has media related to: Flip-dot displays References ^ a b c d Norman Ball, John Vardalas, "Ferranti-Packard", McGill Queen's Press, 1994, ISBN 0773509836 ^ BUSE s. r. o. - Technology v · d · eDisplay technology Video Current generation Electroluminescent display (ELD) · Vacuum fluorescent display (VFD) · Light emitting diode display (LED) · Cathode ray tube (CRT) · Liquid crystal display (LCD) (Thin film transistor liquid crystal display (TFT LCD)) · Plasma display panel (PDP) · Digital light processing (DLP) · Liquid crystal on silicon (LCoS) Next generation Organic light-emitting diode (OLED) · Surface-conduction electron-emitter display (SED) · Field emission display (FED) · Laser TV (Quantum dot laser · Liquid crystal laser) · Ferro liquid display (FLD) · Interferometric modulator display (iMoD) · Thick-film dielectric electroluminescent (TDEL) · Quantum dot display (QD-LED) · Telescopic pixel display (TPD) · Organic light-emitting transistor (OLET) · Laser phosphor display (LPD) Non-video Electromechanical (Flip-dot · Split-flap · Vane) · Electronic paper · Rollable · Eggcrate · Nixie tube · Light-emitting electrochemical cell (LEC) 3D display Stereoscopic · Autostereoscopic · Computer generated holography · Volumetric (Swept-volume) · Laser beam Static media Hologram · Movie projector · Neon sign · Rollsign · Slide projector · Transparency Related articles Display examples · Free-space display · Large-screen television technology · Optimum HDTV viewing distance · High dynamic range imaging (HDRI) Comparison of display technology