Street Rod

Also, the police may fine you during a Pink slip race. Similar dependencies affect the remaining aberrations in the list. Crashing during the race will either total your car, or requre you to pay a fee in order to get it fixed. The second, coma is changes as a function of pupil distance and spherical aberration, hence the well known result that it is impossible to correct the coma in a lens free of spherical aberration by simply moving the pupil. When the race starts, the player must wait for a signal to be given to go or else they forfeit the race. The first Seidel aberration, Spherical Aberration is independent of the position of the exit pupil (as it is the same for axial and extra-axial pencils). Wagers on the races can be set from "Just for fun!" (no wager) to cash to "Pink Slips" (the winner recieves the loser's car). They are always listed in the above order since this expresses their interdependence as first order aberrations via moves of the exit/entrance pupils.

Races take place on either a dragstrip, Mulholland drive, or in an aquaduct. They are now commonly referred to as the five Seidel Aberrations. The player will proceed from the garage to the local diner in order to find some competiton to race. In 1857, Philipp Ludwig von Seidel (1821-1896) decomposed the first order monochromatic aberrations into five constituent aberrations. While racing, the car will eventually run out of fuel, which the payer must obtain from the gas station. Image aberrations can be broken down into two main classes, monochromatic, and polychromatic. To install tires, the car must be jacked up. In reality, perfect mirrors and perfect lenses do not exist, so image aberrations in addition to aperture diffraction must be taken into account.

Then, these parts must be re-installed in order and the screws replaced, otherwise the car will be undrivable. Even if a reflecting telescope could have a perfect mirror, or a refracting telescope could have a perfect lens, the effects of aperture diffraction could still not be escaped. New parts that are purchased must be installed by the player by entering the hood of or going under the car and then removing a series of screws to remove parts of the engine and transmission. No telescope can form a perfect image. The player starts off on the garage, where cars and parts may be purchased from the newspaper. If greater resolution is needed at that wavelength, a wider mirror has to be built or aperture synthesis performed using an array of nearby telescopes. Using money you earn through races you can modify your car and eventually winning enough races earns you the right to challenge the king for his position. This means that a telescope with a certain mirror diameter can resolve up to a certain limit at a certain wavelength.

Equipped with a garage and a small amount of cash, you buy a used car out of the paper and embark on a journey to rise through the ranks by winning races against other racers. This limit depends on the wavelength of the studied light (so that the limit for red light comes much earlier than the limit for blue light) and on the diameter of the telescope mirror. You start the game as a protagonist that seeks to usurp the throne and claim the girlfriend of the local king of the streets. This absolute limit is called the diffraction limit (or sometimes the Rayleigh criterion, Dawes limit or Sparrow's resolution limit). . The phenomenon of optical diffraction sets a limit to the resolution and image quality that a telescope can achieve, which is the effective area of the Airy disc, which limits how close two such discs can be placed. Street Rod exclusively feaured Muscle Cars, specifically those from GM, Ford, and Chrysler. See adaptive optics, speckle imaging and optical interferometry.

Street Rod is a racing video game series developed by Logical Design Works and published by California Dreams for DOS, Amiga, and Commodore 64. In recent years, some technologies to overcome the distortions caused by atmosphere on ground-based telescopes were developed, with good results. Street Rod 3 is an unoffical sequel to the series that is being developed for Windows with the aim of recreating a game similar to Street Rod 2 with more cars and parts, as well as transitioning the series from 2D to 3D grahpics. Current research telescopes have several instruments to choose from such as:. Street Rod 2 was modeled on the same engine as the first game, which yielded an almost identical game with different cars, more parts, an additional track, and improved graphics. After the photographic plate, successive generations of electronic detectors, such as the charge-coupled device (CCDs), have been perfected, each with more sensitivity and resolution, and often with a wider wavelength coverage. Street Rod 2 was released in 1990 and takes place in the year 1971. Later, the sensitized photographic plate took its place, and the spectrograph was introduced, allowing the gathering of spectral information.

Street Rod was released in 1989 and takes place in the year 1965. Initially the detector used in telescopes was the human eye. the Liverpool Telescope and the Faulkes Telescope North and South), allowing automated follow-up of astronomical events. Many are robotic telescopes, computer controlled over the internet (see e.g. These allow many astronomical targets to be monitored continuously, and for large areas of sky to be surveyed.

Relatively cheap, mass-produced ~2 meter telescopes have recently been developed and have made a significant impact on astronomy research. This technology has driven new designs for future telescopes with diameters of 30, 50 and even 100 meters. In this generation of telescopes, the mirror is usually very thin, and is kept in an optimal shape by an array of actuators (see active optics). The largest current ground-based telescopes have primary mirrors of between 6 and 11 meters in diameter.

Its example was followed by the Keck telescopes with 10 m segmented mirrors. This has now been replaced by a single 6.5m mirror. A new era of telescope making was inaugurated by the Multiple Mirror Telescope (MMT), with a mirror composed of six segments synthesizing a mirror of 4.5 meters diameter. They have a pierced primary mirror, a Newtonian focus, and a spider to mount a variety of replaceable secondary mirrors.

Most large research telescopes can operate as either a Cassegrain telescope (longer focal length, and a narrower field with higher magnification) or a Newtonian telescope (brighter field). For example:. There are mountings even simpler than altazimuth, typically used for specialized instruments. Modern large telescopes use computer-controlled altazimuth mounts, and for long exposures they rotate the instruments or have variable-rate image rotators in an image of the telescope pupil.

This is known as an equatorial mount. The preferred solution for small astronomical telescopes is to tip the altazimuth mount so that the azimuth axis is parallel with the axis of the Earth's rotation. The last effect makes an altazimuth mount especially impractical for long-exposure photography with small telescopes. Even if this is done by computer control, the image rotates at a rate that varies depending on the angle of the target from the celestial pole.

When using an altazimuth for astronomy, both axes must be continuously adjusted to compensate for the Earth's rotation. A Dobsonian mount is a type of altazimuth mount which has proven to be very popular as it is simple and inexpensive. A fork rotates in azimuth (in the horizontal plane), and bearings on the tips of the fork allow the telescope to vary in altitude (in a vertical plane). It is similar to that of a surveying transit.

A simple telescope mount is an altitude-azimuth or altazimuth mount. These are more useful for astronomical viewing. Newtonian or reflecting telescopes employ the reflective properties of light, and use mirrors and lenses. These can be used for both terrestrial and astronomical viewing.

Galilean or refracting telescopes employ the refractive properties of light, and are constructed of lenses. Optical telescopes are also divided into two types. Telescopes are broadly classified into two main types. Optical interferometer arrays and arrays of radio telescopes were developed much more recently.

Later, Johannes Kepler described the optics of lenses (see his books Astronomiae Pars Optica and Dioptrice), including a new kind of astronomical telescope with two convex lenses (a principle often called Kepler telescope). Galileo's telescope consisted of a convex object lens and a concave eye lens, which is universally called a Galilean Telescope (used as a viewfinder in many simple cameras). Galileo is generally credited with being the first to use a telescope for astronomical purposes. Galileo Galilei made his own telescope in 1609, calling it at first a perspicillum, and then using the terms telescopium in Latin and telescopio in Italian (from which the English word derives).

Even if Lippershey did not make the first one, he publicized it. Some name that person as Hans Lippershey (c1570-c1619), but Jacob Metius and Zacharias Jansen also claimed to have invented a telescope during the same time period. Leonard Digges is sometimes credited with the invention in England in the 1570s, but usually credit for assembling the first telescope is usually given to an unknown Dutch spectacle maker in about 1608. The Visby lenses tentatively suggest that the technology was known to the Arabs and Persians then to the Vikings in the 10th century.

Article. The first telescopes may have been Assyrian crystal lenses. . The mirrors are usually a section of a rotated parabola.

They use ring-shaped "glancing" mirrors, made of heavy metals, that reflect the rays just a few degrees. X-ray and gamma-ray telescopes have a problem because these rays go through most metals and glasses. Aperture synthesis is now also being applied to optical telescopes using optical interferometers (arrays of optical telescopes) and Aperture Masking Interferometry at single telescopes. As of 2005, the current record is many times the width of the Earth, utilizing space-based Very Long Baseline Interferometry (VLBI) telescopes such as the Japanese HALCA (Highly Advanced Laboratory for Communications and Astronomy) [VSOP (VLBI Space Observatory Program) satellite].

Radio telescopes are often operated in pairs, or larger groups to synthesize large "virtual" apertures that are similar in size to the separation between the telescopes: see aperture synthesis. The dish is sometimes constructed of a conductive wire mesh whose openings are smaller than a wavelength. Radio telescopes are focused radio antennas, usually shaped like large dishes. The word "telescope" usually refers to optical telescopes, but there are telescopes for most of the spectrum of electromagnetic radiation.

Telescopes are used for astronomy and in many non-astronomical instruments including theodolites, transits, spotting scopes, monoculars, binoculars, camera lenses and spyglasses. Telescopes work by employing one or more curved optical elements - lenses or mirrors - to gather light or other electromagnetic radiation and bring that light or radiation to a focus, where the image can be observed, photographed or studied. Telescopes increase the apparent angular size of distant objects, as well as their apparent brightness. A telescope (from the Greek tele = 'far' and skopein = 'to look or see'; teleskopos = 'far-seeing') is an optical tool that gathers and focuses electromagnetic radiation.

The 1-meter refracting Swedish Solar Telescope (SST) on La Palma, is currently the highest-resolution solar telescope in the world. It was a failure. The horizontal tube was 60 m long and the objective had 1.25 m in diameter. The telescope was aimed by the aid of a Foucault sidérostat, which is a movable plane mirror with a 2 m diameter, mounted in a large cast-iron frame.

Its lens was stationary, prefigured so as to sag into the correct shape. It was on display at the 1900 Paris Exposition. The largest refractor ever constructed was French. It was exceeded in size one year later by the 0.91 m refractor at the Lick Observatory.

This was the last time the most powerful operational telescope in the world was located in Europe. The 0.76 m Nice refractor (in France) that became operational in 1888 was at that time the world's largest telescope. The 1.02 m Yerkes Telescope (in Wisconsin) is the largest aimable refracting telescope in use. The telescope now has an adaptive optics system, and is still useful for advanced research.

In 1919, the telescope was used for the first stellar diameter measurements using interferometry. The mirror was made of green glass by Saint-Gobain. The 100 inch (2.54 m) Hooker Telescope at the Mount Wilson Observatory was used by Edwin Hubble to discover galaxies, and the redshift. The mounting is a special design of equatorial mount called a yoke mount, which permits the telescope to be pointed at and near the north celestial pole.

It has a single borosilicate (Pyrex™) mirror that was famously difficult to construct. The 200 inch (5.08 m) Hale telescope on Palomar Mountain was the largest conventional research telescope for many years. One of them is the Overwhelmingly Large Telescope (OWL), which is intended to have a single aperture of 100 meters in diameter. There are many plans for even larger telescopes.

The CHARA (Center for High Angular Resolution Astronomy) array is the telescope array that can currently (2005) produce the highest resolution images at near-infrared wavelengths. The Navy Prototype Optical Interferometer is the optical telescope (array) that can currently (2005) produce the highest resolution images at visible wavelengths. The four telescopes, belonging to the European Southern Observatory (ESO) and located in the Atacama desert in Chile, are usually operated independently for faint astronomical observations, but up to three telescopes can be operated together for aperture synthesis observations of bright objects. The Very Large Telescope array (VLT) is currently (2002) the record holder for total collecting area in an array of telescopes, with four telescopes each 8 meters in diameter.

The Keck telescopes are currently (2005) the largest, but will soon be superseded by the Gran Telescopio Canarias and Southern African Large Telescope. In this way the images can be diffraction limited, and used for coverage in the ultraviolet (UV) and infrared. The Hubble Space Telescope is in orbit beyond Earth's atmosphere to allow for observations not distorted by astronomical seeing. polarimeters, that detect light polarization.

spectrographs, useful in different regions of the spectrum. imagers, of different spectral responses. ball-and-socket (ancient and useless for astronomy). fixed with movable plane mirror for solar observing.

meridian transit (altitude only). Newtonian reflecting telescopes. Galilean refracting telescopes. Radio telescopes.

Optical telescopes.