Perspective (graphical)

(Redirected from Perspective geometry)

Linear or point-projection perspective (from Latin perspicere 'to see through') is one of two types of graphical projection perspective in the graphic arts; the other is parallel projection.[citation needed][dubiousdiscuss] Linear perspective is an approximate representation, generally on a flat surface, of an image as it is seen by the eye. Perspective drawing is useful for representing a three-dimensional scene in a two-dimensional medium, like paper. It is based on the optical fact that for a person an object looks N times (linearly) smaller if it has been moved N times further from the eye than the original distance was.

Staircase in multi-points perspective as a linear or point-projection prospective example. Each point is a vanishing point from which straight lines come, and these lines are a guide to draw 3-dimensional object.
External videos
video icon Linear Perspective: Brunelleschi's Experiment, Khan Academy[1]
video icon How One-Point Linear Perspective Works, Smarthistory[2]
video icon Empire of the Eye: The Magic of Illusion: The Trinity-Masaccio, Part 2, National Gallery of Art[3]

The most characteristic features of linear perspective are that objects appear smaller as their distance from the observer increases, and that they are subject to foreshortening, meaning that an object's dimensions parallel to the line of sight appear shorter than its dimensions perpendicular to the line of sight. All objects will recede to points in the distance, usually along the horizon line, but also above and below the horizon line depending on the view used.

How linear or point-projection prospective works: Rays of light travel from the object (cube), through the picture plane, and to the viewer's eye (O). Vanishing points emitting straightly lines coincident with the edges the cube drawn on the picture plane are located at the left and right of the plane.
A figure explaining point-projection prospective. S is the distance between an observer's eye and an observation point on an object that is a long rectangular wall facing to the observer at a tilted angle. If the observation distance becomes N times longer, then the apparent height of the wall at the observation point is roughly N times smaller. As a result, the apparent shape of the wall over a wide angle roughly becomes a triangle which right vertex is located to the far right.

Italian Renaissance painters and architects including Filippo Brunelleschi, Leon Battista Alberti, Masaccio, Paolo Uccello, Piero della Francesca and Luca Pacioli studied linear perspective, wrote treatises on it, and incorporated it into their artworks.

Overview

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linear or point-projection perspective works by putting an imagery flat plane that is close to an object under observation and directly facing an observer's eyes (i.e., the observer is on a line normal or perpendicular to the plane). Then draw straight lines from the object to the observer. The area on the plane where the drawn lines pass through the plane is a point-projection prospective image resembling what is seen by the observer.

Examples of one-point perspective

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A cube drawing using two-point perspective

Examples of two-point perspective

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A cube in three-points perspective where, compared with the above cube in two-points prospective, there is an additional vanishing point far below the cube, from which straight lines come that are coincident with vertical edges of the cube.

Examples of three-point perspective

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Examples of curvilinear perspective

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Additionally, a central vanishing point can be used (just as with one-point perspective) to indicate frontal (foreshortened) depth.[4]

History

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Early history

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The earliest art paintings and drawings typically sized many objects and characters hierarchically according to their spiritual or thematic importance, not their distance from the viewer, and did not use foreshortening. The most important figures are often shown as the highest in a composition, also from hieratic motives, leading to the so-called "vertical perspective", common in the art of Ancient Egypt, where a group of "nearer" figures are shown below the larger figure or figures; simple overlapping was also employed to relate distance.[6] Additionally, oblique foreshortening of round elements like shields and wheels is evident in Ancient Greek red-figure pottery.[7]

Systematic attempts to evolve a system of perspective are usually considered to have begun around the fifth century BC in the art of ancient Greece, as part of a developing interest in illusionism allied to theatrical scenery. This was detailed within Aristotle's Poetics as skenographia: using flat panels on a stage to give the illusion of depth.[8] The philosophers Anaxagoras and Democritus worked out geometric theories of perspective for use with skenographia. Alcibiades had paintings in his house designed using skenographia, so this art was not confined merely to the stage. Euclid in his Optics (c. 300 BC) argues correctly that the perceived size of an object is not related to its distance from the eye by a simple proportion.[9] In the first-century BC frescoes of the Villa of P. Fannius Synistor, multiple vanishing points are used in a systematic but not fully consistent manner.[5]

Chinese artists made use of oblique projection from the first or second century until the 18th century. It is not certain how they came to use the technique; Dubery and Willats (1983) speculate that the Chinese acquired the technique from India, which acquired it from Ancient Rome,[10] while others credit it as an indigenous invention of Ancient China.[11][12][13] Oblique projection is also seen in Japanese art, such as in the Ukiyo-e paintings of Torii Kiyonaga (1752–1815).[10][a]

By the later periods of antiquity, artists, especially those in less popular traditions, were well aware that distant objects could be shown smaller than those close at hand for increased realism, but whether this convention was actually used in a work depended on many factors. Some of the paintings found in the ruins of Pompeii show a remarkable realism and perspective for their time.[14] It has been claimed that comprehensive systems of perspective were evolved in antiquity, but most scholars do not accept this. Hardly any of the many works where such a system would have been used have survived. A passage in Philostratus suggests that classical artists and theorists thought in terms of "circles" at equal distance from the viewer, like a classical semi-circular theatre seen from the stage.[15] The roof beams in rooms in the Vatican Virgil, from about 400 AD, are shown converging, more or less, on a common vanishing point, but this is not systematically related to the rest of the composition.[16]

Medieval artists in Europe, like those in the Islamic world and China, were aware of the general principle of varying the relative size of elements according to distance, but even more than classical art were perfectly ready to override it for other reasons. Buildings were often shown obliquely according to a particular convention. The use and sophistication of attempts to convey distance increased steadily during the period, but without a basis in a systematic theory. Byzantine art was also aware of these principles, but also used the reverse perspective convention for the setting of principal figures. Ambrogio Lorenzetti painted a floor with convergent lines in his Presentation at the Temple (1342), though the rest of the painting lacks perspective elements.[17]

Renaissance

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Detail of Masolino da Panicale's St. Peter Healing a Cripple and the Raising of Tabitha (c. 1423), the earliest extant artwork known to use a consistent vanishing point[18]

It is generally accepted that Filippo Brunelleschi conducted a series of experiments between 1415 and 1420, which included making drawings of various Florentine buildings in correct perspective.[19] According to Vasari and Antonio Manetti, in about 1420, Brunelleschi demonstrated his discovery by having people look through a hole in the back of a painting he had made. Through it, they would see a building such as the Florence Baptistery. When Brunelleschi lifted a mirror in front of the viewer, it reflected his painting of the buildings which had been seen previously, so that the vanishing point was centered from the perspective of the participant.[20] Brunelleschi applied the new system of perspective to his paintings around 1425.[21]

This scenario is indicative, but faces several problems, that are still debated. First of all, nothing can be said for certain about the correctness of his perspective construction of the Baptistery of San Giovanni, because Brunelleschi's panel is lost. Second, no other perspective painting or drawing by Brunelleschi is known. (In fact, Brunelleschi was not known to have painted at all.) Third, in the account written by Antonio Manetti in his Vita di Ser Brunellesco at the end of the 15th century on Brunelleschi's panel, there is not a single occurrence of the word "experiment". Fourth, the conditions listed by Manetti are contradictory with each other. For example, the description of the eyepiece sets a visual field of 15°, much narrower than the visual field resulting from the urban landscape described.[22][23]

 
Melozzo da Forlì's use of upward foreshortening in his frescoes, Basilica dei Santi Apostoli, Rome, c. 1480

Soon after Brunelleschi's demonstrations, nearly every interested artist in Florence and in Italy used geometrical perspective in their paintings and sculpture,[24] notably Donatello, Masaccio,[25]Lorenzo Ghiberti, Masolino da Panicale, Paolo Uccello,[25] and Filippo Lippi. Not only was perspective a way of showing depth, it was also a new method of creating a composition. Visual art could now depict a single, unified scene, rather than a combination of several. Early examples include Masolino's St. Peter Healing a Cripple and the Raising of Tabitha (c. 1423), Donatello's The Feast of Herod (c. 1427), as well as Ghiberti's Jacob and Esau and other panels from the east doors of the Florence Baptistery.[26] Masaccio (d. 1428) achieved an illusionistic effect by placing the vanishing point at the viewer's eye level in his Holy Trinity (c. 1427),[27] and in The Tribute Money, it is placed behind the face of Jesus.[28][b] In the late 15th century, Melozzo da Forlì first applied the technique of foreshortening (in Rome, Loreto, Forlì and others).[30]

This overall story is based on qualitative judgments, and would need to be faced against the material evaluations that have been conducted on Renaissance perspective paintings. Apart from the paintings of Piero della Francesca, which are a model of the genre, the majority of 15th century works show serious errors in their geometric construction. This is true of Masaccio's Trinity fresco[31][32] and of many works, including those by renowned artists like Leonardo da Vinci.[33][34]

As shown by the quick proliferation of accurate perspective paintings in Florence, Brunelleschi likely understood (with help from his friend the mathematician Toscanelli),[35] but did not publish, the mathematics behind perspective. Decades later, his friend Leon Battista Alberti wrote De pictura (c. 1435), a treatise on proper methods of showing distance in painting. Alberti's primary breakthrough was not to show the mathematics in terms of conical projections, as it actually appears to the eye. Instead, he formulated the theory based on planar projections, or how the rays of light, passing from the viewer's eye to the landscape, would strike the picture plane (the painting). He was then able to calculate the apparent height of a distant object using two similar triangles. The mathematics behind similar triangles is relatively simple, having been long ago formulated by Euclid.[c] Alberti was also trained in the science of optics through the school of Padua and under the influence of Biagio Pelacani da Parma who studied Alhazen's Book of Optics.[36] This book, translated around 1200 into Latin, had laid the mathematical foundation for perspective in Europe.[37]

 
Pietro Perugino's use of perspective in Delivery of the Keys (1482), a fresco at the Sistine Chapel

Piero della Francesca elaborated on De pictura in his De Prospectiva pingendi in the 1470s, making many references to Euclid.[38] Alberti had limited himself to figures on the ground plane and giving an overall basis for perspective. Della Francesca fleshed it out, explicitly covering solids in any area of the picture plane. Della Francesca also started the now common practice of using illustrated figures to explain the mathematical concepts, making his treatise easier to understand than Alberti's. Della Francesca was also the first to accurately draw the Platonic solids as they would appear in perspective. Luca Pacioli's 1509 Divina proportione (Divine Proportion), illustrated by Leonardo da Vinci, summarizes the use of perspective in painting, including much of Della Francesca's treatise.[39] Leonardo applied one-point perspective as well as shallow focus to some of his works.[40]

Two-point perspective was demonstrated as early as 1525 by Albrecht Dürer, who studied perspective by reading Piero and Pacioli's works, in his Unterweisung der Messung ("Instruction of the Measurement").[41]

Limitations

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Satire on False Perspective by William Hogarth, 1753
 
Example of a painting that combines various perspectives: The Frozen City (Museum of Art Aarau, Switzerland) by Matthias A. K. Zimmermann

Perspective images are created with reference to a particular center of vision for the picture plane. In order for the resulting image to appear identical to the original scene, a viewer must view the image from the exact vantage point used in the calculations relative to the image. When viewed from a different point, this cancels out what would appear to be distortions in the image. For example, a sphere drawn in perspective will be stretched into an ellipse. These apparent distortions are more pronounced away from the center of the image as the angle between a projected ray (from the scene to the eye) becomes more acute relative to the picture plane. Artists may choose to "correct" perspective distortions, for example by drawing all spheres as perfect circles, or by drawing figures as if centered on the direction of view. In practice, unless the viewer observes the image from an extreme angle, like standing far to the side of a painting, the perspective normally looks more or less correct. This is referred to as "Zeeman's Paradox".[42]

See also

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Notes

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  1. ^ In the 18th century, Chinese artists began to combine oblique perspective with regular diminution of size of people and objects with distance; no particular vantage point is chosen, but a convincing effect is achieved.[10]
  2. ^ Near the end of the 15th century, Leonardo da Vinci placed the vanishing point in his Last Supper behind Christ's other cheek.[29]
  3. ^ In viewing a wall, for instance, the first triangle has a vertex at the user's eye, and vertices at the top and bottom of the wall. The bottom of this triangle is the distance from the viewer to the wall. The second, similar triangle, has a point at the viewer's eye, and has a length equal to the viewer's eye from the painting. The height of the second triangle can then be determined through a simple ratio, as proven by Euclid.

References

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  1. ^ "Linear Perspective: Brunelleschi's Experiment". Khan Academy. Retrieved 2 June 2024.
  2. ^ "How One-Point Linear Perspective Works". Smarthistory at Khan Academy. Archived from the original on 13 July 2013. Retrieved 12 May 2013.
  3. ^ "Empire of the Eye: The Magic of Illusion: The Trinity-Masaccio, Part 2". National Gallery of Art. Retrieved 12 November 2024.{{cite web}}: CS1 maint: url-status (link)
  4. ^ "The Beginner's Guide to Perspective Drawing". The Curiously Creative. Retrieved 17 August 2019.
  5. ^ a b Hurt, Carla (9 August 2013). "Romans paint better perspective than Renaissance artists". Found in Antiquity. Retrieved 4 October 2020.
  6. ^ Calvert, Amy. "Egyptian Art (article)". Khan Academy. Retrieved 14 May 2020.
  7. ^ Regoli, Gigetta Dalli; Gioseffi, Decio; Mellini, Gian Lorenzo; Salvini, Roberto (1968). Vatican Museums: Rome. Italy: Newsweek. p. 22.
  8. ^ "Skenographia in Fifth Century". CUNY. Archived from the original on 17 December 2007. Retrieved 27 December 2007.
  9. ^ Smith, A. Mark (1999). Ptolemy and the Foundations of Ancient Mathematical Optics: A Source Based Guided Study. Philadelphia: American Philosophical Society. p. 57. ISBN 978-0-87169-893-3.
  10. ^ a b c Cucker, Felipe (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 269–278. ISBN 978-0-521-72876-8. Dubery and Willats (1983:33) write that 'Oblique projection seems to have arrived in China from Rome by way of India round about the first or second century AD.' Figure 10.9 [Wen-Chi returns home, anon, China, 12th century] shows an archetype of the classical use of oblique perspective in Chinese painting.
  11. ^ "Seeing History: Is perspective learned or natural?". Eclectic Light. 10 January 2018. Over the same period, the development of sophisticated and highly-detailed visual art in Asia arrived at a slightly different solution, now known as the oblique projection. Whereas Roman and subsequent European visual art effectively had multiple and incoherent vanishing points, Asian art usually lacked any vanishing point, but aligned recession in parallel. An important factor here is the use of long scrolls, which even now make fully coherent perspective projection unsuitable.
  12. ^ Martijn de Geus (9 March 2019). "China Projections". Arch Daily. Retrieved 8 July 2020.
  13. ^ Krikke, Jan (2 January 2018). "Why the world relies on a Chinese "perspective"". Medium.com. About 2000 years ago, the Chinese developed dengjiao toushi (等角透視), a graphic tool probably invented by Chinese architects. It came to be known in the West as axonometry. Axonometry was crucial in the development of the Chinese hand scroll painting, an art form that art historian George Rowley referred to as "the supreme creation of Chinese genius". Classic hand scroll paintings were up to ten meters in length. They are viewed by unrolling them from right to left in equal segments of about 50 cm. The painting takes the viewer through a visual story in space and time.
  14. ^ "Pompeii. House of the Vettii. Fauces and Priapus". SUNY Buffalo. Archived from the original on 24 December 2007. Retrieved 27 December 2007.
  15. ^ Panofsky, Erwin (1960). Renaissance and Renascences in Western Art. Stockholm: Almqvist & Wiksell. p. 122, note 1. ISBN 0-06-430026-9.
  16. ^ Vatican Virgil image
  17. ^ Heidi J. Hornik and Mikeal Carl Parsons, Illuminating Luke: The infancy narrative in Italian Renaissance painting, p. 132
  18. ^ "Perspective: The Rise of Renaissance Perspective". WebExhibits. Retrieved 15 October 2020.
  19. ^ Gärtner, Peter (1998). Brunelleschi. Cologne: Könemann. p. 23. ISBN 978-3-8290-0701-6.
  20. ^ Edgerton 2009, pp. 44–46.
  21. ^ Edgerton 2009, p. 40.
  22. ^ Dominique Raynaud (1998). L'Hypothèse d'Oxford. Essai sur les origines de la perspective. Paris: Presses universitaires de France. pp. 132–141.
  23. ^ Raynaud, Dominique (2014). Optics and the Rise of Perspective. Oxford: Bardwell Press. pp. 1–2].
  24. ^ "...and these works (of perspective by Brunelleschi) were the means of arousing the minds of the other craftsmen, who afterwards devoted themselves to this with great zeal."
    Vasari's Lives of the Artists, chapter on Brunelleschi.
  25. ^ a b Hale, John R . (1981) [1965]. Great Ages of Man: Renaissance (rev. ed.). Time-Life. p. 98.
  26. ^ "The Gates of Paradise: Lorenzo Ghiberti's Renaissance Masterpiece". Art Institute of Chicago. 2007. Retrieved 20 September 2020.
  27. ^ Vasari, The Lives of the Artists, "Masaccio".
  28. ^ Adams, Laurie (2001). Italian Renaissance Art. Oxford: Westview Press. p. 98. ISBN 978-0-8133-4902-2.
  29. ^ White, Susan D. (2006). Draw Like Da Vinci. London: Cassell Illustrated, p. 132. ISBN 978-1-84403-444-4.
  30. ^ Harness, Brenda. "Melozzo da Forli: Master of Foreshortening". Fine Art Touch. Retrieved 15 October 2020.
  31. ^ Field, J. V.; Lunardi, R.; Settle, T. B. (1989). "The perspective scheme of Masaccio's Trinity fresco". Nuncius. 4 (2): 31–118. doi:10.1163/182539189X00680. INIST 11836604.
  32. ^ Dominique Raynaud (1998). L'Hypothèse d'Oxford. Paris: Presses universitaires de France. pp. 72–120.
  33. ^ Raynaud, Dominique (2016). "Fact and Fiction Regarding Masaccio's Trinity Fresco". Studies on Binocular Vision. Archimedes. Vol. 47. pp. 53–67. doi:10.1007/978-3-319-42721-8_4. ISBN 978-3-319-42720-1.
  34. ^ Raynaud, Dominique (2020). "Las fuentes ópticas de Leonardo". In Ramón-Laca, Luis (ed.). Leonardo da Vinci. Perspectiva y visión. Alcalá de Henares: UAH. pp. 61–62. ISBN 978-84-18254-89-5. OCLC 1243556932.
  35. ^ Vasari, Giorgio (1885). Stories of the Italian Artists. Scribner & Welford. p. 53. Messer Paolo dal Pozzo Toscanelli, having returned from his studies, invited Filippo with other friends to supper in a garden, and the discourse falling on mathematical subjects, Filippo formed a friendship with him and learned geometry from him.
  36. ^ El-Bizri, Nader (2010). "Classical Optics and the Perspectiva Traditions Leading to the Renaissance". In Hendrix, John Shannon; Carman, Charles H. (eds.). Renaissance Theories of Vision (Visual Culture in Early Modernity). Farnham, Surrey: Ashgate Publishing. pp. 11–30. ISBN 978-1-409400-24-0.
  37. ^ Hans, Belting (2011). Florence and Baghdad: Renaissance art and Arab science (1st English ed.). Cambridge, Massachusetts: Belknap Press of Harvard University Press. pp. 90–92. ISBN 978-0-674-05004-4. OCLC 701493612.
  38. ^ Livio, Mario (2003). The Golden Ratio. New York: Broadway Books. p. 126. ISBN 0-7679-0816-3.
  39. ^ O'Connor, J. J.; Robertson, E. F. (July 1999). "Luca Pacioli". University of St Andrews. Archived from the original on 22 September 2015. Retrieved 23 September 2015.
  40. ^ Goldstein, Andrew M. (17 November 2011). "The Male "Mona Lisa"?: Art Historian Martin Kemp on Leonardo da Vinci's Mysterious "Salvator Mundi"". Blouin Artinfo.
  41. ^ MacKinnon, Nick (1993). "The Portrait of Fra Luca Pacioli". The Mathematical Gazette. 77 (479): 206. doi:10.2307/3619717. JSTOR 3619717. S2CID 195006163.
  42. ^ "Handprint : Perspective in the world". Archived from the original on 6 January 2007. Retrieved 25 December 2006. Retrieved on 25 December 2006

Sources

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Further reading

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