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{{Short description|Developer of the Petrie polygon}}
{{copyedit}}
{{Editorial|date=November 2023}}
{{Infobox person
{{Infobox person
| death_date = [[1972]]<br />(65 años)
| death_date = [[1972]]
| nationality = {{GBR|Británico}}
| nationality = {{GBR|British}}
| known =
| known = [[Petrie polygon]]
}}
}}
'''John Flinders Petrie''' (April 26, 1907 1972) was an English [[mathematician]]. He met the geometer [[Harold Coxeter|Harold Scott MacDonald Coxeter]] as a student, beginning a lifelong friendship. They collaborated in discovering infinite warped polyhedra and (finite) warped polyhedra in the fourth dimension, analogous to the previous ones. In addition to being the first to realize the importance of the warped polygon that now bears his name, he was also skilled as a draftsperson.
'''John Flinders Petrie''' was born on [[April 26]], [[1907]], in [[Hampstead, London]]. He was the only son of the renowned Egyptologist [[Sir William Matthew Flinders Petrie]].<ref>W. H. Auden – ‘Family Ghosts’ «John Flinders Petrie».</ref>. Already as a student he showed the remarkable potential of his mathematical abilities and his great visual memory, which his father also showed, allowed him to visualize complex geometries. While studying at a boarding school, he met [[Harold Coxeter]]<ref>A large part of what is known about Petrie is due to Coxeter. See also: {{cite book | last = Hargittai | year = 2005 | title = Candid science|chapter = H. S. M. (Donald) Coxeter}}, pág. 5 ''et seq.''</ref> in a sanatorium while he was recovering from a minor illness, beginning a friendship that would remain throughout their lives.
[[File:4-cube_graph.svg|thumb|275x275px|<div style="text-align:center">{4,3,3}<br /><br />[[Hypercube]]<br /><br />8 lados<br /><br />''V'':(8,8,0)</div>]]
John Flinders Petrie (April 26, 1907 - 1972) was an English [[mathematician, who demonstrated remarkable geometric aptitude in his youth. As a student, he met the great geometer [[Harold Coxeter|Harold Scott MacDonald Coxeter]], beginning a lifelong friendship. They collaborated in the discovery of infinite warped polyhedra and (finite) warped polyhedra in the fourth dimension, analogous to the previous ones. In addition to being the first to realize the importance of the warped polygon that now bears his name, his skills as a draftsman are still appreciated.


==Biography==
==Biography==
Petrie was born on April 26, [[1907]], in [[Hampstead, London]]. He was the only son of the renowned Egyptologist [[Sir William Matthew Flinders Petrie]]. Already as a student he showed the remarkable potential of his mathematical abilities and his great [[visual memory]], which his father also showed, allowed him to visualize [[complex geometry|complex geometries]]. While studying at a boarding school, he met Coxeter in a sanatorium while he was recovering from a minor illness, beginning a friendship that would remain throughout their lives. Looking at a geometry textbook with an appendix on Platonic polyhedra, they wondered why there were only five and tried to increase their number. Petrie commented: How about we put four squares around one corner? In practice, they would lie on a plane, forming a pattern of squares that would cover the plane. Being clever with words, he called this arrangement "tesserohedron"; calling the similar arrangement of triangles a "trigonohedron."
Petrie was born on April 26, [[1907]], in [[Hampstead, London]]. He was the only son of the renowned Egyptologists [[Sir William Matthew Flinders Petrie]] and [[Hilda Petrie]].<ref>W. H. Auden ‘Family Ghosts’ «John Flinders Petrie».</ref> While studying at a boarding school, he met Coxeter in a sanatorium while recovering from a minor illness, beginning a friendship that would remain throughout their lives.<ref>A large part of what is known about Petrie is due to Coxeter. See also: {{cite book | last = Hargittai | year = 2005 | title = Candid science|chapter = H. S. M. (Donald) Coxeter}}, pág. 5 ''et seq.''</ref> Looking at a geometry textbook with an appendix on Platonic polyhedra, they wondered why there were only five and tried to increase their number. Petrie commented: How about we put four squares around one corner? In practice, they would lie on a plane, forming a pattern of squares covering the plane. He called this arrangement a "tesserohedron", reaching the similar structure of triangles a "trigonohedron."


==Polyhedral regular tilings==
==Polyhedral regular tilings==


One day in 1926, Petrie told Coxeter that he had discovered two new regular polyhedra; infinite, but free of "false vertices" (points distinct from the vertices, where three or more faces meet, like those that characterize regular star polyhedra): one consisting of squares, six at each vertex and another consisting of hexagons, four at each vertex, which form a dual or reciprocal pair. To the common objection that there is no room for more than four squares around a vertex, he revealed the trick: allow the faces to be arranged up and down marking a zigzag. When Coxeter understood this, he mentioned a third possibility: hexagons, six around a vertex, its own dual.
In 1926, Petrie told Coxeter that he had discovered two new regular polyhedra, infinite but free of "false vertices" (points distinct from the vertices, where three or more faces meet, like those that characterize regular star polyhedra): one consisting of squares, six at each vertex and another consisting of hexagons, four at each vertex, which form a dual or reciprocal pair. To the common objection that there is no room for more than four squares around a vertex, he revealed the trick: allow the faces to be arranged up and down, marking a zigzag. When Coxeter understood this, he mentioned a third possibility: hexagons, six around a vertex, its dual.


Coxeter suggested a modified [[Schläfli symbol]], {l, m | n} for these figures, with the symbol {l, m} implying the vertex figure, m l-gons around a vertex and n-gonal holes. Then it occurred to them that, although the new [[polyhedra]] are infinite, they could find analogous finite polyhedra by delving into the fourth dimension. Petrie cited one consisting of n2 squares, four at each vertex. They called these figures "regular skew polyhedra". Later, Coxeter would delve deeper into the subject.
Coxeter suggested a modified [[Schläfli symbol]], {l, m | n} for these figures, with the emblem {l, m} implying the vertex figure, m l-gons around a vertex and n-gonal holes. Then it occurred to them that, although the new [[polyhedra]] are infinite, they could find analogous finite polyhedra by delving into the fourth dimension. Petrie cited one consisting of n2 squares, four at each vertex. They called these figures "regular skew polyhedra". Later, Coxeter would delve deeper into the subject.


== University and Work ==
== University and work ==
Because his father belonged to University College London, Petrie enrolled in this institution, where he completed his studies without difficulty. When the [[Second World War]] broke out, he enlisted as an officer and was captured as a prisoner by the Germans, organizing a choir during his captivity. After the war ended and he was released, he went to Darlington Hall, a school in southwest England. He had a mundane job, working many years as a school teacher and apparently never culminated his early mathematical ability. He was one of the tutors who attended to the children who were doing poorly in school.
Because his father belonged to [[University College London]], Petrie enrolled in this institution, where he successfully completed his studies. When the [[Second World War]] broke out, he enlisted as an officer and was captured as a prisoner by the Germans, organizing a choir during his captivity. After the war ended and he was released, he went to Darlington Hall, a school in southwest England. He worked many years as a schoolteacher. He was one of the tutors who attended to the children doing poorly in school.


== The Petrie polygon==
== The Petrie polygon==
Petrie continued to correspond with Coxeter and was the first to notice that, among the edges of a [[Regular polyhedron]], a skew polygon forming a zigzag can be distinguished, in which the first and second are the edges of one face, the second and third are artists of another face and so on, successively. This zigzag is known as the "[[Petrie polygon]]"
Petrie continued to correspond with Coxeter and was the first to notice that, among the edges of a [[regular polyhedron]], a [[skew polygon]] forming a zigzag can be distinguished, in which the first and second are the edges of one face, the second and third are the edges of another face and so on, successively. This zigzag is known as the "[[Petrie polygon]]" and has many applications. The Petrie polygon of a regular polyhedron can be defined as the skew polygon (whose vertices do not all lie in the same plane) such that every two consecutive sides (but not three) belong to one of the faces of the polyhedron.


Each finite regular polyhedron can be orthogonally projected onto a plane so that the Petrie polygon becomes a regular polygon, with the rest of the projection inside. These polygons and their projected graphs help visualize the symmetrical structure of regular polytopes of higher dimensions, which are difficult to conceive or imagine without this aid.
and has many applications. The Petrie polygon of a regular polyhedron can be defined as the skew polygon (whose vertices do not all lie in the same plane) such that every two consecutive sides (but not three) belong to one of the faces of the polyhedron.


His skills as a draftsman are shown in an exquisite set of drawings of the stellated icosahedron, which provides much of the fascination of the much-discussed book he illustrates. On another occasion, to explain the symmetry of the icosahedron, Coxeter showed an orthogonal projection, representing 10 of the 15 [[great circle]]s as ellipses. The difficult task of drawing was performed by Petrie around 1932. It now prominently features on the cover of a popular recreational mathematics book garnished with a touch of colour. It is reported that, in periods of intense concentration, he could answer questions about complex figures of the fourth dimension by "visualizing" them.
Each finite regular polyhedron can be orthogonally projected onto a plane in such a way that the Petrie polygon becomes a regular polygon, with the rest of the projection inside it. These polygons and their projected graphs are useful in visualizing the symmetrical structure of regular polytopes of higher dimensions, which are very difficult to conceive or imagine without this aid.

His skills as a draftsman can be appreciated in an exquisite set of drawings of the stellated icosahedron, which provides much of the fascination of the much-discussed book he illustrates. On another occasion, to explain the symmetry of the icosahedron, Coxeter showed an orthogonal projection, representing 10 of the 15 [[Great circle|great circles]] as ellipses

. The difficult task of drawing was performed by Petrie around 1932. It now prominently features on the cover of a popular recreational mathematics book, garnished with a touch of color. It is reported that, in periods of intense concentration, he could answer questions about complex figures of the fourth dimension by "visualizing" them.


== Final years ==
== Final years ==
Petrie got married and had a daughter. In late 1972, his wife suffered a sudden heart attack and passed away. He missed her so much and was so distracted, that one day he walked onto a highway near his home and, while trying to cross it running, was hit by a car. He died in Surrey, at the age of 64, just two weeks after his wife.
Petrie got married and had a daughter. In late 1972, his wife suffered a sudden heart attack and passed away. He missed her so much and was so distracted that one day he walked onto a highway near his home and was hit by a car while trying to cross it running. He died in Surrey, at 64, just two weeks after his wife.{{Citation needed|date=December 2023}}


== See also ==
== See also ==

* [[Petrie polygon]]
* [[Petrie polygon]]
* [[Skew polygon]]
* [[Skew polygon]]
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{{Reflist}}
{{Reflist}}


* {{Cite book |last=Ball |first=W. W. Rouse |title=Mathematical recreations and essays |last2=Coxeter |first2=H. S. M. |publisher=Dover Publications |year=1987 |isbn=0-486-25357-0 |edition=13.ª |location=Nueva&nbsp;York |language=inglés |author-link=W. W. Rouse Ball}}
* {{Cite book |last=Ball |first=W. W. Rouse |title=Mathematical recreations and essays |last2=Coxeter |first2=H. S. M. |publisher=Dover Publications |year=1987 |isbn=0-486-25357-0 |edition=13.ª |location=Nueva&nbsp;York |language=en |author-link=W. W. Rouse Ball}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=Regular polytopes |publisher=Dover Publications |year=1973 |isbn=0-486-61480-8 |edition=3.ª |location=Nueva&nbsp;York |language=inglés |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=Regular polytopes |publisher=Dover Publications |year=1973 |isbn=0-486-61480-8 |edition=3.ª |location=Nueva&nbsp;York |language=en |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=Introduction to geometry |publisher=Wiley |year=1989 |isbn=9780471504580 |edition=2.ª |series=Wiley Classic Library |volume=19 |location=Nueva&nbsp;York |language=inglés |author-link=H. S. M. Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=Introduction to geometry |publisher=Wiley |year=1989 |isbn=9780471504580 |edition=2.ª |series=Wiley Classic Library |volume=19 |location=Nueva&nbsp;York |language=en |author-link=H. S. M. Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |url=https://archive.org/details/kaleidoscopessel0000coxe |title=Kaleidoscopes: selected writings of H. S. M. Coxeter |publisher=Wiley–Interscience Publication |others=Introducción y compilación de F. A. Sherk; P. Mullen; A. C. Thompson; Ivić Weiss |year=1995 |isbn=9780471010036 |location=Nueva&nbsp;York |language=inglés |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |url=https://archive.org/details/kaleidoscopessel0000coxe |title=Kaleidoscopes: selected writings of H. S. M. Coxeter |publisher=Wiley–Interscience Publication |others=Introducción y compilación de F. A. Sherk; P. Mullen; A. C. Thompson; Ivić Weiss |year=1995 |isbn=9780471010036 |location=Nueva&nbsp;York |language=en |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=The fifty–nine icosahedra |last2=Du Val |first2=P. |last3=Flather |first3=H. T. |last4=Petrie |first4=J. F. |publisher=Tarquin |year=1999a |isbn=9781899618323 |edition=3.ª |location= |language=inglés |author-link=H. S. M. Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |title=The fifty–nine icosahedra |last2=Du Val |first2=P. |last3=Flather |first3=H. T. |last4=Petrie |first4=J. F. |publisher=Tarquin |year=1999a |isbn=9781899618323 |edition=3.ª |location= |language=en |author-link=H. S. M. Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |url=https://archive.org/details/beautyofgeometry0000coxe |title=The beauty of geometry: twelve essays |publisher=Dover Publications |year=1999b |isbn=0-486-40919-8 |location=Nueva&nbsp;York |language=inglés |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Coxeter |first=H. S. M. |url=https://archive.org/details/beautyofgeometry0000coxe |title=The beauty of geometry: twelve essays |publisher=Dover Publications |year=1999b |isbn=0-486-40919-8 |location=Nueva&nbsp;York |language=en |author-link=Harold Scott MacDonald Coxeter}}
* {{Cite book |last=Hargittai |first=Balazs |title=Candid science v: conversations with famous scientists |last2=Hargittai |first2=István |publisher=Imperial College Press |year=2005 |isbn=9781860945069 |location=Londres |language=inglés}}
* {{Cite book |last=Hargittai |first=Balazs |title=Candid science v: conversations with famous scientists |last2=Hargittai |first2=István |publisher=Imperial College Press |year=2005 |isbn=9781860945069 |location=Londres |language=en}}
* {{Cite book |last=Kepler |first=Johannes |title=Harmonices mundi |publisher=The American Philosophical Society |others=Tr. al inglés con introducción y anotaciones por E. J. Aiton; A. M. Duncan; J. V. Field |year=1997 |isbn=0-87169-209-0 |location= |language=latín |author-link=Johannes Kepler}}
* {{Cite book |last=Kepler |first=Johannes |title=Harmonices mundi |publisher=The American Philosophical Society |others=Tr. al inglés con introducción y anotaciones por E. J. Aiton; A. M. Duncan; J. V. Field |year=1997 |isbn=0-87169-209-0 |location= |language=la |author-link=Johannes Kepler}}
* {{Cite book |last=McMullen |first=Peter |url=https://archive.org/details/abstractregularp0000mcmu |title=Abstract regular polytopes |last2=Schulte |first2=Egon |publisher=[[Cambridge University Press]] |year=2002 |isbn=0-521-81496-0 |location=Cambridge |language=inglés |author-link=Peter McMullen}}
* {{Cite book |last=McMullen |first=Peter |url=https://archive.org/details/abstractregularp0000mcmu |title=Abstract regular polytopes |last2=Schulte |first2=Egon |publisher=[[Cambridge University Press]] |year=2002 |isbn=0-521-81496-0 |location=Cambridge |language=en |author-link=Peter McMullen}}
* {{Cite web |last=Jenkins |first=Nicholas |title=John Flinders Petrie |url=http://www.stanford.edu/group/auden/cgi-bin/auden/individual.php?pid=I16825&ged=auden-bicknell.ged |access-date=2012-10-11 |website=W. H. Auden – ‘Family Ghosts’ |language=en }}{{Dead link|date=February 2024 |bot=InternetArchiveBot |fix-attempted=yes }}

* {{Cite web |last=Jenkins |first=Nicholas |title=John Flinders Petrie |url=http://www.stanford.edu/group/auden/cgi-bin/auden/individual.php?pid=I16825&ged=auden-bicknell.ged |access-date=2012-10-11 |website=W. H. Auden – ‘Family Ghosts’ |language=inglés}}
* {{Cite web |last=Jenkins |first=Nicholas |title=John Flinders Petrie |url=http://kindred.stanford.edu/#/kin/full/none/none/I16825// |access-date=2017-07-18 |website=Kindred Britain |language=en}}
* {{Cite web |last=Jenkins |first=Nicholas |title=John Flinders Petrie |url=http://kindred.stanford.edu/#/kin/full/none/none/I16825// |access-date=2017-07-18 |website=Kindred Britain |language=inglés}}
* {{MathWorld|PetriePolygon|Petrie polygon}}
* {{MathWorld|PetriePolygon|Petrie polygon}}
* {{MathWorld|SkewPolygon|Skew polygon}}
* {{MathWorld|SkewPolygon|Skew polygon}}
* {{MathWorld|RegularSkewPolyhedron|Regular skew polyhedron}}
* {{MathWorld|RegularSkewPolyhedron|Regular skew polyhedron}}

[[Category:Road incident deaths]]
{{Authority control}}

{{DEFAULTSORT:Petrie, John Flinders}}
[[Category:Road incident deaths in the United Kingdom]]
[[Category:Polytopes]]
[[Category:Polytopes]]
[[Category:Geometers]]
[[Category:Geometers]]
[[Category:British mathematicians]]
[[Category:20th-century British mathematicians]]
[[Category:1972 deaths]]
[[Category:1907 births]]

Latest revision as of 03:36, 8 February 2024

John Flinders Petrie
Died1972
Nationality United Kingdom
Known forPetrie polygon

John Flinders Petrie (April 26, 1907 – 1972) was an English mathematician. He met the geometer Harold Scott MacDonald Coxeter as a student, beginning a lifelong friendship. They collaborated in discovering infinite warped polyhedra and (finite) warped polyhedra in the fourth dimension, analogous to the previous ones. In addition to being the first to realize the importance of the warped polygon that now bears his name, he was also skilled as a draftsperson.

Biography[edit]

Petrie was born on April 26, 1907, in Hampstead, London. He was the only son of the renowned Egyptologists Sir William Matthew Flinders Petrie and Hilda Petrie.[1] While studying at a boarding school, he met Coxeter in a sanatorium while recovering from a minor illness, beginning a friendship that would remain throughout their lives.[2] Looking at a geometry textbook with an appendix on Platonic polyhedra, they wondered why there were only five and tried to increase their number. Petrie commented: How about we put four squares around one corner? In practice, they would lie on a plane, forming a pattern of squares covering the plane. He called this arrangement a "tesserohedron", reaching the similar structure of triangles a "trigonohedron."

Polyhedral regular tilings[edit]

In 1926, Petrie told Coxeter that he had discovered two new regular polyhedra, infinite but free of "false vertices" (points distinct from the vertices, where three or more faces meet, like those that characterize regular star polyhedra): one consisting of squares, six at each vertex and another consisting of hexagons, four at each vertex, which form a dual or reciprocal pair. To the common objection that there is no room for more than four squares around a vertex, he revealed the trick: allow the faces to be arranged up and down, marking a zigzag. When Coxeter understood this, he mentioned a third possibility: hexagons, six around a vertex, its dual.

Coxeter suggested a modified Schläfli symbol, {l, m | n} for these figures, with the emblem {l, m} implying the vertex figure, m l-gons around a vertex and n-gonal holes. Then it occurred to them that, although the new polyhedra are infinite, they could find analogous finite polyhedra by delving into the fourth dimension. Petrie cited one consisting of n2 squares, four at each vertex. They called these figures "regular skew polyhedra". Later, Coxeter would delve deeper into the subject.

University and work[edit]

Because his father belonged to University College London, Petrie enrolled in this institution, where he successfully completed his studies. When the Second World War broke out, he enlisted as an officer and was captured as a prisoner by the Germans, organizing a choir during his captivity. After the war ended and he was released, he went to Darlington Hall, a school in southwest England. He worked many years as a schoolteacher. He was one of the tutors who attended to the children doing poorly in school.

The Petrie polygon[edit]

Petrie continued to correspond with Coxeter and was the first to notice that, among the edges of a regular polyhedron, a skew polygon forming a zigzag can be distinguished, in which the first and second are the edges of one face, the second and third are the edges of another face and so on, successively. This zigzag is known as the "Petrie polygon" and has many applications. The Petrie polygon of a regular polyhedron can be defined as the skew polygon (whose vertices do not all lie in the same plane) such that every two consecutive sides (but not three) belong to one of the faces of the polyhedron.

Each finite regular polyhedron can be orthogonally projected onto a plane so that the Petrie polygon becomes a regular polygon, with the rest of the projection inside. These polygons and their projected graphs help visualize the symmetrical structure of regular polytopes of higher dimensions, which are difficult to conceive or imagine without this aid.

His skills as a draftsman are shown in an exquisite set of drawings of the stellated icosahedron, which provides much of the fascination of the much-discussed book he illustrates. On another occasion, to explain the symmetry of the icosahedron, Coxeter showed an orthogonal projection, representing 10 of the 15 great circles as ellipses. The difficult task of drawing was performed by Petrie around 1932. It now prominently features on the cover of a popular recreational mathematics book garnished with a touch of colour. It is reported that, in periods of intense concentration, he could answer questions about complex figures of the fourth dimension by "visualizing" them.

Final years[edit]

Petrie got married and had a daughter. In late 1972, his wife suffered a sudden heart attack and passed away. He missed her so much and was so distracted that one day he walked onto a highway near his home and was hit by a car while trying to cross it running. He died in Surrey, at 64, just two weeks after his wife.[citation needed]

See also[edit]

References[edit]

  1. ^ W. H. Auden – ‘Family Ghosts’ «John Flinders Petrie».
  2. ^ A large part of what is known about Petrie is due to Coxeter. See also: Hargittai (2005). "H. S. M. (Donald) Coxeter". Candid science., pág. 5 et seq.
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