Course detail

Constructive Geometry

FAST-BA008Acad. year: 2022/2023

Perspective collineation and affinity,circle in affinity. Monge`s projection, topographic surfaces, theoretical solution of the roofs, orthogonal axonometry and linear perspective.

Language of instruction

Czech

Number of ECTS credits

5

Mode of study

Not applicable.

Department

Institute of Mathematics and Descriptive Geometry (MAT)

Learning outcomes of the course unit

Students should be able to construct conics using their focus properties, perspective colineation and affinity. Understand and get the basics of projection: coted, Monge`s projection, orthogonal axonometry, and linear perspective. They should be able to solve simple 3D problems, display the basic geometric bodies and surfaces in each projection, their section. In a linear perspective, they should be able to draw a building. They should be theoretically able to solve the roof and solve the location of the construction object in the terrain, both in coted projection.

Prerequisites

Basics of plane and 3D geometry a stereometrie as taught at secondary schools.

Co-requisites

Not required.

Planned learning activities and teaching methods

Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations - lectures, seminars.

Assesment methods and criteria linked to learning outcomes

Full-time study programme: Students have to pass two credit tests, submit two drawings and other homework.
Followed by an exam with a pass rate of at least 50%.
Combined study programme: Students will do 6 tests during the semester and send them to the lecturer. Their successful completion is a condition for getting the credit. An exam with a pass rate of at least 50% will follow.

 

Course curriculum

1. Introduction - principles of parallel and central projection. Perspective collineation and affinity-basic properties.
2. System of basic problems, examples. Monge`s projection. Basic problems.
3. Monge`s projection. Basic problems.
4. Monge`s projection. Coted projection.
5. Orthogonal axonometry.
6. Orthogonal axonometry.
7. Basic parts of central projection. Linear perspective.
8. Linear perspective.
9. Linear perspective. Topographic surfaces (basic concepts and constructions).
10. Topographic surfaces.
11. Topographic surfaces. Theoretical solution of the roofs.
12. Theoretical solution of the roofs.
13. Questions.

Work placements

Not applicable.

Aims

Students should be able to construct conics using their focus properties, understand the principles of perspective colineation and affinity using such properties in solving problems, understand and get the basics of projection: Monge`s projection, orthogonal axonometry, and linear perspective. They should develop 3D visualization and be able to solve simple 3D problems, display simple geometric bodies and surfaces in each type of projection, their section with a plane and intercestions with a straight line. In a linear perspective, they should be able to draw a building. They should learn the basics of the theoretical solution of roofs and topographic surfaces.

Specification of controlled education, way of implementation and compensation for absences

Extent and forms are specified by guarantor’s regulation updated for every academic year.

Recommended optional programme components

Students can register for the optional subject VAC001 in the previous semester. The contents of the course is an introduction to the issues of the subject of descriptive geometry.

Prerequisites and corequisites

Not applicable.

Basic literature

Deskriptivní geometrie, multimediální CD-ROM, verze 4.0; BULANTOVÁ,J.,HON,P.,PRUDILOVÁ,K.,PUCHÝŘOVÁ,J.,ROUŠAR,J.,ROUŠAROVÁ,V.,SLABĚŇÁKOVÁ,J.,ŠAFAŘÍK,J. FAST VUT v Brně, 2012 (CS)

Recommended reading

Cvičení z deskr.geometrie II,III HOLÁŇ, Štěpán, HOLÁŇOVÁ, Libuše VUT Brno, 1994 (CS)
Descriptive geometry ČERNÝ, Jaroslav, KOČANDRLOVÁ, Milada ČVUT, Praha, 1996 (EN)
Descriptive geometry Pare, Loving, Hill: London, 1965 (EN)
Deskriptivní geometrie I Drábek K., Harant F.,Setzer O SNTL Praha, 1978 (CS)
Deskriptivní geometrie I, II PISKA, Rudolf, MEDEK, Václav SNTL, 1976 (CS)
Deskriptivní geometrie I,II VALA, Jiří VUT Brno, 1997 (CS)
Konstruktivní geometrie Černý J., Kočandrlová M ČVUT Praha. 2003 (CS)
Sbírka řešených příkladů z konstruktivní geometrie, Autorský kolektiv ÚMDG FaSt VUT v Brně https://mat.fce.vutbr.cz/studium/geometrie/ (CS)

Classification of course in study plans

  • Programme B-P-C-SI Bachelor's

    branch VS , 1 year of study, summer semester, compulsory

  • Programme B-K-C-SI Bachelor's

    branch VS , 1 year of study, summer semester, compulsory

  • Programme B-P-C-MI (N) Bachelor's

    branch MI , 1 year of study, summer semester, compulsory

  • Programme B-P-E-SI Bachelor's

    branch VS , 1 year of study, summer semester, compulsory

Type of course unit

 

Lecture

26 hod., optionally

Teacher / Lecturer

Syllabus

1. Introduction - principles of parallel and central projection. Perspective collineation and affinity-basic properties. 2. System of basic problems, examples. Monge`s projection. Basic problems. 3. Monge`s projection. Basic problems. 4. Monge`s projection. Coted projection. 5. Orthogonal axonometry. 6. Orthogonal axonometry. 7. Basic parts of central projection. Linear perspective. 8. Linear perspective. 9. Linear perspective. Topographic surfaces (basic concepts and constructions). 10. Topographic surfaces. 11. Topographic surfaces. Theoretical solution of the roofs. 12. Theoretical solution of the roofs. 13. Questions.

Exercise

26 hod., compulsory

Teacher / Lecturer

Syllabus

1. Focus properties of conic sections of an ellipse. Construction of an ellipse on the basis of affinity – Rytz´s and trammel construction. 2. Perspective collineation, perspective affinity. Curve affine to the circle. 3. Monge`s projection. Basic problems. 4. Monge`s projection. 5. Monge`s projection. 6. Test. Orthogonal axonometry. 7. Orthogonal axonometry. 8. Linear perspective. 9. Linear perspective. 10. Linear perspective. Topographic surfaces. 11. Test. Topographic surfaces. 12. Topographic surfaces. Theoretical solution of the roofs. 13. Theoretical solution of the roofs. Credits.