Lectures related to Mechanical Construction I: Views Correspondence and Axonometric Projections

Mechanical Construction I: Views and Projections

Covers the basics of mechanical construction, focusing on views correspondence, pivot lines usage, and axonometric projections.

Mechanical Design Principles: Technical Drawing and Projections

Introduces mechanical design principles, focusing on technical drawing and projection methods essential for accurate representation in engineering.

Technical Drawing: Fundamentals and Applications

Covers the basics of technical drawing, including projections, standardized norms, and challenges in incomplete drawings.

Mechanical Construction Basics

Introduces the basics of mechanical construction, technical drawings, and standardization in technical communication.

Mechanical Construction I: Axonometric Projections and Standardization

Explores axonometric projections, intersections, cuts, and the history of standardization in mechanical construction, emphasizing the importance of norms in enhancing productivity and reducing costs.

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Mechanical Design Fundamentals: Technical Drawing

Covers the basics of technical drawing in mechanical design.

Mechanical Construction I: Projections and Standards

Introduces mechanical construction basics, including projections, intersections, and the history of standardization and measurement units.

Mechanical Design Principles: Projections and Representations

Introduces mechanical design principles, focusing on projections, cuts, sections, and dimensioning techniques for technical drawings.

Monge Method: Spatial Geometry Problems and Monge Projections

Explores spatial geometry problem-solving using Monge representation and projections.

True Sizes: Folding Method in Descriptive Geometry

Explains the folding method in descriptive geometry to determine true sizes of segments and distances between points.

Orthogonal Projection: Vector Decomposition

Explains orthogonal projection and vector decomposition with examples in particle trajectory analysis.

Descriptive Geometry: Cones and Cylinders

Explores intersections, curves, and perspectives in descriptive geometry of cones and cylinders.

Axonometry: Image of Points and True Magnitude of Segments

Explains axonometry, focusing on image of points and true magnitude of segments in 3D space.

Axonometry: Core Concepts

Covers the core concepts of axonometry, focusing on projection and linear dependence of vectors.

Descriptive Geometry

Introduces Descriptive Geometry concepts, including conservation laws and projection methods.

Shape from Texture

Explores recovering surface orientation from image texture under different projections and the use of deep learning for normal prediction.

Orthogonality and Projection

Covers orthogonality, scalar products, orthogonal bases, and vector projection in detail.

Projections: Orthographic and Perspective

Explores the transformation pipeline from 3D to 2D, covering orthographic and perspective projections.

Geometric Descriptive: Shadows and Perspective

Explores the basics of Geometric Descriptive, emphasizing shadows and perspective in 2D and 3D.