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4.510 Digital Design Fabrication (MIT) 4.510 Digital Design Fabrication (MIT)

Description

This class serves as an introductory subject in advanced computing, rapid prototyping, and CAD/CAM fabrication for architects. It focuses on the relationship between design and various forms of computer modeling as input, and CAD/CAM tools as output material. It presents the process of design and construction using CAD files introduced by the office of Gehry Partners during the construction of the Guggenheim Museum in Bilbao, Spain. It is taught in phases starting with rapid prototyping and ending with digital mockups of building components fabricated from CAD files on a one-to-one scale. This class serves as an introductory subject in advanced computing, rapid prototyping, and CAD/CAM fabrication for architects. It focuses on the relationship between design and various forms of computer modeling as input, and CAD/CAM tools as output material. It presents the process of design and construction using CAD files introduced by the office of Gehry Partners during the construction of the Guggenheim Museum in Bilbao, Spain. It is taught in phases starting with rapid prototyping and ending with digital mockups of building components fabricated from CAD files on a one-to-one scale.

Subjects

architectural design and computation | architectural design and computation | computer modeling | computer modeling | rendering | rendering | digital fabrication | digital fabrication | exploration of space | exploration of space | place making | place making | computer rendering | computer rendering | design construction | design construction | CAD/CAM fabrication | CAD/CAM fabrication | computer models | computer models | computer aided drawings | computer aided drawings | rapid prototyped models | rapid prototyped models | architecture | architecture | design | design | computation | computation | CAD CAM fabrication | CAD CAM fabrication

License

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6.152J Microelectronics Processing Technology (MIT) 6.152J Microelectronics Processing Technology (MIT)

Description

This course introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions focus on basic processing techniques such as diffusion, oxidation, photolithography, chemical vapor deposition, and more. Through team lab assignments, students are expected to gain an understanding of these processing techniques, and how they are applied in concert to device fabrication. Students enrolled in this course have a unique opportunity to fashion and test micro/nano-devices, using modern techniques and technology. This course introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions focus on basic processing techniques such as diffusion, oxidation, photolithography, chemical vapor deposition, and more. Through team lab assignments, students are expected to gain an understanding of these processing techniques, and how they are applied in concert to device fabrication. Students enrolled in this course have a unique opportunity to fashion and test micro/nano-devices, using modern techniques and technology.

Subjects

microelectronics | microelectronics | Microelectronics processing | Microelectronics processing | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | integrated circuits;vacuum;chemical vapor deposition;CVD;oxidation;diffusion;implantation;lithography;soft lithography;etching;sputtering;evaporation;interconnect;metallization;crystal growth;reliability;fabrication;processing;photolithography;physical vapor deposition;MOS;MOS capacitor;microcantilever;microfluidic | integrated circuits;vacuum;chemical vapor deposition;CVD;oxidation;diffusion;implantation;lithography;soft lithography;etching;sputtering;evaporation;interconnect;metallization;crystal growth;reliability;fabrication;processing;photolithography;physical vapor deposition;MOS;MOS capacitor;microcantilever;microfluidic | integrated circuits | integrated circuits | vacuum | vacuum | chemical vapor deposition | chemical vapor deposition | CVD | CVD | oxidation | oxidation | diffusion | diffusion | implantation | implantation | lithography | lithography | soft lithography | soft lithography | etching | etching | sputtering | sputtering | evaporation | evaporation | interconnect | interconnect | metallization | metallization | crystal growth | crystal growth | reliability | reliability | fabrication | fabrication | processing | processing | photolithography | photolithography | physical vapor deposition | physical vapor deposition | MOS | MOS | MOS capacitor | MOS capacitor | microcantilever | microcantilever | microfluidic | microfluidic | 6.152 | 6.152 | 3.155 | 3.155

License

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4.510 Digital Design Fabrication (MIT) 4.510 Digital Design Fabrication (MIT)

Description

This course will guide graduate students through the process of using rapid prototyping and CAD/CAM devices in a studio environment. The class has a theoretical focus on machine use within the process of design. Each student is expected to have completed one graduate level of design computing with a full understanding of solid modeling in CAD. Students are also expected to have completed at least one graduate design studio. This course will guide graduate students through the process of using rapid prototyping and CAD/CAM devices in a studio environment. The class has a theoretical focus on machine use within the process of design. Each student is expected to have completed one graduate level of design computing with a full understanding of solid modeling in CAD. Students are also expected to have completed at least one graduate design studio.

Subjects

digital fabrication | digital fabrication | design | design | cad | cad | cam | cam | digital manufacturing | digital manufacturing | assembly | assembly | design geometry | design geometry | fabrication | fabrication | drafting | drafting | modeling | modeling | printing | printing | waterjet cutting | waterjet cutting | cnc manufacturing | cnc manufacturing | generative fabrication | generative fabrication | construction grammars | construction grammars | prototyping | prototyping | boston water taxi | boston water taxi

License

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4.173 Digital Mock-Up Workshop (MIT) 4.173 Digital Mock-Up Workshop (MIT)

Description

This is an advanced subject in computer modeling and CAD CAM fabrication in building large-scale prototypes and digital mock-ups within a studio setting. Prototypes and mock-ups are developed with the aid of outside designers, consultants and fabricators. Field trips and in depth relationships with building fabricators demonstrate new methods for building design. The class analyzes complex shapes, shape relationships and curved surfaces fabrication at a macro scale leading to new architectural languages based on new methods of design and construction. This is an advanced subject in computer modeling and CAD CAM fabrication in building large-scale prototypes and digital mock-ups within a studio setting. Prototypes and mock-ups are developed with the aid of outside designers, consultants and fabricators. Field trips and in depth relationships with building fabricators demonstrate new methods for building design. The class analyzes complex shapes, shape relationships and curved surfaces fabrication at a macro scale leading to new architectural languages based on new methods of design and construction.

Subjects

architecture | architecture | digital fabrication | digital fabrication | CAD / CAM | CAD / CAM | machining | machining | computer aided design | computer aided design | digital prototype | digital prototype | fabrication | fabrication | Gehry | Gehry | TriPyramid | TriPyramid | Stata Center | Stata Center | Disney Concert Hall | Disney Concert Hall | digital architecture | digital architecture | 3D modelling | 3D modelling | 3D printing | 3D printing | Palladio | Palladio | design and manufacture | design and manufacture | construction | construction | assembly | assembly | tectonics | tectonics

License

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4.500 Introduction to Design Computing (MIT) 4.500 Introduction to Design Computing (MIT)

Description

This course introduces students to architectural design and computation through the use of computer modeling, rendering, and digital fabrication. The focus is on the exploration of space and place-making through the use of computer rendering and design construction and fabrication. Students design a small building using computer models leading to a full package of physical and virtual materials, from computer generated drawings to rapid, prototyped models. This course introduces students to architectural design and computation through the use of computer modeling, rendering, and digital fabrication. The focus is on the exploration of space and place-making through the use of computer rendering and design construction and fabrication. Students design a small building using computer models leading to a full package of physical and virtual materials, from computer generated drawings to rapid, prototyped models.

Subjects

architectural design and computation | architectural design and computation | computer modeling | computer modeling | rendering | rendering | digital fabrication | digital fabrication | exploration of space | exploration of space | place making | place making | computer rendering | computer rendering | design construction | design construction | CAD CAM fabrication | CAD CAM fabrication | computer models | computer models | computer aided drawings | computer aided drawings | rapid prototyped models | rapid prototyped models | architecture | architecture | design | design | computation | computation

License

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4.206 Introduction to Design Computing (MIT) 4.206 Introduction to Design Computing (MIT)

Description

This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations within a computational environment. Each semester will explore a particular historical period in architecture and the work of a selected architect. This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations within a computational environment. Each semester will explore a particular historical period in architecture and the work of a selected architect.

Subjects

architectural design and computation | architectural design and computation | computer modeling | computer modeling | rendering | rendering | digital fabrication | digital fabrication | exploration of space | exploration of space | place making | place making | computer rendering | computer rendering | design construction | design construction | CAD CAM fabrication | CAD CAM fabrication | computer models | computer models | computer aided drawings | computer aided drawings | rapid prototyped models | rapid prototyped models | architecture | architecture | design | design | computation | computation | representational mediums | representational mediums | architectural design | architectural design | complex phenomena | complex phenomena | constructs | constructs | information visualization | information visualization | programming | programming | computer graphics | computer graphics | data respresentation | data respresentation

License

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4.212 Design Fabrication (MIT) 4.212 Design Fabrication (MIT)

Description

Design Fabrication is an introductory course in the field of advanced computing, prototyping and building fabrication. The class is focused on the relationship between design, various forms of computer modeling both explicit and generative and the physical representation of information using rapid prototyping devices. Design Fabrication is an introductory course in the field of advanced computing, prototyping and building fabrication. The class is focused on the relationship between design, various forms of computer modeling both explicit and generative and the physical representation of information using rapid prototyping devices.

Subjects

architectural design and computation | architectural design and computation | computer modeling | computer modeling | rendering | rendering | digital fabrication | digital fabrication | exploration of space | exploration of space | place making | place making | computer rendering | computer rendering | design construction | design construction | CAD CAM fabrication | CAD CAM fabrication | computer models | computer models | computer aided drawings | computer aided drawings | rapid prototyped models | rapid prototyped models | architecture | architecture | design | design | computation | computation

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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4.511 Digital Mock-Up Workshop (MIT) 4.511 Digital Mock-Up Workshop (MIT)

Description

This is an advanced subject in computer modeling and CAD CAM fabrication, with a focus on building large-scale prototypes and digital mock-ups within a classroom setting. Prototypes and mock-ups are developed with the aid of outside designers, consultants, and fabricators. Field trips and in-depth relationships with building fabricators demonstrate new methods for building design. The class analyzes complex shapes, shape relationships, and curved surfaces fabrication at a macro scale leading to new architectural languages, based on methods of construction. This is an advanced subject in computer modeling and CAD CAM fabrication, with a focus on building large-scale prototypes and digital mock-ups within a classroom setting. Prototypes and mock-ups are developed with the aid of outside designers, consultants, and fabricators. Field trips and in-depth relationships with building fabricators demonstrate new methods for building design. The class analyzes complex shapes, shape relationships, and curved surfaces fabrication at a macro scale leading to new architectural languages, based on methods of construction.

Subjects

architecture | architecture | digital fabrication | digital fabrication | CAD / CAM | CAD / CAM | machining | machining | computer aided design | computer aided design | digital prototype | digital prototype | fabrication | fabrication | Gehry | Gehry | TriPyramid | TriPyramid | Stata Center | Stata Center | Disney Concert Hall | Disney Concert Hall | digital architecture | digital architecture | 3D modelling | 3D modelling | 3D printing | 3D printing | Palladio | Palladio | design and manufacture | design and manufacture | construction | construction | assembly | assembly | tectonics | tectonics

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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4.501 Architectural Construction and Computation (MIT) 4.501 Architectural Construction and Computation (MIT)

Description

This class investigates the use of computers in architectural design and construction. It begins with a pre-prepared design computer model, which is used for testing and process investigation in construction. It then explores the process of construction from all sides of the practice: detail design, structural design, and both legal and computational issues. This class investigates the use of computers in architectural design and construction. It begins with a pre-prepared design computer model, which is used for testing and process investigation in construction. It then explores the process of construction from all sides of the practice: detail design, structural design, and both legal and computational issues.

Subjects

architecture | architecture | digital fabrication | digital fabrication | CAD / CAM | CAD / CAM | machining | machining | computer aided design | computer aided design | digital prototype | digital prototype | fabrication | fabrication | Gehry | Gehry | TriPyramid | TriPyramid | Stata Center | Stata Center | Disney Concert Hall | Disney Concert Hall | digital architecture | digital architecture | 3D modelling | 3D modelling | 3D printing | 3D printing | Palladio | Palladio | design and manufacture | design and manufacture | construction | construction | assembly | assembly | tectonics | tectonics | building | building | building materials | building materials | joints | joints | connections | connections

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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6.774 Physics of Microfabrication: Front End Processing (MIT) 6.774 Physics of Microfabrication: Front End Processing (MIT)

Description

Includes audio/video content: AV lectures. This course is offered to graduates and focuses on understanding the fundamental principles of the "front-end" processes used in the fabrication of devices for silicon integrated circuits. This includes advanced physical models and practical aspects of major processes, such as oxidation, diffusion, ion implantation, and epitaxy. Other topics covered include: high performance MOS and bipolar devices including ultra-thin gate oxides, implant-damage enhanced diffusion, advanced metrology, and new materials such as Silicon Germanium (SiGe). Includes audio/video content: AV lectures. This course is offered to graduates and focuses on understanding the fundamental principles of the "front-end" processes used in the fabrication of devices for silicon integrated circuits. This includes advanced physical models and practical aspects of major processes, such as oxidation, diffusion, ion implantation, and epitaxy. Other topics covered include: high performance MOS and bipolar devices including ultra-thin gate oxides, implant-damage enhanced diffusion, advanced metrology, and new materials such as Silicon Germanium (SiGe).

Subjects

fabrication processes | fabrication processes | silicon | silicon | integrated circuits | integrated circuits | monolithic integrated circuits | monolithic integrated circuits | physical models | physical models | bulk crystal growth | bulk crystal growth | thermal oxidation | thermal oxidation | solid-state diffusion | solid-state diffusion | ion implantation | ion implantation | epitaxial deposition | epitaxial deposition | chemical vapor deposition | chemical vapor deposition | physical vapor deposition | physical vapor deposition | refractory metal silicides | refractory metal silicides | plasma and reactive ion etching | plasma and reactive ion etching | rapid thermal processing | rapid thermal processing | process modeling | process modeling | process simulation | process simulation | technological limitations | technological limitations | integrated circuit design | integrated circuit design | integrated circuit fabrication | integrated circuit fabrication | device operation | device operation | sige materials | sige materials | processing | processing

License

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3.91 Mechanical Behavior of Plastics (MIT) 3.91 Mechanical Behavior of Plastics (MIT)

Description

This course is aimed at presenting the concepts underlying the response of polymeric materials to applied loads. These will include both the molecular mechanisms involved and the mathematical description of the relevant continuum mechanics. It is dominantly an "engineering" subject, but with an atomistic flavor. It covers the influence of processing and structure on mechanical properties of synthetic and natural polymers: Hookean and entropic elastic deformation, linear viscoelasticity, composite materials and laminates, yield and fracture. This course is aimed at presenting the concepts underlying the response of polymeric materials to applied loads. These will include both the molecular mechanisms involved and the mathematical description of the relevant continuum mechanics. It is dominantly an "engineering" subject, but with an atomistic flavor. It covers the influence of processing and structure on mechanical properties of synthetic and natural polymers: Hookean and entropic elastic deformation, linear viscoelasticity, composite materials and laminates, yield and fracture.

Subjects

plastics; synthetic high polymers; viscoelastic phenomena; viscoelastic and strength properties; mechanical property evaluation; plastics fabrication methods | plastics; synthetic high polymers; viscoelastic phenomena; viscoelastic and strength properties; mechanical property evaluation; plastics fabrication methods | plastics | plastics | synthetic high polymers | synthetic high polymers | viscoelastic phenomena | viscoelastic phenomena | viscoelastic and strength properties | viscoelastic and strength properties | mechanical property evaluation | mechanical property evaluation | plastics fabrication methods | plastics fabrication methods

License

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6.777J Design and Fabrication of Microelectromechanical Devices (MIT) 6.777J Design and Fabrication of Microelectromechanical Devices (MIT)

Description

6.777J / 2.372J is an introduction to microsystem design. Topics covered include: material properties, microfabrication technologies, structural behavior, sensing methods, fluid flow, microscale transport, noise, and amplifiers feedback systems. Student teams design microsystems (sensors, actuators, and sensing/control systems) of a variety of types, (e.g., optical MEMS, bioMEMS, inertial sensors) to meet a set of performance specifications (e.g., sensitivity, signal-to-noise) using a realistic microfabrication process. There is an emphasis on modeling and simulation in the design process. Prior fabrication experience is desirable. The course is worth 4 Engineering Design Points. 6.777J / 2.372J is an introduction to microsystem design. Topics covered include: material properties, microfabrication technologies, structural behavior, sensing methods, fluid flow, microscale transport, noise, and amplifiers feedback systems. Student teams design microsystems (sensors, actuators, and sensing/control systems) of a variety of types, (e.g., optical MEMS, bioMEMS, inertial sensors) to meet a set of performance specifications (e.g., sensitivity, signal-to-noise) using a realistic microfabrication process. There is an emphasis on modeling and simulation in the design process. Prior fabrication experience is desirable. The course is worth 4 Engineering Design Points.

Subjects

microsystem design | microsystem design | material properties | material properties | microfabrication technologies | microfabrication technologies | structural behavior | structural behavior | sensing methods | sensing methods | fluid flow | fluid flow | microscale transport | microscale transport | noise | noise | amplifiers feedback systems | amplifiers feedback systems | sensors | sensors | actuators | actuators | sensing/control systems | sensing/control systems | optical MEMS | optical MEMS | bioMEMS | bioMEMS | inertial sensors | inertial sensors | sensitivity | sensitivity | signal-to-noise | signal-to-noise | realistic microfabrication process | realistic microfabrication process

License

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4.510 Digital Design Fabrication (MIT)

Description

This class serves as an introductory subject in advanced computing, rapid prototyping, and CAD/CAM fabrication for architects. It focuses on the relationship between design and various forms of computer modeling as input, and CAD/CAM tools as output material. It presents the process of design and construction using CAD files introduced by the office of Gehry Partners during the construction of the Guggenheim Museum in Bilbao, Spain. It is taught in phases starting with rapid prototyping and ending with digital mockups of building components fabricated from CAD files on a one-to-one scale.

Subjects

architectural design and computation | computer modeling | rendering | digital fabrication | exploration of space | place making | computer rendering | design construction | CAD/CAM fabrication | computer models | computer aided drawings | rapid prototyped models | architecture | design | computation | CAD CAM fabrication

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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6.152J Microelectronics Processing Technology (MIT)

Description

This course introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions focus on basic processing techniques such as diffusion, oxidation, photolithography, chemical vapor deposition, and more. Through team lab assignments, students are expected to gain an understanding of these processing techniques, and how they are applied in concert to device fabrication. Students enrolled in this course have a unique opportunity to fashion and test micro/nano-devices, using modern techniques and technology.

Subjects

microelectronics | Microelectronics processing | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | integrated circuits;vacuum;chemical vapor deposition;CVD;oxidation;diffusion;implantation;lithography;soft lithography;etching;sputtering;evaporation;interconnect;metallization;crystal growth;reliability;fabrication;processing;photolithography;physical vapor deposition;MOS;MOS capacitor;microcantilever;microfluidic | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | 6.152 | 3.155

License

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4.510 Digital Design Fabrication (MIT)

Description

This course will guide graduate students through the process of using rapid prototyping and CAD/CAM devices in a studio environment. The class has a theoretical focus on machine use within the process of design. Each student is expected to have completed one graduate level of design computing with a full understanding of solid modeling in CAD. Students are also expected to have completed at least one graduate design studio.

Subjects

digital fabrication | design | cad | cam | digital manufacturing | assembly | design geometry | fabrication | drafting | modeling | printing | waterjet cutting | cnc manufacturing | generative fabrication | construction grammars | prototyping | boston water taxi

License

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2.72 Elements of Mechanical Design (MIT) 2.72 Elements of Mechanical Design (MIT)

Description

This course provides an advanced treatment of machine elements such as bearings, springs, gears, cams, and mechanisms. Analysis of these elements includes extensive application of core engineering curriculum including solid mechanics and fluid dynamics. The course offers practice in skills needed for machine design such as estimation, drawing, and experimentation. Students work in small teams to design and build machines that address real-world challenges. This course provides an advanced treatment of machine elements such as bearings, springs, gears, cams, and mechanisms. Analysis of these elements includes extensive application of core engineering curriculum including solid mechanics and fluid dynamics. The course offers practice in skills needed for machine design such as estimation, drawing, and experimentation. Students work in small teams to design and build machines that address real-world challenges.

Subjects

machine design | machine design | hardware | hardware | project | project | machine element | machine element | design process | design process | design layout | design layout | prototype | prototype | mechanism | mechanism | engineering | engineering | fabrication | fabrication

License

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3.91J Mechanical Behavior of Plastics (MIT) 3.91J Mechanical Behavior of Plastics (MIT)

Description

Relation among chemical composition, physical structure, and mechanical behavior of plastics or synthetic high polymers. Study of types of polymers; fundamentals of viscoelastic phenomena such as creep, stress relaxation, stress rupture, mechanical damping, impact; effects of chemical composition and structure on viscoelastic and strength properties; methods of mechanical property evaluation. Influences of plastics fabrication methods. Emphasis on recent research techniques and results. Individual laboratory projects investigating problems related to current research. Relation among chemical composition, physical structure, and mechanical behavior of plastics or synthetic high polymers. Study of types of polymers; fundamentals of viscoelastic phenomena such as creep, stress relaxation, stress rupture, mechanical damping, impact; effects of chemical composition and structure on viscoelastic and strength properties; methods of mechanical property evaluation. Influences of plastics fabrication methods. Emphasis on recent research techniques and results. Individual laboratory projects investigating problems related to current research.

Subjects

plastics | | plastics | | synthetic high polymers | | synthetic high polymers | | viscoelastic phenomena | | viscoelastic phenomena | | viscoelastic and strength properties | | viscoelastic and strength properties | | mechanical property evaluation | | mechanical property evaluation | | plastics fabrication methods | plastics fabrication methods | plastics | plastics | synthetic high polymers | synthetic high polymers | viscoelastic phenomena | viscoelastic phenomena | viscoelastic and strength properties | viscoelastic and strength properties | mechanical property evaluation | mechanical property evaluation | 3.91 | 3.91 | 1.593 | 1.593

License

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22.351 Systems Analysis of the Nuclear Fuel Cycle (MIT) 22.351 Systems Analysis of the Nuclear Fuel Cycle (MIT)

Description

In-depth technical and policy analysis of various options for the nuclear fuel cycle. Topics include uranium supply, enrichment fuel fabrication, in-core physics and fuel management of uranium, thorium and other fuel types, reprocessing and waste disposal. Principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors are presented. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of actinides and selected fission products in spent fuel are examined. Several state-of-the-art computer programs are provided for student use in problem sets and term papers. In-depth technical and policy analysis of various options for the nuclear fuel cycle. Topics include uranium supply, enrichment fuel fabrication, in-core physics and fuel management of uranium, thorium and other fuel types, reprocessing and waste disposal. Principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors are presented. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of actinides and selected fission products in spent fuel are examined. Several state-of-the-art computer programs are provided for student use in problem sets and term papers.

Subjects

nuclear fuel cycle | nuclear fuel cycle | uranium supply | uranium supply | enrichment fuel fabrication | enrichment fuel fabrication | in-core physics | in-core physics | fuel cycle economics | fuel cycle economics | applied reactor physics | applied reactor physics | Nonproliferation aspects | Nonproliferation aspects | disposal of excess weapons plutonium | disposal of excess weapons plutonium | transmutation of actinides | transmutation of actinides | fission products | fission products | spent fuel | spent fuel

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4.500 Introduction to Design Computing (MIT) 4.500 Introduction to Design Computing (MIT)

Description

This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, 3-D modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations with computers. Each semester we will explore the design process of a particular building type and building material. The course also investigates a few design processes of selected architects. The course is critical of design principles and building production methods. Student assignments are graded based on the quality of design, representation and constructability. Great design input is always encouraged. This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, 3-D modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations with computers. Each semester we will explore the design process of a particular building type and building material. The course also investigates a few design processes of selected architects. The course is critical of design principles and building production methods. Student assignments are graded based on the quality of design, representation and constructability. Great design input is always encouraged.

Subjects

architectural design and computation | architectural design and computation | computer modeling | computer modeling | rendering | rendering | digital fabrication | digital fabrication | exploration of space | exploration of space | place | place

License

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4.131 Architectural Design, Level II: Material Essence: The Glass House (MIT) 4.131 Architectural Design, Level II: Material Essence: The Glass House (MIT)

Description

The theme that unites the Level II studios in the fall semester is a focus upon the 'making of architecture and built form' as a tectonic, technical and materially driven endeavor. It is a design investigation that is rooted in a larger culture of materiality and the associated phenomena, but a study of the language and production of built form as an integrated response to the conceptual proposition of the project. The studio will look to works of architecture where the material tectonic and its resultant technology or fabrication become instrumental to the realization of the ideas, in whatever form they may take. This becomes the 'art of technology' -- suggesting a level of innovation and creative manipulation as part of the design process to transform material into a composition of b The theme that unites the Level II studios in the fall semester is a focus upon the 'making of architecture and built form' as a tectonic, technical and materially driven endeavor. It is a design investigation that is rooted in a larger culture of materiality and the associated phenomena, but a study of the language and production of built form as an integrated response to the conceptual proposition of the project. The studio will look to works of architecture where the material tectonic and its resultant technology or fabrication become instrumental to the realization of the ideas, in whatever form they may take. This becomes the 'art of technology' -- suggesting a level of innovation and creative manipulation as part of the design process to transform material into a composition of b

Subjects

architecture | architecture | tectonics | tectonics | materials | materials | relationships | relationships | interventions | interventions | physics | physics | place and space | place and space | wellesley campus | wellesley campus | thomson island | thomson island | glass | glass | structures | structures | advanced design | advanced design | rapid prototyping | rapid prototyping | environmental control | environmental control | "art of technology" | "art of technology" | fabrication | fabrication | design from detailing | design from detailing | built form | built form | technical | technical | design investigation | design investigation | materiality | materiality | art of technology | art of technology | glasshouse | glasshouse

License

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1.101 Introduction to Civil and Environmental Engineering Design I (MIT) 1.101 Introduction to Civil and Environmental Engineering Design I (MIT)

Description

This sophomore-level course is a project-oriented introduction to the principles and practice of engineering design. Design projects and exercises are chosen that relate to the built and natural environments. Emphasis is placed on achieving function and sustainability through choice of materials and processes, compatibility with natural cycles, and the use of active or adaptive systems. The course also encourages development of hands-on skills, teamwork, and communication; exercises and projects engage students in the building, implementation, and testing of their designs. This sophomore-level course is a project-oriented introduction to the principles and practice of engineering design. Design projects and exercises are chosen that relate to the built and natural environments. Emphasis is placed on achieving function and sustainability through choice of materials and processes, compatibility with natural cycles, and the use of active or adaptive systems. The course also encourages development of hands-on skills, teamwork, and communication; exercises and projects engage students in the building, implementation, and testing of their designs.

Subjects

Design | Design | water resources | water resources | water treatment | water treatment | structures | structures | structural design | structural design | fabrication | fabrication | testing | testing | hardware | hardware | laboratory experiments | laboratory experiments | pH | pH | neutralization | neutralization | hydraulic conductivity | hydraulic conductivity | porosity | porosity | truss | truss | tension | tension | beam bending | beam bending | beam buckling | beam buckling | thermal design | thermal design | heating | heating | cooling | cooling | thermal infrared camera | thermal infrared camera | thermal IR imaging | thermal IR imaging | heat loss | heat loss

License

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2.019 Design of Ocean Systems (MIT) 2.019 Design of Ocean Systems (MIT)

Description

This course covers the complete cycle of designing an ocean system using computational design tools for the conceptual and preliminary design stages. Students complete the projects in teams with each student responsible for a specific subsystem. Lectures cover such topics as hydrodynamics; structures; power and thermal aspects of ocean vehicles; environment, materials, and construction for ocean use; and generation and evaluation of design alternatives. The course focuses on innovative design concepts chosen from high-speed ships, submersibles, autonomous vehicles, and floating and submerged deep-water offshore platforms. Lectures on ethics in engineering practice are included, and instruction and practice in oral and written communication is provided. This course covers the complete cycle of designing an ocean system using computational design tools for the conceptual and preliminary design stages. Students complete the projects in teams with each student responsible for a specific subsystem. Lectures cover such topics as hydrodynamics; structures; power and thermal aspects of ocean vehicles; environment, materials, and construction for ocean use; and generation and evaluation of design alternatives. The course focuses on innovative design concepts chosen from high-speed ships, submersibles, autonomous vehicles, and floating and submerged deep-water offshore platforms. Lectures on ethics in engineering practice are included, and instruction and practice in oral and written communication is provided.

Subjects

ocean environment | ocean environment | seakeeping | seakeeping | hydrodynamics | hydrodynamics | mooring dynamics | mooring dynamics | propulsion and power | propulsion and power | structural dynamics | structural dynamics | manufacturing and fabrication | manufacturing and fabrication | floating offshore structures | floating offshore structures | design process | design process | group dynamics | group dynamics | ethics in engineering practice | ethics in engineering practice

License

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2.72 Elements of Mechanical Design (MIT) 2.72 Elements of Mechanical Design (MIT)

Description

This is an advanced course on modeling, design, integration and best practices for use of machine elements such as bearings, springs, gears, cams and mechanisms. Modeling and analysis of these elements is based upon extensive application of physics, mathematics and core mechanical engineering principles (solid mechanics, fluid mechanics, manufacturing, estimation, computer simulation, etc.). These principles are reinforced via (1) hands-on laboratory experiences wherein students conduct experiments and disassemble machines and (2) a substantial design project wherein students model, design, fabricate and characterize a mechanical system that is relevant to a real world application. Students master the materials via problems sets that are directly related to, and coordinated with, the deliv This is an advanced course on modeling, design, integration and best practices for use of machine elements such as bearings, springs, gears, cams and mechanisms. Modeling and analysis of these elements is based upon extensive application of physics, mathematics and core mechanical engineering principles (solid mechanics, fluid mechanics, manufacturing, estimation, computer simulation, etc.). These principles are reinforced via (1) hands-on laboratory experiences wherein students conduct experiments and disassemble machines and (2) a substantial design project wherein students model, design, fabricate and characterize a mechanical system that is relevant to a real world application. Students master the materials via problems sets that are directly related to, and coordinated with, the deliv

Subjects

biology | biology | chemistry | chemistry | synthetic biology | synthetic biology | project | project | biotech | biotech | genetic engineering | genetic engineering | GMO | GMO | ethics | ethics | biomedical ethics | biomedical ethics | genetics | genetics | recombinant DNA | recombinant DNA | DNA | DNA | gene sequencing | gene sequencing | gene synthesis | gene synthesis | biohacking | biohacking | computational biology | computational biology | iGEM | iGEM | BioBrick | BioBrick | systems biology | systems biology | machine design | machine design | hardware | hardware | machine element | machine element | design process | design process | design layout | design layout | prototype | prototype | mechanism | mechanism | engineering | engineering | fabrication | fabrication | lathe | lathe | precision engineering | precision engineering | group project | group project | project management | project management | CAD | CAD | fatigue | fatigue | Gantt chart | Gantt chart

License

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2.76 Multi-Scale System Design (MIT) 2.76 Multi-Scale System Design (MIT)

Description

Multi-scale systems (MuSS) consist of components from two or more length scales (nano, micro, meso, or macro-scales). In MuSS, the engineering modeling, design principles, and fabrication processes of the components are fundamentally different. The challenge is to make these components so they are conceptually and model-wise compatible with other-scale components with which they interface. This course covers the fundamental properties of scales, design theories, modeling methods and manufacturing issues which must be addressed in these systems. Examples of MuSS include precision instruments, nanomanipulators, fiber optics, micro/nano-photonics, nanorobotics, MEMS (piezoelectric driven manipulators and optics), X-Ray telescopes and carbon nano-tube assemblies. Students master the materials Multi-scale systems (MuSS) consist of components from two or more length scales (nano, micro, meso, or macro-scales). In MuSS, the engineering modeling, design principles, and fabrication processes of the components are fundamentally different. The challenge is to make these components so they are conceptually and model-wise compatible with other-scale components with which they interface. This course covers the fundamental properties of scales, design theories, modeling methods and manufacturing issues which must be addressed in these systems. Examples of MuSS include precision instruments, nanomanipulators, fiber optics, micro/nano-photonics, nanorobotics, MEMS (piezoelectric driven manipulators and optics), X-Ray telescopes and carbon nano-tube assemblies. Students master the materials

Subjects

scale | scale | complexity | complexity | nano | micro | meso | or macro-scale | nano | micro | meso | or macro-scale | kinematics | kinematics | metrology | metrology | engineering modeling | motion | engineering modeling | motion | modeling | modeling | design | design | manufacture | manufacture | design principles | design principles | fabrication process | fabrication process | functional requirements | functional requirements | precision instruments | precision instruments | nanomanipulators | fiber optics | micro- photonics | nano-photonics | nanorobotics | MEMS | nanomanipulators | fiber optics | micro- photonics | nano-photonics | nanorobotics | MEMS | piezoelectric | transducer | actuator | sensor | piezoelectric | transducer | actuator | sensor | constraint | rigid constraint | flexible constraint | ride-flexible constraint | constraint | rigid constraint | flexible constraint | ride-flexible constraint | constaint-based design | constaint-based design | carbon nanotube | carbon nanotube | nanowire | nanowire | scanning tunneling microscope | scanning tunneling microscope | flexure | flexure | protein structure | protein structure | polymer structure | polymer structure | nanopelleting | nanopipette | nanowire | nanopelleting | nanopipette | nanowire | TMA pixel array | TMA pixel array | error modeling | error modeling | repeatability | repeatability

License

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3.042 Materials Project Laboratory (MIT) 3.042 Materials Project Laboratory (MIT)

Description

As its name implies, the 3.042 Materials Project Laboratory involves working with such operations as investment casting of metals, injection molding of polymers, and sintering of ceramics. After all the abstraction and theory in the lecture part of the DMSE curriculum, many students have found this hands-on experience with materials to be very fun stuff - several have said that 3.042/3.082 was their favorite DMSE subject. The lab is more than operating processing equipment, however. It is intended also to emulate professional practice in materials engineering project management, with aspects of design, analysis, teamwork, literature and patent searching, Web creation and oral presentation, and more. As its name implies, the 3.042 Materials Project Laboratory involves working with such operations as investment casting of metals, injection molding of polymers, and sintering of ceramics. After all the abstraction and theory in the lecture part of the DMSE curriculum, many students have found this hands-on experience with materials to be very fun stuff - several have said that 3.042/3.082 was their favorite DMSE subject. The lab is more than operating processing equipment, however. It is intended also to emulate professional practice in materials engineering project management, with aspects of design, analysis, teamwork, literature and patent searching, Web creation and oral presentation, and more.

Subjects

Student project teams design and fabricate a materials engineering prototype using processing technologies (injection molding | Student project teams design and fabricate a materials engineering prototype using processing technologies (injection molding | thermoforming | thermoforming | investment casting | investment casting | powder processing | powder processing | three-dimensional printing | three-dimensional printing | physical vapor deposition | physical vapor deposition | etc.) appropriate for the materials and device of interest. Goals include using MSE fundamentals in a practical application; understanding trade-offs between design | etc.) appropriate for the materials and device of interest. Goals include using MSE fundamentals in a practical application; understanding trade-offs between design | processing and performance; and fabrication of a deliverable prototype. Emphasis on teamwork | processing and performance; and fabrication of a deliverable prototype. Emphasis on teamwork | project management | project management | communications and computer skills | communications and computer skills | and hands-on work using student and MIT laboratory shops. Teams document their progress and final results by means of web pages and weekly oral presentations. Instruction and practice in oral communication provided. | and hands-on work using student and MIT laboratory shops. Teams document their progress and final results by means of web pages and weekly oral presentations. Instruction and practice in oral communication provided.

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