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6.374 Analysis and Design of Digital Integrated Circuits (MIT) 6.374 Analysis and Design of Digital Integrated Circuits (MIT)

Description

6.374 examines the device and circuit level optimization of digital building blocks. Topics covered include: MOS device models including Deep Sub-Micron effects; circuit design styles for logic, arithmetic and sequential blocks; estimation and minimization of energy consumption; interconnect models and parasitics; device sizing and logical effort; timing issues (clock skew and jitter) and active clock distribution techniques; memory architectures, circuits (sense amplifiers) and devices; testing of integrated circuits. The course employs extensive use of circuit layout and SPICE in design projects and software labs. 6.374 examines the device and circuit level optimization of digital building blocks. Topics covered include: MOS device models including Deep Sub-Micron effects; circuit design styles for logic, arithmetic and sequential blocks; estimation and minimization of energy consumption; interconnect models and parasitics; device sizing and logical effort; timing issues (clock skew and jitter) and active clock distribution techniques; memory architectures, circuits (sense amplifiers) and devices; testing of integrated circuits. The course employs extensive use of circuit layout and SPICE in design projects and software labs.

Subjects

digital integrated circuit | device | circuit | digital | MOS | digital integrated circuit | device | circuit | digital | MOS | digital integrated circuit | digital integrated circuit | device | device | circuit | circuit | digital | digital | MOS | MOS | Deep Sub-Micron effects | Deep Sub-Micron effects | circuit design | circuit design | logic | logic | interconnect models; parasitics | interconnect models; parasitics | device sizing | device sizing | timing | timing | clock skew | clock skew | jitter; clock distribution techniques | jitter; clock distribution techniques | memory architectures | memory architectures | circuits | circuits | sense amplifiers | sense amplifiers | SPICE | SPICE | HSPICE | HSPICE | Magic | Magic | Nanosim | Nanosim | Avanwaves | Avanwaves | device level optimization | device level optimization | interconnect models | interconnect models | parasitics | parasitics | jitter | jitter | clock distribution techniques | clock distribution techniques | CMOS inverter | CMOS inverter | combinational logic | combinational logic | sequential circuits | sequential circuits

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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ónica ónica

Description

Este curso permitirá a los estudiantes entrar en contacto con la tecnología actual de los circuitos integrados, principalmente dispositivos digitales. No sólo se tratan en profundidad los aspectos relacionados con la fabricación, encapsulado y con soluciones modernas de mejora de prestaciones y fiabilidad de este tipo de circuitos, sino que también se presenta una metodología de diseño junto con los útiles necesarios para obtener circuitos integrados digitales competitivos, tales como lenguajes de descripción hardware, herramientas de síntesis, diseño para testabilidad, etc. Este curso permitirá a los estudiantes entrar en contacto con la tecnología actual de los circuitos integrados, principalmente dispositivos digitales. No sólo se tratan en profundidad los aspectos relacionados con la fabricación, encapsulado y con soluciones modernas de mejora de prestaciones y fiabilidad de este tipo de circuitos, sino que también se presenta una metodología de diseño junto con los útiles necesarios para obtener circuitos integrados digitales competitivos, tales como lenguajes de descripción hardware, herramientas de síntesis, diseño para testabilidad, etc.

Subjects

álisis y diseño de circuitos integrados | álisis y diseño de circuitos integrados | ño vhdl | ño vhdl | ón y encapsulado de circuitos | ón y encapsulado de circuitos | ía de Telecomunicación | ía de Telecomunicación | 2011 | 2011 | circuitos combinacionales | circuitos combinacionales | Tecnologia Electronica | Tecnologia Electronica | circuitos integrados | circuitos integrados | lenguaje vhdl | lenguaje vhdl | circuitos secuenciales | circuitos secuenciales | test de circuitos integrados | test de circuitos integrados

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Copyright 2015, UC3M http://creativecommons.org/licenses/by-nc-sa/4.0/

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6.301 Solid-State Circuits (MIT) 6.301 Solid-State Circuits (MIT)

Description

6.301 is a course in analog circuit analysis and design. We cover the tools and methods necessary for the creative design of useful circuits using active devices. The class stresses insight and intuition, applied to the design of transistor circuits and the estimation of their performance. We concentrate on circuits using the bipolar junction transistor, but the techniques that we study can be equally applied to circuits using JFETs, MOSFETs, MESFETs, future exotic devices, or even vacuum tubes. 6.301 is a course in analog circuit analysis and design. We cover the tools and methods necessary for the creative design of useful circuits using active devices. The class stresses insight and intuition, applied to the design of transistor circuits and the estimation of their performance. We concentrate on circuits using the bipolar junction transistor, but the techniques that we study can be equally applied to circuits using JFETs, MOSFETs, MESFETs, future exotic devices, or even vacuum tubes.

Subjects

analog circuits | analog circuits | circuit analysis | circuit analysis | circuit design | circuit design | transistor circuits | transistor circuits | bipolar junction transistor | bipolar junction transistor | op amps | op amps | charge control | charge control | open circuit time constants | open circuit time constants

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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EC.S06 Practical Electronics (MIT) EC.S06 Practical Electronics (MIT)

Description

You can build a wide range of practical electronic devices if you understand a few basic electronics concepts and follow some simple rules. These devices include light-activated and sound-activated toys and appliances, remote controls, timers and clocks, and motorized devices. The subject begins with an overview of the fundamental concepts, followed by a series of laboratory exercises that demonstrate the basic rules, and a final project. You can build a wide range of practical electronic devices if you understand a few basic electronics concepts and follow some simple rules. These devices include light-activated and sound-activated toys and appliances, remote controls, timers and clocks, and motorized devices. The subject begins with an overview of the fundamental concepts, followed by a series of laboratory exercises that demonstrate the basic rules, and a final project.

Subjects

Electronics | Electronics | circuit | circuit | analog circuits | analog circuits | testing circuits | testing circuits | bridge circuits | bridge circuits | passive components | passive components | resistors | resistors | diodes | diodes | capacitors | capacitors | filters | filters | flip-flops | flip-flops | relays | relays | transistors | transistors | switches | switches | rectifiers | rectifiers | function generators | function generators | comparators | comparators | operational amplifiers | operational amplifiers | op-amps | op-amps | timing circuits | timing circuits | sensors | sensors | actuators | actuators | electronics | electronics | SP.764 | SP.764 | SP.765 | SP.765

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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6.301 Solid-State Circuits (MIT) 6.301 Solid-State Circuits (MIT)

Description

This course covers analog circuit analysis and design, focusing on the tools and methods necessary for the creative design of useful circuits using active devices. The class stresses insight and intuition, applied to the design of transistor circuits and the estimation of their performance. The course concentrates on circuits using the bipolar junction transistor, but the techniques that are studied can be equally applied to circuits using JFETs, MOSFETs, MESFETs, future exotic devices, or even vacuum tubes. This course covers analog circuit analysis and design, focusing on the tools and methods necessary for the creative design of useful circuits using active devices. The class stresses insight and intuition, applied to the design of transistor circuits and the estimation of their performance. The course concentrates on circuits using the bipolar junction transistor, but the techniques that are studied can be equally applied to circuits using JFETs, MOSFETs, MESFETs, future exotic devices, or even vacuum tubes.

Subjects

solid state circuits | solid state circuits | analog | analog | circuit | circuit | transistor | transistor | bipolar junction transistor | bipolar junction transistor | JFET | JFET | MOSFET | MOSFET | MESFET | MESFET | vacuum tubes | vacuum tubes | single-transistor common-emitter amplifier | single-transistor common-emitter amplifier | op amps | op amps | multipliers | multipliers | references | references | high speed logic | high speed logic | high-frequency analysis | high-frequency analysis | open-circuit time constants | open-circuit time constants | transimpedance amps | transimpedance amps | translinear circuits | translinear circuits | bandgap references | bandgap references | charge control model | charge control model

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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Integrated Circuits and Microelectronics Integrated Circuits and Microelectronics

Description

This course introduces to the students the current integrated circuits tecnologies, mainly for digital devices. During this course it will be studied in detail aspects related with manufacturing, packaging and modern solutions for performance and reliability improvements, as well as a design methodology with the necessary tools for obtaining competitive digital integrated circuits, such as hardware description languages, synthesis tools, design for testability, etc. This course introduces to the students the current integrated circuits tecnologies, mainly for digital devices. During this course it will be studied in detail aspects related with manufacturing, packaging and modern solutions for performance and reliability improvements, as well as a design methodology with the necessary tools for obtaining competitive digital integrated circuits, such as hardware description languages, synthesis tools, design for testability, etc.

Subjects

Design of basic combinational circuits | Design of basic combinational circuits | Design simulation | Design simulation | ía Técnica Industrial: Electrónica Industrial | ía Técnica Industrial: Electrónica Industrial | VHDL language | VHDL language | Analysis and design | Analysis and design | Microelectronics | Microelectronics | Design of secuential circuits | Design of secuential circuits | Tecnologia Electronica | Tecnologia Electronica | Manufacturing and packaging | Manufacturing and packaging | Integrated circuits test | Integrated circuits test | 2011 | 2011 | Integrated Circuits | Integrated Circuits | Analog integrated circuits | Analog integrated circuits

License

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6.374 Analysis and Design of Digital Integrated Circuits (MIT)

Description

6.374 examines the device and circuit level optimization of digital building blocks. Topics covered include: MOS device models including Deep Sub-Micron effects; circuit design styles for logic, arithmetic and sequential blocks; estimation and minimization of energy consumption; interconnect models and parasitics; device sizing and logical effort; timing issues (clock skew and jitter) and active clock distribution techniques; memory architectures, circuits (sense amplifiers) and devices; testing of integrated circuits. The course employs extensive use of circuit layout and SPICE in design projects and software labs.

Subjects

digital integrated circuit | device | circuit | digital | MOS | digital integrated circuit | device | circuit | digital | MOS | Deep Sub-Micron effects | circuit design | logic | interconnect models; parasitics | device sizing | timing | clock skew | jitter; clock distribution techniques | memory architectures | circuits | sense amplifiers | SPICE | HSPICE | Magic | Nanosim | Avanwaves | device level optimization | interconnect models | parasitics | jitter | clock distribution techniques | CMOS inverter | combinational logic | sequential circuits

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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6.374 Analysis and Design of Digital Integrated Circuits (MIT)

Description

6.374 examines the device and circuit level optimization of digital building blocks. Topics covered include: MOS device models including Deep Sub-Micron effects; circuit design styles for logic, arithmetic and sequential blocks; estimation and minimization of energy consumption; interconnect models and parasitics; device sizing and logical effort; timing issues (clock skew and jitter) and active clock distribution techniques; memory architectures, circuits (sense amplifiers) and devices; testing of integrated circuits. The course employs extensive use of circuit layout and SPICE in design projects and software labs.

Subjects

digital integrated circuit | device | circuit | digital | MOS | digital integrated circuit | device | circuit | digital | MOS | Deep Sub-Micron effects | circuit design | logic | interconnect models; parasitics | device sizing | timing | clock skew | jitter; clock distribution techniques | memory architectures | circuits | sense amplifiers | SPICE | HSPICE | Magic | Nanosim | Avanwaves | device level optimization | interconnect models | parasitics | jitter | clock distribution techniques | CMOS inverter | combinational logic | sequential circuits

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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6.374 Analysis and Design of Digital Integrated Circuits (MIT)

Description

6.374 examines the device and circuit level optimization of digital building blocks. Topics covered include: MOS device models including Deep Sub-Micron effects; circuit design styles for logic, arithmetic and sequential blocks; estimation and minimization of energy consumption; interconnect models and parasitics; device sizing and logical effort; timing issues (clock skew and jitter) and active clock distribution techniques; memory architectures, circuits (sense amplifiers) and devices; testing of integrated circuits. The course employs extensive use of circuit layout and SPICE in design projects and software labs.

Subjects

digital integrated circuit | device | circuit | digital | MOS | digital integrated circuit | device | circuit | digital | MOS | Deep Sub-Micron effects | circuit design | logic | interconnect models; parasitics | device sizing | timing | clock skew | jitter; clock distribution techniques | memory architectures | circuits | sense amplifiers | SPICE | HSPICE | Magic | Nanosim | Avanwaves | device level optimization | interconnect models | parasitics | jitter | clock distribution techniques | CMOS inverter | combinational logic | sequential circuits

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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6.004 Computation Structures (MIT) 6.004 Computation Structures (MIT)

Description

6.004 offers an introduction to the engineering of digital systems. Starting with MOS transistors, the course develops a series of building blocks - logic gates, combinational and sequential circuits, finite-state machines, computers and finally complete systems. Both hardware and software mechanisms are explored through a series of design examples.6.004 is required material for any EECS undergraduate who wants to understand (and ultimately design) digital systems. A good grasp of the material is essential for later courses in digital design, computer architecture and systems. Before taking 6.004, students should feel comfortable using computers; a rudimentary knowledge of programming language concepts (6.001) and electrical fundamentals (6.002) is assumed. 6.004 offers an introduction to the engineering of digital systems. Starting with MOS transistors, the course develops a series of building blocks - logic gates, combinational and sequential circuits, finite-state machines, computers and finally complete systems. Both hardware and software mechanisms are explored through a series of design examples.6.004 is required material for any EECS undergraduate who wants to understand (and ultimately design) digital systems. A good grasp of the material is essential for later courses in digital design, computer architecture and systems. Before taking 6.004, students should feel comfortable using computers; a rudimentary knowledge of programming language concepts (6.001) and electrical fundamentals (6.002) is assumed.

Subjects

computation | computation | computation structure | computation structure | primitives | primitives | gates | gates | nstructions | nstructions | procedures | procedures | processes | processes | concurrency | concurrency | instruction set design | instruction set design | software structure | software structure | digital system | digital system | MOS transistor | MOS transistor | logic gate | logic gate | combinational circuit | combinational circuit | sequential circuit | | sequential circuit | | finite-state machines | finite-state machines | sequential circuit | sequential circuit | computer architecture | computer architecture | programming | programming | RISC processor | RISC processor | instructions | instructions

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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6.012 Microelectronic Devices and Circuits (MIT) 6.012 Microelectronic Devices and Circuits (MIT)

Description

6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is worth 4 Engineering Design Points. 6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is worth 4 Engineering Design Points.

Subjects

microelectronic device | microelectronic device | circuit | circuit | design | design | physical electronics | physical electronics | semiconductor junction | semiconductor junction | MOS device | MOS device | electrical behavior | electrical behavior | incremental technique | incremental technique | large-signal technique | large-signal technique | bipolar transistor | bipolar transistor | field effect transistor | field effect transistor | digital circuit | digital circuit | single-ended amplifier | single-ended amplifier | differential linear amplifier | differential linear amplifier | integrated circuit | integrated circuit

License

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6.071 Introduction to Electronics (MIT) 6.071 Introduction to Electronics (MIT)

Description

Subject 6.071, a lab-based course, provides undergraduate students with both a basic and practical undertanding of electricity and electronics. The emphasis is on applications rather than theory. Consequently there is a strong hands-on component to the subject to enable students to gain practical experience. Topics covered in the subject include:DC and AC circuitsDiodes, transistors, operational amplifierAnalog and digital electronicsDetectors and transducersElectronic controlSignal processing and noiseThe focus of the subject is understanding the critical issues involved in assembling and using an array of electronic equipment to carry out various missions. Thus, there is more emphasis on the application as opposed to design. The breadth of topics covered in 6.071 makes this a good choice Subject 6.071, a lab-based course, provides undergraduate students with both a basic and practical undertanding of electricity and electronics. The emphasis is on applications rather than theory. Consequently there is a strong hands-on component to the subject to enable students to gain practical experience. Topics covered in the subject include:DC and AC circuitsDiodes, transistors, operational amplifierAnalog and digital electronicsDetectors and transducersElectronic controlSignal processing and noiseThe focus of the subject is understanding the critical issues involved in assembling and using an array of electronic equipment to carry out various missions. Thus, there is more emphasis on the application as opposed to design. The breadth of topics covered in 6.071 makes this a good choice

Subjects

digital circuits | digital circuits | transistor circuits | transistor circuits | diode circuits | diode circuits | AM and FM modulation | AM and FM modulation | transients | transients | op-amps | op-amps

License

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6.012 Microelectronic Devices and Circuits (MIT) 6.012 Microelectronic Devices and Circuits (MIT)

Description

6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is 12 units and is worth 4 Engineering Design Points. 6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is 12 units and is worth 4 Engineering Design Points.

Subjects

microelectronic device | microelectronic device | circuit | circuit | design | design | physical electronics | physical electronics | semiconductor junction | semiconductor junction | MOS device | MOS device | electrical behavior | electrical behavior | incremental technique | incremental technique | large-signal technique | large-signal technique | bipolar transistor | bipolar transistor | field effect transistor | field effect transistor | digital circuit | digital circuit | single-ended amplifier | single-ended amplifier | differential linear amplifier | differential linear amplifier | integrated circuit | integrated circuit

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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6.976 High Speed Communication Circuits and Systems (MIT) 6.976 High Speed Communication Circuits and Systems (MIT)

Description

6.976 covers circuit and system level design issues of high speed communication systems, with primary focus being placed on wireless and broadband data link applications. Specific circuit topics include transmission lines, high speed and low noise amplifiers, VCO's, and high speed digital circuits. Specific system topics include frequency synthesizers, clock and data recovery circuits, and GMSK transceivers. In addition to learning analysis skills for the above items, students will gain a significant amount of experience in simulating circuits in SPICE and systems in CppSim (a custom C++ simulator). 6.976 covers circuit and system level design issues of high speed communication systems, with primary focus being placed on wireless and broadband data link applications. Specific circuit topics include transmission lines, high speed and low noise amplifiers, VCO's, and high speed digital circuits. Specific system topics include frequency synthesizers, clock and data recovery circuits, and GMSK transceivers. In addition to learning analysis skills for the above items, students will gain a significant amount of experience in simulating circuits in SPICE and systems in CppSim (a custom C++ simulator).

Subjects

high speed communication circuits | high speed communication circuits | high speed communication systems | high speed communication systems | communication | communication | circuit | circuit | wireless | wireless | broadband | broadband | data link | data link | transistor level design | transistor level design | high speed amplifiers | high speed amplifiers | mixers | mixers | VCO's | VCO's | registers | registers | gates | gates | phase locked loops | phase locked loops | transmission line effects | transmission line effects | circuit design | circuit design | narrowband | narrowband | behavioral level simulation techniques | behavioral level simulation techniques

License

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2.996 Biomedical Devices Design Laboratory (MIT) 2.996 Biomedical Devices Design Laboratory (MIT)

Description

This course provides intensive coverage of the theory and practice of electromechanical instrument design with application to biomedical devices. Students will work with MGH doctors to develop new medical products from concept to prototype development and testing. Lectures will present techniques for designing electronic circuits as part of complete sensor systems. Topics covered include: basic electronics circuits, principles of accuracy, op amp circuits, analog signal conditioning, power supplies, microprocessors, wireless communications, sensors, and sensor interface circuits. Labs will cover practical printed circuit board (PCB) design including component selection, PCB layout, assembly, and planning and budgeting for large projects. Problem sets and labs in the first six weeks are in This course provides intensive coverage of the theory and practice of electromechanical instrument design with application to biomedical devices. Students will work with MGH doctors to develop new medical products from concept to prototype development and testing. Lectures will present techniques for designing electronic circuits as part of complete sensor systems. Topics covered include: basic electronics circuits, principles of accuracy, op amp circuits, analog signal conditioning, power supplies, microprocessors, wireless communications, sensors, and sensor interface circuits. Labs will cover practical printed circuit board (PCB) design including component selection, PCB layout, assembly, and planning and budgeting for large projects. Problem sets and labs in the first six weeks are in

Subjects

biomedical devices | biomedical devices | electrical engineering in medicine | electrical engineering in medicine | basic electronic circuits | basic electronic circuits | op amp | op amp | op amp circuits | op amp circuits | analog signal conditioning | analog signal conditioning | microprocessors | microprocessors | wireless communication | wireless communication | PCB design | PCB design | printed circuit board | printed circuit board | microprocessor programming | microprocessor programming

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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6.012 Microelectronic Devices and Circuits (MIT) 6.012 Microelectronic Devices and Circuits (MIT)

Description

6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is worth 4 Engineering Design Points. 6.012 is the header course for the department's "Devices, Circuits and Systems" concentration. The topics covered include: modeling of microelectronic devices, basic microelectronic circuit analysis and design, physical electronics of semiconductor junction and MOS devices, relation of electrical behavior to internal physical processes, development of circuit models, and understanding the uses and limitations of various models. The course uses incremental and large-signal techniques to analyze and design bipolar and field effect transistor circuits, with examples chosen from digital circuits, single-ended and differential linear amplifiers, and other integrated circuits. This course is worth 4 Engineering Design Points.

Subjects

microelectronic device | microelectronic device | circuit | circuit | design | design | physical electronics | physical electronics | semiconductor junction | semiconductor junction | MOS device | MOS device | electrical behavior | electrical behavior | incremental technique | incremental technique | large-signal technique | large-signal technique | bipolar transistor | bipolar transistor | field effect transistor | field effect transistor | digital circuit | digital circuit | single-ended amplifier | single-ended amplifier | differential linear amplifier | differential linear amplifier | integrated circuit | integrated circuit

License

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6.334 Power Electronics (MIT) 6.334 Power Electronics (MIT)

Description

6.334 examines the application of electronics to energy conversion and control. Topics covered include: phase-controlled rectifier/inverter circuits, DC/DC converters, high-frequency inverters, and motion control systems; characteristics of power semiconductor devices: diodes, bipolar and field effect transistors, IGBTS, and thyristors; modeling, analysis, and control techniques; magnetic circuits. Numerous application examples are covered. 6.334 examines the application of electronics to energy conversion and control. Topics covered include: phase-controlled rectifier/inverter circuits, DC/DC converters, high-frequency inverters, and motion control systems; characteristics of power semiconductor devices: diodes, bipolar and field effect transistors, IGBTS, and thyristors; modeling, analysis, and control techniques; magnetic circuits. Numerous application examples are covered.

Subjects

power electronics | power electronics | electronics | electronics | energy | energy | phase-controlled rectifier | phase-controlled rectifier | inverter circuits | inverter circuits | dc | dc | dc/dc converters | dc/dc converters | high-frequency inverters | high-frequency inverters | motion control systems | motion control systems | power semiconductors | power semiconductors | diodes | diodes | bipolar | bipolar | field effect transistors | field effect transistors | IGBTS | IGBTS | thyristors | thyristors | magnetic circuits | magnetic circuits | energy conversion | energy conversion | energy control | energy control | phas-controlled rectifier/invertor circuits | phas-controlled rectifier/invertor circuits | bipolar transistors | bipolar transistors | field effect transisitors | field effect transisitors | modeling | modeling | analysis | analysis | control techniques | control techniques | application | application

License

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Electronic Components and Circuits Electronic Components and Circuits

Description

Operating principle, models and applications of basic semiconductors electronic components (diodes, bipolar transistors and field effect transistors), including the bias circuits. In addition, the concepts related to electronic analog amplification stages (small signal gain, input and output impedances and frequency response). Finally, the characteristics of operational amplifiers (OA) as analog integrated circuits and some of the most important AO applications. Operating principle, models and applications of basic semiconductors electronic components (diodes, bipolar transistors and field effect transistors), including the bias circuits. In addition, the concepts related to electronic analog amplification stages (small signal gain, input and output impedances and frequency response). Finally, the characteristics of operational amplifiers (OA) as analog integrated circuits and some of the most important AO applications.

Subjects

polarization | polarization | Single-stage amplification circuits | Single-stage amplification circuits | electronic circuits analysis | electronic circuits analysis | semiconductor devices | semiconductor devices | Frequency response of transistor amplifier | Frequency response of transistor amplifier | electronic circuits | electronic circuits | ía Electrónica | ía Electrónica | Multi-stage amplifiers | Multi-stage amplifiers | electronic components | electronic components | Electronic Amplification | Electronic Amplification | Operational Amplifier | Operational Amplifier | 2010 | 2010 | ía de Sistemas Audiovisuales | ía de Sistemas Audiovisuales

License

Copyright 2015, UC3M http://creativecommons.org/licenses/by-nc-sa/4.0/

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Digital Electronics Digital Electronics

Description

The basic goal of this subject is to cover an introduction to digital electronics from an updated point of view. To this purpose, the course starts by the fundamentals, i.e., number systems, binary coding and Boolean Algebra. The study of digital circuits begins by logic gates, combinational circuits, including the simplest arithmetic circuits, and ends by sequential circuits, including latches and flip-flops, synchronous sequential circuits, registers and counters. There is one chapter devoted to memories and another one devoted to programmable logic devices. An introduction to digital systems and microprocessors is also included. The basic goal of this subject is to cover an introduction to digital electronics from an updated point of view. To this purpose, the course starts by the fundamentals, i.e., number systems, binary coding and Boolean Algebra. The study of digital circuits begins by logic gates, combinational circuits, including the simplest arithmetic circuits, and ends by sequential circuits, including latches and flip-flops, synchronous sequential circuits, registers and counters. There is one chapter devoted to memories and another one devoted to programmable logic devices. An introduction to digital systems and microprocessors is also included.

Subjects

Boolean Algebra | Boolean Algebra | ía de Sistemas Audiovisuales | ía de Sistemas Audiovisuales | Memories | Memories | ática | ática | ía Eléctrica | ía Eléctrica | ía en Tecnologías Industriales | ía en Tecnologías Industriales | Combinational circuits | Combinational circuits | ía Telemática | ía Telemática | Registers and counters | Registers and counters | Digital systems and microprocessors | Digital systems and microprocessors | Synchronous sequential circuits | Synchronous sequential circuits | 2011 | 2011 | ía Electrónica Industrial y Automática | ía Electrónica Industrial y Automática | ía en Tecnologías de Telecomunicación | ía en Tecnologías de Telecomunicación | ía de Sistemas de Comunicaciones | ía de Sistemas de Comunicaciones | Information representation | Information representation | logic gates | logic gates | Arithmetic combinational circuits | Arithmetic combinational circuits | Latches and Flip-flops | Latches and Flip-flops | Tecnologia Electronica | Tecnologia Electronica | Programmable Logic Devices (PLD) | Programmable Logic Devices (PLD)

License

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2.18 Biomolecular Feedback Systems (MIT) 2.18 Biomolecular Feedback Systems (MIT)

Description

This course focuses on feedback control mechanisms that living organisms implement at the molecular level to execute their functions, with emphasis on techniques to design novel systems with prescribed behaviors. Students will learn how biological functions can be understood and designed using notions from feedback control. This course focuses on feedback control mechanisms that living organisms implement at the molecular level to execute their functions, with emphasis on techniques to design novel systems with prescribed behaviors. Students will learn how biological functions can be understood and designed using notions from feedback control.

Subjects

biomolecular feedback systems | biomolecular feedback systems | systems biology | systems biology | modeling | modeling | feedback | feedback | cell | cell | system | system | control | control | dynamical | dynamical | input/output | input/output | synthetic biology | synthetic biology | techniques | techniques | transcription | transcription | translation | translation | transcriptional regulation | transcriptional regulation | post-transcriptional regulation | post-transcriptional regulation | cellular subsystems | cellular subsystems | dynamic behavior | dynamic behavior | analysis | analysis | equilibrium | equilibrium | robustness | robustness | oscillatory behavior | oscillatory behavior | bifurcations | bifurcations | model reduction | model reduction | stochastic | stochastic | biochemical | biochemical | simulation | simulation | linear | linear | circuit | circuit | design | design | biological circuit design | biological circuit design | negative autoregulation | negative autoregulation | toggle switch | toggle switch | repressilator | repressilator | activator-repressor clock | activator-repressor clock | IFFL | IFFL | incoherent feedforward loop | incoherent feedforward loop | bacterial chemotaxis | bacterial chemotaxis | interconnecting components | interconnecting components | modularity | modularity | retroactivity | retroactivity | gene circuit | gene circuit

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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EC.S06 Practical Electronics (MIT)

Description

You can build a wide range of practical electronic devices if you understand a few basic electronics concepts and follow some simple rules. These devices include light-activated and sound-activated toys and appliances, remote controls, timers and clocks, and motorized devices. The subject begins with an overview of the fundamental concepts, followed by a series of laboratory exercises that demonstrate the basic rules, and a final project.

Subjects

Electronics | circuit | analog circuits | testing circuits | bridge circuits | passive components | resistors | diodes | capacitors | filters | flip-flops | relays | transistors | switches | rectifiers | function generators | comparators | operational amplifiers | op-amps | timing circuits | sensors | actuators | electronics | SP.764 | SP.765

License

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SP.764 Practical Electronics (MIT)

Description

You can build a wide range of practical electronic devices if you understand a few basic electronics concepts and follow some simple rules. These devices include light-activated and sound-activated toys and appliances, remote controls, timers and clocks, and motorized devices. The subject begins with an overview of the fundamental concepts, followed by a series of laboratory exercises that demonstrate the basic rules, and a final project.

Subjects

Electronics | circuit | analog circuits | testing circuits | bridge circuits | passive components | resistors | diodes | capacitors | filters | flip-flops | relays | transistors | switches | rectifiers | function generators | comparators | operational amplifiers | op-amps | timing circuits | sensors | actuators | electronics

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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6.301 Solid-State Circuits (MIT)

Description

6.301 is a course in analog circuit analysis and design. We cover the tools and methods necessary for the creative design of useful circuits using active devices. The class stresses insight and intuition, applied to the design of transistor circuits and the estimation of their performance. We concentrate on circuits using the bipolar junction transistor, but the techniques that we study can be equally applied to circuits using JFETs, MOSFETs, MESFETs, future exotic devices, or even vacuum tubes.

Subjects

analog circuits | circuit analysis | circuit design | transistor circuits | bipolar junction transistor | op amps | charge control | open circuit time constants

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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