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MIT Circuits and Electronics - EE01电子电路课程
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班级规模及环境--热线:4008699035 手机:15921673576( 微信同号) |
每个班级的人数限3到5人,互动授课, 保障效果,小班授课。 |
上间和地点 |
上部份地点:【上海】同济大学(沪西)/新城金郡商务楼(11号线白银路站)【深圳分部】:电影大厦(地铁一号线大剧院站)/深圳大学成教院【北京分部】:北京中山学院/福鑫大楼【南京分部】:金港大厦(和燕路)【武汉分部】:佳源大厦(高新二路)【成都分部】:领馆区1号(中和大道)【沈阳分部】:沈阳理工大学/六宅臻品【郑州分部】:郑州大学/锦华大厦【石家庄分部】:河北科技大学/瑞景大厦 最近开间(周末班/连续班/晚班):2019年1月26日 |
实验设备 |
◆小班教学,教学效果好 ☆注重质量☆边讲边练 ☆合格学员免费推荐工作 ★实验设备请点击这儿查看★ |
质量保障 |
1、培训过程中,如有部分内容理解不透或消化不好,可免费在以后培训班中重听; 2、培训结束后,授课老师留给学员联系方式,保障培训效果,免费提供课后技术支持。 3、培训合格学员可享受免费推荐就业机会。☆合格学员免费颁发相关工程师等资格证书,提升职业资质。专注高端技术培训15年,端海学员的能力得到大家的认同,受到用人单位的广泛赞誉,端海的证书受到广泛认可。 |
部份程大纲 |
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Course Objectives
The subject aims to provide the student with:
An understanding of basic EE abstractions on which analysis and design of electrical and electronic circuits and systems are based, including lumped circuit, digital and operational amplifier abstractions.
The capability to use abstractions to analyze and design simple electronic circuits.
The ability to formulate and solve the differential equations describing time behavior of circuits containing energy storage elements.
An understanding of how complex devices such as semiconductor diodes and field-effect transistors are modeled and how the models are used in the design and analysis of useful circuits.
The capability to design and construct circuits, take measurements of circuit behavior and performance, compare with predicted circuit models and explain discrepancies.
What will you learn
Learn how to develop and employ circuit models for elementary electronic components, e.g., resistors, sources, inductors, capacitors, diodes and transistors;
Become adept at using various methods of circuit analysis, including simplified methods such as series-parallel reductions, voltage and current dividers, and the node method;
Appreciate the consequences of linearity, in particular the principle of superposition and Thevenin-Norton equivalent circuits;
Gain an intuitive understanding of the role of power flow and energy storage in electronic circuits;
Develop the capability to analyze and design simple circuits containing non-linear elements such as transistors using the concepts of load lines, operating points and incremental analysis;
Learn how the primitives of Boolean algebra are used to describe the processing of binary signals and to use electronic components such as MOSFET's as building blocks in electronically implementing binary functions;
Learn how the concept of noise margin is used to provide noise immunity in digital circuits;
Be introduced to the concept of state in a dynamical physical system and learn how to analyze simple first and second order linear circuits containing memory elements;
Be introduced to the concept of singularity functions and learn how to analyze simple circuits containing step and impulse sources;
Be introduced to the concept of sinusoidal-steady-state (SSS) and to use impedance methods to analyze the SSS response of first and second-order systems;
Learn how to calculate frequency response curves and to interpret the salient features in terms of poles and zeros of the system function;
Gain insight into the behavior of a physical system driven near resonance, in particular the relationship to the transient response and the significance of the quality factor Q;
Learn how operational amplifiers are modeled and analyzed, and to design Op-Amp circuits to perform operations such as integration, differentiation and filtering on electronic signals;
Be introduced to the concepts of both positive and negative feedback in electronic circuits;
Learn how negative feedback is used to stabilize the gain of an Op-Amp-based amplifier and how positive feedback can be used to design an oscillator;
Acquire experience in building and trouble-shooting simple electronic analog and digital circuits.
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