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電気回路学I

科目基礎情報

学校 熊本高等専門学校 開講年度 令和04年度 (2022年度)
授業科目 電気回路学I
科目番号 CI1302 科目区分 専門 / 必修
授業形態 授業 単位の種別と単位数 履修単位: 2
開設学科 制御情報システム工学科 対象学年 3
開設期 通年 週時間数 2
教科書/教材 Fundamentals of Electric Circuits, 6/e (Charles K. Alexander, Matthew N. O. Sadiku, McGraw-Hill Science Engineering)
担当教員 須田 隆夫

到達目標

This course aims that students can:
1) analyse DC circuits consists of passive elements.
2) express AC voltage/current in phasor form and/or complex form.
3) calculate power which is absorbed in circuits.
4) know methods of analysis, e.g. nodal analysis, mesh analysis and source transformation and apply them to analyse AC circuits.

ルーブリック

理想的な到達レベルの目安標準的な到達レベルの目安未到達レベルの目安
Basic lawsMethod of analysis(DC circuits and AC circuits)Students can solve advanced problems, e.g. Thevenin and Norton equivalent circuits, in the textbook.Students can solve examples of mesh/nodal analysis, superposision theorem, source transformation, Thevenin/Norton equivalent circuits in the text book and solve simple problemStudents need to study how to solve example or problems in the textbook.
AC voltage/current in phasor form and/or complex formStudents can solve advanced problems, e.g. Phase-Shifters, in the textbook.Students can solve examples of representation of the AC voltage/current in phasor in the text book and solve simple problemStudents need to study how to solve example or problems in the textbook.
AC powerStudents can solve advanced problems, e.g. Complex power and improvement of power factor, in the textbook.Students can solve examples of AC power in the text book and solve simple problemStudents need to study how to solve example or problems in the textbook.
Series/Parallel resonance circuitStudents can design a series/parallel resonance circuit.Students can solve examples of resonance circuit in the text book and solve simple problem.Students need to study how to solve example or problems in the textbook.

学科の到達目標項目との関係

教育方法等

概要:
This course covers two parts; One is analysis of Direct Current (DC) circuits and the other is analysis of Alternative Current (AC) circuits. DC circuits parts will cover basic laws which you've already learnt. AC circuits parts will cover fundamental concepts of AC circuits, phasor and complex form of AC voltage and current, AC power analysis and magnetically coupled circuits.
授業の進め方・方法:
This class will proceed according to the contents of the textbook. Students need to prepare the basics and examples of the textbook. Exercises presented during the class should be discussed and resolved with your teammates. A quiz will be held to confirm the student's understanding.
注意点:
Put in as much effort as you can. Problem solving is an essential part of the learning process. Solve as many problems as you can. The best way to learn is to solve a lot of problems.
Prescribed teaching hours : 60 hours a year

授業の属性・履修上の区分

アクティブラーニング
ICT 利用
遠隔授業対応
実務経験のある教員による授業

授業計画

授業内容 週ごとの到達目標
前期
1stQ
1週 Introduction to electric circuits which consist of passive elements Students will be able to understand the basic concepts of electric circuits.
2週 Basic laws(1) Students will be able to solve simple problems using Ohm's law, Kirchhoff's laws and Wye-Delta transformations.
3週 Basic laws(2) Same as above.
4週 Methods of analysis(1) Students will be able to analyze simple DC circuits using nodal analysis and/or mesh analysis.
5週 Methods of analysis(2) Same as above.
6週 Circuits theorem(1) Students will be able to understand some fundamental circuits theorems; superposition, source transformation, Thevenin's theorem, Norton's theorem, and so forth. Furthermore students will be able to solve simple problems of DC circuits using the circuits theorems.
7週 Circuits theorem(2) Same as above.
8週 Mid-term Test Students will be able to review the all topics they study from week 1 to week 7, and check their comprehension of the topics.
2ndQ
9週 Circuits theorem(3) Students will be able to understand some fundamental circuits theorems; superposition, source transformation, Thevenin's theorem, Norton's theorem, and so forth. Furthermore students will be able to solve simple problems of DC circuits using the circuits theorems.
10週 Circuits theorem(4) same as above.
11週 Comprehensive exercise Students will be able to analyse simple electric circuits using theorems.
12週 Comprehensive exercise same as above.
13週 Capacitors and Inductors(1) Students will be able to understand the volt-ampcharacteristics of capacitors and inductors. Also students will be able to express sinusoids in phasor form, complex form and/or exponential form.
14週 Capacitors and Inductors(2) same as above.
15週 Examination, Evaluation & Course summary Students will be able to check their comprehension from the results of the final exam.
16週
後期
3rdQ
1週 Sinusoids and Phasors(1) Students will be able to know what the phasor is. Also students will be able to express sinusoids in phasor form, complex form and/or exponential form.
2週 Sinusoids and Phasors(2) Same as above.
3週 Sinusoidal steady-state analysis(1) Students will be able to apply some circuits theorems to AC circuits.
4週 Sinusoidal steady-state analysis(2) Same as above.
5週 Sinusoidal steady-state analysis(3) Same as above.
6週 Comprehensive exercise Students will be able to analyse simple electric circuits using theorems.
7週 Comprehensive exercise Same as above.
8週 Mid-term test Students will be able to review the all topics they study from week 1 to week 8, and check their comprehension of the topics.
4thQ
9週 AC power analysis(1) Students will be able to understand the basic concepts of AC power and how to calculate AC power which is absorbed in a circuit.
10週 AC power analysis(2) Same as above.
11週 Frequency Response(1) Students will be able to understand meanings of frequency response and how to analyse AC circuits in frequency domain.
12週 Frequency Response(2) Same as above.
13週 Series Resonance Students will be able to able to analyse series resonance in RLC circuit.
14週 Parallel Resonance Students will be able to able to analyse parallel resonance in RLC circuit.
15週 Examination, Evaluation & Course summary Students will be able to check their comprehension from the results of the final exam.
16週

モデルコアカリキュラムの学習内容と到達目標

分類分野学習内容学習内容の到達目標到達レベル授業週
専門的能力分野別の専門工学電気・電子系分野電気回路電荷と電流、電圧を説明できる。3前2
オームの法則を説明し、電流・電圧・抵抗の計算ができる。3前2
キルヒホッフの法則を用いて、直流回路の計算ができる。3前2,前3,前4,前5,前6,前7,前8
合成抵抗や分圧・分流の考え方を用いて、直流回路の計算ができる。3前2,前3,前4,前5,前6,前7,前8
ブリッジ回路を計算し、平衡条件を求められる。3前4,前5,前6,前7,前8
電力量と電力を説明し、これらを計算できる。3前8
正弦波交流の特徴を説明し、周波数や位相などを計算できる。4前10,前11,前12,前13,前14,後13,後14
平均値と実効値を説明し、これらを計算できる。4前10,前11,前12,前13,前14,後13,後14
正弦波交流のフェーザ表示を説明できる。4前10,前11,前12,前13,前14,後1,後2,後3,後4,後5,後9,後13,後14
R、L、C素子における正弦波電圧と電流の関係を説明できる。4前10,前11,前12,前13,前14,後1,後2,後3,後4,後5,後9,後13,後14
瞬時値を用いて、交流回路の計算ができる。4前12,前13,前14
フェーザ表示を用いて、交流回路の計算ができる。4前10,前11,後1,後2,後3,後4,後5,後9
インピーダンスとアドミタンスを説明し、これらを計算できる。4前10,前11,前12,前13,前14,後1,後2,後3,後4,後5,後9
キルヒホッフの法則を用いて、交流回路の計算ができる。3前12,前13,前14,後1,後2,後3,後4,後5,後9,後13,後14
合成インピーダンスや分圧・分流の考え方を用いて、交流回路の計算ができる。3前12,前13,前14,後1,後2,後3,後4,後5,後9,後13,後14
直列共振回路と並列共振回路の計算ができる。4後13,後14
交流電力と力率を説明し、これらを計算できる。4後6,後7,後8,後9,後10,後11,後12
重ねの理を用いて、回路の計算ができる。3前4,前5,後1,後2,後3,後9
網目電流法を用いて回路の計算ができる。3前4,前5,後1,後2,後3,後9
節点電位法を用いて回路の計算ができる。3前4,前5,後1,後2,後3,後9
テブナンの定理を回路の計算に用いることができる。3前4,前5,後1,後2,後3,後9

評価割合

Midterm TestRegular ExaminationRepot and Quiz合計
総合評価割合353530100
基礎的能力0000
専門的能力353530100
分野横断的能力0000