(1) Understand capacitors and DC circuits.
(2) Can solve computational problems related to AC circuits and electromagnetic waves.
(3) Can handle force and motion based on the basic laws of mechanics, including handling by calculus and vector arithmetic.
Outline:
In the first semester, we will mainly study the field of electromagnetic (taught by Ono).
In the second semester, we will learn about mechanics using calculus and vector arithmetic (taught by Ogasawara).
Style:
Classes will be taught in a lecture style, and there will also be exercises and quizzes.
Notice:
Students must pre-study, review, and solve exercise questions for each class.
Students can earn extra points by submitting voluntary assignments, and lose their points depending on their attitude, etc. in the class.
Students who miss 1/3 or more of classes will not be eligible for a passing grade.
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Theme |
Goals |
1st Semester |
1st Quarter |
1st |
Capacitor's electrical capacity, capacitors, and dielectric (pp. 129-135) |
Can explain 332, 334, and 335 from the workbook.
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2nd |
Capacitor connections and energy stored in capacitors (pp. 136-140) |
Can explain 336, 337, and 342 from the workbook.
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3rd |
Ohm's law (pp. 142-147) |
Can explain 357(1) to (4) from the workbook.
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4th |
Joule heat, electrical energy, power, and DC circuits (pp. 148-153) |
Can explain 351, 354, and 356 from the workbook.
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5th |
Kirchhoff's circuit laws, batteries, and Wheatstone bridges (pp. 156-159) |
Can explain 360, 363, and 365 from the workbook.
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6th |
Measurement of electromotive force, non-linear resistance, and DC circuits including capacitators (pp. 160-163) |
Can explain 364, 368, and 369 from the workbook.
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7th |
Semiconductors and transistors (pp. 164-167) |
Can explain 370 and 371 from the workbook.
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8th |
Midterm exam |
Can answer 80% of the questions correctly.
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2nd Quarter |
9th |
Current and magnetic field (pp. 172-179) |
Can explain 377, 379, and 380 from the workbook.
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10th |
The force the current receives from the magnetic field (pp. 180-190) |
Can explain 381, 384, and 385 from the workbook.
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11th |
Electromagnetic induction and Lorentz force (pp. 192-199) |
Can explain 393, 395, and 398 from the workbook.
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12th |
Swirl current, self-inductance, and mutual inductance (pp. 200-205) |
Can explain 399, 400, and 402 from the workbook.
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13th |
Occurrence of alternating current (pp. 206-210) |
Can explain 409, 410, and 412 from the workbook.
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14th |
AC circuits (pp. 211-224) |
Can explain 413, 414, and 415 from the workbook.
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15th |
Resonance and electromagnetic waves (pp. 225-232) |
Can explain 416, 417, and 418 from the workbook.
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16th |
Final exam |
Can answer 80% of the questions correctly.
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2nd Semester |
3rd Quarter |
1st |
Position, velocity, and acceleration |
Can describe motions of a point mass based on vector calculus.
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2nd |
Position, velocity, and acceleration |
Can describe motions of a point mass based on vector calculus.
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3rd |
Laws of motion |
Can explain the laws of motion and apply them to specific problems.
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4th |
Laws of motion |
Can explain the laws of motion and apply them to specific problems.
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5th |
Work and kinetic energy |
Can explain work, and kinetic energy and the law of its conservation, and apply them to specific problems.
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6th |
Work and kinetic energy |
Can explain work, and kinetic energy and the law of its conservation, and apply them to specific problems.
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7th |
Work and kinetic energy |
Can explain work, and kinetic energy and the law of its conservation, and apply them to specific problems.
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8th |
Midterm exam |
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4th Quarter |
9th |
Equations of motion and the law of conservation of momentum about the center of gravity |
Can explain equations of motion and the law of conservation of momentum about the center of gravity of a point mass, and apply them to specific problems.
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10th |
Equations of motion and the law of conservation of momentum about the center of gravity |
Can explain equations of motion and the law of conservation of momentum about the center of gravity of a point mass, and apply them to specific problems.
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11th |
Equations of motion and the law of conservation of angular momentum about rotation |
Can explain equations of motion and the law of conservation of angular momentum about angular momentum and rotation, and apply them to specific problems.
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12th |
Equations of motion and the law of conservation of angular momentum about rotation |
Can explain equations of motion and the law of conservation of angular momentum about angular momentum and rotation, and apply them to specific problems.
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13th |
Rigid body dynamics |
Can explain the motion of rigid bodies, which are important examples of a point mass, and apply it to specific problems.
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14th |
Rigid body dynamics
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Can explain the dynamics of rigid bodies, which are important examples of a point mass, and apply it to specific problems.
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15th |
Rigid body dynamics |
Can explain the dynamics of rigid bodies, which are important examples of a point mass, and apply it to specific problems.
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16th |
Final exam |
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