Difference between revisions of "Math100Videos"
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− | | | + | |Exponential change |
|[https://youtu.be/eblBM7tvRLY] | |[https://youtu.be/eblBM7tvRLY] | ||
|Exponential growth and decay, such as radioactive decay, compound interest, and population growth. Introduction to differential equations. | |Exponential growth and decay, such as radioactive decay, compound interest, and population growth. Introduction to differential equations. | ||
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| Calculating the rate of change in systems with lots of interconnected changing parts. | | Calculating the rate of change in systems with lots of interconnected changing parts. | ||
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− | + | |- class="NewWeek OddWeek" | |
− | + | | Polynomial Approximations | |
− | + | | First Approximations | |
− | + | |[https://youtu.be/cYtRR2NVeY0 | |
− | + | |Estimating the value of a function with a constant, linear, or quadratic approximation. | |
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− | + | |- class="OddWeek" | |
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− | + | |Error Bounding | |
− | + | |[https://youtu.be/QavL2wnf8qk] | |
− | + | | Give an approximation of a function, and bound the error you introduced. | |
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− | + | |- class="OddWeek" | |
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− | + | |[https://youtu.be/VbjR6JF1OG4] | |
− | + | |If you are given an error tolerance, which approximation should you use? | |
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− | + | |- class="NewWeek EvenWeek" | |
− | + | | Optimization | |
− | + | | Extrema | |
− | + | |[https://youtu.be/pxMPYzEm_-o] | |
− | + | |Finding maxima and minima of a function. | |
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− | + | |- | |
− | + | | | |
− | + | | Optimization | |
− | + | |[https://youtu.be/IxYA1IWs2R4] | |
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− | + | ||
− | + | |- | |
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− | + | |[https://youtu.be/E-20K2Mby60] | |
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<td rowspan=2> MVT </td> | <td rowspan=2> MVT </td> | ||
<td> Rolle's Theorem </td> | <td> Rolle's Theorem </td> |
Revision as of 13:43, 18 August 2017
Topic | Video link | Video contents | |
---|---|---|---|
Limits | Limits and tangent lines | [1] | Average and Instantaneous Velocity; secant and tangent line; limit notation |
One-sided limits | [2] | A simple example motivating one-sided limits | |
Limits, continued | [3] | Sometimes limits don't exist; one-sided limits; calculating limits | |
Limits at Infinity | [4] | Limits at infinity
| |
Continuity | Intro to Continuity | [5] | Before we learn the formal definition of a continuous function, dwell a little on what it means for a function's limit to differ from its value at a point. Being used to this behaviour will help you build intuition about continuity. |
Limits, Continuity, IVT | [6] | Strategies for evaluating limits; continuity; Intermediate Value Theorem | |
Extra: continuity | [7] | Think you understand continuity? Test yourself with a graph that has no limit... anywhere. (This video goes beyond the course material. Think of it as recreational.) | |
Derivatives | Intro to Derivatives | [8] | Introduction to derivatives: interpretations, derivatives at a point, derivatives of a function |
Graphing Derivatives | [9] | Use the graph of a function to create the graph of its derivative. Review the interpretation of positive and negative derivatives, and get used to looking at a line and intuiting its slope. | |
Tangent Lines | [10] | Find the tangent line to a curve; calculate derivatives using simple rules. | |
Differentiation | Product and Quotient Rules | [11] | Derivatives of Products and Ratios |
Exponential | [12] | Product rule and derivatives of exponential functions | |
Trigonometric | [13] | Derivatives of trigonometric functions. | |
Chain Rule | [14] | Derivatives of compound functions. | |
Review: Inverse Functions | [15] | Inverse functions. | |
Logarithms | [16] | Logarithmic functions and logarithmic differentiation. | |
Rates of Change | Rates of Change | [17] | Rates of Change |
Exponential change | [18] | Exponential growth and decay, such as radioactive decay, compound interest, and population growth. Introduction to differential equations. | |
Newton's Law of Cooling | [19] | Exponential rates of change applied to cooling bodies. | |
Related Rates | [20] | Calculating the rate of change in systems with lots of interconnected changing parts.
| |
Polynomial Approximations | First Approximations | [https://youtu.be/cYtRR2NVeY0 | Estimating the value of a function with a constant, linear, or quadratic approximation. |
Error Bounding | [21] | Give an approximation of a function, and bound the error you introduced. | |
[22] | If you are given an error tolerance, which approximation should you use? | ||
Optimization | Extrema | [23] | Finding maxima and minima of a function. |
Optimization | [24]
| ||
[25]
<td rowspan=2> MVT </td>
<td> Rolle's Theorem </td>
<td> <a href='100/video/Rolle.mp4'>video</a> </td> </tr>
<tr>
<td> Mean Value Theorem </td>
<td> <a href='100/video/MVT.mp4'>video</a> </td> </tr>
<tr>
<td rowspan=3> Curve Sketching </td>
<td> Curve Sketching 1 </td>
<td> <a href='100/video/sketch1.mp4'>video</a>
| |||
[26] | Approximating a rational function near the origin. | ||
[27] | Approximating a rational function for large x. Introduction to Hill functions. | ||
[28] | Sketching Hill functions by hand and by Desmos (see Hill functions demo). Comparing Hill functions with different parameter values. | ||
See video [1] above for an introduction to even and odd functions and also Sec 1.2.3 and Appendix C.D of the course notes. | |||
[29] | Average rate of change and secant lines. Instantaneous rate of change. | ||
[30] | Definition of the derivative. | ||
[31] | Continuity - definition and examples of three types of discontinuities. | ||
[32] | Examples of computing the derivative of a function from the definition of the derivative.
|