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2020년 12월 26일 (토) 04:59 판

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  1. and it turns out that it’s actually fairly simple to differentiate a function composition using the Chain Rule.[1]
  2. In general, we don’t really do all the composition stuff in using the Chain Rule.[1]
  3. In general, this is how we think of the chain rule.[1]
  4. First, there are two terms and each will require a different application of the chain rule.[1]
  5. For the chain rule in probability theory, see Chain rule (probability) .[2]
  6. In calculus, the chain rule is a formula to compute the derivative of a composite function.[2]
  7. The chain rule may also be rewritten in Leibniz's notation in the following way.[2]
  8. The chain rule seems to have first been used by Gottfried Wilhelm Leibniz.[2]
  9. Chain rule, in calculus, basic method for differentiating a composite function.[3]
  10. The chain rule has been known since Isaac Newton and Leibniz first discovered the calculus at the end of the 17th century.[3]
  11. Recall that we used the ordinary chain rule to do implicit differentiation.[4]
  12. The chain rule has a particularly simple expression if we use the Leibniz notation for the derivative.[5]
  13. This is a quotient with a constant numerator, so we could use the quotient rule, but it is simpler to use the chain rule.[5]
  14. And it's called the chain rule.[6]
  15. And to do this, I'm going to use the chain rule.[6]
  16. I'm going to use the chain rule, and the chain rule comes into play every time, any time your function can be used as a composition of more than one function.[6]
  17. And so there we've applied the chain rule.[6]
  18. Now that we have derived a special case of the chain rule, we state the general case and then apply it in a general form to other composite functions.[7]
  19. The Chain Rule Let \(f\) and \(g\) be functions.[7]
  20. This rule is called the chain rule because we use it to take derivatives of composties of functions by chaining together their derivatives.[8]
  21. The chain rule can be thought of as taking the derivative of the outer function (applied to the inner function) and multiplying it times the derivative of the inner function.[8]
  22. It is commonly where most students tend to make mistakes, by forgetting to apply the chain rule when it needs to be applied, or by applying it improperly.[8]
  23. The chain rule can be extended to composites of more than two functions.[8]
  24. If the expression is simplified first, the chain rule is not needed.[9]
  25. The chain rule allows the differentiation of composite functions, notated by.[9]
  26. The chain rule is used to differentiate composite functions.[10]
  27. It is often useful to create a visual representation of Equation 4.29 for the chain rule.[11]
  28. The answer is given by the Chain Rule.[12]
  29. However, for our purposes, a chain rule inequality is satisfied 'on average' and this is enough to achieve our goals.[13]
  30. Consequently, the differential operators for which this chain rule holds will be generated by these rotations.[13]
  31. The chain rule could still be used in the proof of this ‘sine rule’.[14]
  32. In any case, the chain rule is not directly needed when working out specific derivatives.[14]
  33. But this fact requires proof; it is the chain rule (or at least a prerequisite for using (1) as the chain rule), and it is not a triviality.[14]
  34. The chain rule can also be discussed as a piece of formal algebra of power series (over a general commutative ring A A ).[14]
  35. Finally, here is a trigonometric function which combines the two previous examples; for this, we will need to repeat the chain rule.[15]
  36. The Chain Rule is a mathematical method to differentiate a composition of functions.[16]
  37. The Chain Rule can be used to differentiate many types of functions.[16]
  38. The Chain Rule can also help us deduce rates of change in the real world.[16]
  39. More importantly for economic theory, the chain rule allows us to find the derivatives of expressions involving arbitrary functions of functions.[17]
  40. Thus the chain rule implies the expression for F'(t) in the result.[17]
  41. Here is a precise result, discovered by Gottfried Wilhelm von Leibniz (1646–1716).As with other expressions obtained by the chain rule, we can interpret each of its parts.[17]
  42. Note: In the Chain Rule, we work from the outside to the inside.[18]
  43. This tutorial presents the chain rule and a specialized version called the generalized power rule.[18]
  44. the question was changed from xto xThe exponential rule is a special case of the chain rule.[18]
  45. In some cases, applying this rule makes differentiation simpler, but this is hardly the power of the chain rule.[19]
  46. Rather, the chain rule is extremely powerful when we do not know what , and/or are.[19]
  47. The chain rule also tells us something about the meaning of the gradient.[19]
  48. Comparing this to the chain rule we see: this tells us that the gradient is orthogonal to the tangent vectors of our level curve.[19]
  49. The chain rule allows us to deal with this case.[20]
  50. It will take a bit of practice to make the use of the chain rule come naturally, it is more complicated than the earlier differentiation rules we have seen.[20]
  51. Using the chain rule, the power rule, and the product rule it is possible to avoid using the quotient rule entirely.[20]
  52. The method is called the "chain rule" because it can be applied sequentially to as many functions as are nested inside one another.[21]
  53. The chain rule has broad applications in physics, chemistry, and engineering, as well as being used to study related rates in many disciplines.[21]
  54. Because one physical quantity often depends on another, which, in turn depends on others, the chain rule has broad applications in physics.[21]
  55. This section presents examples of the chain rule in kinematics and simple harmonic motion.[21]
  56. To do this we need a chain rule for functions of more than one variable.[22]
  57. We may also extend the chain rule to cases when x and y are functions of two variables rather than one.[22]
  58. We may of course extend the chain rule to functions of n variables each of which is a function of m other variables.[22]

소스

  1. 1.0 1.1 1.2 1.3 Calculus I
  2. 2.0 2.1 2.2 2.3 Chain rule
  3. 3.0 3.1 Chain rule | mathematics
  4. 14.4 The Chain Rule
  5. 5.0 5.1 3.5 The Chain Rule
  6. 6.0 6.1 6.2 6.3 Chain rule (video)
  7. 7.0 7.1 3.6: The Chain Rule
  8. 8.0 8.1 8.2 8.3 World Web Math: The Chain Rule
  9. 9.0 9.1 Chain Rule
  10. The chain rule
  11. 4.5 The Chain Rule - Calculus Volume 3
  12. The Chain Rule
  13. 13.0 13.1 Example sentences
  14. 14.0 14.1 14.2 14.3 chain rule in nLab
  15. The Chain Rule
  16. 16.0 16.1 16.2 The Chain Rule
  17. 17.0 17.1 17.2 Mathematical methods for economic theory: 2.2 The chain rule
  18. 18.0 18.1 18.2 Chain Rule (examples, solutions, videos)
  19. 19.0 19.1 19.2 19.3 The chain rule
  20. 20.0 20.1 20.2 The chain rule
  21. 21.0 21.1 21.2 21.3 Wikibooks, open books for an open world
  22. 22.0 22.1 22.2 The Chain Rule for Functions of Two Variables

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