미분방정식

개요

• 미분방정식은 자연현상을 기술하는 수학적인 언어
• 함수를 계수로 하여 미지수가 되는 일변수 함수와 고계도함수 사이에 만족되는 방정식을 말함
• 학부과정에서는 상미분방정식 과목과 편미분방정식이 있음
• 미분방정식의 해를 적당한 클래스의 함수(가령 초등함수, 초등함수의 적분) 들을 이용하여 표현하는 문제(solvability, integrability, quadrature)
• 분류법
  • 미분방정식의 계(order)
  • 선형미분방정식과 비선형미분방정식
  • 상미분방정식과 편미분방정식

일계 미분방정식

• 일계선형미분방정식\[\frac{dy}{dt}+a(t)y=b(t)\]
• 완전미분방정식\[M_y=N_x\]를 만족시키는 \(M(x, y)\, dx + N(x, y)\, dy = 0\) 꼴의 미분방정식
• 다음 미분방정식들은 비선형이다
• 리카티 미분방정식\[y' = A(x)+ B(x)y + C(x)y^2, A(x)\neq 0, C(x)\neq 0\]
• 베르누이 미분방정식\[y'+ P(x)y = Q(x)y^n\]

이계 선형미분방정식

• 다음 형태로 주어지는 미분방정식을 이계선형미분방정식이라 함\[\frac{d^2y}{dx^2}+p(x)\frac{dy}{dx}+q(x)y=g(x)\]
• 상수계수 이계 선형미분방정식\[ay''+by'+cy=0\]
• Airy 미분방정식\[y'' - xy = 0\]
• 베셀 미분방정식\[x^2 \frac{d^2 y}{dx^2} + x \frac{dy}{dx} + (x^2 - \alpha^2)y = 0\]
• 에르미트 다항식(Hermite polynomials)\[y''-2xy'+\lambda y=0\]
• 르장드르 다항식\[(1-x^2)y''-2xy'+\lambda(\lambda+1) y=0\]
• 체비셰프 다항식\[(1-x^2)y''-xy'+\lambda^2 y=0\]
• 라게르 미분방정식\[xy''+(1-x)y'+\lambda y=0\]
• 오일러 미분방정식\[x^2\frac{d^2y}{dx^2}+\alpha x\frac{dy}{dx}+\beta y=0\]
• 초기하 미분방정식(Hypergeometric differential equations)\[z(1-z)\frac{d^2w}{dz^2}+(c-(a+b+1)z)\frac{dw}{dz}-abw = 0\]
• 리만 미분방정식\[\frac{d^2w}{dz^2} + \left[ \frac{1-\alpha-\alpha'}{z-a} + \frac{1-\beta-\beta'}{z-b} + \frac{1-\gamma-\gamma'}{z-c} \right] \frac{dw}{dz}+\left[ \frac{\alpha\alpha' (a-b)(a-c)} {z-a} +\frac{\beta\beta' (b-c)(b-a)} {z-b} +\frac{\gamma\gamma' (c-a)(c-b)} {z-c} \right] \frac{w}{(z-a)(z-b)(z-c)}=0\] 여기서 \(\alpha+\alpha'+\beta+\beta'+\gamma+\gamma'=1\)

• 호인 미분방정식(Heun's equation)\[\frac {d^2w}{dz^2} + \left[\frac{\gamma}{z}+ \frac{\delta}{z-1} + \frac{\epsilon}{z-d} \right] \frac {dw}{dz} + \frac {\alpha \beta z -q} {z(z-1)(z-d)} w = 0\] (여기서 \(\epsilon=\alpha+\beta-\gamma-\delta+1\))

비선형 미분방저식

• 팽르베 미분방정식
• 바이어슈트라스의 타원함수\[(\frac{dw}{dz})^2=4w^3-g_2w-g_3\]

스텀-리우빌

• 스텀-리우빌 이론 항목에서 자세히 다룸

스텀-리우빌 이론

재미있는 사실

• 네이버 지식인 http://kin.search.naver.com/search.naver?where=kin_qna&query=

역사

• http://www.google.com/search?hl=en&tbs=tl:1&q=differential+equation
• 수학사 연표

메모

• qualitative study

하위페이지

• 미분방정식
  • Fuchsian 미분방정식(Fuchsian differential equation)
  • 그린 함수(Green's function)
  • 리만 미분방정식
  • 리카티 미분방정식
  • 맴돌이군과 미분방정식
  • 베르누이 미분방정식
  • 베셀 미분방정식
  • 스텀-리우빌 이론
  • 오일러 미분방정식
  • 완전미분방정식
  • 이계 미분방정식
    • 상수계수 이계 선형미분방정식
    • 이계 선형 미분방정식
  • 일계 선형미분방정식
  • 정규특이점(regular singular points)
  • 치환적분과 변수분리형 미분방정식
  • 팽르베 미분방정식(Painlevé Equations)
  • 호인 미분방정식(Heun's equation)

관련된 항목들

• 상미분방정식
• 편미분방정식
• 초기하 미분방정식(Hypergeometric differential equations)
• Special functions
• 불가능성의 정리들

수학용어번역

• http://www.google.com/dictionary?langpair=en%7Cko&q=
• 대한수학회 수학 학술 용어집
  • http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=eng_term&fstr=
• 대한수학회 수학용어한글화 게시판

사전 형태의 자료

• http://ko.wikipedia.org/wiki/상미분_방정식
• http://ko.wikipedia.org/wiki/
• http://en.wikipedia.org/wiki/differential_equation
• http://www.wolframalpha.com/input/?i=
• NIST Digital Library of Mathematical Functions
• The On-Line Encyclopedia of Integer Sequences
  • http://www.research.att.com/~njas/sequences/?q=

리뷰, 에세이, 강의노트

• What It Means to Understand a Differential Equation
  • John H. Hubbard, The College Mathematics Journal, Vol. 25, No. 5 (Nov., 1994), pp. 372-384
• Elementary Quadratures of Ordinary Differential Equations
  • Li Hong-Xiang, The American Mathematical Monthly, Vol. 89, No. 3 (Mar., 1982), pp. 198-208
• Symmetry and Differential Equations
  • J. V. Greenman, The Mathematical Gazette, Vol. 61, No. 418 (Dec., 1977), pp. 279-283
• Anatomy of the Ordinary Differential Equation
  • W. T. Reid, The American Mathematical Monthly, Vol. 82, No. 10 (Dec., 1975), pp. 971-984
• • T. Craig

관련링크와 웹페이지

• http://eqworld.ipmnet.ru/en/solutions/ode.htm

노트

위키데이터

• ID : Q11214

말뭉치

1. The Differential Equation says it well, but is hard to use.^[1]
2. Creating a differential equation is the first major step.^[1]
3. In Mathematics, a differential equation is an equation that contains one or more functions with its derivatives.^[2]
4. The primary purpose of the differential equation is the study of solutions that satisfy the equations and the properties of the solutions.^[2]
5. One of the easiest ways to solve the differential equation is by using explicit formulas.^[2]
6. A differential equation contains derivatives which are either partial derivatives or ordinary derivatives.^[2]
7. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, and the differential equation defines a relationship between the two.^[3]
8. A partial differential equation (PDE) is a differential equation that contains unknown multivariable functions and their partial derivatives.^[3]
9. Conduction of heat, the theory of which was developed by Joseph Fourier, is governed by another second-order partial differential equation, the heat equation.^[3]
10. A differential equation is an equation involving a function and its derivatives.^[4]
11. It can be referred to as an ordinary differential equation (ODE) or a partial differential equation (PDE) depending on whether or not partial derivatives are involved.^[4]
12. The first definition that we should cover should be that of differential equation.^[5]
13. There is one differential equation that everybody probably knows, that is Newton’s Second Law of Motion.^[5]
14. A differential equation is called an ordinary differential equation, abbreviated by ode, if it has ordinary derivatives in it.^[5]
15. Likewise, a differential equation is called a partial differential equation, abbreviated by pde, if it has partial derivatives in it.^[5]
16. We also investigate how direction fields can be used to determine some information about the solution to a differential equation without actually having the solution.^[6]
17. Series Solutions – In this section we define ordinary and singular points for a differential equation.^[6]
18. We also show who to construct a series solution for a differential equation about an ordinary point.^[6]
19. rd order differential equation just to say that we looked at one with order higher than 2nd.^[6]
20. A differential equation is an equation involving derivatives.^[7]
21. You can find the general solution to any separable first order differential equation by integration, (or as it is sometimes referred to, by "quadrature").^[7]
22. Suppose we have a first order differential equation that is not separable, so we cannot reduce its solution to quadratures directly.^[7]
23. at least look at what a differential equation actually is.^[8]
24. And you might have just caught from how I described it that the solution to a differential equation is a function, or a class of functions.^[8]
25. We'll verify that these indeed are solutions for I guess this is really just one differential equation represented in different ways.^[8]
26. But you'll hopefully appreciate what a solution to a differential equation looks like.^[8]
27. Differential equation, mathematical statement containing one or more derivatives—that is, terms representing the rates of change of continuously varying quantities.^[9]
28. When the function involved in the equation depends on only a single variable, its derivatives are ordinary derivatives and the differential equation is classed as an ordinary differential equation.^[9]
29. On the other hand, if the function depends on several independent variables, so that its derivatives are partial derivatives, the differential equation is classed as a partial differential equation.^[9]
30. Whichever the type may be, a differential equation is said to be of the nth order if it involves a derivative of the nth order but no derivative of an order higher than this.^[9]
31. Learning Objectives Calculate the order and degree of a differential equation.^[10]
32. The higher the order of the differential equation, the more arbitrary constants need to be added to the general solution.^[10]
33. The “order” of a differential equation depends on the derivative of the highest order in the equation.^[10]
34. The “degree” of a differential equation, similarly, is determined by the highest exponent on any variables involved.^[10]
35. Also as we have seen so far, a differential equation typically has an infinite number of solutions.^[11]
36. Solve a differential equation analytically by using the dsolve function, with or without initial conditions.^[12]
37. First-Order Linear ODE Solve this differential equation.^[12]
38. Solve this third-order differential equation with three initial conditions.^[12]
39. The last example is the Airy differential equation, whose solution is called the Airy function.^[12]
40. Thus, one of the most common ways to use calculus is to set up an equation containing an unknown function \(y=f(x)\) and its derivative, known as a differential equation.^[13]
41. Combining like terms leads to the expression \(6x+11\), which is equal to the right-hand side of the differential equation.^[13]
42. A differential equation is an equation involving an unknown function \(y=f(x)\) and one or more of its derivatives.^[13]
43. Consider the equation \(y′=3x^2,\) which is an example of a differential equation because it includes a derivative.^[13]
44. A differential equation is an equation involving terms that are derivatives (or differentials).^[14]
45. A partial differential equation need not have any solution at all.^[15]
46. If the partial differential equation being considered is the Euler equation for a problem of variational calculus in more dimensions, a variational method is often employed.^[15]
47. The order of a partial differential equation is the order of the highest derivative involved.^[16]
48. A solution (or a particular solution) to a partial differential equation is a function that solves the equation or, in other words, turns it into an identity when substituted into the equation.^[16]
49. A differential equation can look pretty intimidating, with lots of fancy math symbols.^[17]
50. Each of those variables has a differential equation saying how that variable evolves over time.^[17]
51. The task is to find a function whose various derivatives fit the differential equation over a long span of time.^[17]
52. It is easy to confirm that you have a solution: just plug the solution in to the differential equation!^[17]
53. The final few pages of this class will be devoted to an introduction to differential equation.^[18]
54. A differential equation is an equation (you will see an " = " sign) that has derivatives.^[18]
55. If y = f(x) is a solution to a differential equation, then if we plug " y " into the equation, we get a true statement.^[18]
56. We derive a second-order ordinary differential equation (ODE) which is the limit of Nesterov's accelerated gradient method.^[19]
57. The aim of this paper is to study a boundary value problem of the hybrid differential equation with linear and nonlinear perturbations.^[20]
58. The example of a cooling coffee cup is used to find the differential equation and solve it using differentiation.^[21]
59. If we solve a first order differential equation by variables separable method, we necessarily have to introduce an arbitrary constant as soon as the integration is performed.^[22]
60. Similarly, the general solution of a second order differential equation will contain 2 necessary arbitrary constants and so on.^[22]
61. A Particular Solution of a differential equation is a solution obtained from the General Solution by assigning specific values to the arbitrary constants.^[22]
62. The function f(t) must satisfy the differential equation in order to be a solution.^[22]
63. In this tutorial we will show you how to define an ordinary differential equation (ODE) in the Fitting function Builder dialog and perform a fit of the data using this fitting function.^[23]
64. In this tutorial, we will use a first order ordinary differential equation as an example: where a is a parameter in the ordinary differential equation and y0 is the initial value for the ODE.^[23]

소스

메타데이터

위키데이터

• ID : Q11214