Find the type of partial solution to the differential equation. First order differential equations. Examples of solutions. Differential equations with separable variables

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In some problems of physics, it is not possible to establish a direct connection between the quantities describing the process. But it is possible to obtain an equality containing the derivatives of the functions under study. This is how differential equations arise and the need to solve them to find an unknown function.

This article is intended for those who are faced with the problem of solving a differential equation in which the unknown function is a function of one variable. The theory is constructed in such a way that null representation about differential equations, you will be able to cope with your task.

Each type of differential equation is associated with a solution method with detailed explanations and solutions to typical examples and problems. All you have to do is determine the type of differential equation of your problem, find a similar analyzed example and carry out similar actions.

To successfully solve differential equations, you will also need the ability to find sets of antiderivatives (indefinite integrals) various functions. If necessary, we recommend that you refer to the section.

First, we will consider the types of ordinary differential equations of the first order that can be resolved with respect to the derivative, then we will move on to second-order ODEs, then we will dwell on higher-order equations and end with systems of differential equations.

Recall that if y is a function of the argument x.

First order differential equations.

The simplest differential equations of the first order of the form.

Let's write down a few examples of such remote control .

Differential equations can be resolved with respect to the derivative by dividing both sides of the equality by f(x) . In this case, we arrive at an equation that will be equivalent to the original one for f(x) ≠ 0. Examples of such ODEs are .

If there are values ​​of the argument x at which the functions f(x) and g(x) simultaneously vanish, then additional solutions appear. Additional solutions to the equation given x are any functions defined for these argument values. Examples of such differential equations include:

Second order differential equations.

Linear homogeneous differential equations of the second order with constant coefficients.

LDE with constant coefficients is a very common type of differential equation. Their solution is not particularly difficult. First, the roots of the characteristic equation are found . For different p and q, three cases are possible: the roots of the characteristic equation can be real and different, real and coinciding or complex conjugates. Depending on the values ​​of the roots of the characteristic equation, it is written common decision differential equation as , or , or respectively.

For example, consider a linear homogeneous second-order differential equation with constant coefficients. The roots of its characteristic equation are k 1 = -3 and k 2 = 0. The roots are real and different, therefore, the general solution of a LODE with constant coefficients has the form


Linear inhomogeneous differential equations of the second order with constant coefficients.

The general solution of a second-order LDDE with constant coefficients y is sought in the form of the sum of the general solution of the corresponding LDDE and a particular solution to the original inhomogeneous equation, that is, . The previous paragraph is devoted to finding a general solution to a homogeneous differential equation with constant coefficients. And a particular solution is determined either by the method uncertain coefficients for a certain form of the function f(x) on the right side of the original equation, or by the method of varying arbitrary constants.

As examples of second-order LDDEs with constant coefficients, we give


To understand the theory and get acquainted with detailed solutions of examples, we offer you on the page linear inhomogeneous second-order differential equations with constant coefficients.

Linear homogeneous differential equations (LODE) and linear inhomogeneous differential equations (LNDEs) of the second order.

A special case of differential equations of this type are LODE and LDDE with constant coefficients.

The general solution of the LODE on a certain segment is represented by a linear combination of two linearly independent partial solutions y 1 and y 2 of this equation, that is, .

The main difficulty lies precisely in finding linearly independent partial solutions to a differential equation of this type. Typically, particular solutions are selected from the following systems of linearly independent functions:


However, particular solutions are not always presented in this form.

An example of a LOD is .

The general solution of the LDDE is sought in the form , where is the general solution of the corresponding LDDE, and is the particular solution of the original differential equation. We just talked about finding it, but it can be determined using the method of varying arbitrary constants.

An example of LNDU can be given .

Differential equations of higher orders.

Differential equations that allow a reduction in order.

Order of differential equation , which does not contain the desired function and its derivatives up to k-1 order, can be reduced to n-k by replacing .

In this case, the original differential equation will be reduced to . After finding its solution p(x), it remains to return to the replacement and determine the unknown function y.

For example, the differential equation after the replacement, it will become an equation with separable variables, and its order will be reduced from third to first.

Let us recall the task that confronted us when finding definite integrals:

or dy = f(x)dx. Her solution:

and it comes down to calculating the indefinite integral. In practice, more often occurs difficult task: find function y, if it is known that it satisfies a relation of the form

This relationship relates the independent variable x, unknown function y and its derivatives up to the order n inclusive, are called .

A differential equation includes a function under the sign of derivatives (or differentials) of one order or another. The highest order is called order (9.1) .

Differential equations:

- first order,

Second order

- fifth order, etc.

The function that satisfies a given differential equation is called its solution , or integral . Solving it means finding all its solutions. If for the required function y managed to obtain a formula that gives all solutions, then we say that we have found its general solution , or general integral .

Common decision contains n arbitrary constants and looks like

If a relation is obtained that relates x, y And n arbitrary constants, in a form not permitted with respect to y -

then such a relation is called the general integral of equation (9.1).

Cauchy problem

Each specific solution, i.e., each specific function that satisfies a given differential equation and does not depend on arbitrary constants, is called a particular solution , or a partial integral. To obtain particular solutions (integrals) from general ones, it is necessary to give specific constants numeric values.

The graph of a particular solution is called an integral curve. The general solution, which contains all the partial solutions, is a family of integral curves. For a first-order equation this family depends on one arbitrary constant, for the equation n-th order - from n arbitrary constants.

The Cauchy problem is to find a particular solution for the equation n-th order, satisfying n initial conditions:

by which n constants c 1, c 2,..., c n are determined.

1st order differential equations

For a 1st order differential equation that is unresolved with respect to the derivative, it has the form

or for permitted relatively

Example 3.46. Find the general solution to the equation

Solution. Integrating, we get

where C is an arbitrary constant. If we assign specific numerical values ​​to C, we obtain particular solutions, for example,

Example 3.47. Consider an increasing amount of money deposited in the bank subject to the accrual of 100 r compound interest per year. Let Yo be the initial amount of money, and Yx - at the end x years. If interest is calculated once a year, we get

where x = 0, 1, 2, 3,.... When interest is calculated twice a year, we get

where x = 0, 1/2, 1, 3/2,.... When calculating interest n once a year and if x takes sequential values ​​0, 1/n, 2/n, 3/n,..., then

Designate 1/n = h, then the previous equality will look like:

With unlimited magnification n(at ) in the limit we come to the process of increasing sum of money with continuous interest accrual:

Thus it is clear that with continuous change x the law of change in the money supply is expressed by a 1st order differential equation. Where Y x is an unknown function, x- independent variable, r- constant. Let's solve this equation, to do this we rewrite it as follows:

where , or , where P denotes e C .

From the initial conditions Y(0) = Yo, we find P: Yo = Pe o, from where, Yo = P. Therefore, the solution has the form:

Let's consider the second economic problem. Macroeconomic models are also described by linear differential equations of the 1st order, describing changes in income or output Y as functions of time.

Example 3.48. Let national income Y increase at a rate proportional to its value:

and let the deficit in government spending be directly proportional to income Y with the proportionality coefficient q. A spending deficit leads to an increase in national debt D:

Initial conditions Y = Yo and D = Do at t = 0. From the first equation Y= Yoe kt. Substituting Y we get dD/dt = qYoe kt . The general solution has the form
D = (q/ k) Yoe kt +С, where С = const, which is determined from the initial conditions. Substituting the initial conditions, we get Do = (q/ k)Yo + C. So, finally,

D = Do +(q/ k)Yo (e kt -1),

this shows that the national debt is increasing at the same relative rate k, the same as national income.

Let us consider the simplest differential equations n th order, these are equations of the form

Its general solution can be obtained using n times integrations.

Example 3.49. Consider the example y """ = cos x.

Solution. Integrating, we find

The general solution has the form

Linear differential equations

They are widely used in economics; let’s consider solving such equations. If (9.1) has the form:

then it is called linear, where рo(x), р1(x),..., рn(x), f(x) are given functions. If f(x) = 0, then (9.2) is called homogeneous, otherwise it is called inhomogeneous. The general solution of equation (9.2) is equal to the sum of any of its particular solutions y(x) and the general solution of the homogeneous equation corresponding to it:

If the coefficients р o (x), р 1 (x),..., р n (x) are constant, then (9.2)

(9.4) is called a linear differential equation with constant coefficients of order n .

For (9.4) has the form:

Without loss of generality, we can set p o = 1 and write (9.5) in the form

We will look for a solution (9.6) in the form y = e kx, where k is a constant. We have: ; y " = ke kx , y "" = k 2 e kx , ..., y (n) = kne kx . Substituting the resulting expressions into (9.6), we will have:

(9.7) yes algebraic equation, its unknown is k, it is called characteristic. The characteristic equation has degree n And n roots, among which there can be both multiple and complex. Let k 1 , k 2 ,..., k n be real and distinct, then - particular solutions (9.7), and general

Consider a linear homogeneous second-order differential equation with constant coefficients:

Its characteristic equation has the form

(9.9)

its discriminant D = p 2 - 4q, depending on the sign of D, three cases are possible.

1. If D>0, then the roots k 1 and k 2 (9.9) are real and different, and the general solution has the form:

Solution. Characteristic equation: k 2 + 9 = 0, whence k = ± 3i, a = 0, b = 3, the general solution has the form:

y = C 1 cos 3x + C 2 sin 3x.

Linear differential equations of the 2nd order are used when studying a web-type economic model with inventories of goods, where the rate of change in price P depends on the size of the inventory (see paragraph 10). In case supply and demand are linear functions prices, that is

a is a constant that determines the reaction rate, then the process of price change is described by the differential equation:

For a particular solution we can take a constant

meaningful equilibrium price. Deviation satisfies the homogeneous equation

(9.10)

The characteristic equation will be as follows:

In case the term is positive. Let's denote . The roots of the characteristic equation k 1,2 = ± i w, therefore the general solution (9.10) has the form:

where C and are arbitrary constants, they are determined from the initial conditions. We obtained the law of price change over time:

Either have already been solved with respect to the derivative, or they can be solved with respect to the derivative .

General solution of differential equations of the type on the interval X, which is given, can be found by taking the integral of both sides of this equality.

We get .

If we look at the properties of the indefinite integral, we find the desired general solution:

y = F(x) + C,

Where F(x)- one of the primitive functions f(x) in between X, A WITH- arbitrary constant.

Please note that in most problems the interval X do not indicate. This means that a solution must be found for everyone. x, for which and the desired function y, and the original equation make sense.

If you need to calculate a particular solution to a differential equation that satisfies the initial condition y(x 0) = y 0, then after calculating the general integral y = F(x) + C, it is still necessary to determine the value of the constant C = C 0, using the initial condition. That is, a constant C = C 0 determined from the equation F(x 0) + C = y 0, and the desired partial solution of the differential equation will take the form:

y = F(x) + C 0.

Let's look at an example:

Let's find a general solution to the differential equation and check the correctness of the result. Let us find a particular solution to this equation that would satisfy the initial condition.

Solution:

After we integrate the given differential equation, we get:

.

Let's take this integral using the method of integration by parts:

That., is a general solution to the differential equation.

To make sure the result is correct, let's do a check. To do this, we substitute the solution we found into the given equation:

.

That is, when the original equation turns into an identity:

therefore, the general solution of the differential equation was determined correctly.

The solution we found is a general solution to the differential equation for every real value of the argument x.

It remains to calculate a particular solution to the ODE that would satisfy the initial condition. In other words, it is necessary to calculate the value of the constant WITH, at which the equality will be true:

.

.

Then, substituting C = 2 into the general solution of the ODE, we obtain a particular solution of the differential equation that satisfies the initial condition:

.

Ordinary differential equation can be solved for the derivative by dividing the 2 sides of the equation by f(x). This transformation will be equivalent if f(x) does not turn to zero under any circumstances x from the integration interval of the differential equation X.

There are likely situations when, for some values ​​of the argument x ∈ X functions f(x) And g(x) simultaneously become zero. For similar values x the general solution of a differential equation is any function y, which is defined in them, because .

If for some argument values x ∈ X the condition is satisfied, which means that in this case the ODE has no solutions.

For everyone else x from the interval X the general solution of the differential equation is determined from the transformed equation.

Let's look at examples:

Example 1.

Let's find a general solution to the ODE: .

Solution.

From the main properties elementary functions it is clear that the function natural logarithm is defined for non-negative argument values, so the scope of the expression is ln(x+3) there is an interval x > -3 . This means that the given differential equation makes sense for x > -3 . For these argument values, the expression x+3 does not vanish, so you can solve the ODE for the derivative by dividing the 2 parts by x + 3.

We get .

Next, we integrate the resulting differential equation, solved with respect to the derivative: . To take this integral, we use the method of subsuming it under the differential sign.

The online calculator allows you to solve differential equations online. It is enough to enter your equation in the appropriate field, denoting the derivative of the function through an apostrophe, and click on the “solve equation” button. And the system, implemented on the basis of the popular WolframAlpha website, will give detailed solving a differential equation absolutely free. You can also define a Cauchy problem to select from the entire set of possible solutions the quotient that corresponds to the given initial conditions. The Cauchy problem is entered in a separate field.

Differential equation

By default, the function in the equation y is a function of a variable x. However, you can specify your own designation for the variable; if you write, for example, y(t) in the equation, the calculator will automatically recognize that y there is a function from a variable t. With the help of a calculator you can solve differential equations of any complexity and type: homogeneous and inhomogeneous, linear or nonlinear, first order or second and higher orders, equations with separable or nonseparable variables, etc. Solution diff. equation is given in analytical form, has detailed description. Differential equations are very common in physics and mathematics. Without calculating them, it is impossible to solve many problems (especially in mathematical physics).

One of the stages of solving differential equations is integrating functions. Eat standard methods solutions of differential equations. It is necessary to reduce the equations to a form with separable variables y and x and separately integrate the separated functions. To do this, sometimes a certain replacement must be made.