Examples of differential equations: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
en>Mcpancakes
Linear systems of ODEs: fixed broken link
 
Line 1: Line 1:
{{Differential equations}}
Myspace makes it possible for any member to be extremely versatile, and they can set up their profile in numerous techniques. They have access not only to free of charge layouts in Myspace, as there are free Myspace backgrounds also. Practically any member with this on the [http://Search.about.com/?q=internet+neighborhood internet neighborhood] will know that there are a lot of free backgrounds to be employed from several sites.<br><br>Finding access to these no cost Myspace backgrounds is also an simple process, where customers may possibly look at several websites to get what they want. The variety is also spectacular, and there would seem a in no way-ending flow of backgrounds, out of which any a single of them will be inventive for the profile. However, if chosen nicely to blend with the theme of the profile, it will be significantly far better to look at.<br><br>Free Myspace background operate really just, which is a reason for the recognition of its use. In addition to getting accessible to all members at no price, the application is straightforward as effectively. It operates the same way as layouts, and all members have to do is copy paste the certain code of the background to the house page of the profile.<br><br>The totally free backgrounds for Myspace are sorted out categorically and that is why it can do wonders. As it has such a significant variety, they appear to be really confusing, but in reality they offer you innovative alternatives. The number of backgrounds that a user can use will be endless. These no cost Myspace backgrounds can do wonders for a persons profile, as it will break away from the monotony of the typical ones.<br><br>The profile parts will also be colorful and versatile, compared to what is offered initially. These utilized these free of charge Myspace background will understand that the use will give a completely various appear and feel to the profile when applied. They will not only create individuality, it naturally speaks of what the particular person is interested in as well.<br><br>All members should attempt out these totally free Myspace backgrounds, as the choices are wonderful. No other social networking site offers such alternatives, and the users should make the most of these internet sites. Several categories are provided as well, with cartoons, flowers, particular backgrounds for occasions and so on.<br><br>Dont forget, what make Myspace backgrounds unique are its various attributes. My pastor found out about [http://perrybelcherpinterest.skyrock.com/3208597391-Who-Is-Perry-Belcher-Information-for-Those-Who-Are-Curious.html sponsors] by browsing Google. A profile ought to be touched up with these backgrounds, as they are of so many different categories that it would be impossible to ignore. In the event you choose to identify further about [http://perry-belcher.wix.com/perrybelcher perry belcher update], there are many resources people might consider investigating. No cost backgrounds can be checked with help forums if any members have doubts about how they have to be used. Browse here at the link [http://perrybelcherwp.livejournal.com/762.html the best] to read why to consider this view. They might encounter difficulties with the usage of some free of charge backgrounds, and they can do the very same.<br><br>No matter what occasion it is, you can decorate the profile, as you want. Thus it enables the profile to get a lot of variety and different looks as nicely. The backgrounds are available in such big numbers that it would perfectly suit the profile in any way..<br><br>If you adored this post and you would certainly such as to get even more facts regarding [http://www.iamsport.org/pg/blog/reflectivewall731 health answers] kindly go to our own web-page.
 
'''[[Differential equation]]s''' arise in many problems in [[physics]], [[engineering]], and other sciences. The following examples show how to solve differential equations in a few simple cases when an exact solution exists.
 
== Separable first-order ordinary differential equations ==
Equations in the form <math>\frac {dy}{dx} = f(x)g(y)</math> are called separable and solved by <math>\frac {dy}{g(y)} = f(x)dx</math> and thus
<math>\int\frac {dy}{g(y)} = \int f(x)dx</math>. Prior to dividing by <math>g(y)</math>, one needs to check if there are stationary (also called equilibrium)
solutions <math>y=const</math> satisfying <math>g(y)=0</math>.
 
==Separable (homogeneous) first-order linear ordinary differential equations==
A separable ''linear'' [[ordinary differential equation]] of the first order
must be homogeneous and has the general form
 
:<math>\frac{dy}{dt} + f(t) y = 0</math>
 
where <math>f(t)</math> is some known [[function (mathematics)|function]].  We may solve this by [[separation of variables]] (moving the ''y'' terms to one side and the ''t'' terms to the other side),
 
:<math>\frac{dy}{y} = -f(t)\, dt</math>
 
Since the [[separation of variables]] in this case involves dividing by ''y'', we must check if the constant function ''y=0'' is a solution of the original equation. Trivially, if ''y=0'' then ''y'=0'', so ''y=0'' is actually a solution of the original equation. We note that ''y=0'' is not allowed in the transformed equation.
 
We solve the transformed equation with the variables already separated by [[Integral Calculus|Integrating]],  
 
:<math>\ln |y| = \left(-\int f(t)\,dt\right) + C\,</math>
 
where ''C'' is an arbitrary constant. Then, by [[exponentiation]], we obtain
 
:<math>y = \pm e^{\left(-\int f(t)\,dt\right) + C} = \pm e^{C} e^{-\int f(t)\,dt}</math>.
 
Here, <math>e^{C}>0</math>, so <math>\pm e^{C}\neq 0</math>. But we have independently checked that ''y=0'' is also a solution of the original equation, thus
:<math>y = A e^{-\int f(t)\,dt}</math>.
with an arbitrary constant ''A'', which covers all the cases. It is easy to confirm that this is a solution by plugging it into the original differential equation:
 
:<math>\frac{dy}{dt} + f(t) y = -f(t) \cdot A e^{-\int f(t)\,dt} + f(t) \cdot A e^{-\int f(t)\,dt} = 0</math>
 
Some elaboration is needed because ''&fnof;''(''t'')  might not even be integrable. One must also assume something about the domains of the functions involved before the equation is fully defined. The solution above assumes the [[real number|real]] case.
 
If <math>f(t)=\alpha</math> is a constant, the solution is particularly simple, <math>y = A e^{-\alpha t}</math> and describes, e.g., if <math>\alpha>0</math>, the exponential decay of radioactive material at the macroscopic level. If the value of <math>\alpha</math> is not known a priori, it can be determined from two measurements of the solution. For example,
 
:<math>\frac{dy}{dt} + \alpha y = 0, y(1)=2, y(2)=1</math>
 
gives <math>\alpha = ln(2)</math> and <math>y = 4 e^{-ln(2) t}= 2^{2-t}</math>.
 
==Non-separable (non-homogeneous) first-order linear ordinary differential equations==
First-order linear non-homogeneous ODEs (ordinary [[differential equation]]s) are not separable. They can be solved by the following approach, known as an ''[[integrating factor]]'' method. Consider first-order linear ODEs of the general form:
 
:<math>\frac{dy}{dx} + p(x)y = q(x)</math>
 
The method for solving this equation relies on a special integrating factor, ''&mu;'':
 
:<math>\mu = e^{\int p(x)\, dx}</math>
 
We choose this integrating factor because it has the special property that its derivative is itself times the function we are integrating, that is:
 
:<math>\frac{d{\mu}}{dx} = e^{\int p(x)\, dx} \cdot p(x) = \mu p(x)</math>
 
Multiply both sides of the original differential equation by ''&mu;'' to get:
 
:<math>\mu{\frac{dy}{dx}} + \mu{p(x)y}  = \mu{q(x)}</math>
 
Because of the special ''&mu;'' we picked, we may substitute ''d&mu;''/''dx'' for ''&mu;''&nbsp;''p''(''x''), simplifying the equation to:
 
:<math>\mu{\frac{dy}{dx}} + y{\frac{d{\mu}}{dx}} = \mu{q(x)}</math>
 
Using the [[product rule (calculus)|product rule]] in reverse, we get:
 
:<math>\frac{d}{dx}{(\mu{y})} = \mu{q(x)}</math>
 
Integrating both sides:
 
:<math>\mu{y} = \left(\int\mu q(x)\, dx\right) + C</math>
 
Finally, to solve for ''y'' we divide both sides by <math>\mu</math>:
 
:<math>y = \frac{\left(\int\mu q(x)\, dx\right) + C}{\mu}</math>
 
Since ''&mu;'' is a function of ''x'', we cannot simplify any further directly.
 
==Second-order linear ordinary differential equations==
 
===A simple example===
Suppose a mass is attached to a spring which exerts an attractive force on the mass [[Proportionality (mathematics)|proportional]] to the extension/compression of the spring. For now, we may ignore any other forces ([[gravity]], [[friction]], etc.).  We shall write the extension of the spring at a time ''t'' as&nbsp;''x''(''t''). Now, using [[Newton's laws of motion|Newton's second law]] we can write (using convenient units):
 
: <math>m\frac{d^2x}{dt^2} +kx=0,</math>
 
where ''m'' is the mass and ''k'' is the spring constant that represents a measure of spring stiffness. Let us for simplicity take ''m=k'' as an example.
 
If we look for solutions that have the form <math>Ce^{\lambda t}</math>, where ''C'' is a constant, we discover the relationship <math>\lambda^2+1=0</math>, and thus <math>\lambda</math> must be one of the [[complex number]]s <math>i</math> or <math>-i</math>. Thus, using [[Eulers formula in complex analysis|Euler's theorem]] we can say that the solution must be of the form:
 
: <math>x(t) = A \cos t + B \sin t</math>
 
See a [http://www.wolframalpha.com/input/?i=x%27%27%3D-x solution] by [[WolframAlpha]].  
 
To determine the unknown constants ''A'' and ''B'', we need ''initial conditions'', i.e. equalities that specify the state of the system at a given time (usually&nbsp;''t''&nbsp;=&nbsp;0).
 
For example, if we suppose at ''t''&nbsp;=&nbsp;0 the extension is a unit distance (''x''&nbsp;=&nbsp;1), and the particle is not moving (''dx''/''dt''&nbsp;=&nbsp;0). We have
 
: <math>x(0) = A \cos 0 + B \sin 0 = A = 1, \, </math>
 
and so&nbsp;''A''&nbsp;=&nbsp;1.
 
: <math>x'(0) = -A \sin 0 + B \cos 0 = B = 0, \,</math>
 
and so ''B''&nbsp;=&nbsp;0.
 
Therefore ''x''(''t'')&nbsp;=&nbsp;cos&nbsp;''t''. This is an example of [[simple harmonic motion]].
 
See a [http://www.wolframalpha.com/input/?i=x%27%27%3D-x%2Cx%280%29%3D1%2Cx%27%280%29%3D0 solution] by [[WolframAlpha]].
 
===A more complicated model===
The above model of an oscillating mass on a spring is plausible but not very realistic: in practice, [[friction]] will tend to decelerate the mass and have magnitude proportional to its velocity (i.e.&nbsp;''dx''/''dt'').  Our new differential equation, expressing the balancing of the acceleration and the forces, is
 
: <math>m\frac{d^2x}{dt^2} + c \frac{dx}{dt} + kx=0,</math>
 
where <math>c</math> is the damping coefficient representing  friction.  Again looking for solutions of the form <math>Ce^{\lambda t}</math>, we find that
 
: <math>m\lambda^2 + c \lambda + k = 0. \, </math>
 
This is a [[quadratic equation]] which we can solve.  If <math>c^2<4km</math> there are two complex conjugate  roots ''a''&nbsp;±&nbsp;''ib'', and the solution (with the above boundary conditions) will look like this:
 
: <math>x(t) = e^{at} \left(\cos bt - \frac{a}{b} \sin bt \right) </math>
 
Let us for simplicity take <math>m=1</math>, then <math>0<c=-2a</math> and <math>k=a^2+b^2</math>.
 
The equation can be also solved in MATLAB symbolic toolbox as
<source lang="matlab">
x = dsolve('D2x+c*Dx+k*x=0','x(0)=1','Dx(0)=0')
</source>
although the solution looks rather ugly,
<source lang="matlab">
x = (c + (c^2 - 4*k)^(1/2))/(2*exp(t*(c/2 - (c^2 - 4*k)^(1/2)/2))*(c^2 - 4*k)^(1/2)) -
    (c - (c^2 - 4*k)^(1/2))/(2*exp(t*(c/2 + (c^2 - 4*k)^(1/2)/2))*(c^2 - 4*k)^(1/2))
</source>
 
This is a model of ''[[Damping|damped oscillator]]''. The plot of displacement against time would look like this:
 
: [[Image:Damped Oscillation2.svg|400px|center]]
 
which does resemble how one would expect a vibrating spring to behave as friction removed the energy from the system.
 
==Linear systems of ODEs==
 
The following example of a first order linear systems of ODEs
: <math> y_1'=y_1+2y_2+t</math>
: <math> y_2'=2y_1-2y_2+\sin(t)</math>
 
can be easily symbolically
[http://www.wolframalpha.com/input/?i=y%27+%3D+{{1%2C2}%2C{2%2C-2}}.y%2B+{t%2C+sin%28t%29} solved]
in [[WolframAlpha]].
 
==See also==
* [[Closed and exact differential forms]]
* [[Ordinary differential equation]]
* [[Bernoulli differential equation]]
 
== Bibliography ==
* A. D. Polyanin and V. F. Zaitsev, ''Handbook of Exact Solutions for Ordinary Differential Equations'', 2nd Edition, [[Chapman & Hall]]/[[CRC Press]], Boca Raton, 2003; ISBN 1-58488-297-2.
 
==External links==
* [http://eqworld.ipmnet.ru/en/solutions/ode.htm Ordinary Differential Equations] at EqWorld: The World of Mathematical Equations.
 
[[Category:Ordinary differential equations]]
[[Category:Mathematical examples|Differential equations]]

Latest revision as of 05:53, 8 December 2014

Myspace makes it possible for any member to be extremely versatile, and they can set up their profile in numerous techniques. They have access not only to free of charge layouts in Myspace, as there are free Myspace backgrounds also. Practically any member with this on the internet neighborhood will know that there are a lot of free backgrounds to be employed from several sites.

Finding access to these no cost Myspace backgrounds is also an simple process, where customers may possibly look at several websites to get what they want. The variety is also spectacular, and there would seem a in no way-ending flow of backgrounds, out of which any a single of them will be inventive for the profile. However, if chosen nicely to blend with the theme of the profile, it will be significantly far better to look at.

Free Myspace background operate really just, which is a reason for the recognition of its use. In addition to getting accessible to all members at no price, the application is straightforward as effectively. It operates the same way as layouts, and all members have to do is copy paste the certain code of the background to the house page of the profile.

The totally free backgrounds for Myspace are sorted out categorically and that is why it can do wonders. As it has such a significant variety, they appear to be really confusing, but in reality they offer you innovative alternatives. The number of backgrounds that a user can use will be endless. These no cost Myspace backgrounds can do wonders for a persons profile, as it will break away from the monotony of the typical ones.

The profile parts will also be colorful and versatile, compared to what is offered initially. These utilized these free of charge Myspace background will understand that the use will give a completely various appear and feel to the profile when applied. They will not only create individuality, it naturally speaks of what the particular person is interested in as well.

All members should attempt out these totally free Myspace backgrounds, as the choices are wonderful. No other social networking site offers such alternatives, and the users should make the most of these internet sites. Several categories are provided as well, with cartoons, flowers, particular backgrounds for occasions and so on.

Dont forget, what make Myspace backgrounds unique are its various attributes. My pastor found out about sponsors by browsing Google. A profile ought to be touched up with these backgrounds, as they are of so many different categories that it would be impossible to ignore. In the event you choose to identify further about perry belcher update, there are many resources people might consider investigating. No cost backgrounds can be checked with help forums if any members have doubts about how they have to be used. Browse here at the link the best to read why to consider this view. They might encounter difficulties with the usage of some free of charge backgrounds, and they can do the very same.

No matter what occasion it is, you can decorate the profile, as you want. Thus it enables the profile to get a lot of variety and different looks as nicely. The backgrounds are available in such big numbers that it would perfectly suit the profile in any way..

If you adored this post and you would certainly such as to get even more facts regarding health answers kindly go to our own web-page.