What is the difference between a differential equation and a derivative?by Alshia Tags: derivative, difference, differential, equation 

#1
Dec912, 08:22 AM

P: 28

For example, if y=x^2, then the derivative of y is 2x. We write the derivative as either f'(x)=2x or dy/dx=2x.
Well, the differential equation is also written as dy/dx=2x. So is there a difference between a differential equation and a derivative? !~Alshia~! 



#2
Dec912, 08:35 AM

Admin
P: 21,634

The derivative is just the slope of a tangent line to a function as a give point.
A differential equation is a mathematical equation for an unknown function of one or several variables that relates the values of the function itself and its derivatives of various orders, e.g., first derivative, second derivative, . . . . The challenge then is to find the function. http://en.wikipedia.org/wiki/Differential_equation In the case of a derivative, one knows the function, i.e., given y = f(x), y' = f'(x). 



#3
Dec912, 08:55 PM

P: 28

So let's see if I'm getting this.
A derivative:  is the slope of a line tangent to a function at a given point,  cannot contain a third (or more) variable since it's supposed to tell us the instantaneous rate of change of a variable in relation to one other variable,  cannot contain other levels of derivatives because of the same reason as above,  the function which tells us about the relationship between the variables is known, and  is a function itself. A differential equation:  may or may not tell us what the derivative of the function is, since it may contain different levels of derivatives and/or other variables,  the function which relates the DV (dependent variable) to the independent variable is not known,  an equation, not a function. So my guess is, the reason why it's called differently from a linguistic standpoint is that a derivative is derived from a function (which of course requires the function to be known), whereas a diferential equation may not have been derived from a function (since it IS possible to measure rate of change without knowing the function). Other than that, a differential equation MUST contain a derivative, but it may contain additional things like different levels of derivatives, other variables, etc. Is this understanding correct? 



#4
Dec1712, 12:48 AM

P: 136

What is the difference between a differential equation and a derivative?
I have what may help as a perspective as I often find myself trying to explain what differential equations is to people that took calculus but stopped after that. You seem to be in that position. We'll stick with the traditional definition (something along the lines of what) Astronuc gave you: a derivative is the instantaneous slope of a function.
Let's generalize this definition a bit, and let just make clear that when i say "nth order derivative" of y(x) , I'm referring to the 0th order of y(x) as just y(x), i.e. [itex] y^{(n)}(x) [/itex], such that n=0. Notice that the equation you provided for [itex] y^{'}(x) = 2x [/itex] is just an equation involving one "nth order derivative" of y(x). A differential equation involves more than one of these nth order derivatives. A differential equation can be expressed as a function, we'll call it g, set to 0 (if required by simply moving all terms over to one side). [itex] g(x,y^{(n)}(x),y^{(k)}(x),...)=0[/itex]. It's still not a differential equation until I tell you that n=/=k. and keep in mind it can involve even more derivatives. A differential equation is a generalized relationship between different orders of derivatives. "Solving the equation" means finding a closed form expression for y(x). In most calculus problems, you're usually given f(x) or y(x) , or you've found it from the physics of a given problem, and you're asked to find the derivative  you follow rules and patterns you learn from the limit definition. Usually, however (at least in more realistic scenarios), we can't directly come up with an expression for f(x) or y(x), just the relationship between various derivatives of y(x) or f(x) and "solve the differential equation". 



#5
Dec1712, 10:59 AM

P: 685

A differential equation is an equation that contains a function f(x) and one or more derivatives of f(x).
Example 1: f(x) = f ''(x) This is a differential equation since it contains f(x) and the second derivative f ''(x). The goal is to find a function f(x) that fulfills the differential equation. Such an f(x) is called the solution of the differential equation. For the above equation a solution is given by f(x) = sin(x). Let us verify this: f(x) = sin(x) f '(x) = cos(x) f ''(x) = sin(x) We find that f(x)= sin(x) = (sin(x)) = f ''(x) such that f(x) = f ''(x). Example 2: Let us consider the equation 2*f(x)  x*f '(x) = 0 The equation is a differential equation since it contains the function f(x) and its first derivative f '(x). Verify that f(x) = x^2 is a solution for the differential equation. Example 3: f(x) = f '(x) Do you know a function f(x) that fulfills this differential equation? Example 4: f ''(x)*f(x)  x*f '(x) = 0 Verify that f(x) = x^2 is a solution. 



#6
Dec2712, 12:05 PM

P: 11

The difference is that a derivative, in an abstract sense, is a mathematical operation you apply onto a function/variable (like logarithms, exponentiation, square roots, etc). A differential equation is an equation that justsohappens to contain derivatives. Here's a simple example:
we call x^{5} + 5x + 1 = 0 a polynomial equation because the variables are exponentiated (raised to a certain power). we also call 5d^{2}x/dt^{2}  2 dx/dt  10 = 0 a differential equation because it contains derivatives (aka differentials). And just like any other equation, we normally want to solve for the variables being operated on. This is a sort of heuristic explanation. I hope you find it helpful! 


Register to reply 
Related Discussions  
Any help on this firstorder differentialdifference equation ?  Differential Equations  0  
Differential equation question, 4th derivative of y + y = 0  Calculus & Beyond Homework  12  
Difference equation vs differential equation  Electrical Engineering  2  
Separable Differential Equation (Perfect Derivative)  Calculus & Beyond Homework  13  
Reducible Second Order Differential Equation: Ind. and First Derivative Missing  Calculus & Beyond Homework  2 