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What is the global solution of an ordinary differential equation?
The global solution of an ordinary differential equation (ODE) is a solution of which there are no extensions; i.e. you can't add a solution to the global solution to make it more general, the global solution is as general as it gets.
What is the general solution of a differential equation?
It is the solution of a differential equation without there being any restrictions on the variables (No boundary conditions are given). Presence of arbitrary constants indicates a general solution, the number of arbitrary constants depending on the order of the differential equation.
What is a numerical solution of a partial differential equation?
Some partial differential equations do not have analytical solutions. These can only be solved numerically.
Why you need the numerical solution of partial differential equations?
Very often because no analytical solution is available.
What is the local solution of an ordinary differential equation?
The local solution of an ordinary differential equation (ODE) is the solution you get at a specific point of the function involved in the differential equation. One can Taylor expand the function at this point, turning non-linear ODEs into linear ones, if needed, to find the behavior of the solution around that one specific point. Of course, a local solution tells you very little about the ODE's global solution, but sometimes you don't want to know that anyways.
What is the global solution of an ordinary differential equation?
The global solution of an ordinary differential equation (ODE) is a solution of which there are no extensions; i.e. you can't add a solution to the global solution to make it more general, the global solution is as general as it gets.
What is the general solution of a differential equation?
It is the solution of a differential equation without there being any restrictions on the variables (No boundary conditions are given). Presence of arbitrary constants indicates a general solution, the number of arbitrary constants depending on the order of the differential equation.
What is a numerical solution of a partial differential equation?
Some partial differential equations do not have analytical solutions. These can only be solved numerically.
What is impulsive system in differential equation?
A differential equation have a solution. It is continuous in the given region, but the solution of the impulsive differential equations have piecewise continuous. The impulsive differential system have first order discontinuity. This type of problems have more applications in day today life. Impulses are arise more natural in evolution system.
Why you need the numerical solution of partial differential equations?
Very often because no analytical solution is available.
What is the local solution of an ordinary differential equation?
The local solution of an ordinary differential equation (ODE) is the solution you get at a specific point of the function involved in the differential equation. One can Taylor expand the function at this point, turning non-linear ODEs into linear ones, if needed, to find the behavior of the solution around that one specific point. Of course, a local solution tells you very little about the ODE's global solution, but sometimes you don't want to know that anyways.
What is oscillatory solution in differential equations?
It happens when the solution for the equation is periodic and contains oscillatory functions such as cos, sin and their combinations.
What is the significance of the boundary condition in the context of solving differential equations?
The boundary condition is important in solving differential equations because it provides additional information that helps determine the specific solution to the equation. It helps to define the behavior of the solution at the boundaries of the domain, ensuring that the solution is unique and accurate.
What is the solution to the damped pendulum differential equation?
The solution to the damped pendulum differential equation involves using mathematical techniques to find the motion of a pendulum that is affected by damping forces. The solution typically involves finding the general solution using methods such as separation of variables or Laplace transforms, and then applying initial conditions to determine the specific motion of the pendulum.
The solution to the differential equation dydxx2y3 , where y (3) 3 is?
y = 43x3+45‾‾‾‾‾‾‾‾‾‾√4
What are the differences between Neumann and Dirichlet boundary conditions in the context of solving partial differential equations?
Neumann boundary conditions specify the derivative of the solution at the boundary, while Dirichlet boundary conditions specify the value of the solution at the boundary. These conditions affect how the solution behaves at the boundary when solving partial differential equations.
What is monge's Method?
Monge's method, also known as the method of characteristics, is a mathematical technique used to solve certain types of partial differential equations. It involves transforming a partial differential equation into a system of ordinary differential equations by introducing characteristic curves. By solving these ordinary differential equations, one can find a solution to the original partial differential equation.
