This equation is a first-order linear differential equation that is commonly used in mathematical and scientific fields to model various physical phenomena, such as chemical reactions, population growth, and heat transfer.
To solve this equation, you can use the method of separation of variables. This involves isolating the variables dy and dx on opposite sides of the equation and then integrating both sides to obtain the general solution. You can also use other techniques such as substitution or the integrating factor method.
The initial condition y(0)=-1 represents the value of the dependent variable y at the initial value of the independent variable x=0. This information is necessary to find the particular solution of the differential equation.
This equation can be solved analytically using various methods as mentioned in the answer to question 2. However, in some cases, the equation may be too complex to solve analytically, and numerical methods such as Euler's method or Runge-Kutta methods may be required to approximate the solution.
This type of differential equation has numerous real-world applications in fields such as physics, chemistry, biology, engineering, and economics. It can be used to model various processes and make predictions about their behavior, which can then be used to inform decision making and problem-solving.