Introducing Weird Differential Equations: Delay, Fractional, Integro, Stochastic!

Faculty of Khan

3 Aug 202007:56

Summary

TLDRThis educational video introduces viewers to four unusual types of differential equations: delay, integral, stochastic, and fractional. Delay differential equations (DDEs) are notable for their dependence on past values of the function. Integral differential equations combine derivatives and integrals of the function. Stochastic differential equations incorporate random fluctuations, while fractional differential equations involve non-integer order derivatives. The video briefly explains these concepts and mentions methods for solving them, such as the method of steps for DDEs and Laplace transforms for integral equations, without going into complex mathematical details.

Takeaways

📚 The lesson introduces four types of unusual differential equations not typically covered in early undergraduate courses.
🕒 Delay Differential Equations (DDEs) depend on the value of the dependent variable at a previous time, not just the present.
🔍 There are three types of DDEs: continuous delay, fixed and discrete delay, and scaled delay, with the latter including the pantograph equation as a special case.
📉 Solving DDEs requires specifying an initial function over a time interval, rather than a single initial condition, due to their dependence on past values.
👣 The method of steps is a special technique used to solve DDEs with discrete delays by iteratively solving over intervals.
🧩 Integral Differential Equations include both derivatives and integrals of the function of interest, and can be solved using integral transforms for simple cases.
🔄 Stochastic Differential Equations incorporate random fluctuations or 'white noise' terms, requiring techniques from stochastic calculus and numerical methods for solutions.
🎲 Fractional Differential Equations involve fractional derivatives, which are derived from fractional calculus allowing for non-integer orders of differentiation.
🎯 Fractional calculus extends the concept of differentiation to allow for taking derivatives of real or even complex numbers, not just integers.
👨‍🏫 The video is educational, aiming to introduce and explain these advanced types of differential equations to a presumably upper-level audience.
🌟 The video concludes with acknowledgments to patrons and an invitation for viewers to like and subscribe for more content.

Q & A

What are the four types of 'weird' differential equations mentioned in the lesson?
-The four types of 'weird' differential equations discussed are delay differential equations (DDEs), integral differential equations, fractional differential equations, and stochastic differential equations.
What is a delay differential equation (DDE)?
-A delay differential equation (DDE) is a differential equation that depends on the value of the dependent variable x at a previous time, denoted as x(t-tau), where tau represents the time delay.
Can you explain the three types of delay differential equations?
-The three types of DDEs are: 1) Continuous delay DDE, which depends on the sum of all possible past values of x. 2) Fixed and discrete delay DDE, where the delay is a fixed amount of time. 3) Scale delay DDE, which depends on a previous value of x corresponding to lambda times t, where lambda is a constant between 0 and 1.
What is the method of steps used for solving delay differential equations?
-The method of steps involves specifying an initial function from negative tau to 0, and then iteratively substituting the function into the DDE to solve for x(t) over successive intervals of tau units of time.
How does an integral differential equation differ from a regular differential equation?
-An integral differential equation contains both derivatives and integrals of the function of interest, unlike regular differential equations which only involve derivatives.
What is a stochastic differential equation?
-A stochastic differential equation is a differential equation that includes a random fluctuating or stochastic process, often represented by a term involving sigma(x, t) times epsilon(t), where epsilon is a white noise term.
What is fractional calculus and how does it relate to fractional differential equations?
-Fractional calculus is a field of study that allows for the taking of non-integer order derivatives, such as half or quarter derivatives. Fractional differential equations involve these fractional derivatives of an unknown function.
Why is it necessary to specify an initial function for a delay differential equation with a discrete delay?
-Specifying an initial function is necessary because to determine the value of dx/dt at a future time, one needs the value of x at previous times, which is not provided by just an initial condition at t=0.
How can integral transforms be used to solve integral differential equations?
-Integral transforms, such as the Laplace transform, can be used to convert integral differential equations into a form that is easier to solve analytically, especially for simple linear cases.
What techniques are used to solve stochastic differential equations?
-Solving stochastic differential equations typically involves using techniques from stochastic calculus in combination with numerical methods.