Phrak said:"RL circuit with dependent voltage source and indep. current source with unit step"
Do you know what this shorthand means?
And do you know what the shorthand "inductor assumed to have no energy stored" means?
This looks like hasty notes scibbled in class, as the professor talks to fast. But it's important to know what these mean.
tritium_3 said:OK, maybe the title isn't accurate of the circuit, but i listed everything in the circuit. excuse me if it has some other meaning.
and also I was trying to add addtional details, saying that there was no mention of stored charge in the inductor. But this problem isn't a tranisent problem anyway, so that has no relevance..
these are not scribbled notes, this is a homework assignment, on a printed piece of paper. It seems the instructor wrote this up too fast.
But If you cannot help me, just say nothing at all. I am no closer to finding the solution if you simply just question my methods of describing the problem.
tritium_3 said:right. I was just using the notion commonly used in my textbook. The voltage source is dependent because it depends on the value of Vx. The current source is independent since it provides 100Amps constantly no matter what, after time 0. Using circle as independent, and diamond as dependent. that's all i meant.
thanks for the hint. i see that from -infinity to 0 the current hasn't changed, so the V in inductor is 0.
An inductor is a passive electronic component that is designed to store energy in the form of a magnetic field. It consists of a coil of wire that is wound around a core material, such as iron, and is commonly used in electronic circuits to control the flow of current.
When we say an inductor has no energy stored, it means that the magnetic field within the inductor has fully dissipated and there is no longer any stored energy within the component. This can happen when the current flowing through the inductor has been interrupted or when the inductor has been disconnected from the circuit.
Finding Vx, the voltage across the inductor, is important because it allows us to determine the current flowing through the inductor. This information is necessary for analyzing and designing electronic circuits, as well as troubleshooting any issues that may arise.
To find Vx for an inductor assumed to have no energy stored, we can use the equation Vx = L(di/dt), where L is the inductance of the component and di/dt is the rate of change of current. If we know the inductance and the current flowing through the inductor before it was disconnected, we can calculate Vx.
The voltage across an inductor can be affected by factors such as the inductance of the component, the current flowing through it, and the rate at which the current changes. It can also be affected by external factors such as the presence of other components in the circuit, the type of core material used in the inductor, and any resistance in the circuit.