Well, you can't reduce the applied voltage and have a higher current through a fixed resistance as it contradicts Ohm's law.bbrianc said:Thanks for the correction! I forgot to add the goal of keeping constant power my mistake. Original question edited. Thank you
Forgetting your mistake about lower voltage meaning higher current, since I understand what you mean, you could, in theory, probably go a lot lower than it would be possible to measure, given the sensitivity and precision of actual voltage and current meters, so it's interesting only in a theoretical way. In practical terms you would also run into problems trying to create a voltage source that would produce extremely low voltages and extremely high currents. This too, would be a limiting factor in practical terms.bbrianc said:Simple premise: take ohms law with a purely resistive ac circuit. 1 volt through in series with a 2 ohm resistor, I have 0.5 amps of current. I want to maintain constant power. In practice, "how low can I go" with the voltage to increase the current? There's probably many variables I'm missing, so please feel free to mention them. If it's more straight forward to use rms for voltage that's fine. Thank you for your responses!
Well I'm just guessing as well. Hopefully the OP will get back and clarify the direction, it was pretty open ended I think.magoo said:If that's the case, then you can ignore my post. Sorry if I misunderstood.
NTL2009 said:I think the OP is asking something like - does the formula fall apart near the electron-volt level? Or, can we even have a current if the source were below the electron-volt level?
NTL2009 said:I think the OP is asking something like - does the formula fall apart near the electron-volt level? Or, can we even have a current if the source were below the electron-volt level?
Winding n turns on a coil gives n times the magnetic field of one turn. The wire is n times longer and the wire cross-section is proportional to 1/n, so the wire weighs the same. If the voltage available is known, then the current will be limited by resistance. You choose the wire size, and the number of turns, so as to match the coil resistance to the power supply voltage.bbrianc said:My basic thought experiment is related to magnetism actually.
Ohm's law is a fundamental principle in electricity that states that the current through a conductor between two points is directly proportional to the voltage across the two points, and inversely proportional to the resistance between them.
Yes, there are practical limits to Ohm's law. As the voltage increases, the current may reach a point where the resistance of the conductor causes it to heat up and potentially melt, leading to a breakdown of the circuit. This is known as the maximum power dissipation limit.
No, Ohm's law is not applicable to all materials. It is only applicable to materials that have a linear relationship between voltage and current, known as ohmic materials. Materials such as diodes and transistors do not follow Ohm's law.
Temperature can have an impact on Ohm's law. As the temperature of a conductor increases, its resistance also increases. This can result in a decrease in current, even if the voltage remains the same. Therefore, Ohm's law is only accurate for a given temperature.
The length and thickness of a conductor can affect Ohm's law. As the length of a conductor increases, its resistance also increases, resulting in a decrease in current. On the other hand, as the thickness of a conductor increases, its resistance decreases, leading to an increase in current.