David Elbert said:
ZapperZ said:
Not just applying a voltage for an instant but varying the voltage will carry information. Binary signalling with just two levels, ternary signalling with three levels etc. And there are many other more complex strategies, many of them involving a ' carrier wave' that is modulated to increase the channel capacity further.David Elbert said:
Then you have taken classes that should have explained this, no?David Elbert said:
If the conductivity of the metal wires were infinite, I could understand some confusion. But the conductivity is finite, so the voltage drop and driving electric fields are ________?David Elbert said:
You are expressing one of the most common problems that people have with 'Electricity'. (I know you have a good answer, btwberkeman said:If the conductivity of the metal wires were infinite, I could understand some confusion. But the conductivity is finite, so the voltage drop and driving electric fields are ________?
) The mechanism of Power transfer through a wire is always being confused with the loss mechanism. This is not a worry for other power / signal transfer systems. When we describe a bicycle chain transferring the Power from feet to wheel, do we consider the hysteresis and friction in the chain in order to describe how the system works? Do we instantly worry about internal losses in air or solids when we think of sound being transferred? (only way down the line of reasoning) There is something about 'Electricity' that makes us think differently. We can't just be happy with the fact that very high Electric forces between particles result in 'one in one out' for charges in a wire but for some reason we worry about losses. It's only in circuits where there is a problem putting in enough copper that the resistance of the wires is relevant. If we want to manufacture a "resistance" we have to go to some trouble and find a fancy alloy (or Carbon) with enough Resistivity to give us 10kΩ in a small package. Electrical signals are changes in the flow of electric charge, which can be transmitted through wires. These signals propagate through the wire as a result of the movement of electrons, which are negatively charged particles, through the conductive material of the wire.
Electrical signals travel through wires by creating a chain reaction of electrons. When a voltage is applied to one end of the wire, the electrons at that end start to move, pushing the electrons in the neighboring atoms to move as well. This process continues down the wire, creating a flow of electrons and thus transmitting the electrical signal.
The speed at which electrical signals propagate through wires is affected by several factors, including the type of material the wire is made of, the thickness and length of the wire, and the temperature of the wire. In general, thicker and shorter wires made of highly conductive materials will allow for faster propagation of electrical signals.
As electrical signals travel through wires, they experience resistance from the material of the wire. This resistance causes some energy to be lost in the form of heat. However, electrical signals also possess the ability to regenerate themselves as they travel, which helps to maintain their strength and allows them to travel long distances without significant loss of energy.
Yes, electrical signals can travel in both directions through a wire. This is because electrons are not limited to moving in only one direction. The direction of the signal will depend on the source of the voltage and the direction of the flow of electrons. For example, in household wiring, electricity flows from the power source to the appliance, but in electronic circuits, signals can travel in both directions depending on the design of the circuit.