1) What materials the conductor is made of;
2) the average cross-sectional area along the length of the conductor;
3) the temperature of a conductor also affects its resistance;
4) the length of the conductor is also very important.
Generally, the longer the conductor, the higher its resistance.
Your students' course materials can probably give you a better answer than mine, or at least you'll know it is the right one.
The length, the cross sectional area, temperature of conductor along with the intrinsic property called the specific resistance of the substance.
This are the factor which affect resistance of a conductor (1). Area of conductor (2). Length of conductor (3) Temperature (4). Type or substance of material used in conducting the electricity.
It depends on the intermolecular structure of the individual material. It varies for various material.
Generalised formula for calculating the resistance of any material is :
R = k* L/A
Where
R = Total Resistance.
K = Specific Resistance of the material.
A = cross-sectional area of material for which resistance is measured.
The material it is made from. The temperature and use.
resistance is not affected by either voltage or current.it is either too low or too heigh
the material the resistance is
temperature
area of the conductor, length of the conductor and temperature around the conductor..........
Conductor resistance = Conductor resistivity * Length of conductor / Cross sectional area of conductor. So. It is directly proportional to material & conductor length. And inversely proportional to the cross sectional area of conductor.
Any load would do or anything that has resistance. Which is pretty much everything you can hook up to a circuit. For example, lightbulb, buzzer, resistor etc.
the answer is current, voltage, and resistance
There isn't a specific standard length for the unprotected length of a tap conductor in relation to the current carrying capacity of a main conductor. The length of the tap conductor is typically determined by factors such as voltage drop and local electrical codes. It is recommended to consult the National Electrical Code (NEC) or an electrical professional for specific guidance on tap conductor lengths.
Factors affecting the resistance of a conductor include the material from which it is made, its length, its cross-sectional area, and its temperature.
The factors are: length, cross-sectional area and nature of substance.
area of the conductor, length of the conductor and temperature around the conductor..........
Conductor resistance = Conductor resistivity * Length of conductor / Cross sectional area of conductor. So. It is directly proportional to material & conductor length. And inversely proportional to the cross sectional area of conductor.
The factors that determine resistance are thickness, length, temperature, and the conductivity of the resistance of an object
1) What materials the conductor is made of;2) the average cross-sectional area along the length of the conductor;3) the temperature of a conductor also affects its resistance;4) the length of the conductor is also very important.Generally, the longer the conductor, the higher its resistance.Your students' course materials can probably give you a better answer than mine, or at least you'll know it is the right one.
Resistance is affected by the length, cross-sectional area, and resistivity of the conductor. The resistivity, in turn, is affected by temperature. So only by changing one of these four factors will the resistance of a conductor change. Changing voltage will have no affect upon the conductor's resistance.
The material, the length, the cross section.
electrical resistance increases current flow decreases.so to know the current flow in the network ,electrical resistance is required.AnswerResistivity is important, because it is one of the three factors that affect the resistance of a material. The other factors are the length and cross-sectional area of the material.
Any load would do or anything that has resistance. Which is pretty much everything you can hook up to a circuit. For example, lightbulb, buzzer, resistor etc.
Magnetism does not affect the resistance of a conductor. The factors affecting resistance are the conductor's length, cross-sectional area, and resistivity. As resistivity is affected by temperature, temperature indirectly affects resistance. However, the changing magnetic field surrounding a conductor carrying an AC current causes the current to flow closer to the surface rather than being distributed throughout the cross-section of the conductor. The greater the frequency, the greater this effect. This has the equivalent effect of reducing the cross-sectional area of the conductor, causing its resistance to rise. This is misleadingly called the 'AC resistance' of the conductor!
the answer is current, voltage, and resistance