E = f/q
=mlt-2/at
=mla-1t-1
The symbol "I " was used by André-Marie Ampère, after whom the unit of electric current is named and stands for "intensité de courant": Current Intensity.
Amperage refers to the amount of electric current flowingthrough a circuit and is measured in amperes, or amps. Theamount of water flowing through a pipe can be compared toamperage. Amperage is abbreviated A or I.So the answer is= "A" or "I"Unit of Electric Current is= "A"I is the symbol for current (I traditionally means intensity). Current is measured in amperes (symbol = A).Letter ' I 'Other letters used as symbols for electricity or charge:Either 'e' or 'v' for potential difference (voltage)'Q' for charge (coulombs)'R' for resistance (ohms)'C' for capacitance (farads)'L' for inductance (Henrys).Unit of Electric Current is= "A"I is the symbol for current (I traditionally means intensity). Current is measured in amperes (symbol = A).Letter ' I 'Other letters used as symbols for electricity or charge:Either 'e' or 'v' for potential difference (voltage)'Q' for charge (coulombs)'R' for resistance (ohms)'C' for capacitance (farads)'L' for inductance (Henrys).
The electric motor changes electric energy into mechanical energy.
The vividness or dullness of a color
Electricity is the interaction of many components. These include electric charges, electric fields, electric potentials, electric currents, and electromagnets.
The abbreviation for electric intensity is " I " the intensity is measured in amps using an ammeter.
Electric field intensity is related to electric potential by the equation E = -∇V, where E is the electric field intensity and V is the electric potential. This means that the electric field points in the direction of steepest decrease of the electric potential. In other words, the electric field intensity is the negative gradient of the electric potential.
The unit of electric intensity is volts per meter (V/m). Electric intensity represents the electric field strength at a specific point in space and is measured in terms of volts per meter.
The electric field intensity at the midpoint of a dipole is zero. This is because the electric fields created by the positive and negative charges of the dipole cancel each other out at that point, resulting in a net electric field intensity of zero.
Electric flux.
Electric field intensity is related to electric potential by the equation E = -dV/dx, where E is the electric field intensity, V is the electric potential, and x is the distance in the direction of the field. Essentially, the electric field points in the direction of decreasing potential, and the magnitude of the field is related to the rate at which the potential changes.
It is represented with [C] or [Q] and recently [A]it varies from bk 2 bk
The intensity of an electric field is determined by the amount of charge creating the field and the distance from the charge. The closer you are to the charge, the stronger the electric field will be.
The dimension of electric potential is energy per unit charge, which is equivalent to joules per coulomb or volts. It is a scalar quantity that represents the amount of work needed to move a unit positive charge from a reference point to a specific point in an electric field.
Yes, electric field intensity is a vector quantity because it has both magnitude and direction. The direction of the electric field intensity indicates the direction of the force that a positive test charge would experience if placed in that field.
Electricity Man
At the center of an electric dipole, the electric field vectors from the positive and negative charges cancel each other out due to their opposite directions. This results in a net electric field intensity of zero at the center of the dipole.