What is Electric Current?
The electric current is one of the most important and fundamental elements in our day-to-day life. The current flowing in a circuit can be used for various purposes from generating heat to causing circuits to switch, or storing information in an integrated circuit. We have come across a lot about electric currents in our classrooms as well as at home. The flow of current or charge in electric circuits is called an Electric current. Sometimes both ions and electrons carry the charge at the same time. Electric current or charge is measured using an ammeter. There are different measurement methods and units of current. Here is a detailed explanation of current, its SI unit, standard electrical units and measurement.
What is Electric Current?
We hear a lot about electric currents in our daily life: in the classroom as well as at our home. The electric current in terms of scientific understanding is basically the flow of current or charge in electric circuits. The charge is sometimes simultaneously carried by the ions and electrons.
The charge of the current flowing through the circuit needs to be measured. It enables us to understand the performance of the circuit and the circuit to operate as required. Electric current is measured by an ammeter and its unit is Ampere or Amp. However, nowadays there are different measurement methods for taking the unit of current.
SI Unit of Electric Current
The SI unit of current is Ampere. It can be used to measure the flow of electric charge across a surface at the rate of one coulomb per second. Since the charge is measured in coulombs and seconds the unit is coulomb/Sec (C/s) or amp. The formula for electric current is,
\[ I = \frac {V}{R}\]
Where,
I = Electric Current.
V = Voltage.
R = Resistance of the material.
What is the Unit of Current?
To define the unit of current, the Ampere is nominated after Andre-Marie Ampere, who was one of the early forerunners in electrical science. However, the practical realization of the Ampere is equivalent to a charge of coulomb per second flowing in a circuit. The formal description of an ampere is the constant current which if continuous in two straight parallel conductors of infinite length, of insignificant circular cross-section, and placed one meter apart in vaccum, would yield between these conductors a force equal to newton per meter of length.
Interestingly, one ampere is roughly equivalent to approx elementary charges such as holes or electrons going past a given point or limit in one second. Physicists consider current to flow from moderately positive points to somewhat negative points; this is called standard current or Franklin current. This definition uses electromagnetism to define the unit of current. This starts to implicitly verify the value for the magnetic constant. Therefore, the base unit ampere and thus, all other electrical units are associated with the base unit's meter, kilogram, and second via this important constant.
In written languages, without accentuated letters (namely English), it has become normal to write the unit as Ampere and, in confidential communication, to reduce the word to an amp. There is no need to use capital "A" at the starting Ampere as implied to physicists. Here, Ampere (or amp) suggests a unit.
This is an algebraic link, not a definition. An Ampere is a vital unit in the International System while other units are obtained from it. Here, the fundamental units identify this research. In the case of the Ampere, the testing is electromagnetic in nature. Some Standard Electrical Units of Measure
Separately from Ampere, there are many standard units of measurement used for the articulation of electrical properties like the voltage, power, capacitance, resistance, inductance, electric field, electric charge, frequency, the magnetic flux which are all line to electric current.
How to Measure the Unit of Current?
Ampere meter, normally known as Ammeter, is an electrical device used to measure electrical current in Amperes. The electrical current on the load is quantified with the help of an Ampere meter by linking it in series to the load. It has zero resistance, and so the calculated circuit remains unchanged.
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The Ammeter cannot be linked in parallel to the load because of its minimal resistance. If it is linked in parallel, it becomes a short circuit path granting all the current to flow through it, which may be steered to the burning of the meter due to the elevated value of current. An ultimate ammeter has zero impedance so that the power failure in the instrument is zero. But this ideal situation is not practically achievable. Types of Ammeter
The categorization of the Ammeter is based on the building design and the type of current that flows through it.
Based on the Layout of the Structure, it is Categorized as Follows:
Moving iron ammeter
Rectifier type ammeter
Permanent moving coil ammeter
Electro-dynamometer ammeter
Other Units of Current
Ampere is one of the SI units of current. Apart from ampere, there are various standard units to measure electrical properties such as voltage, resistance, power, capacitance, inductance, electric field, electric charge, frequency, and magnetic flux which are interrelated to electric current.
Voltage is calculated using Volt and is represented as V or E
Resistance is calculated using Ohm is represented as R or Ω
Capacitance is calculated using Farad is represented as C
Charge is calculated using Coulomb is represented as Q
Inductance is calculated using Henry is represented as L or H
Power is calculated using Watts is represented as W
Impedance is calculated using Ohm is represented as Z
Frequency is calculated using Hertz is represented as Hz
Conductance is calculated using Siemen is represented as G or ℧
FAQs on Unit of Current
1. What is the SI unit of electric current and how is it defined as per the CBSE 2025–26 syllabus?
The SI unit of electric current is the Ampere (A). One ampere is defined as the constant current that, if maintained in two straight parallel conductors of infinite length, one meter apart in vacuum, would produce a force of 2 × 10−7 newton per meter of length between those conductors. It is also equivalent to a flow of one coulomb of charge per second through any cross-section of a conductor.
2. How does electric current flow in a circuit, and what are its main carriers?
In a circuit, electric current flows due to the movement of electric charges, mainly electrons in metals. In electrolytes, both positive and negative ions can act as current carriers. The direction of conventional current is taken from the positive terminal to the negative terminal of a cell or power source.
3. What are the common devices used to measure electric current and how do they function?
The most common device to measure electric current is the Ammeter. An ammeter is connected in series with the electrical load so that all current flows through it. It typically has very low resistance to avoid affecting the circuit. Different types include:
- Moving iron ammeter
- Permanently moving coil ammeter
- Rectifier type ammeter
4. What is the difference between ampere and volt in the context of electric circuits?
Ampere measures the amount of electric current, while volt measures the electrical potential difference or voltage between two points. Current (in amperes) indicates the rate of flow of charge, whereas voltage (in volts) represents the energy per unit charge supplied or consumed in a circuit.
5. Why is the Ampere considered a fundamental unit in the International System of Units?
The Ampere is a base unit in the SI system because it is not derived from any other electrical quantity, but other units like volt (V), ohm (Ω), and watt (W) are defined using it. The relationships among these units are established through physical laws, such as Ohm's law: I = V/R, where I is current, V is voltage, and R is resistance.
6. How can you calculate the electric current in a circuit using Ohm's law?
To calculate electric current using Ohm's law:
- Use the formula I = V/R
- Where I is the current (in amperes), V is the voltage (in volts), and R is the resistance (in ohms)
- This formula helps determine the current when the voltage across and resistance of a circuit are known.
7. What is the practical significance of knowing the unit of current in real-life applications?
Knowing the unit of current (ampere) is crucial for designing and safely operating electrical devices. For example:
- Determining the capacity of wires and circuit breakers to prevent overheating
- Ensuring safe operation of appliances
- Measuring battery output and charging requirements
8. Compare the terms "conventional current" and "electron flow". How do they differ in direction?
Conventional current is defined as the flow of positive charge from the positive terminal to the negative terminal of a circuit. Electron flow is the actual movement of electrons, which is from the negative terminal to the positive terminal. The two are opposite in direction, but conventional current is used for circuit analysis.
9. What could happen if an ammeter with significant resistance is connected in parallel with the load?
If an ammeter with appreciable resistance is connected in parallel, it may create a short-circuit path because current prefers the path of least resistance. This can lead to:
- All current passing through the ammeter, possibly damaging it
- Overheating and risk of fire
- Incorrect current measurement and circuit malfunction
10. Why is it necessary for students to understand the relationship between current, voltage, and resistance for board exams?
Understanding the relationship between current, voltage, and resistance (Ohm's Law) helps students to solve numerical and conceptual questions accurately, forms the foundation for advanced physics topics, and is often tested in board exams with high-weightage problems.
