Series and Parallel Circuits | Electricity | Physics | FuseSchool

FuseSchool - Global Education

22 Jun 202104:56

Summary

TLDRThis script explains the basics of electrical circuits, focusing on series and parallel configurations. It describes how components are connected and the flow of current in each. The script also covers voltage, measured in volts, and how it represents the energy push from a battery. It introduces the use of voltmeters and ammeters, explaining their connection methods. The concept of resistance, measured in ohms, is explored, along with how it affects current flow. The script concludes with calculations for total voltage, current, and resistance in both series and parallel circuits, providing examples to illustrate the principles.

Takeaways

🔌 There are two main types of electrical circuits: series and parallel.
🔄 In a series circuit, components are connected end-to-end, creating a single path for current flow.
🔄 In a parallel circuit, components are connected side-by-side, allowing current to divide and flow in multiple paths.
🔋 Voltage is the electrical push provided by a battery, measured in joules per coulomb (volts).
🔌 Voltmeters measure voltage and are always connected in parallel to the circuit.
💧 Current is the flow of negatively charged electrons in a circuit, analogous to water flowing in a pipe.
📏 Resistance is the opposition to current flow, measured in ohms (symbolized by the Greek letter omega).
🔗 In series circuits, the total voltage is shared among components, with the same current flowing through each.
🔗 In parallel circuits, the voltage across each component is the same, but the total current is the sum of the individual currents.
🔢 The total resistance in a series circuit is the sum of the individual resistances.
🔢 The total resistance in a parallel circuit is less than the smallest individual resistance, calculated using specific formulas.
📘 The script provides examples of calculating voltage, current, and resistance in both series and parallel circuits.

Q & A

What are the two main types of electrical circuits?
-The two main types of electrical circuits are series and parallel circuits.
How are components connected in a series circuit?
-In a series circuit, components are connected end to end, one after the other, forming a simple loop for the current to flow round.
What is the difference between a series and a parallel circuit?
-In a series circuit, components are connected end to end with a single path for current flow, whereas in a parallel circuit, components are connected side by side allowing the current to divide and flow in multiple paths.
What is voltage and how is it measured?
-Voltage is a measure of the electrical push that the battery gives to the electrons, representing the energy in joules given to each packet of electrons. It is measured in volts using a voltmeter.
How should a voltmeter be connected in a circuit?
-A voltmeter should always be connected in parallel when added to a circuit to measure the voltage across a component.
What is the relationship between current, coulombs, and amps?
-Electric current is the flow of negatively charged electrons, measured in coulombs per second, which is equivalent to amps.
How is an ammeter connected in a circuit?
-An ammeter must be connected in series with the circuit to measure the current flowing through it.
What is resistance and how is it measured?
-Resistance is a measure of the opposition to current flow in an electrical circuit and is measured in ohms, symbolized by the Greek letter omega.
How does the total voltage in a series circuit relate to individual components?
-In a series circuit, the total voltage or potential difference of the power supply is shared between the components, with the same current flowing through each component.
What is the formula for calculating total resistance when resistors are in parallel?
-When resistors are in parallel, the total resistance (R) can be calculated using the formula: 1/R = 1/R1 + 1/R2, where R1 and R2 are the resistances of the individual components.
How does the total current in a parallel circuit compare to the currents through individual components?
-In a parallel circuit, the total current through the whole circuit is the sum of the currents through the separate components.
If each cell provides a potential difference of 1.5 volts, what is the total potential difference provided by four cells in a circuit?
-The total potential difference provided by four cells in a circuit would be 4 times 1.5 volts, which equals 6 volts.
If the current through a lamp is 0.20 amps and through a resistor is 0.10 amps, what would be the reading on the ammeter in a parallel circuit?
-In a parallel circuit, the reading on the ammeter would be the sum of the currents through the lamp and the resistor, which is 0.20 amps + 0.10 amps = 0.30 amps.