Measuring A Resistor | Understand Resistor Color Codes

Practical ways to measure resistance:

As a beginner, you might find it difficult. Believe me, it is simple and fascinating. You can measure resistance using a multimeter or with the help of colour codes.

Using Multimeter:

An ohmmeter is an instrument used to measure the value of resistance. Today, you might not find an ohmmeter. Because it is a part of a multimeter.

A multimeter is an instrument that combines several measuring instruments. Usually, you can measure voltage, current and resistance with a multimeter.

A multimeter is a handy instrument for measuring resistances. Adjust the multimeter knob such that it can measure resistance. There are various ranges available like kΩ, MΩ etc. Place the resistor in parallel with the multimeter. You can also check for open and short-circuit.

Touch the probes with resistor legs. If the meter reads “1” or “OL”, it means overload. Select higher ranges. If the meter reads “0.00”, then select lower ranges.

Keep in mind that the resistance may vary due to temperature and tolerance level.

Understand the colour coding:

Even if you are a beginner, you must have seen a resistor. You also observe the different colour bands painted on resistors. Each colour represents a number and every band has a different value. These colour bands help determine the resistance of resistors as well as the tolerance level. Now we will learn how to read the resistor value from these colour codes.

Colour-code is a system of standards for the identification of resistances of resistors. The colours painted on the resistor body are called colour bands.

There are three different types of marking standards for resistors. Some resistors are marked with four bands of colours, some are marked with five bands of colours. We will see each standard in detail in the next section.

The multiplier band is a decimal multiplier.

The tolerance band gives you accuracy. It indicates the difference between the actual value and theoretical value. It is measured in percent. You can measure the actual value with the help of a multimeter. While theoretical value can be determined from the colour codes. The gold band means +/- 5% tolerance. A 1000 ohm resistor with a gold band means its value is between 950-1050 ohms.

TCR stands for the temperature coefficient of resistors. It is defined as the rate of change of resistance of a resistor with the temperature change. It is available in high precision resistors only.

Digits	Colour Codes	Multiplier	Tolerance	TCR
0	Black	100
1	Brown	101	+/- 1%	100
2	Red	102	+/- 2%	50
3	Orange	103		15
4	Yellow	104		25
5	Green	105	+/- 0.5%
6	Blue	106	+/- 0.25%	10
7	Violet	107	+/- 0.1%	5
8	Gray	108
9	White	109
	Silver		+/- 5%
	Gold		+/- 10%

Four band resistors:

Four band resistors are the most commonly used. The placement of colour bands on the resistor is very important.  3 bands are painted on the left, while 4th is on the right. Put a resistor read it from your left, the tolerance band is on your right.

• 1st band represent the first significant value
• 2nd band represent the second significant value
• 3rd band is a multiplier.
• 4th band is a tolerance band. The tolerance band is separated from the others.

You can get your resistor value with the help of the following formula. This is applicable for +/- 5 % tolerance carbon film resistors.

R = (a*10 + b)m +/- tolerance

Where,

a and b are the values of the first and second band,

m is the multiplier band.  

Example:

Look at the figure above, it shows a 4 band resistor. Brown, black, red and gold colour band. How do you know the resistance value?

Brown >> 1 >> 1st significant digit

Black >> 0 >> 2nd significant digit

Red >> 2 >> multiplier

Gold >> +/- 5% >> tolerance

The theoretical resistance of above resistor is 10*102 = 10*100 = 1000 ohms.

The actual value may vary from 950 ohms to 1050 ohms. Evaluate 5% of 1000 ohm, which is 50. The 5% tolerance shows the precision of the resistor.

Five band resistors:

The placement of colour bands on a five-band resistor is such that 4 bands are painted closely while the 5th band is painted such that it is separated by a small distance.

• 1st band represent the first significant value
• 2nd band represent the second significant value
• 3rd band represent the third significant value
• 4th band is a multiplier
• 5th band is a tolerance band. The tolerance band is separated from the others

Example:

Look at the figure above, it shows a 6 band resistor. Brown, blue, black, yellow, brown, red colour band. How do you know the resistance value?

Yellow >> 4 >> 1st significant digit

Violet >> 7 >> 2nd significant digit

Black >> 0 >> 3rd significant digit

Red >> 2 >> multiplier

Brown >> +/- 1% >> tolerance

The theoretical resistance of above resistor is 470*102 = 470*100 = 47000 ohms = 47 Kilo ohms.

To evaluate tolerance level, calculate the 1% of 47000, which is 470. The actual value of the above resistor may vary from 46530 to 47470.

Six band resistors:

The placement of colour bands on a six-band resistor is such that 4 bands are painted closely while the 5th and 6th bands are painted such that they are separated by a small distance.

• 1st band represent the first significant value
• 2nd band represent the second significant value
• 3rd band represent the third significant value
• 4th band is a multiplier
• 5th band is a tolerance band. The tolerance band is separated from the others
• 6th band TCR

Example:

Look at the figure above, it shows a 6 band resistor. Brown, blue, black, yellow, brown, red colour band. How do you know the resistance value?

Brown >> 1 >> 1st significant digit

Blue >> 6 >> 2nd significant digit

Black >> 0 >> 3rd significant digit

Yellow >> 4 >> multiplier

Red >> +/- 2% >> tolerance

Violet >> 5 >> TCR

The theoretical resistance of above resistor is 160*104 = 160*10000 = 1600000 ohms = 1.6 Mega ohms

To evaluate tolerance level, evaluate 2% of 1.6*106, which is 32000. The actual value of the resistor may vary from 1.56*106 ohms to 1.63*106 ohms.

Frequently Asked Questions:

Why don't manufacturers print numerical values on resistors?

Preciously, it is very difficult to print numerical values on a tiny component like resistors. Modern printing technologies are also available to print numerical values on resistors. But the colour-coded resistors are still popular.

A disadvantage of resistor colour codes

Colour blindness is a common problem, colour-coded resistance value might be problematic for such people.

Why do we measure resistance when there is no power?

It is advisable to isolate the resistor you want to measure and switch off the supply. This is because, when you place the multimeter probes to a resistor present in a circuit, it provides a small voltage and current flows through the resistor. With the help of Ohm's law, the resistance multimeter calculates the resistance.

If there is a supply voltage, the measured value of resistance is wrong. Also, if a resistor is placed in a circuit, other components may affect the value of resistance.

Checking for a defective resistor

A resistor can burn easily with over-voltage and is responsible for malfunctioning. A defective resistor can either be short or open internally. Now, we aim to check whether a resistor is defective or not.

Place the multimeter probes to the resistor, if the reading is too high as compared to its rated value then it is open-circuited internally. If the resistance is too low and approaches zero, then it is shorted internally. 

Resistors & Resistances - Definitions, Composition, Construction

Resistors - Introduction, Effect of Temperature on conductors and Semiconductors

In this article I am going to introduce the most important and basic passive element, that is a resistor. Resistor is a tiny two terminal element, that is used in electrical and electronic circuits for variety of purposes. Like divide voltages, limit currents, adjust signal levels, bias active elements etc. It is mainly used to limit the current through each component. The larger the resistance, the smaller the current.

Mostly students think this is a redundant element or the resistance is responsible for signal degradation. The article will help you to understand the importance and practicality of resistors in different types of applications. This is a detailed article, I tried to cover every aspect and every question on this topic.

Outline:

• What is resistor and resistance?
• Resistance of metals and semiconductors
• Temperature dependence of resistance
• 2 practical ways to measure resistance
• What is inside the resistor (construction, advantages, disadvantages, applications of different types of resistors)

• Types of resistors

• Linear resistors
• Variable resistors
• Semi Fixed resistors
• Fixed resistors
• Non linear resistors
• Thermistors
• LDR (Photoresistor)
• Varistors
• Special type of resistors
• Zero ohm
• Fusible resistor

• Series connected resistors
• Voltage division rule for series connected resistors
• Parallel connected resistors
• Current division rule for parallel connected resistors

Resistor, Resistance & Resistivity :

What do you know about resistors? It decreases the rate of flow of charges through the circuit.

Resistance is the measure of flow of charges through the circuit. While the opposite quantity is conductance, which is defined as the ease with which charges flow through the circuit. Every component in a circuit offers some internal resistance, it could be an ohmic resistance or non ohmic resistance. 

The electrical resistance of a component can also be defined as the ratio of voltage applied to the current flows through it.

R = V/I

The electrical resistance of a wire is dependent on size and geometry. Larger (L) wires offer more resistance. For larger cross sectional area (A) of wires offer less resistance.

R = ρ * L/A

Where, ρ is the coefficient called resistivity of the material.

Resistivity can be defined as resistance offered by per unit length and per unit cross sectional area. It is measured in (Ω⋅m). It is the ability of material to conduct or resist the flow of charges through the material. The higher the resistivity, the lower the flow of charges through the conductor.

Resistance and resistivity are temperature dependent. So it's time to understand temperature dependence of resistance.

Resistance and temperature dependence:

While, learning basic electronics we come across two types of conducting materials that are metals and semiconductors. Connecting wires, contacts are made from metals whereas electronic components like diodes, transistors are made from semiconductors. We have to visualize the behaviour of both materials at higher temperatures.

Effect of temperature on resistance of a conductor:

In pure metals, the resistance increases with increase in temperature. They have positive temperature coefficient (α)

                    Rt = Ro (1+ αot)

In metals or good conductors, there are large number of free electrons available. As the temperature increases, molecular vibrations increases violently. Due to these vibrations, the mean free path of molecules decreases. The molecular vibrations disturbs the motion of free electrons, and the electrons can't not move freely. They experience more frequent collisions from vibrating molecules. This is the basic cause of resistance or hindrance in the flow of free electrons at higher temperature. Or in other words increased temperature decreases conductivity of the metals.

Effect of temperature on resistance of a semiconductor:

In semiconductors, the resistance decreases with increase in temperature. They have negative temperature coefficient.

In semiconductors, there are a few free electrons at room temperature. An increase in temperature, the loosely bound valence band electrons get enough energy and escape from their parent atom. It produce greater number of free electrons. Resistance of semiconductors decreases with an increase in temperature. That's why it has negative temperature coefficient. You can further read about temperature dependence of semiconductors here.

What is inside the resistor?

Have you ever thought about what is inside the resistor? A 10 ohm resistor and a 10k resistor both have same size, two terminals but different values.

Actually resistors are made up of different types of materials having different resistivity values. R = p*L/A where p is the resistivity. Resistance can vary by varying these three quantities.

• Resistivity (p) varies different for each material
• Length (L)
• Cross sectional area (A)

Frequently Asked Questions:

Difference between ohmic and non ohmic resistance:

Ohmic resistance, which obeys Ohm's law or voltage and current have linear relation. Or the IV characteristics graph is a straight line. Current and resistance are temperature dependent. It is static resistance. Example, a metal.

Ohmic and non-ohmic resistances (linear and non-linear resistance)

Non ohmic resistance, which doesn't obey Ohm's law or voltage and current doesn't have linear relation. Or the IV characteristics graph is not a straight line.Current and resistance are not temperature dependent. It is dynamic resistance.  Example, semiconductors.

Difference between resistance and resistivity:

Resistivity: Each material has different ability to resist the flow of current. Some materials allow more charges to flow, while other offers more resistance. It measures how strongly a material can oppose charges to flow.  This is known as resistivity or specific electrical resistance. It is the physical property of the material of the conductor, it doesn't depends on shape or geometry of the conductor. Resistivity depends on nature of material and temperature. A good conductor offers low resistance at lower temperatures.

Resistance: It is the measure of flow of charges. It is the property of the conductor. The resistance of a conductor depends upon its geometry, nature of material and temperature as well. For example, thicker wires have less resistance.

How does resistivity change with temperature? Temperature coefficient of resistance | resistivity

As you have seen, resistance and resistivity both are temperature dependent. Increase in temperature will increase in resistivity.

Temperature coefficient of resistivity can be defined as rate of change of resistivity per degree change in temperature. It is denoted by“alpha” (α).

The resistivity of metallic conductors linearly changes with temperature. As temperature increases resistivity increases. So they have positive temperature coefficient.

Similarly for semiconductors, resistivity decreases with an increase in temperature. So they have negative temperature coefficient.

Figure: Resistivity depends on temperature

Power Sources - Current & Voltage Sources

To derive an electronic circuitry there has to be source of energy. A voltage source and a current source is an example of energy source. An electrical energy source is a device that is capable of converting non-electrical energy into electrical energy. For example a battery which converts chemical energy into electrical energy. A dynamo which converts mechanical energy into electrical energy. It delivers power to rest of the circuit elements which are passive in nature. Our aim in this article is to explain some important concepts regarding voltage sources and current sources.

Key Concepts

• Ideal Vs practical sources (voltage and current sources)
• Independent voltage and current sources
• Dependent voltage and current sources

Concept Of An Ideal Voltage Source:

As the name implies it is responsible for delivering voltage across the circuit. It is a two terminal device. There are various definitions found for an ideal voltage source. An ideal voltage source is the one which maintains prescribed/constant voltage across its terminals regardless of the load connected to its terminals. Or we can say an ideal voltage source maintains a constant voltage across its terminals regardless of the current flowing through its terminals. I will explain it with the help of Ohm's law. Or in other words an ideal voltage source has 'zero’ internal resistance. If zero internal resistance then you can definitely have no voltage drop across the terminals.

According to Ohm's law V=IR

Consider

• V=12V, and R=10Ω (load resistor) it can not maintain unlimited current as per Ohm's law. As the load varies current varies accordingly
• V=12V, R=0Ω (internal resistance)   I = 12/0 = ∞ , it was is capable of supplying infinite current
• For ideal voltage source terminal voltage (V) remains same regardless of the load connected. E=V, where E=EMF and V=Terminal Voltage.

Concept Of A Practical Voltage Source:

Do you think an ideal voltage source exists?? Ideal voltage sources are not practical. For a practical voltage source there's a finite internal resistance that's associated with it's internal connection and terminals. This causes voltage drop across the terminals.

• All practical voltage sources have small internal resistance Ri
• Internal resistance Ri is connected in series with any load resistance RL
• There's a voltage drop of I*Ri because of this internal resistance
• Terminal voltage (V) which appears across load is V=E-I*Ri.
• Because of this small internal resistance load voltage is always less than the source voltage

Concept Of An Ideal Current Source:

As the name suggests it is the source of current, that supplies constant current to the circuit. An ideal current source has infinite internal resistance. Or an ideal current source maintains a constant current flow regardless of the voltage drop across its terminals.

• It provides constant current to the load irrespective of other conditions in the circuit
• It has 100% efficiency
• Because of infinite internal resistance all the current supplies to the load
• Ri = internal resistance = ∞ From Ohm's law I=V/Ri , because of such high internal resistance all the current will flow through the load irrespective of the voltage

Concept Of A Practical Current Source:

As the ideal voltage source doesn't exist, in the same way ideal current source also doesn't exist. No current source can maintain constant current. We have seen a practical voltage source can be modelled by a voltage source and a small resistance in series with it. Whereas a practical current source is represented a shunt resistor (Rs) connected in parallel with an ideal current source. Rs should be very large. It should be large enough so that small load resistances have no effect on the load current.

Reason for larger value of Rs

Do you remember, the current finds the lowest resistance path. The path which has lowest resistance, maximum current will flow through that path. From Ohm's law,  I=V/R lower the resistance higher will be the current value.

• Rs should be large enough so that all current flows through the load resistor

Independent Voltage Source:

Independent voltage sources that have voltage (fixed or time variant) which is not affected by any other current or voltage elsewhere in the circuit.

Independent Current Sources:

Independent current sources that delivers or absorbs current (fixed or time variant) at its terminals which is not affected by any other voltage or current elsewhere in the circuit.

Dependent Voltage Sources:

Dependent sources are also called controlled sources. A dependent voltage source can either be controlled by voltage or current elsewhere in the circuit. Input and output are linearly dependent. The equation for current and voltage is a linear equation.

There are two possible types of dependent voltage sources:

• Voltage Controlled Voltage Source (VCVS)
• Current Controlled Voltage Source (CCVS)

Voltage Controlled Voltage Source is a voltage source controlled by a voltage vc. vc= controlled voltage.

V= K*vc

Where K is the constant of proportionality

Current Controlled Voltage Source is a voltage source controlled by current ic. ic= controlled current.

V = K*ic

Where K is the constant of proportionality

Dependent Current Sources:

There are two possible types of dependent current sources:

• Voltage Controlled Current Source (VCCS)
• Current Controlled Current Source (CCCS)

Voltage Controlled Current Source is a current source controlled by voltage vc. vc is the controlled voltage.

I = K*vc

Where K is the constant of proportionality.

Current Controlled Current Source is a current source controlled by current ic. ic= controlled current.

I = K*ic

Where K is the constant of proportionality.

Circuit Analysis - Methods, Laws & Theorems

This tutorial is intended to provide detailed information about the circuit or network analysis, methods of analysis and network theorems. It is just an introductory article, in which I gather all the laws, methods and theorems. This topic is usually a part of the ECE basic course on circuits. The term solving a circuit means determining all the voltage across each element and currents through each element present in a circuit.

Key Concepts:

• What are fundamental laws for solving circuits?
• Methods used for network/circuit analysis
• Network theorems
• What is the purpose of network theorems or why do we study network theorems

Fundamental Circuit Laws:

To determine current and voltage in an electric circuit, we need to gain knowledge of fundamental laws that govern electronic circuits.

1. Ohm's law
2. Kirchhoff's Voltage Law (KVL)
3. Kirchhoff's Current Law (KCL)

Ohm's Law defines a linear relationship between voltage and current in an ideal conductor. This is one of the most important and fundamental laws of electric circuits.

Kirchhoff’s Current Law is used when analysing a parallel circuit. It is based on the idea of conservation of charge. According to KCL 'current entering the node is equal to current leaving the node’.

Kirchhoff's Voltage Law is used when analysing a series circuit. It is based on the idea of conservation of potential. According to KVL 'the sum of voltage drop or potential difference across a closed loop is zero’.

Methods of Analysis:

Analysis of a circuit is the determination of output response. These methods of analysis are based on basic circuit laws. These methods are restricted to linear circuits only. The two most common methods are

1. Mesh analysis
2. Nodal analysis

Nodal analysis is nothing but an application of KCL. In the nodal analysis, we apply KCL to each node. If we have 'n’ number of nodes, then there are (n-1) linearly independent node equations. These equations are in terms of node potential.

Mesh | loop analysis is nothing but an application of KVL. In mesh analysis, we apply KVL around each loop in a circuit. If we have 'b’ branches and 'n’ nodes in a circuit then we have b-(n-1) linearly independent equations. These equations are in terms of mesh currents.

Why do we study network theorems?

I suppose you are familiar with basic network analysis methods. Like node analysis and mesh analysis. When dealing with KCL and KVL we will have a fairly large number of independent equations. As I discussed in methods of analysis, we get (n-1) node equations and b-(n-1) mesh current equations, so total ‘b’ number of equations. Did you find them time-consuming, you have to deal with so many equations (the number of node and mesh equations are equal to the number of elements/branches present in a network). For example, you have a network/circuit having 4 passive elements, then there are 4 current or voltage equations. And if there are 5 passive elements you have to solve 5 equations and so on. Analysing more complex circuits by using these methods seem to be ridiculous. What do you think?? So instead of applying tedious mesh and nodal analysis to complex networks, we develop network theorems.

Network theorems

1. Superposition theorem
2. Reciprocating theorem
3. Thevenin’s theorem
4. Norton's theorem
5. Compensation theorem
6. Millman's theorem
7. Substitution theorem
8. Maximum power transfer theorem
9. Tellegen's theorem

Applications

• Some of these apply to linear as well as non-linear circuits
• With the help of these theorems, we can solve DC as well as AC Circuits
• Easy comprehension of complex circuits