Connecting Resistors Together 

Individual resistors can be connected together in either a series connection, a parallel connection or combinations of both series and parallel together, to produce more complex networks whose equivalent resistance is a combination of the individual resistors. Then complicated networks of resistors or impedances can be replaced by a single equivalent resistor or impedance. Whatever the combination or complexity of the circuit, all resistors obey Ohm's Law and Kirchoff's Circuit Laws. 



Resistors in Series 

Resistors are said to be connected in "Series", when they are daisy chained together in a single line. Since all the current flowing through the first resistor has no other way to go it must also pass through the second resistor and the third and so on. Then, resistors in series have a Common Current flowing through them as the current that flows through one resistor must also flow through the others as it can only take one path. Then the amount of current that flows through a set of resistors in series is the same at all points in a series circuit. For example: 

I_{R1 }= I_{R2} = I_{R3} = I_{AB} = 1mA  
In the following example the resistors R_{1}, R_{2} and R_{3} are all connected together in series between points A and B. 



Series Resistor Circuit 

As the resistors are connected together in series the same current passes through each resistor in the chain and the total resistance, R_{T} of the circuit must be equal to the sum of all the individual resistors added together. That is 

R_{T} = R_{1 }+ R_{2} + R_{3} 

and by taking the individual values of the resistors in our simple example above, the total equivalent resistance, R_{EQ} is therefore given as: 

R_{EQ} = R_{1} + R_{2} + R_{3} = 1kΩ + 2kΩ + 6kΩ = 9kΩ 



So we can replace all three individual resistors above with just one single equivalent resistor which will have a value of 9kΩ. Where four, five or even more resistors are all connected together in a series circuit, the total or equivalent resistance of the circuit, R_{T} would still be the sum of all the individual resistors connected together and the more resistors added to the series, the greater the equivalent resistance (no matter what their value). This total resistance is generally known as the Equivalent Resistance and can be defined as; "a single value of resistance that can replace any number of resistors in series without altering the values of the current or the voltage in the circuit". 

Then the equation given for calculating total resistance of the circuit when connecting together resistors in series is given as: 

Series Resistor Equation 

R_{Total} = R_{1} + R_{2} + R_{3} +......R_{n }etc.  
Note then that the total or equivalent resistance, R_{T} has the same effect on the circuit as the original combination of resistors as it is the algebraic sum of the individual resistances. One important point to remember about resistors in series circuits, the total resistance (R_{T}) of any two or more resistors connected together in series will always be GREATER than the value of the largest resistor in the chain and in our example above R_{T} = 9kΩ were as the largest value resistor is only 6kΩ. 



Series Resistor Voltage 

The voltage across each resistor connected in series follows different rules to that of the series current. We know from the above circuit that the total supply voltage across the resistors is equal to the sum of the potential differences across R_{1} , R_{2} and R_{3} , V_{AB} = V_{R1} + V_{R2} + V_{R3} = 9V. 

Using Ohm's Law, the voltage across the individual resistors can be calculated as: 

Voltage across R_{1} = IR_{1} = 1mA x 1kΩ = 1V 

Voltage across R_{2} = IR_{2} = 1mA x 2kΩ = 2V 

Voltage across R_{3} = IR_{3} = 1mA x 6kΩ = 6V 

giving a total voltage V_{AB} of ( 1V + 2V + 6V ) = 9V which is equal to the value of the supply voltage. Then the sum of the potential differences across the resistors is equal to the total potential difference across the combination and in our example this is 9V. 

The equation given for calculating the total voltage in a series circuit which is the sum of all the individual voltages added together is given as: 

R_{Total} = V_{R1} + V_{R2} + V_{R3} +......+ V_{N }  
Then series resistor networks can also be thought of as "voltage dividers" and a series resistor circuit having N resistive components will have Ndifferent voltages across it while maintaining a common current. 

By using Ohm's Law, either the voltage, current or resistance of any series connected circuit can easily be found and resistor of a series circuit can be interchanged without affecting the total resistance, current, or power to each resistor. 



Example No1 

Calculate the equivalent resistance, series current, voltage drop and power for each resistor of the following resistors in series circuit. 



All the data can be found by using Ohm's Law, and to make life a little easier we can present this data in tabular form.




The Potential Divider Circuit 

Connecting resistors in series like this across a single DC supply voltage has one major advantage, different voltages appear across each resistor with the amount of voltage being determined by the resistors value only because as we now know, the current through a series circuit is common. This ability to generate different voltages produces a circuit called a Potential or Voltage Divider Network. 

The series circuit shown above is a simple potential divider where three voltages 1V, 2V and 6V are produced from a single 9V supply.Kirchoff's voltage laws states that "the supply voltage in a closed circuit is equal to the sum of all the voltage drops (IR) around the circuit" and this can be used to good effect as this allows us to determine the voltage levels of a circuit without first finding the current. 

The basic circuit for a potential divider network (also known as a voltage divider) for resistors in series is shown below. 



Potential Divider Network 





In this circuit the two resistors are connected in series across V_{in}, which is the power supply voltage connected to the resistor, R_{1}, where the output voltage V_{out} is the voltage across the resistor R_{2} which is given by the formula. If more resistors are connected in series to the circuit then different voltages will appear across each resistor with regards to their individual resistance R (Ohms law IxR) providing different voltage points from a single supply. However, care must be taken when using this type of network as the impedance of any load connected to it can affect the output voltage. For example, 

Suppose you only have a 12V DC supply and your circuit which has an impedance of 50Ω requires a 6V supply. Connecting two equal value resistors, of say 50Ω each, together as a potential divider network across the 12V will do this very nicely until you connect your load circuit to the network. This is demonstrated below. 



Example No2 

Calculate the voltage across X and Y. 

a) Without R_{L} connected 

b) With R_{L} connected 

As you can see from above, the output voltage V_{out} without the load resistor connected gives us the required output voltage of 6V but the same output voltage at V_{out} when the load is connected drops to only 4V, (Resistors in Parallel). Then the output voltage V_{out} is determined by the ratio of V_{1} to V_{2} with the effect of reducing the signal or voltage level being known as Attenuation so care must be taken when using a potential divider networks. The higher the load impedance the less is the loading effect on the output. 

A variable resistor, potentiometer or pot as it is more commonly called, is a good example of a multiresistor potential divider within a single package as it can be thought of as thousands of miniresistors in series. Here a fixed voltage is applied across the two outer fixed connections and the variable output voltage is taken from the wiper terminal. Multiturn pots allow for a more accurate output voltage control. 



Resistors in Series Applications 

We have seen that resistors in series can be used to produce different voltages across themselves and this type of resistor network is very useful for producing a voltage divider network. If we replace one of the resistors in the voltage divider circuit above with a Sensor such as a thermistor, light dependant resistor (LDR) or even a switch, we can convert an analogue quantity being sensed into a suitable electrical signal which is capable of being measured. 

For example, the following thermistor circuit has a resistance of 10KΩ at 25°C and a resistance of 100Ω at 100°C. Calculate the output voltage (Vout) for both temperatures. 

Thermistor Circuit 



At 25°C 

At 100°C 

By changing the fixed 1KΩ resistor, R_{2} in our simple circuit above to a variable resistor or potentiometer, a particular output voltage set point can be obtained over a wider temperature range. 



Resistors in Series Summary 

Then to summarise. When two or more resistors are connected together endtoend in a single branch they are said to be connected together in series. Resistors in Series carry the same current, but the potential differences across them are not the same. In a series circuit the individual resistors add together to give the equivalent resistance, ( R_{T} ) of the series combination. The resistors in a series circuit can be interchanged without affecting the total resistance, current, or power to each resistor or the circuit. 

In the next tutorial about Resistors, we will look at connecting resistors together in parallel and show that the total resistance is the reciprocal sum of all the resistors added together and that the voltage is common to a parallel circuit. 



Reproduced with permission from Wayne Storr 
