Answer :
in parallel connections the voltage remain same while in series it is different.
in series connections the current remain same while in parallel it is different.
in parallel we can put separate switch for each while in series it is not done.
in parallel the bulb will glow brighter because the voltage is across each conductor or resistance.
in series the resistance is higher than parallel connecton.
in parallel connection the resistance is minimum hence current is high because [{resistance is inversely proportional to current}]
r equivalent for parallel=1÷R1 +1÷R2+1÷RN.....
plz mark it best
in series connections the current remain same while in parallel it is different.
in parallel we can put separate switch for each while in series it is not done.
in parallel the bulb will glow brighter because the voltage is across each conductor or resistance.
in series the resistance is higher than parallel connecton.
in parallel connection the resistance is minimum hence current is high because [{resistance is inversely proportional to current}]
r equivalent for parallel=1÷R1 +1÷R2+1÷RN.....
plz mark it best
Parallel connection I Series connection
1) The current varies 1)The current remains constant across the across the connection connection.
2) The Potential difference 2) The Potential difference changes remains constant
Equation for parallel restors
[tex] R_{eq}=\frac{1}{R_{1}}+\frac{1}{R_{2}}+\frac{1}{R_{3}}......\frac{1}{R_{n}} [/tex]
Equation for series resistor
[tex] R_{eq} =R_{1} +R_{2}+R_{3}......+R_{n} [/tex]
1) The current varies 1)The current remains constant across the across the connection connection.
2) The Potential difference 2) The Potential difference changes remains constant
Equation for parallel restors
[tex] R_{eq}=\frac{1}{R_{1}}+\frac{1}{R_{2}}+\frac{1}{R_{3}}......\frac{1}{R_{n}} [/tex]
Equation for series resistor
[tex] R_{eq} =R_{1} +R_{2}+R_{3}......+R_{n} [/tex]