Two wires of resistance R1 and R2 have temperature 0 degree celsious coefficient of resistance Alpha 1 in Alpha 2 respectively, these are joined in series. The effective temperature coefficient of resistance is: ----
Answers
= \frac{R_1\alpha_2+R_2\alpha_2}{R_1+R_2}
Step by Step Solution:
We have,
Resistance of wires are R₁ and R₂ respectively.
Temperature coefficient is α₁ and α₂ respectively.
Let us take that their resistance at temperature t are R_{t1} and R_{t2} respectively.
Now,
We know that,
Resistance of a wire t having temperature coefficient α at temperature t° C is,
R_t=R_0(1+\alpha t)
Similarly,
For First wire,
R_{t1}=R_1(1+\alpha_1t)\;\;\;\;..........i)
For second wire,
R_{t2}=R_2(1+\alpha_2t)\;\;\;\;.........ii)
Now,
As per given that, resistance are connected in the series,So their equivalent resistance is given by,
R_{eq.}=R_{t1}+R_{t2}\\\;\\R_{eq.}=R_1(1+\alpha_1t})+R_2(1+\alpha_2t})\\\;\\R_{eq.}=R_1+R_1\alpha_1t+R_2+R_2\alpha_2t\\\;\\R_{eq.}=R_1+R_2+(R_1\alpha_1+R_2\alpha_2)t\\\;\\R_{eq.}=R_1+R_2+(R_1+R_2)[\frac{R_1\alpha_1+R_2\alpha_2}{R_1+R_2}]t\\\;\\R_{eq.}=(R_1+R_2)[1+(\frac{R_1\alpha_2+R_2\alpha_2}{R_1+R_2})t]\\\;\\\text{Comparing this equation with standard form of equation,}\\\;\\\text{Effective Temperature coefficient}=\frac{R_1\alpha_2+R_2\alpha_2}{R_1+R_2}