Announcements
•WebAssign HW Set 5 due this Friday• Problems cover material from Chapters 17
• Prof. Kumar’s Tea and Cookies today at 5 pm• or by appointment
•Exam 1 8:20 – 10:10 pm Wednesday, February 16• Covers Ch. 15-18 • 20 questions• Room assignments:
QUESTIONS? PLEASE ASK!
From last time
Temperature dependence of resistivity/resistance
Electrical Energy:
Superconductors Remarkable materials
)]TT(1[ oo )]TT(1[RR oo
QV I V
t
22 V
I RR
Example Problem
17.40 A certain toaster has a heating element made of Nichrome resistance wire. When the toaster (at 20°C) is first connected to 120 V source, the initial current is 1.80 A, but the current decreases when the element heats up. When the toaster reaches it final temperature, the current is 1.53 A. (a) Find the power the toaster produces at its final temperature. (b) What is the final temperature?
Chapter 18
Direct Current Circuits
emf emf maintains the current in a closed
circuit Any device that increases the potential
energy of charges circulating in circuits; e.g., batteries and generators
SI units are Volts The emf is the work done per unit charge
Real batteries have small internal resistance
Therefore, the terminal voltage is not equal to the emf
Internal Resistance internal resistance r
Terminal voltage: ΔV = Vb-Va
ΔV = ε – Ir This is the voltage drop that the circuit ‘sees’
For the entire circuit, ε = IR + Ir load resistance R When R >> r, r can be ignored Generally assumed in problems
Power: I = I2 R + I2 r When R >> r, most of the power
delivered by the battery is transferred to the load resistor
Resistors in Series Current is the same in R1 and R2
Conservation of charge
ΔV = ΔV1 + ΔV2 = IR1 + IR2 = I (R1+R2) = I Req
General: Req = R1 + R2 + R3 + …
The equivalent resistance has the effect on the circuit as the original combination of resistors
Equivalent Resistance – Series: An Example
Four resistors are replaced with their equivalent resistance
Resistors in Parallel
Equivalent resistance replaces the two original resistances
Equivalent Resistance – Parallel
Current splits at upper junction: I = I1 + I2 + I3
Write in terms of voltage drop
Equivalent Resistance
The equivalent resistance is always less than the smallest resistor in the group!
Example Problem 18.8
(a) Calculate the equivalent resistance of the 10 Ω and 5 Ω resistors. (b) Calculate the combined equivalent resistance of the 10 Ω, 5 Ω, and 4 Ω resistors. (c) Calculate the equivalent resistance found in part b and the parallel 3 Ω resistor. (d) Combine the equivalent resistance from part c and the 2 Ω resistor. (e) Calculate the total current in the circuit. (f) What is the voltage drop across the 2 Ω resistor? (g) Subtracting the result of part f from the battery voltage, find the voltage across the 3 Ω resistor. (h) Calculate the current in the 3 Ω resistor.
Example Problem 18.13
Find the current in the 12 Ω resistor.
Solution to 17.40
Solution to 18.8 (I)
Solution to 18.8 (II)
Solution to 18.13 (I)
Solution to 18.13 (II)