Homework 6 Solutions PHYS 212 Dr. Amir

Size: px

Start display at page:

Download "Homework 6 Solutions PHYS 212 Dr. Amir"

Vincent Johnston
7 years ago
Views:

1 Homework 6 Solutions PHYS Dr. Amir Chapter 5: 9. (II) A 00-W lightbulb has a resistance of about Ω when cold (0 C) and 0 Ω when on (hot). Estimate the temperature of the filament when hot assuming an average temperature coefficient of resistivity α= 0.00(C ) Use Eq. 5-5 multiplied by l A so that it expresses resistances instead of resistivity. 0 0 T T 0 T T 0 C 390 C 00 C C 5. (II) A length of wire is cut in half and the two lengths are wrapped together side by side to make a thicker wire. How does the resistance of this new combination compare to the resistance of the original wire? 5. The resistance depends on the length and area as l A. Cutting the wire and running the wires side by side will halve the length and double the area. l l A A 3. (I) What is the maximum power consumption of a 3.0-V portable CD player that draws a maximum of 70 ma of current? 3. Use Eq. 5-6 to find the power from the voltage and the current. P IV 0.7 A 3.0 V 0.8W Chapter 6 8. (II) (a) Determine the equivalent resistance of the ladder of equal 5-V resistors shown in Fig In other words, what resistance would an ohmmeter read if connected between points A and B? (b) What is the current through each of the three resistors on the left if a 50.0-V battery is connected between points A and B?

2 Homework 6 Solutions PHYS Dr. Amir 8. (a) The three resistors on the far right are in series, so their equivalent resistance is 3. That combination is in parallel with the next resistor to the left, as shown in the dashed box in the second figure. The equivalent resistance of the dashed box is found as follows. 3 eq 3 This equivalent resistance of 3 is in series with the next two resistors, as shown in the dashed box in the third figure (on the next page). The equivalent 3 resistance of that dashed box is. This is in parallel with the next eq resistor to the left, as shown in the fourth figure. The equivalent resistance of that dashed box is found as follows.. eq 5 This is in series with the last two resistors, the ones connected directly to A and B. The final equivalent resistance is given below. eq (b) The current flowing from the battery is found from Ohm s law. V 50.0V I 0.63A 0.6 A total 3.67 eq This is the current in the top and bottom resistors. There will be less current in the next resistor because the current splits, with some current passing through the resistor in question, and the rest of the current passing through the equivalent resistance of, as shown in the last figure. The voltage across and across must be the same, since they are in parallel. Use this to find the desired current. V V I I I I total I I I 0.63A 0.07 A 5 total 5 total 3. (II) Calculate the currents in each resistor of Fig There are three currents involved, and so there must be three independent equations to determine those three currents. One comes from Kirchhoff s junction rule applied to the junction of the three branches at the top center of the circuit. I I I 3 I I3 58V 0 8 I 5 3.0V 6 0

3 Homework 6 Solutions PHYS Dr. Amir Another equation comes from Kirchhoff s loop rule applied to the left loop, starting at the negative terminal of the battery and progressing counterclockwise. 58V I 0 I 8 I I 6I The final equation comes from Kirchhoff s loop rule applied to the right loop, starting at the negative terminal of the battery and progressing counterclockwise. 3.0 V I 5 I 6 I I 35I Substitute I I I into the left loop equation, so that there are two equations with two unknowns I I 6I 66I 0I 3 3 Solve the right loop equation for I and substitute into the left loop equation, resulting in an equation with only one unknown, which can be solved. 35I I I 35 I I ; 58 66I 0I I I 3 3 I A ; I 0.79 A ; I I I 0.05A The current in each resistor is as follows: 0 : 0.A 8 : 0.A 6 : 0.5A 5 : 0.09A 0 : 0.09A 50. (III) Determine the time constant for charging the capacitor in the circuit of Fig [Hint: Use Kirchhoff s rules.] (b) What is the maximum charge on the capacitor? 50. (a) With the currents and junctions labeled as in the diagram, we use point a for the junction rule and the right and left loops for the loop rule. We set current I 3 equal to the derivative of the charge on the capacitor and combine the equations to obtain a single differential equation in terms of the capacitor charge. Solving this equation yields the charging time constant. I I I3 [] ; e I I 0 [] ; I 0 [3] C We use Eq. [] to eliminate I in Eq. []. Then we use Eq. [3] to eliminate I from Eq. []. 0 e I I3 I ; 0 e I I3 ; 0 e I3 C We set I 3 as the derivative of the charge on the capacitor and solve the differential equation by separation of variables.

4 Homework 6 Solutions PHYS Dr. Amir d d t 0= e dt 0 0 C dt C e C C e t C e ln t ln t 0 C C 0 e C C e e t C C From the exponential term we obtain the time constant,. (b) We obtain the maximum charge on the capacitor by taking the limit as time goes to infinity. Ce t C Ce max lim e t 5. (III) Two resistors and two uncharged capacitors are arranged as shown in Fig Then a potential difference of V is applied across the combination as shown. (a) What is the potential at point a with switch S open? (Let V 0 at the negative terminal of the source.) (b) What is the potential at point b with the switch open? (c) When the switch is closed, what is the final potential of point b? (d) How much charge flows through the switch S after it is closed? 5. (a) With the switch open, the resistors are in series with each other, and so have the same current. Apply the loop rule clockwise around the left loop, starting at the negative terminal of the source, to find the current. V V V I I 0 I.88 A 8.8.

5 Homework 6 Solutions PHYS Dr. Amir The voltage at point a is the voltage across the.-resistor. Va I.88 A. 8.0 V (b) With the switch open, the capacitors are in series with each other. Find the equivalent capacitance. The charge stored on the equivalent capacitance is the same value as the charge stored on each capacitor in series. CC 0.8F0.36F C 0.057F eq C C C C C 0.8F 0.36F eq VC.0 V F.937C eq eq The voltage at point b is the voltage across the 0.F -capacitor. V b C.937C 3.7 V V 0.36F (c) The switch is now closed. After equilibrium has been reached a long time, there is no current flowing in the capacitors, and so the resistors are again in series, and the voltage of point a must be 8.0 V. Point b is connected by a conductor to point a, and so point b must be at the same potential as point a, 8.0 V. This also means that the voltage across C is 8.0 V, and the voltage across C is 6 V. (d) Find the charge on each of the capacitors, which are no longer in series. V C 6 V 0.8F 7.68C V C 8.0 V 0.36 F.88C When the switch was open, point b had a net charge of 0, because the charge on the negative plate of C had the same magnitude as the charge on the positive plate of C. With the switch closed, these charges are not equal. The net charge at point b is the sum of the charge on the negative plate of C and the charge on the positive plate of C. 7.68C.88C.80C.8C b Thus.8 C of charge has passed through the switch, from right to left.

Circuits. The light bulbs in the circuits below are identical. Which configuration produces more light? (a) circuit I (b) circuit II (c) both the same

Circuits. The light bulbs in the circuits below are identical. Which configuration produces more light? (a) circuit I (b) circuit II (c) both the same Circuits The light bulbs in the circuits below are identical. Which configuration produces more light? (a) circuit I (b) circuit II (c) both the same Circuit II has ½ current of each branch of circuit