40 1227 10 e 3+ 2.32 fb) Find the totatcurrent flowing through all the resistors To...
Question 2 40 pts Part A) 25 pts Find the equivalent resistance of all the resistors in the circuit below. Part B) 15 pts Find the current through the battery. 1512 1012 4012 < 3012 1.5 V 2012 W
Part A) Find the equivalent resistance of all the resistors in the circuit below. Part B) Find the current through the battery. Part C) Find total amount of energy stored across all the capacitors once they are completely charged by a 1.5V battery. 10Ω 15Ω ΛΜΑ 40Ω 30Ω 20Ω 1.5V
number 3 1. Find the capacitance of a conductive sphere of radius 1.0fm charged with 1.60. 10-19C. 2. Now a conductive sphere of charge -I placed concentric to the sphere of the problem 1. Find the combined capacitance of the two together. 3. Find the capacitance of two spherical capacitors of the type in problem two placed in together in series. 4. Find the time constant for chargingthe configuratonin problem Зі the two capacitors are made of siver and they...
COI) (15 pts) Two capacitors, C and C2, are connected in series to a 60 V battery as shown in the sketch in part b). The capacitance of C, is 1.0 x10 F, and it carries a charge of2.0 10 C. R-100 ohms. Assume that no current is flowing through the circuit. a) () Find the potential across C b) (3) Find fE dA for the surface S, shown in the sketch below. The surface encloses one plate of capacitor...
number 7 please 1. Find the capacitance of a conductive sphere of radius 1.0fm charged with 1.60 10-19C. 2. Now a conductive sphere of charge -1.60 10-1°C and radius of -1.0 10-10m is placed concentric to the sphere of the problem 1. Find the combined capacitance of the two together 3. Find the capacitance of two spherical capacitors of the type in problem two placed in 4. Find the time constant for charging the configuration in problem 3 if the...
4) Midterm question Problem 2 (30 points) C=30 uF The air capacitors with C=Cq=3.0 MF, C=2.04F and C3= 1.0F are connected to a Vo battery as shown. If the charge on C2 is Q2=20.0 C, | ,2015 Foton C1.0 F (a) (15 pts. Find the equivalent capacitance of the circuit. (b) (15 pts.) Find V. 1) A charge Q is placed on a capacitor of capacitance C=C. The capacitor is then, connected to a resistor and another capacitor of capacitance...
November 6, 2017 (3) Find (3) Find (s) 10 Mev the equivalent resistance of the circuit shown in rie 1 in Fie. 2 the current owing through resister R3 for the circuit shows in Fie tery, switch, resister and capacitor are connected in series as shown in (Fig. 4). when the is closed how much Eurrent flows through the circuit at 2 s7 protons are launched into "pace that has uniform magnetic field of 2.0 T at right angles to...
Need help with all of these please 1. What is Coulomb's Law? Write the value of Coulomb's constant (ke)? Describe vector nature of electric force (F) with diagram? Problem-1: Find the electric force between two charges of +5 C, and-5 C separated by a distance of 0.001 m? 2. Define electric field (E)? Write S.I. unit? Explain with necessary diagram the directions of electric fields due to a positive and negative charges separately? Problem-2: What is the electric field (E)...
Find the Equivalent ResistanceFour resistors are connected as shown in figure (a), below. (Let R=3.00 Ω.)The original network of resistors is reduced to a single equivalent resistance.(a) Find the equivalent resistance between points \(a\) and \(\mathrm{c}\).solutionConceptualize Imagine charges flowing into and through this combination from the left. All charges must pass from a to \(b\) through the first two resistors, but the charges split at \(b\) into Categorize Because of the simple nature of the combination of resistors in the...
Question [5x2 marks 10 marks] In the circuit in Figure 4, the resistance value R1, R2, R3 and R4 have a value of 30, 40, 40 and 50 (a) Find the equivalent resistance (Req) in the circuit (b) Determine the current through each resistance 1 to 14. (c) Determine the power dissipated by each resistor and the power delivered by the independence voltage source. Confirm that the power delivered by the independent source is the same as the power absorbed...