tailieunhanh - Lecture Electric circuits analysis - Lecture 15: Problem solving - series parallel circuits
In this chapter, the following content will be discussed: Identifying series-parallel relationships, analysis of series-parallel resistive circuits, voltage dividers with resistive loads, ladder networks. | Previous Lectures 13 & 14 Problem Solving-Series Parallel Circuits Identifying Series-Parallel Relationships Analysis of Series-Parallel Resistive Circuits Voltage Dividers with Resistive loads Ladder Networks Problem Solving_Series Parallel Circuits Position 1: RT= kΩ, V1 = V, V2 = V, V3 = The voltage divider in the following Figure has a switched load. Determine the voltage at each tap (V1, V2 , and V3 ) for each position of the switch. (Solved on 3 slides) Lecture 15 Position 2 :RT= kΩ, R34//RL= Ω , V1=, V2= V, V3= Position 3:RT= kΩ, V1=89V, V2=58 V, V3=27V Design a voltage divider to provide a 6V output with no load and a minimum of V across a kΩ load. The source voltage is 24 V, and the unloaded current drain is not to exceed 100 mA. RT=240 Ω, R2=60 Ω, R1= 180 Ω, R2 || RL = Ω, VOUT = V Problems related to Ladder Networks For the circuit shown in the following Figure, calculate the following: (a) Total resistance across the source (b) Total current from the source (c) Current through the 910Ω resistor (d) Voltage from A to point B (Solved on 3 slides) RT = 271 Ω, IT=221 mA, I2= 114 mA, I910 = mA, I4 = = 55 mA , Ω = V,VAB = 12 V RT = 271 Ω, IT=221 mA, I2= 114 mA, I910 = mA, I4 = = 55 mA , Ω = V,VAB = 12 V RT = 271 Ω, IT=221 mA, I2= 114 mA, I910 = mA, I4 = = 55 mA , Ω = V,VAB = 12 V Determine the total resistance and the voltage at nodes A, B, and C in the ladder network of the following Figure. (Solved on 2 slides) RT = kΩ, RC= 1 kΩ, RB= kΩ, RA= kΩ, VA = V, VB = V,VC = 35 mV RT = kΩ, RC= 1 kΩ, RB= kΩ, RA= kΩ, VA = V, VB = V,VC = 35 mV Determine the total resistance between terminals A and B of the ladder network in the given Figure. Also calculate the voltage across each resistor and current in each branch with 10 V between A and B. (Solved on 3 slides) RT = 621 Ω, . | Previous Lectures 13 & 14 Problem Solving-Series Parallel Circuits Identifying Series-Parallel Relationships Analysis of Series-Parallel Resistive Circuits Voltage Dividers with Resistive loads Ladder Networks Problem Solving_Series Parallel Circuits Position 1: RT= kΩ, V1 = V, V2 = V, V3 = The voltage divider in the following Figure has a switched load. Determine the voltage at each tap (V1, V2 , and V3 ) for each position of the switch. (Solved on 3 slides) Lecture 15 Position 2 :RT= kΩ, R34//RL= Ω , V1=, V2= V, V3= Position 3:RT= kΩ, V1=89V, V2=58 V, V3=27V Design a voltage divider to provide a 6V output with no load and a minimum of V across a kΩ load. The source voltage is 24 V, and the unloaded current drain is not to exceed 100 mA. RT=240 Ω, R2=60 Ω, R1= 180 Ω, R2 || RL = Ω, VOUT = V Problems related to Ladder Networks For the circuit shown in the following Figure, calculate the following: (a) Total
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