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Chapter 7 – Serial-Parallel Networks

Chapter 7 – Serial-Parallel Networks. Introductory Circuit Analysis Robert L. Boylestad. 7.1 - Series-Parallel Networks. Series and parallel circuits are networks that contain both series and parallel circuit configurations

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Chapter 7 – Serial-Parallel Networks

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  1. Chapter 7 – Serial-Parallel Networks Introductory Circuit Analysis Robert L. Boylestad

  2. 7.1 - Series-Parallel Networks • Series and parallel circuits are networks that contain both series and parallel circuit configurations • One can become proficient in the analysis of series-parallel networks only through exposure, practice and experience

  3. Series-Parallel Networks • General approach • Study the problem in total and make a brief mental sketch of the overall approach you plan to use • Examine each region of the network independently before tying them together in series-parallel combinations • Redraw the network as often as possible with reduced branches and undisturbed unknown quantities to maintain clarity • When you have a solution, check to see that it is reasonable by considering the magnitudes of the energy source and the elements in the network. If it does not seem reasonable, either solve using another approach or check over your work very carefully

  4. Series-Parallel Networks • Reduce and return approach • This analysis is one that works back to the source, determines the source current and then finds its way to the desired unknown • Work back for Is and then follow the return path for the specific unknown

  5. Series-Parallel Networks • Block diagram approach • Network is broken down into combinations of elements • Initially, there will be some concern about identifying series and parallel elements, but that will come by working through some examples • In reverse, the block diagram approach can be used effectively to reduce the apparent complexity of a system by identifying the major series and parallel components of the network

  6. 7.2 - Descriptive Examples • Example 7.4 – Find the current of I4 and the voltage of V2 for the network of Fig 7.10

  7. Descriptive Examples • Example 7.5 – Find the indicated currents and voltages for the network of Fig. 7.13

  8. Descriptive Examples • Example 7.6 a. Find the voltages V1, V2 and Vab for the network of Fig. 7.16 b. Calculate the source current Is

  9. Descriptive Examples • Example 7.7 – For the network of Fig. 7.18, determine the voltages V1 and V2 and the current I

  10. Descriptive Examples • Example 7.9 – Calculate the indicated currents and voltages of Fig. 7.22. Insert Fig. 7.22

  11. 7.3 - Ladder Networks • Repetitive structure that looks like a ladder • Method 1 – Calculate the total resistance and resulting source current, and then work back through the ladder until the desired current or voltage is obtained • Method 2 – Assign a letter symbol to the last branch current, and work back through the network to the source, maintaining this assigned current or other current of interest.

  12. 7.4 - Voltage Divider Supply (Unloaded and Loaded) • Loaded refers to the application of an element, network, or system to a supply that will draw current from the supply • The larger the resistance level of the applied loads compared to the resistance of the voltage divider network, the closer the resulting terminal voltage to the no-load levels. In other words, the lower the current demand from a supply, the closer the terminal characteristics are to the no-load levels.

  13. 7.5 - Potential Loading • Unloaded potentiometer – the output voltage is determined by the voltage divider rule, with RT representing the total resistance of the potentiometer Insert Fig 7.37

  14. Potential Loading • When a load is applied as shown, the output voltage VL is now a function of the magnitude of the load applied since R1 is not as shown in the previous slide but is instead the parallel combination of R1 and RL. Insert Fig 7.38

  15. 7.6 - Ammeter, Voltmeter, and Ohmmeter Design • Fundamental design of an ammeter, voltmeter, and ohmmeter. • d’Arsonval analog movement: an iron-core coil mounted on bearings between a permanent magnet. The helical springs limit the tuning motion of the coil and provide a path for the current to reach the coil. • When current is passed through the movable coil, the fluxes of the coil and permanent magnet will interact to develop a torque on the coil that will cause it to rotate on its bearings • The movement is adjusted to indicate zero deflection on a meter scale when the current through the coil is zero • The direction of the current through the coil will determine whether the pointer will display an up-scale or below-zero indication

  16. Ammeter, Voltmeter, and Ohmmeter Design • The ammeter • The maximum current that the d’Arsonval movement can read is equal to the current sensitivity of the movement. Higher current can be measured if additional circuitry is introduced. • Multirange ammeters can be constructed using a rotary switch that determines the Rshunt to be used for the maximum current indicated on the face of the meter

  17. Ammeter, Voltmeter, and Ohmmeter Design • The voltmeter • Additional circuitry in the d’Arsonval movement is introduced to create a voltmeter • The millivolt rating is sometimes referred to as the voltage sensitivity (VS) • The Rseries is adjusted to limit the current through the movement when maximum voltage is applied

  18. Ammeter, Voltmeter, and Ohmmeter Design • The ohmmeter • Ohmmeters are designed to measure resistance in the low, mid-, or high range • The most common is the series ohmmeter, designed to read resistance levels in the midrange • The design is different from that of the ammeter and voltmeter because it will show a full-scale deflection for zero ohms and no deflection for infinite resistance • The megohmmeter (megger) is an instrument for measuring very high resistance. Its primary function is to test the insulation found in power transmission systems, electrical machinery, transformers and so on.

  19. 7.7 - Grounding • Grounding and the measure of safety it provides to a design is very important • Ground potential is 0 V at every point in the network that has a ground symbol • All ground potentials are the same and so they can all be connected together, but for clarity most are left isolated on a large schematic • On a schematic, the voltage levels provided are always with respect to ground • To check a system, connect the black lead of a meter to ground and the red lead at the various points where the typical operating voltage is provided. A close match to the expected voltage normally implies that that portion of the network is operating properly.

  20. Grounding • Earth ground: ground directly connected to the earth by a low impedance connection • The entire surface of the earth is defined to have a potential of 0 V. • Every home has an earth ground, usually established by a long conductor rod driven into the ground and connected to the power panel • The electrical code requires a direct connection from earth ground to the cold-water pipes of a home for safety reasons

  21. Grounding • Chassis ground: may be floating or connected directly to an earth ground • A chassis ground simply states that the chassis has a reference potential for all points of the network • If the chassis is not connected to earth potential (0 V), it is considered to be floating and can have any other reference voltage for other voltages to be compared to

  22. Grounding • Grounding can be particularly important when working with numerous pieces of measuring equipment in the laboratory • Oscilloscope • The National Electrical Code requires that the “hot” (or feeder) line that carries the current load to a load be black, and the line (called the neutral) that carries the current back to the supply be white. Three-wire conductors have a ground wire that must be green or bare

  23. 7.8 - Applications • Boosting a car battery • Cables should have sufficient length (16-ft) with #6 gage stranded wire and well-designed clips • Proper sequence of events in connecting the cable to a car with a discharged battery • Protective eye equipment is recommended • Identify which terminals are positive and which terminals are negative • Connect the red wire to the positive terminal of the discharged battery making sure that the black lead is not touching the negative terminal or the car. • Connect the red wire to the positive terminal of the fully charged battery again making sure that the black lead is not touching the negative terminal of the battery or the car. • Connect the black terminal to the negative terminal of the fully charged battery and the black lead of the discharged battery to the block of the car and have someone maintain a constant idle speed on the car with the good battery

  24. Applications • It is advised to let the charging action of the running car occur for 10 to 15 minutes before starting the car with the discharged battery • This is to protect the battery of the car with the good battery • Disconnecting the cables from a jumped car • Remove the cables in the reverse order as they were connected, making sure that the clamps don’t accidentally come in contact with the battery or the chassis of the car

  25. Applications • Electronic Circuits • The operation of most electronic systems requires a distribution of dc voltages throughout the design

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