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EB 101- DC Circuits I

EB-102 DC Circuits II

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EB-131 Logic Circuits I

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EB-151 Introduction to Microprocessors I

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EB-190 Autotronics I

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EB-220 Logic Families

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Description

The EB-102 is a single board, comprehensive instructional module designed to teach advanced concepts of DC CIRCUITS to technology students.

The module can be operated as a stand-alone unit or integrated to EB-2000 Computer Managed Laboratory.

Objectives

  • Determine T (thevenin) from measurements taken with a voltmeter.

  • Determine Thevenin from measurements taken with an ohmmeter.

  • Connect Thevenin's equivalent circuit.

  • Test the original circuit and Thevenin if they provide the same current
    and voltage to various loads.

  • Connect a potentiometer as a voltage divider.

  • Measure the no-load and loaded output voltage of a potentiometer connected
    as a voltage divider.

  • Plot a graph that shows the relationship between the rotation of the
    wiper arm and the output voltage.

  • Calculate the output voltage applied to an electrical load by multiple
    voltage sources by Millman's theorem.

  • Verify Millman's theorem by measurements in a circuit.

  • Determine the internal resistance of voltage sources from measurements.

  • Determine the voltage regulation of a voltage source.

  • Compare voltage sources and determine the best quality by using the
    voltage regulation.

  • Determine the power from measured values of voltage and current.

  • Plot graphs of output voltage, current and power in the vertical axis and
    resistance on the horizontal axis.

  • Determine the resistance relationship that produced maximum power from
    measurements arid graphs.

  • Using the color code values of the resistors, convert the WYE circuit to DELTA circuit.

  • Using the code values of the resistors convert the DELTA circuit to WYE Measure the resistance of equivalent WYE and DELTA circuits.

  • Identify components and test points in a complete circuit.

  • Measure key voltages in an operating electrical circuit.

  • Locate faulty components

Recommended Experiments

  1. Thevenin's Theorem

  2. Potentiometer

  3. Miliman's Theorem

  4. Superposition Theorem

  5. Voltage Source

  6. Maximum Power Transfer

  7. WYS-DELTA and DELTA-WYE Conversions

  8. Troubleshooting direct current circuits

 

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