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AC Circuits

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AC Circuits AC Current peak-to-peak and rms Capacitive Reactiance magnitude and phase Inductive Reactance magnitude and phase AC Circuits AC Signals and rms Values ... – PowerPoint PPT presentation

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Title: AC Circuits


1
AC Circuits
  • AC Current
  • peak-to-peak and rms
  • Capacitive Reactiance
  • magnitude and phase
  • Inductive Reactance
  • magnitude and phase

2
AC Circuits
  • AC Signals and rms Values
  • There are a number of ways to describe the
    current or voltage for a time varying signal
    peak value, peak-to-peak, and rms. Write in your
    own words what each means and indicate the three
    values on the sine wave signal shown below.

3
AC Circuits
  • What is V average, Vave?
  • How is Vrms related to Vm?
  • We will derive this in a minute.
  • When you measure an ac current or voltage with a
    DMM you are measuring rms values.

4
AC Circuits
  • Connect the cables from the Signal/Function
    Generator and the voltage input cables to the 2.2
    kW resistor on the EM board. The red and black
    cables with the red and black plugs are the input
    to the voltage sensor. Make sure the two grounds
    (black cables) are connected to the same side of
    the resistor. Start DataStudio and configure the
    program to measure voltage using channel A. You
    will recall that you do this by clicking and
    dragging the plug icon to channel A and choosing
    Voltage Sensor. For output we will connect both
    the digital output and the oscilloscope. Connect
    both to channel A.
  • Next select the Signal/Function Generator by
    clicking the Signal icon on the lower left side
    of the DataStudio window. Set the amplitude to 5
    volt and the frequency to 100 Hz on the function
    generator. Select the sine wave (AC) and click
    ON.
  • Measure the peak value and the peak-to-peak value
    using the oscilloscope and measure the rms value
    using the digital meter.

5
AC Circuits
  • Measure the peak value and the peak-to-peak value
    using the oscilloscope and measure the rms value
    using the digital meter.
  • Vm Vpp Vrms
  • What is the ratio of Vrms to Vp?
  • Vrms/Vp 0.707
  • Is this what you expect? Explain.

Yes, at least we expect the value to be less than
one.
6
AC Circuits
  • The rms value is found by squaring the signal,
    integrating over one period, and then taking the
    square root. Lets do it. First square the
    following signal.
  • V(t) Vpsin(wt)
  • Now integrate this with respect to time from t
    0 to t T (the period). Look in Appendix A page
    A-10 for the integral.
  • Hint What is wT?
  • Finally, dividing by T and take
  • the square root you should get

V2(t) Vp2sin2(wt)
7
AC Circuits
  • Resistance, Capacitance, and Inductance
  • When we discuss resistors, capacitors, and
    inductors in a circuit there are two important
    points to remember.
  • The magnitude relationship between the current in
    and voltage across a resistor, capacitor, or
    inductor.
  • The phase relationship between the current in and
    voltage across a resistor, capacitor, or inductor.

8
AC Circuits
  • Resistance
  • The simplest case is a resistor in a circuit.
  • The current and voltage are in phase
  • The magnitude is VRIR

The current and voltage are in phase in a
resistor.
Current and voltage reaches a minimum at time T
9
AC Circuits
  • Capacitive Reactance
  • When we discuss capacitors in a circuit there are
    two important points for a capacitor. One is the
    phase relationship between the current in and
    voltage across a capacitor. What is the phase
    relationship? This is the bold statement on page
    855 in your text.

The current in a capacitor leads the voltage by
900.
10
AC Circuits
  • The second point is the magnitude relationship
    between current and voltage for a capacitor.
    What is this relationship?
  • This is equation (33-5) in your text. To make
    this look like Ohms law we define capacitive
    reactance. What is the definition for capacitive
    reactance?
  • What are the units?

ohms
11
AC Circuits
  • Lets check this out. Connect the 2.2 kW
    resistor on the EM board in series with the
    0.047 mF capacitor to the output of the function
    generator. Set the amplitude to 5 volts, the
    frequency to 200 Hz, and the function to sine
    wave. Connect the voltage probes to the Pasco
    750 Interface across the resistor. To get the
    phase correct connect the black voltage lead to
    one side of the resistor and connected the ground
    lead (black cable) from the ground side of the
    signal generator. We will also measure the
    voltage across the capacitor by connecting the
    leads from channel B across the capacitor. Make
    sure the positive lead is connected to the
    positive side of the capacitor. This is the side
    connected to the positive lead from the signal
    generator. You need to click the plug icon and
    drag it to channel B and choose Voltage Sensor.
    To connect the output to the oscilloscope do not
    open a new window but go to the oscilloscope
    window and click the second trace icon (Which
    should be No Signal) on the right and select
    Channel B.

12
AC Circuits
  • Measure the peak voltage across the resistor and
    the capacitor. Use the resistance to calculate
    the peak current. Record the values in the table
    below. Change the frequency and repeat the
    measurements.
  • frequency voltage voltage
    current capacitive
  • (resistor) (capacitor)
    reactance
  • Hz Vp (V) Vp (V)
    Ip (mA) XC (W)
  • ____20__ __________ __________ __________
    __________
  • __2000__ __________ __________ __________
    __________

13
AC Circuits
  • Measure the peak voltage across the resistor and
    the capacitor. Use the resistance to calculate
    the peak current. Record the values in the table
    below. Change the frequency and repeat the
    measurements.

14
AC Circuits
  • Use DataStudio or open Excel and plot the
    capacitive reactance as a function of frequency.
    Does the curve look like what you would expect
    from the definition of capacitive reactance?
    Explain.

15
AC Circuits
  • Use the definition to figure out how to plot the
    data so that you get a straight line. Replot the
    data and do a linear fit. From the slope
    calculate the capacitance.

16
AC Circuits
  • Next we will measure the phase shift between the
    voltage across the capacitor and the current
    through the capacitor. Set the frequency to 2000
    Hz. Make sure both positive voltage leads are
    connected to the side connected to the positive
    side of the signal generator. The two traces
    should look like Figure 33-4.

17
AC Circuits
  • Measure the phase difference between the current
    and voltage. Do this by measuring the period
    which is 3600 and the time shift between the two
    signal. Then
  • q 3600 t/T where t is the time shift and T is
    the period.
  • Change the frequency and see if the phase
    difference between the two signals changes.

18
AC Circuits
  • Inductive Reactance
  • When we discuss inductors in a circuit there are
    two important points for an inductor. One is the
    phase relationship between the current in and
    voltage across an inductor. What is the phase
    relationship? This is the bold statement at the
    bottom of page 836 in your text.

The voltage across an inductor leads the current
by 900.
19
AC Circuits
  • The second point is the magnitude relationship
    between current and voltage for a inductor. What
    is this relationship?
  • This is equation (33-7) in your text. To make
    this look like Ohms law we define inductive
    reactance. What is the definition for inductive
    reactance?
  • What are the units?

ohms
20
AC Circuits
  • On the axis below show what you expect for the
    inductive reactance as a function of frequency.

21
AC Circuits
  • Replace the capacitor with the inductor in the
    circuit. Using the digital meter measure the
    voltage across the inductor and resistor as we
    did for the capacitor.
  • frequency voltage voltage
    current capacitive
  • (resistor) (capacitor)
    reactance
  • Hz Vp (V) Vp (V)
    Ip (mA) R (W)
  • ____20__ __________ __________ __________
    __________
  • __2000__ __________ __________ __________
    __________

22
AC Circuits
  • Measure the peak voltage across the resistor and
    the inductor. Use the resistance to calculate
    the peak current. Record the values in the table
    below. Change the frequency and repeat the
    measurements.

23
AC Circuits
  • Plot the inductive reactance as a function of
    frequency. Does the graph agree with what you
    know about inductive reactance?

24
AC Circuits
  • Measure the phase shift between the current and
    voltage across the inductor. Your two traces
    should look like Figure 33-6.

25
AC Circuits
Summary of AC circuit equations
This is everything you need to know from today
26
AC Circuits
Summary of AC circuit concepts
This is a little more than you want to know!
27
AC Circuits
  • Phase shift and Phasors
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