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Subelement E4

AMATEUR PRACTICES

Section E4B

Measurement technique and limitations: instrument accuracy and performance limitations; probes; techniques to minimize errors; measurement of Q; instrument calibration; S parameters; vector network analyzers

Which of the following factors most affects the accuracy of a frequency counter?

  • Input attenuator accuracy
  • Correct Answer
    Time base accuracy
  • Decade divider accuracy
  • Temperature coefficient of the logic

A frequency counter has an internal frequency reference it uses to compare against the signal being measured. "Time base" is another term for "frequency reference" (frequency being the reciprocal of time, therefore a time reference is also a frequency reference). The more accurate the time base, the more accurate the frequency counter.

The other 3 factors mentioned are insignificant -- an attenuator changes the amplitude of the signal but not the frequency; and the logic components (including a decade divider) have no cumulative effect on accuracy since they are referenced to the time base.

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Tags: arrl chapter 7 arrl module 7b

What is the significance of voltmeter sensitivity expressed in ohms per volt?

  • Correct Answer
    The full scale reading of the voltmeter multiplied by its ohms per volt rating will indicate the input impedance of the voltmeter
  • When used as a galvanometer, the reading in volts multiplied by the ohms per volt rating will determine the power drawn by the device under test
  • When used as an ohmmeter, the reading in ohms divided by the ohms per volt rating will determine the voltage applied to the circuit
  • When used as an ammeter, the full scale reading in amps divided by ohms per volt rating will determine the size of shunt needed

\begin{align} \frac{\text{Ohms}}{\text{volt}} \times \text{full scale volts} &= \text{full scale impedance} \\ &=\text{input impedance} \end{align} (drichmond60)

Hint: all the "When used as..." answers are incorrect.

Hint: The word "voltmeter" appears in the question and in the correct answer.

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Tags: arrl chapter 7 arrl module 7b

Which S parameter is equivalent to forward gain?

  • S11
  • S12
  • Correct Answer
    S21
  • S22

The 2-port S (scattering) voltage parameters for a linear electrical network are defined as

S11 = input reflection coefficient
S12 = reverse gain
S21 = forward gain
S22 = output reflection coefficient

Therefore, S21 is the forward gain.

Hint: Sab is the outgoing wave at Port a when there is an incoming wave at Port B and there is no incoming wave at the other port.

See https://en.wikipedia.org/wiki/Scattering_parameters for a summary of the technical explanation

Mnemonic:
21: Big element followed by a small element is a Yagi with forward gain
12: Small element followed by a big element is a Yagi pointing the other way giving reverse gain.
11: The 1 sees a reflection and 1 looks like I for input.
22: The 2 sees a reflection and 2 does not look like an I.


Poor man's hint: In the United States, you look forward to turning 21 years old.

Another stupid hint: the greater number of 2 in S21 is before (forward) the 1. The reverse is true with reverse gain (pun unintended).

One more stupid hint: Watch out, because there are two very similar questions like this. The way you can remember is this question is shorter, so choose the bigger number. The other question is longer, so choose the smaller number. If that makes sense.

Silly Hint: The shifter on a car goes Park, Reverse, Forward, Overdrive... it's very similar to how the S parameters are structured:

  • S11 Input (In park)
  • S12 Reverse
  • S21 Forward
  • S22 Output (Overdrive)

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Tags: arrl chapter 9 arrl module 9g

Which S parameter represents input port return loss or reflection coefficient (equivalent to VSWR)?

  • Correct Answer
    S11
  • S12
  • S21
  • S22

The 2-port \(S\) (scattering) voltage parameters for a linear electrical network are defined as

\[\begin{align} S_{11} &= \text{input reflection coefficient} \\ S_{12} &= \text{reverse gain} \\ S_{21} &= \text{forward gain} \\ S_{22} &= \text{output reflection coefficient} \\ \end{align}\]

SWR and signal return loss are both calculated by using the input reflection coefficient. Therefore, \(S_{11}\) represents return loss. SWR can be directly calculated from S11 by a simple formula.

See https://en.wikipedia.org/wiki/Scattering_parameters for a summary of the technical explanation

Memory aid: picture the device facing toward the right, with left side numbered as 1 and right as 2. Then 1-2 and 2-1 would be traveling from one end to the other. Only 1-1 both goes in and (back) out on the left side.

Silly memory tip: The straight lines of "11" look like the tips of an electrical plug you "input" into a electrical socket.

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Tags: arrl chapter 9 arrl module 9g

What three test loads are used to calibrate an RF vector network analyzer?

  • 50 ohms, 75 ohms, and 90 ohms
  • Correct Answer
    Short circuit, open circuit, and 50 ohms
  • Short circuit, open circuit, and resonant circuit
  • 50 ohms through 1/8 wavelength, 1/4 wavelength, and 1/2 wavelength of coaxial cable

\(50\Omega\) ohms is the most common impedance used in RF power systems, and amateur transmitters also use this standard. Therefore it is a useful point to calibrate to. After that, short-circuit and open-circuit are two "boundary cases" that ensure the analyzer behaves correctly at the edges of its range.

Calibrating to \(75\Omega\) or \(90\Omega\) ohms might be somewhat helpful, but after covering the full range with the 3 correct answers there is limited value in any further calibration. The other answers are not simple loads or make no sense at all.

Funny reminder: The movie "short circuit" and the robot Johnny 5. Only 1 answer has "short circuit" and 5 (\(50\Omega\)) in it.

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Tags: arrl chapter 9 arrl module 9g

How much power is being absorbed by the load when a directional power meter connected between a transmitter and a terminating load reads 100 watts forward power and 25 watts reflected power?

  • 100 watts
  • 125 watts
  • 25 watts
  • Correct Answer
    75 watts

Where \(P\) is power:

\begin{align} \text{(load absorption)} &= P_\text{forward} - P_\text{reflected} &=100-25=75\:\text{Watts} \end{align}

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Tags: arrl chapter 9 arrl module 9f

What do the subscripts of S parameters represent?

  • Correct Answer
    The port or ports at which measurements are made
  • The relative time between measurements
  • Relative quality of the data
  • Frequency order of the measurements

S parameters are a way of measuring the frequency response of devices and can refer to as many ports as are on the device.

For example, an antenna has 1 port, a filter may have 2 ports, a power divider may have 3 or more ports.

The subscripts tell us from which ports the measurements were made and are in the order of "To -> From" or S<out><in>

So S11 would be a measurement to Port 1, from Port 1. (Perhaps an antenna measurement, or other reflection measurement).

S21 would be a measurement made at port 2 with the signal being delivered from port 1. (Such as measuring a filter to see what frequencies are blocked or passed through).

Silly hint: Submarines go to ports Silly hint: Think "Sports" as in football, basebasell, etc. for S Ports

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Which of the following can be used to measure the Q of a series-tuned circuit?

  • The inductance to capacitance ratio
  • The frequency shift
  • Correct Answer
    The bandwidth of the circuit's frequency response
  • The resonant frequency of the circuit

Quick silly attempt at remembering the right answer:

The right answer has "frequency response" in it. So, Every Question (Q) deserves a response

(you're welcome)

Q stands for quality. The frequency response is a measurement of quality.

Definition Of \(Q\) Factor: In the context of resonators, \(Q\) is defined in terms of the ratio of the energy stored in the resonator to the energy supplied by a generator, per cycle, to keep signal amplitude constant, at a frequency \(f_r\) (the resonant frequency), where the stored energy is constant with time:

\[\begin{align} Q &= 2π \times \left( \frac{\text{Energy}_{\text{stored}}}{\text{Energy}_{\text{dissipated per cycle}}} \right) \\ &= 2π\times f_r \times \left( \frac{\text{Energy}_{\text{stored}}}{\text{Power}_{\text{loss}}} \right) \end{align}\]

http://en.wikipedia.org/wiki/Q_factor#Explanation

There are a few ways to define \(Q\). With regard to this question, the bandwidth is the width of the range of frequencies for which the energy is at least half its peak value. The higher the \(Q\), the narrower the bandwidth. That is,

\[\text{bandwidth} = \frac{f_r}{Q}\]

-wileyj2956

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What is indicated if the current reading on an RF ammeter placed in series with the antenna feed line of a transmitter increases as the transmitter is tuned to resonance?

  • There is possibly a short to ground in the feed line
  • The transmitter is not properly neutralized
  • There is an impedance mismatch between the antenna and feed line
  • Correct Answer
    There is more power going into the antenna

The magnitude of a complex impedance is always higher than its resistive component (see Pythagorean Theorem). This means that a resistive load with a reactive component will always draw less current than the same load with no reactive component.

When an antenna is tuned to resonance its inductive and capacitive reactances add to zero, leaving only the resistive component of the antenna's impedance. As the antenna's reactance is reduced, more current flows into the antenna. Current is maximum when the antenna's reactance is zero.

Increased current means more power is being delivered to the antenna.

Hint: When something increases there is more of it.

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Which of the following methods measures intermodulation distortion in an SSB transmitter?

  • Modulate the transmitter using two RF signals having non-harmonically related frequencies and observe the RF output with a spectrum analyzer
  • Correct Answer
    Modulate the transmitter using two AF signals having non-harmonically related frequencies and observe the RF output with a spectrum analyzer
  • Modulate the transmitter using two AF signals having harmonically related frequencies and observe the RF output with a peak reading wattmeter
  • Modulate the transmitter using two RF signals having harmonically related frequencies and observe the RF output with a logic analyzer

Caution, this one is easy to misread.

Both choices that Modulate the transmitter using two RF signals are distractors because we use audio frequencies (here abbreviated AF) to modulate the carrier in SSB mode.

You can rule out the distractors mentioning logic analyzer, which only handles digital logic signals, and peak reading wattmeter, because it just outputs a watt number - you'd have no way to know if that number represents your signal peak or a intermodulation distortion peak.
Instead you want a spectrum analyser, which shows many frequencies at once, and their current power level, letting you spot intermodulation distortion at nearby frequencies.

That leaves the correct answer Modulate the transmitter with two non-harmonically related audio frequencies and observe the RF output with a spectrum analyzer.

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Tags: arrl chapter 7 arrl module 7b

Which of the following can be measured with a vector network analyzer?

  • Input impedance
  • Output impedance
  • Reflection coefficient
  • Correct Answer
    All these choices are correct

A Vector Network Analyzer is fundamentally a device for measuring incident and reflected power, usually expressed as S Parameters (Scattering Parameters).

While Input Impedance and Output Impedance are not actually S Parameters, these things can be calculated based on a combination of S parameter measurements and calibration data. A VNA will typically calculate these for you based on measurements/calibration and present them to you, therefore they can effectively be used to measure these values. Since Reflection coefficient is an S parameter and the others are normally calculated for you by a VNA, the best answer here is All these choices are correct.

Note that "network" in the name Vector Network Analyzer refers to electrical networks, not computer networks or communication networks. An electrical network is what you see on a schematic diagram.

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