Vol 2: Electrical and Electronic Fundamentals

Question 1

Describe matter.

Answer 1

Any substance that has weight and takes up space.

Question 2

What cannot be broken down into a simpler substance using ordinary chemical means?

Answer 2

Elements.

Question 3

Define molecule.

Answer 3

The smallest part of a substance that has all the characteristics of that substance.

Question 4

What are the elements that form molecules?

Answer 4

Atoms.

Question 5

What type of charge does a proton carry? An electron?

Answer 5

Positive; negative.

Question 6

When do we consider an atom to be electrically balanced?

Answer 6

When the negative charge of the electron is equal to the positive charge of the proton.

Question 7

Provide a description of electrical current.

Answer 7

The uniform movement of electrons in a specific direction through a conductor (wire).

Question 8

What is the term for an atom with eight electrons in the valence shell?

Answer 8

Stable or balanced atom.

Question 9

What is an atom that has gained an electron called?

Answer 9

Negative ion.

Question 10

What type of charge does a normal atom that has lost one electron have?

Answer 10

Positive.

Question 11

The uniform movement of free electrons in a specific direction.

Answer 11

Current flow.

Question 12

6.28 × 1018 electrical charges.

Answer 12

Coulomb.

Question 13

One coulomb passing a given point per second.

Answer 13

Ampere.

Question 14

Symbol for current used in equations.

Answer 14

I

Question 15

Symbol for quantity of amperes.

Answer 15

A or a.

Question 16

List four effects of current flow.

Answer 16

Heat, chemical change, magnetism, and physical shock.

Question 17

Unit of measure for “electrical pressure.”

Answer 17

Volt.

Question 18

The force which causes electrons to move from atom to atom.

Answer 18

Voltage or emf.

Question 19

“E.”

Answer 19

Voltage.

Question 20

Changes mechanical energy into electrical energy.

Answer 20

Generator.

Question 21

Changes heat energy into electrical energy.

Answer 21

Thermocouple.

Question 22

Unit of measure for all electrical opposition.

Answer 22

Ohm.

Question 23

When 1 volt of pressure pushes 1 ampere of current flow through an electrical path, then 1 ohm
of resistance is present.

Answer 23

Ohm’s Law.

Question 24

“R.”

Answer 24

Resistance.

Question 25

Name four factors that affect resistance.

Answer 25

Any four of these: length, size, material, temperature, and reactance.

Question 26

“W” or “P.”

Answer 26

Power

Question 27

The rate of doing work.

Answer 27

Power

Question 28

Unit in which electrical motors are rated.

Answer 28

Horsepower

Question 29

Unit in which generators and regulators are rated.

Answer 29

Watts

Question 30

Number of watts per horsepower.

Answer 30

746 Watts

Question 31

What is magnetic material?

Answer 31

A material, usually iron, that has the ability to retain magnetic lines of force.

Question 32

Define residual magnetism.

Answer 32

The induced magnetism that remains in a magnetic substance after we remove the magnetic field.

Question 33

What materials do you use to make high-grade artificial magnets?

Answer 33

Aluminum, nickel, iron, and cobalt.

Question 34

In what direction do the lines of force travel outside a bar magnet?

Answer 34

From the north pole to the south pole.

Question 35

What action takes place when you place the south pole of one magnet near the south pole of
another?

Answer 35

They repel each other.

Question 36

State the fundamental laws of magnetism.

Answer 36

Like poles repel each other; unlike poles attract.

Question 37

When do magnetic lines of force cross?

Answer 37

Never.

Question 38

What surrounds all current-carrying conductors?

Answer 38

Magnetic lines of force.

Question 39

How can you strengthen the magnetic lines of force around a conductor?

Answer 39

By forming a number of loops close together.

Question 40

What three items are necessary to have an electromagnet?

Answer 40

Coil of wire, core material, and current flow.

Question 41

What type of core is preferred in the construction of relays and solenoids?

Answer 41

Soft iron core.

Question 42

What is the relationship of the current to the voltage and resistance in a DC circuit according to
Ohm’s law?

Answer 42

The current in amperes is equal to the emf in volts divided by resistance in ohms.

Question 43

Voltage = 90, current = 30, R = ?

Answer 43

3

Question 44

Voltage = ?; current = 2; and resistance: R1 = 7, R2 = 5.

Answer 44

24

Question 45

Voltage = 24; current = ?; resistance: R1 = 10, R2 = 8, R3 = 6.

Answer 45

1

Question 46

What are the characteristics of resistance, current, and voltage in a DC-series circuit?

Answer 46

(1) The total resistance is the sum of the individual resistors.
(2) The same current flows in each part of the circuit.
(3) The applied voltage divides among the resistors according to their resistance.

Question 47

What is the rule that pertains to the total current in a parallel circuit?

Answer 47

In a parallel circuit, the total current equals the sum of the current in the branches.

Question 48

In solving for a value in a series-parallel circuit, what do you do to the circuit first?

Answer 48

Reduce a series-parallel circuit to an equivalent, simplified circuit. Replace each group of parallel resistors
with its equivalent single resistance; then, treat the entire circuit as a series circuit.

Question 49

In your own words, define Kirchhoff’s voltage law.

Answer 49

The algebraic sum of the voltages around a closed loop must equal zero.

Question 50

The ability to do work measured in joules.

Answer 50

Energy.

Question 51

The production of motion against a resisting force measured in joules.

Answer 51

Work.

Question 52

The rate of doing work measured in watts.

Answer 52

Power.

Question 53

That which produces a change in motion of a body measured in dynes.

Answer 53

Force.

Question 54

What formula do you use to compute power in a DC circuit when you only know resistance and
current?

Answer 54

P = I2R.

Question 55

In a parallel circuit having four equal lamps, with an applied voltage of 120 volts and a total
current flow of 4 amperes, what is the power consumed at each lamp?

Answer 55

120 watts.

Question 56

How do electrons travel in a circuit?

Answer 56

From negative to positive.

Question 57

What is the difference in current flow between an AC circuit that contains only resistance and a
DC circuit that contains only resistance?

Answer 57

The current flow in a circuit containing resistance only is the same, regardless of whether the applied
voltage is AC or DC.

Question 58

Explain Kirchhoff’s law for current as it applies to AC circuits.

Answer 58

AC circuits normally contain inductive and capacitive loads as well. Although they have different formulas
for determining their ohmic values, you can find their voltage and current values the same way as you did
by applying Kirchhoff’s laws for voltage and current in DC circuits.

Question 59

In an AC circuit, when is the apparent power equal to the true power?

Answer 59

When the circuit consists of pure resistance.

Question 60

When is the true power less than the apparent power?

Answer 60

When the current and voltage are out of phase due to reactance in the circuit.

Question 61

What is the formula for power factor?

Answer 61

Power factor =100 watts (true power) / 
volts amps (apparent power)

Question 62

A 240-volt AC motor records 35 in-line amperes. The in-line wattmeter shows only 7,600 watts
being consumed. What is the power factor of the AC circuit?

Answer 62

pf = 90.47, or 90.5 percent.

Question 63

Name the portion of the applied power that produces the magnetic field in an AC circuit.

Answer 63

Wattless power or reactive power expressed in VARs.

Question 64

What is the function of a generator?

Answer 64

To convert mechanical energy into electrical energy.

Question 65

What are the types of alternators?

Answer 65

Single-phase and three-phase

Question 66

In what two ways does an alternator operate?

Answer 66

By the principle of either moving conductors across a magnetic field or moving a magnetic field across the
conductors.

Question 67

What are the operations of a single-phase alternator?

Answer 67

The first half revolution of the rotor produces a voltage in one direction and completes the first half of the
cycle; the second half revolution produces a voltage in the opposite direction and completes the last half of
the cycle.

Question 68

What supplies the DC voltage in a three-phase alternator?

Answer 68

An exciter.

Question 69

How many degrees are the poles set apart for three-phase operation of an alternator?

Answer 69

120

Question 70

What is the difference between a primary and a secondary cell?

Answer 70

The primary cell can’t be recharged; the secondary cell can.

Question 71

What solution is used for the electrolyte in a lead-acid battery?

Answer 71

Sulfuric acid and water solution.

Question 72

What materials make up the negative and positive plates of a lead-acid battery?

Answer 72

The negative plate is spongy lead and the positive plate is lead peroxide.

Question 73

What solution is used for the electrolyte in a nickel-cadmium battery?

Answer 73

Potassium hydroxide and distilled water.

Question 74

What isolates instruments from high voltages or large currents?

Answer 74

Instrument transformers.

Question 75

If the ratio of a transformer is 6 to 1 and the applied voltage to the primary is 120-VAC, what is
the voltage output from the secondary?

Answer 75

20 VAC

Question 76

What causes voltage to be induced in a transformer?

Answer 76

Buildup and collapse of the current.

Question 77

What does a transformer with a 1- to 2-turn ratio do to the voltage?

Answer 77

Step it up.

Question 78

Name the main parts of a transformer.

Answer 78

Primary winding and secondary winding

Question 79

What can you do to the secondary winding of a transformer to produce more than one voltage?

Answer 79

Center tap it.

Question 80

Transistors have three leads. They are labeled E, B, and C, as follows:

Answer 80

1. Emitter - Identified by diode symbol or arrow (Emits carriers).
2. Base - Center electrode (controls flow).
3. Collector- Unidentified electrode (Collects carriers).

Question 81

Define the word electronics.

Answer 81

All applications involving the control of electricity using gasses or semiconductors.

Question 82

What do we call the movement of free electons?

Answer 82

Current flow.

Question 83

What are the two most common materials used to make semiconductors?

Answer 83

Germanium and silicon.

Question 84

By what other term do we refer to a diode?

Answer 84

PN junction.

Question 85

Is the N-type material of a diode the anode or cathode?

Answer 85

Cathode.

Question 86

Is the P-type material of a diode the anode or cathode?

Answer 86

Anode.

Question 87

What could happen if you do not observe polarity when connecting a diode?

Answer 87

You could unintentionally block current to a circuit.

Question 88

Do electrons flow from cathode to anode or from anode to cathode?

Answer 88

Cathode to anode.

Question 89

Which rating on a diode tells you the maximum voltage allowed in reverse bias?

Answer 89

PIV

Question 90

Can we use a photo diode to trigger an LED?

Answer 90

No. (Although you can use an LED to trigger a photo diode.)

Question 91

Name two applications for Zener diodes.

Answer 91

Voltage regulation and voltage limiting.

Question 92

To what can we compare an SCR?

Answer 92

Latching relay.

Question 93

A transistor may be connected in any one of three basic configurations:

Answer 93

1. The common (grounded) emitter.
2. The common (grounded) base.
3. The common (grounded) collector

Question 94

There are five major classes of circuit

components:

Answer 94

1. Direct logic (DL).
2. Resistor-transistor logic (RTL).
3. Diode-transistor logic (DTL).
4. Transistor-transistor logic (TTL).
5. Direct-coupled transistor logic (DCTL).

Question 95

What is the only difference between the symbols of the PNP and NPN transistors?

Answer 95

The direction of the arrow on the emitter lead.

Question 96

In which direction does external current flow in a transistor?

Answer 96

Against the arrow on the emitter lead.

Question 97

How do we show proper bias for a transistor on a schematic?

Answer 97

We use symbols to show proper bias polarities for the battery to the transistor.

Question 98

What are the three basic configurations in which you can connect a transistor?

Answer 98

Common emitter; common base; and common collector.

Question 99

To what is the grounded element common?

Answer 99

Both the input and output circuits.

Question 100

What type of voltage is applied to a PNP transistor to satisfy the requirement for reverse bias
between the collector and base?

Answer 100

Negative voltage.

Question 101

When testing an SCR or any other electronic devices, what precautions must you take?

Answer 101

Ensure that you know what voltage and current levels you are dealing with.

Question 102

How can you vary or control the value of the forward breakover potential?

Answer 102

By applying an external signal at the control electrode (gate).

Question 103

If you apply an AC signal to the anode, how can you make an SCR conduct during any portion of
the positive alternation?

Answer 103

By applying a portion of that positive signal to the gate.

Question 104

How can an SCR be turned off in minimum time?

Answer 104

By reverse biasing the anode.

Question 105

How does the gate of an SCR receive its signal?

Answer 105

A resistor is used as part of a voltage divider circuit.

Question 106

How are most integrated circuits produced?

Answer 106

By a batch-fabrication method.

Question 107

What are the changes in characteristics of integrated circuits that result from the differences in
manufacture and physical size?

Answer 107

1) Very few capacitors and almost no inductors are used.
(2) All voltages used are smaller than for discrete circuits.
(3) Component values tend to be smaller than for discrete circuits.
(4) Integrated circuit transistors normally will be NPN.
(5) Throw-away maintenance is used with integrated circuits.

Question 108

How do you classify circuits that you use in digital equipment?

Answer 108

According to the types of components used in the circuit.

Question 109

What are the five major classes of circuit components?

Answer 109

(1) Direct logic (DL).
(2) Resistor-transistor logic (RTL).
(3) Diode-transistor logic (DTL).
(4) Transistor-transistor logic (TTL).
(5) Direct-coupled transistor logic (DCTL).

Question 110

What is one of the largest problems in integrated semiconductor operations?

Answer 110

Faulty connection between components and circuits.

Question 111

Why is an integrated circuit a self-contained circuit?

Answer 111

It contains all required components.

Question 112

How is half-wave rectification accomplished?

Answer 112

By placing a diode in series with a source of AC and a load resistor.

Question 113

What does the application of AC cause that results in rectification?

Answer 113

A forward- and reverse-bias condition on a diode.

Question 114

What is the unit of measure for the output ripple frequency of a half-wave rectifier?

Answer 114

Pulses per second (pps).

Question 115

What is the operating characteristic of a full-wave rectifier?

Answer 115

It permits current to flow in the same direction through the load during both alternations of an AC input.

Question 116

What are the identifying features of a full-wave rectifier?

Answer 116

Two diodes, a center-tapped transformer, and a load resistor.

Question 117

Where is the output voltage of a full-wave rectifier developed?

Answer 117

Across the load resistor.

Question 118

How much inverse voltage must each diode withstand in a full-wave rectifier?

Answer 118

An inverse voltage twice the value of the output peak voltage.

Question 119

What must the breakdown rating be for diodes you use in a full-wave rectifier?

Answer 119

It must be twice as great as that of the half-wave diode.

Question 120

How does the bridge rectifier design compare to that of the full-wave rectifier?

Answer 120

The bridge rectifier is a modified full-wave rectifier that may have either two or four diodes. Also, a bridge
rectifier does not have a center-tapped transformer.

Question 121

Why are bridge and full-wave rectifiers considered full-wave devices?

Answer 121

Because current flows through the load resistor during both alternations of the input signal.

Question 122

How does the peak output voltage from the bridge rectifier compare to that of the full-wave
rectifier?

Answer 122

The peak output voltage from the bridge is twice that of the full-wave.

Question 123

What is the peak inverse voltage for bridge rectifier and full-wave rectifier circuits?

Answer 123

The PIV is the peak voltage applied across the entire secondary of the input transformer.

Question 124

What can you use instead of a single-phase input when you need large amounts of power?

Answer 124

A three-phase input.

Question 125

What is the phase angle between the three equal single-phase voltages of a three-phase generator?

Answer 125

120°.

Question 126

What does current flow through the load produce in a three-phase bridge circuit?

Answer 126

Output polarity.

Question 127

What is the three-phase, full-wave rectified output ripple frequency with a 60-hertz input?

Answer 127

360 pps.

Question 128

How much filtering is needed to smooth DC output with low-amplitude ripple voltage?

Answer 128

Very little.

Question 129

What is the purpose of a filter?

Answer 129

To convert pulsating DC to smooth DC.

Question 130

Why does ripple voltage exist?

Answer 130

Because the rectifier supplies energy to the load in pulses.

Question 131

How does a filter affect the ripple amplitude of the output of a rectifier?

Answer 131

Smoothes out the peak, or reduces the amplitude.

Question 132

What is the relationship between the charge and discharge times a capacitive filter should have?

Answer 132

It should have a short charge time and a long discharge time.

Question 133

What does the charge on a capacitor represent?

Answer 133

A storage of energy.

Question 134

Once the capacitor is charged, when does the rectifier conduct?

Answer 134

It conducts when the input voltage to the rectifier exceeds the voltage across the capacitor.

Question 135

How are capacitive filters connected with the load?

Answer 135

In parallel

Question 136

What does the inductive filter use to provide filtering action?

Answer 136

The inductive reactance properties of the coil.

Question 137

How are inductive filters connected to the load?

Answer 137

In series

Question 138

What are the two types of L-type filters?

Answer 138

L-type inductor input filter and L-type capacitor input filter

Question 139

What components make up an L-type filter?

Answer 139

An inductor and a capacitor.

Question 140

When does the rectifier diode connected to the L-type filter in figure 3–21 conduct?

Answer 140

When the positive half of the incoming sine wave is applied to the transformer.

Question 141

How much resistance is offered by the forward biased diode of an L-type filter?

Answer 141

Very little.

Question 142

What happens as the positive half cycle of the L-type filter begins to decrease?

Answer 142

The diode approaches cutoff and the capacitor discharges through the load resistor.

Question 143

Why is the output voltage across the load resistor high in the L-type capacitive input filter circuit?

Answer 143

Because the capacitor charges to the peak value of the L-type filter.

Question 144

When you compare it to the capacitive input L-type filter, what does the inductive input L-type
filter provide?

Answer 144

It gives a lower output voltage and better voltage regulation.

Question 145

What are the common characteristics of the two types of Pi-type filters?

Answer 145

Both of them have two capacitors to ground.

Question 146

When you compare it to the RC Pi-type filter, what does the LC Pi-type filter provide?

Answer 146

It gives a high-output voltage and better voltage regulation.

Question 147

In the transistor circuit, on what factors does the gain of the current, voltage, and power
amplifiers depend?

Answer 147

The alpha and beta values and the ratio of output to input resistance.

Question 148

What factor enables a transistor to amplify?

Answer 148

A transistor can amplify because its middle electrode, the base, has an electrical advantage.

Question 149

The input signal to the NPN transistor causes base current to change at the same rate as the input
signal, thus causing a change in transistor resistance. What does this change in resistance cause?

Answer 149

A relatively large voltage change.

Question 150

In a common emitter configuration, what do we call resistor RL?

Answer 150

Collector load resistor.

Question 151

What happens to base current, emitter current, and collector current during the negative
alternation of the input signal to a NPN common emitter amplifier?

Answer 151

They all decrease.

Question 152

In the above question, what happens to the output that is taken from the collector with respect to
the emitter?

Answer 152

It is a voltage waveform that has the same characteristics as the input signal except that it has been enlarged
or amplified

Question 153

What does the positive alternation of the input signal applied to the emitter of the NPN common
base amplifier cause?

Answer 153

The emitter current to decrease.

Question 154

What is the controlling element in a common base configuration?

Answer 154

The emitter.

Question 155

With a decrease in emitter and collector current, the voltage across the load resistor (RL)
decreases. What does this cause in a common base amplifier?

Answer 155

A positive output from collector to ground.

Question 156

For the negative alternation of the input signal, the collector voltage varies at the same rate as the
input. What does this produce in a common base amplifier?

Answer 156

An amplified negative alternation.

Question 157

What do we sometimes call a common collector amplifier configuration?

Answer 157

A grounded collector or emitter follower.

Question 158

Where is the input signal applied and where is the output signal developed in a common collector
amplifier?

Answer 158

The input signal is applied between the base and ground. The output signal is developed between the
emitter and the ground collector. Thus, the collector is common to both input and output circuits.

Question 159

What is degeneration?

Answer 159

The process of returning a part of the output of an amplifier to its input in such a manner that it cancels part
of the input signal.

Question 160

What is the phase relationship between the input signal voltage and the output signal voltage of a
common or grounded emitter?

Answer 160

180° out-of-phase.

Question 161

How is an electronic voltage regulator designed to operate?

Answer 161

It is designed to maintain the output voltage nearly constant regardless of input voltage or load changes.

Question 162

How can you improve the operation of a simplified electronic voltage regulator?

Answer 162

By incorporating two class A amplifiers and a voltage divider network.

Question 163

How can you change the output voltage of the electronic voltage regulator?

Answer 163

By moving the arm of the output voltage adjuster.

Question 164

Are all AC-voltage waveforms sine waves?

Answer 164

No.

Question 165

What is the most common frequency used for the transmission of electrical energy?

Answer 165

60 Hz in North America, 50 Hz in Europe, and 400 Hz in and around aircraft and air ground equipment.

Question 166

What may high harmonic levels cause?

Answer 166

Interference to control and communication lines, heating of AC motors, higher reactive power demand and
hence poor power factor, misoperation of sensitive electronics, overloading of shunt capacitors, and higher
power loss.

Question 167

What are the four purposes of harmonic measurements?

Answer 167

(1) Monitoring existing values of harmonics and checking against recommended or admissible levels.
(2) Testing equipment that generates harmonics.
(3) Diagnosis and trouble-shooting situations where the equipment performance is unacceptable to the
utility or to the US.
(4) Observations of existing background levels and tracking the trends in theme of voltage and current
harmonics (daily, monthly, seasonal patterns).

Question 168

What kind of information does the display of the voltage waveform on the oscilloscope give?

Answer 168

Immediate qualitative information on the degree and type of distortion

Question 169

How do spectrum analyzers display signals?

Answer 169

As a function of frequency

Question 170

What do harmonic analyzers or wave analyzers measure?

Answer 170

The amplitude (and more complex units of the phase angles also) of a periodic function.