Phase and Phase Angle
Phase is the concept that describes where a sine wave is in its cycle at a given moment in time. When two signals of the same frequency are compared, the phase angle tells you by how much they are offset from each other. Phase is a core concept in AC circuit theory, antenna engineering and RF system design — and once you understand it, you can make sense of subjects from impedance matching to phased array antennas.
What Is Phase
Phase describes the position of a wave within its cycle at a particular instant. A full cycle spans 360°. Halfway through a cycle is 180°. A quarter of a cycle is 90°.
When two sine waves of the same frequency are compared, the phase difference (or phase angle) tells you how far apart they are in their cycles:
- Two waves that reach their positive peak at exactly the same time are in phase — 0° difference.
- Two waves where the positive peak of one coincides with the negative peak of the other are 180° out of phase.
- Any other offset is described as a phase angle between 0° and 360° (or equivalently, between −180° and +180°).
Two sine waves at the same frequency but with a phase difference. The phase angle φ is the horizontal offset measured in degrees.
View LargerMeasuring Phase Angle
Phase angle (φ, phi) is measured in degrees or radians. The two are related by: 360° = 2π radians.
| Phase Angle | Radians | Meaning |
|---|---|---|
| 0° | 0 | In phase — peaks align perfectly |
| 90° | π/2 | One quarter cycle apart — common in LC circuits (voltage vs current) |
| 180° | π | Half cycle apart — completely out of phase; equal amplitudes cancel |
| 270° | 3π/2 | Three-quarter cycle apart — equivalent to −90° |
| 360° | 2π | One full cycle — identical to 0°, back in phase |
The phase angle of a signal is often written as part of its mathematical description: v(t) = Vpeak × sin(2πft + φ), where φ is the initial phase angle at t = 0.
Leading and Lagging
If wave A reaches its positive peak before wave B, then A is said to lead B by the phase angle between them. Conversely, B lags A.
Wave A leads wave B by 90°. The positive peak of A occurs one quarter cycle before the positive peak of B.
View LargerTwo classic examples from circuit theory that you will use throughout this course:
- In a series RC circuit, the current leads the voltage across the capacitor by 90°.
- In a series RL circuit, the voltage across the inductor leads the current by 90°.
ELI: voltage (E) Leads current (I) in an inductor (L)
ICE: current (I) leads voltage (E) in a capacitor (C)
In Phase and Out of Phase
The phase relationship between two signals determines whether they reinforce or cancel each other:
- 0° (in phase): the signals add constructively. Their amplitudes add together. Two identical signals in phase produce double the amplitude.
- 180° (out of phase): the signals add destructively. If they are equal in amplitude, they cancel completely, producing zero output.
- Other angles: partial reinforcement or partial cancellation, depending on how close the angle is to 0° or 180°.
This principle has direct practical consequences:
- Antenna phasing: two identical antennas fed with a 90° or 180° phase difference create a shaped radiation pattern — stronger in some directions, reduced in others.
- Signal interference: two RF signals arriving via different paths can add or cancel at the receiver depending on their relative phase. This is multipath fading.
- Balanced circuits: differential amplifiers use 180° phase inversion to reject common-mode noise, passing only the signal difference between the two inputs.
- Push-pull amplifiers: two transistors handle alternate half-cycles, operating 180° apart. This halves the distortion compared to a single-ended stage.
Phasors
A phasor is a rotating vector used to represent a sine wave. The length of the vector represents the amplitude (usually the RMS value). The angle of the vector from the reference direction (conventionally the positive x-axis) represents the phase.
Two sine waves of the same frequency can be drawn as two vectors at different angles on the same diagram. The phase difference between them is simply the angle between the two vectors.
A phasor diagram showing two signals. The length of each vector represents amplitude; the angle between them represents the phase difference.
View LargerPhasors make it much easier to add and subtract AC signals at the same frequency — instead of adding two sine wave equations, you add two vectors. Full phasor analysis, including the use of complex numbers to represent impedance, is covered in Module 6 (AC Circuit Theory). The concept is introduced here because you will encounter phasor diagrams in capacitor and inductor lessons before then.
Phase in Ham Radio
Phase relationships appear throughout amateur radio practice:
- Phased vertical antennas: two quarter-wave verticals fed with a 90° phase difference produce a cardioid radiation pattern — significantly stronger in one direction and reduced in the opposite direction. This technique is widely used on LF and HF where large beam antennas are impractical. The phase difference is created by feeding the two elements through a phasing network — a combination of coax lengths or LC components.
- Power factor: in an AC circuit containing reactive components (capacitors or inductors), the current and voltage are out of phase. The cosine of the phase angle is the power factor. When current and voltage are in phase (purely resistive load), all the apparent power is real power doing useful work. A phase shift between V and I means some power oscillates back and forth between source and reactive component without being consumed — this is reactive power.
- Balanced feedlines: the two conductors of a ladder line (open-wire feeder) carry signals 180° out of phase. Any interference — whether from nearby transmitters or electrical wiring — is picked up equally on both conductors. Because these common-mode signals are in phase with each other (not 180° apart), they cancel at the balanced input of the antenna tuner or balun, rejecting the interference.
- Phase noise: an ideal oscillator produces a carrier with a perfectly stable phase. In practice, random thermal and electronic noise causes tiny random variations in the instantaneous phase of the output — called phase noise. This appears on a spectrum analyzer as energy spread across frequencies close to the carrier. Phase noise limits the ability to receive a weak signal close in frequency to a strong one — a critical consideration for contest operating and DXpedition chasing where signals may be only a few kilohertz apart.
Frequently Asked Questions
What does it mean for two signals to be "out of phase"?
Loosely, "out of phase" means the signals are not in perfect alignment — their peaks and troughs do not occur at the same time. Technically, any non-zero phase difference means they are out of phase. However, in common usage "out of phase" often specifically means 180° apart, where the peaks of one align with the troughs of the other. At 180°, two equal-amplitude signals cancel completely when added. In audio, accidentally connecting a speaker with reversed polarity puts it 180° out of phase with the other speakers — this is audibly noticeable as weak, thin bass because the low frequencies cancel across the room.
What is the relationship between phase and time delay?
Phase and time delay both describe the offset between two signals, just in different units. A phase angle of φ degrees corresponds to a time delay of t = φ / (360 × f) seconds, where f is the frequency. At 14 MHz, a 90° phase shift corresponds to a time delay of 90 / (360 × 14,000,000) = 17.9 nanoseconds. For a transmission line, a physical delay in the cable translates to a phase shift that depends on frequency — which is why the same physical length of coax looks like a different electrical length at different frequencies.
Can two signals have different phases if they have different frequencies?
Phase as a fixed angle only has a definitive meaning when comparing two signals at the same frequency. Signals at different frequencies drift through all possible phase relationships continuously — a higher-frequency signal completes its cycles faster, so their relative phase changes over time. For this reason, phase difference is always described in the context of two signals at the same frequency. When two frequencies are mixed in a mixer circuit, new frequencies are generated at the sum and difference, but the phase relationships between the original signals do not directly transfer to the output in the same straightforward way.
What is phase modulation and how is it different from frequency modulation?
In frequency modulation (FM), the audio signal varies the instantaneous frequency of the carrier. In phase modulation (PM), the audio signal varies the instantaneous phase of the carrier. Because phase and frequency are mathematically related (frequency is the rate of change of phase), PM and FM sound similar and can be difficult to distinguish by listening. They differ in the emphasis given to higher audio frequencies and in how the modulation index varies with audio frequency. Modern digital modes such as PSK31, BPSK and QPSK, as well as many digital radio protocols including those used in digital television and LTE mobile networks, use phase modulation as their primary modulation method.
Test Your Knowledge
Answer the questions below to check your understanding. Every answer can be found in the lesson above.