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Understanding Key Loudspeaker Parameters(17): Loudspeaker Directivity
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posted by Vincent Zhang
Published by IWISTAO
Among the many parameters that describe a loudspeaker’s performance, Directivity is one of the most important yet often misunderstood. While parameters such as sensitivity, frequency range, Qts, and Bl describe how a driver behaves in a controlled environment, directivity describes how it behaves in a real acoustic space—how sound spreads, how listeners perceive it, and how the system interacts with the room.
Directivity affects imaging, soundstage, clarity, power response, room reflections, and tonal balance. For speaker designers and audio enthusiasts, understanding directivity is crucial for achieving accurate and consistent sound reproduction.
1. What Is Directivity?
Directivity refers to how a loudspeaker distributes its acoustic energy in different directions as a function of frequency. It describes the relationship between on-axis sound (directly in front of the speaker) and off-axis sound (angles away from the center).
A loudspeaker with high directivity focuses sound into a narrow beam, while a loudspeaker with low directivity spreads sound broadly in all directions.
Directivity is commonly expressed through:
- Polar patterns
- Beamwidth
- Directivity Index (DI)
- Q factor
- Off-axis frequency response
(How to Read a Polar Pattern of Loudspeaker Directivity)
2. Why Directivity Matters
a. Soundstage & Imaging
Consistent and smooth directivity creates stable imaging and a wide listening sweet spot. Poor directivity causes uneven tonal balance and unstable imaging across angles.
b. Room Interaction
- Wide directivity → more reflections → spacious but less clarity
- Narrow directivity → fewer reflections → cleaner detail but smaller sweet spot
c. Tonal Balance
Uneven directivity leads to off-axis dips or peaks, causing coloration and inconsistent power response across the room.
d. Speech Intelligibility
PA and cinema systems rely on controlled directivity to deliver clear audio to specific audience areas.
3. How Directivity Changes With Frequency
Directivity is strongly related to wavelength and driver diameter.
Low Frequencies
- Long wavelengths dominate
- Drivers behave nearly omnidirectional
Mid Frequencies
- Driver size becomes comparable to wavelength
- Directivity gradually increases
High Frequencies
- Short wavelengths
- Drivers become highly directional
- Horns and waveguides used to control dispersion
4. Directivity Index (DI) and Q Factor
Directivity is often quantified using:
a. Directivity Index (DI)
DI = 10 × log₁₀(Q)
b. Q Factor
Describes how concentrated the radiation pattern is.
| Speaker Type | Q | DI (approx.) | Pattern |
|---|---|---|---|
| Omnidirectional (subwoofer) | 1 | 0 dB | Omni |
| Typical woofer | 2–3 | 3–5 dB | Mild directivity |
| Dome tweeter | 4–6 | 6–8 dB | Narrow dispersion |
| Horn tweeter | 10–20 | 10–13 dB | Highly focused |
5. Common Directivity Patterns
Omnidirectional
Uniform radiation in all directions; typical for low frequencies.
Wide Dispersion
Broad horizontal/vertical spread, good for home Hi-Fi systems.
Controlled Directivity
Reduces room reflections; achieved using horns or waveguides.
Narrow Beam
Used for PA or long-throw projection.
6. How Speaker Design Affects Directivity
a. Driver Size
Larger drivers become directional at lower frequencies; smaller drivers stay wide longer.
b. Cone Shape
Shallow cones → wide dispersion; deep cones → narrow dispersion.
c. Dome vs Cone vs Horn
- Dome tweeters: wide and smooth
- Cone midranges: moderate dispersion
- Horn-loaded tweeters: controlled directivity
d. Waveguides
Improve off-axis smoothness and shape dispersion across frequency.
e. Crossover Design
Poorly chosen crossover points cause lobing, cancellations, or off-axis irregularities.
7. Directivity and Room Acoustics
Room acoustics strongly influence perceived sound:
- Small rooms: moderate directivity is ideal
- Large rooms: controlled directivity prevents excessive reflections
- PA systems: narrow directivity is essential for audience coverage
8. Directivity in Multi-Way Systems
2-Way Speakers
Woofer and tweeter directivity must match at crossover to avoid tonal discontinuity.
3-Way Systems
Better control: woofer → midrange → tweeter each handle appropriate bandwidth.
Line Arrays
Create wide horizontal but narrow vertical dispersion for long-throw projection.
9. Measuring Directivity
Common measurement tools:
- Polar plots
- Beamwidth charts
- Off-axis frequency response
- Sound power response
Smooth polar patterns indicate consistent directivity; irregular patterns reveal lobing or diffraction issues.
10. Common Misunderstandings
“Wide dispersion is always better.”
Not always. It increases reflections and may reduce clarity.
“Narrow directivity always sounds harsh.”
Good horns are extremely smooth and natural.
“Directivity doesn’t matter in home audio.”
Wrong — directivity strongly affects imaging and room response.
“Drivers can operate anywhere within their range regardless of dispersion.”
Crossover decisions must be based on directivity matching, not just frequency range.
Conclusion
Directivity describes how a loudspeaker radiates sound into the room and how listeners perceive that sound. It affects imaging, clarity, tonal balance, room interaction, and overall acoustic performance. Through careful design—using appropriate drivers, waveguides, horns, and properly matched crossovers—directivity can be controlled to achieve consistent, accurate, and high-quality audio reproduction in any environment.
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How to Read a Polar Pattern of Loudspeaker Directivity
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