Understanding Key Loudspeaker Parameters(8): Effective Piston Area (Sd)--The Relationship Between Cone Size and Output
Published by IWISTAO
Among all loudspeaker parameters, Sd (Effective Radiating Area) is one of the most fundamental. It defines how much air a speaker can move—directly determining bass output, efficiency, maximum SPL, and distortion characteristics. Although simple in concept, Sd has a powerful influence on how “big” a loudspeaker sounds.
1. What Is Effective Radiating Area (Sd)?
Sd represents the effective surface area of the diaphragm that actively pushes air to produce sound. It includes:
- The main cone surface
- A portion of the surround (usually half its width)
Sd is measured in cm² or m². It does not include non-moving or low-motion components such as the dust cap or frame.
2. Relationship Between Sd and Din
Sd is calculated using the Effective Diaphragm Diameter (Din):
Sd = π × Din² / 4Because Sd depends on the square of Din, even small changes in diaphragm diameter can cause large differences in radiating area.
3. Typical Sd Values by Driver Size
| Nominal Size | Typical Sd (cm²) | Description |
|---|---|---|
| 2″ | 15–20 | Micro drivers |
| 3″ | 25–35 | Compact full-range |
| 4″ | 45–55 | Small mid-bass |
| 5.25″ | 75–95 | Bookshelf woofer size |
| 6.5″ | 120–150 | Most common Hi-Fi woofer |
| 8″ | 210–260 | Strong bass capability |
| 10″ | 330–380 | Home theater woofer |
| 12″ | 450–550 | Classic subwoofer |
| 15″ | 750–900 | Professional bass drivers |
| 18″ | 1100–1300 | High-SPL subwoofers |
4. Why Sd Matters
a. Air Displacement (Vd)
Sd is one of the two key components of air displacement:
Vd = Sd × XmaxA larger Sd allows a speaker to produce deep, powerful bass even at modest excursion levels.
b. Maximum SPL
Below 200 Hz, volume depends largely on how much air the driver can move. Bigger Sd = higher potential SPL.
c. Bass Extension
A driver with larger Sd can maintain strong output at lower frequencies compared to drivers with small Sd.
d. Efficiency
Large Sd improves low-frequency efficiency, an advantage in woofers, subwoofers, and pro audio drivers.
e. Distortion Behavior
A small Sd driver must move farther (large excursion), increasing distortion. A large Sd driver moves less for the same output, reducing distortion.
f. Directivity
As Sd increases, high-frequency dispersion narrows. This is why large woofers require lower crossover points.
5. Measuring Sd
To measure Sd:
- Measure the diaphragm including half the surround width.
- Calculate Din (effective diameter).
- Compute Sd using the circular area formula.
Professional tools such as DATS, CLIO, or ARTA can also derive Sd from impedance or acoustical modeling.
6. Real-World Examples
| Driver Model | Size | Din (mm) | Sd (cm²) | Notes |
|---|---|---|---|---|
| Full-range A | 3″ | 60 | 28 | Fast but limited bass |
| Woofer B | 6.5″ | 140 | 154 | Most common Hi-Fi woofer size |
| Woofer C | 8″ | 180 | 254 | Strong low-frequency performance |
| Subwoofer D | 12″ | 260 | 530 | Classic deep bass |
| Subwoofer E | 15″ | 340 | 907 | High displacement capability |
7. How Designers Use Sd
- Calculating air displacement (Vd)
- Designing subwoofers
- Estimating maximum SPL
- Predicting low-frequency roll-off
- Determining crossover frequencies
- Modeling port/vent airflow
- Selecting appropriate Xmax
- Optimizing multi-way driver matching
Conclusion
Effective Radiating Area (Sd) is one of the most critical Thiele–Small parameters because it determines how much air a loudspeaker can move. Together with Xmax, Bl, and Vas, Sd defines the bass strength, efficiency, and overall dynamic capability of a driver.
Understanding Sd helps designers and enthusiasts build speaker systems that deliver deep, powerful, and controlled low-frequency performance.
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