Understanding the Frequency Response of Contact Mics
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Contact microphones, or contact mics, are unique in how they capture sound—not through air, but through the vibrations of solid objects. This makes them invaluable for experimental musicians, sound designers, and even scientific researchers who want to capture sounds in ways traditional microphones can’t. To use them effectively, it’s crucial to understand their frequency response and how it shapes the sounds they record.
What Is Frequency Response?
Frequency response refers to how well a microphone reproduces different frequencies of sound. It’s typically displayed as a curve on a graph, showing which frequencies are amplified or reduced. A flat frequency response means the mic captures all frequencies evenly, while a shaped response emphasizes certain frequency ranges.
In contact mics, the frequency response tends to be far from flat. Because they pick up mechanical vibrations rather than airborne sound waves, their response is shaped by both the material they’re attached to and the design of the piezo element inside.
How Contact Mics Capture Vibrations
A contact mic works by converting vibrations into electrical signals using a piezoelectric crystal. When the surface it’s attached to vibrates, the crystal flexes and produces a voltage that mirrors those vibrations. Unlike air mics, contact mics are more sensitive to mid and low frequencies transmitted through dense materials.
For instance, when attached to a guitar body, a contact mic might emphasize lower frequencies that resonate through the wood. On a metallic surface, it may capture a bright, percussive tone rich in upper harmonics.
Factors That Affect Frequency Response in Contact Mics
- Mounting Surface – The type of material the mic is attached to has the greatest influence. Wood tends to produce warmer, bass-rich tones, while metal and glass create sharper, more resonant sounds.
- Piezo Element Size – Larger piezo elements often capture more low-frequency information, while smaller ones can highlight high-frequency details.
- Adhesion Method – Using tape, glue, or a clip can each change the frequency response slightly by altering how vibrations transfer to the element.
- Preamp and Impedance – Contact mics require a high-impedance input to maintain accurate frequency response. Without proper impedance matching, low-end response can be lost.
Typical Frequency Range of Contact Mics
Most contact mics respond best in the 100 Hz to 10 kHz range, though the exact curve varies widely. They may roll off below 100 Hz, making them less ideal for sub-bass frequencies, and sometimes accentuate frequencies around 2–6 kHz, resulting in a crisp, tactile sound.
For critical recording, pairing the mic with a high-quality preamp designed for piezo sources helps preserve detail and balance across the spectrum.
Applications That Benefit from Frequency Awareness
- Musical Performance – Musicians use contact mics on acoustic instruments, metal plates, and even water containers to produce textured tones.
- Field Recording – Sound artists capture the inner workings of machines, engines, and natural objects like ice or trees.
- Scientific Measurement – Engineers and researchers use them to detect vibrations in machinery or structures.
Understanding the frequency response helps tailor mic placement and equalization. For example, if a mic emphasizes mids too heavily, you can EQ down the 2–4 kHz range to achieve a more natural tone.
How to Test a Contact Mic’s Frequency Response
You can test the mic’s response by recording controlled tones or impulses on different materials, then analyzing the resulting waveform or spectrum using audio software. This experiment reveals which frequencies are most pronounced and how they vary with mounting surfaces.
Choosing the Right Contact Mic for Your Needs
When selecting a contact mic, look for these qualities:
- A wide and balanced frequency response for versatility
- Durable construction and flexible cable
- Compatibility with high-impedance preamps
- Low self-noise for clean signal capture
Different brands tune their piezo elements differently, so it’s worth experimenting. Some mics are voiced for instruments, while others are designed for industrial or experimental use.
Final Thoughts
The frequency response of a contact mic defines how it interprets the world of vibration. By understanding how materials, mounting methods, and impedance shape their sound, you can better control and creatively use the unique sonic qualities that contact mics provide.
