String Tension Calculator 2026
Instantly calculate the tension in a vibrating string or musical instrument. Estimate wave speed, linear density, and safety margins with precision.
String Properties & Specs
Define your string’s length, frequency, and material parameters
The vibrating length of the string (e.g., guitar scale length)
The target fundamental frequency (e.g., A4 = 440 Hz)
Mass of the string divided by its length (kg/m)
The maximum tension the string can withstand before snapping
Reduces breaking strength to determine max safe working tension
Tension & Wave Estimates
Force, wave speed, and safety margins
Enter your string’s dimensions and material properties above, then click Estimate String Tension to reveal the physics breakdown.
Common String Tensions & Playability
Typical tension ranges for various musical strings and their corresponding feel. Always check your instrument’s structural limits before changing string gauges.
| String Type | Typical Tension (N) | Playability | Common Use |
|---|---|---|---|
| Nylon Classical | 40 – 50 | Soft, Low tension | Fingerstyle, Classical |
| Phosphor Bronze | 70 – 90 | Medium, Crisp | Acoustic Strumming |
| Nickel Wound (Electric) | 50 – 70 | Light, Fast | Lead Guitar, Bending |
| Steel Bass | 90 – 120 | High, Stiff | Bass Grooves, Slap |
| Piano Wire | 150 – 300+ | Extreme, Rigid | Piano, Industrial |
String Physics FAQ
Learn more about the physics of vibrating strings, how tension affects musical instruments, and how to calculate wave speed.
The tension (T) in a vibrating string can be calculated using the formula T = μ × (2Lf)², where μ is the linear mass density (kg/m), L is the scale length of the string (m), and f is the fundamental frequency (Hz). This derives from the wave speed equation v = √(T/μ) and the relationship v = 2Lf.
Linear mass density (μ) is the mass of the string per unit of length, typically measured in kilograms per meter (kg/m). To find it, weigh a known length of the string in kilograms and divide that mass by the length in meters. For example, if a 1-meter string weighs 2 grams (0.002 kg), its linear density is 0.002 kg/m.
Higher string tension generally produces a brighter, more focused tone with increased volume and sustain, but requires more finger pressure to fret. Lower tension yields a warmer, softer sound with easier playability, but may be more prone to buzzing and has less projection.
Wave speed (v) is the speed at which a transverse wave travels along the string. It is calculated using the formula v = √(T/μ), where T is tension in Newtons and μ is linear mass density. Alternatively, for the fundamental frequency, it can be found using v = 2Lf, where L is length and f is frequency.
The safety factor (or safety margin) ensures the working tension remains well below the string’s breaking strength. It is calculated as: Working Tension = Breaking Strength × (1 – Safety Margin %). For example, if a string breaks at 100N and you want a 20% safety margin, the maximum safe working tension is 80N.
