All resistive elements generate random voltage fluctuations due to the thermal agitation of charge carriers. This effect was first described by John B. Johnson and later analyzed by Harry Nyquist, leading to the term Johnson–Nyquist noise. The phenomenon is present in every conductor and sets a fundamental limit on how quiet an electronic circuit can be. Because it stems from thermodynamics, this noise exists even in perfectly stable circuits with no external interference. Understanding its magnitude helps engineers design low-noise amplifiers, radio receivers, and high-precision measurements.
The RMS voltage of thermal noise across a resistor is expressed by , where is Boltzmann’s constant (1.380649×10⁻²³ J/K), is the absolute temperature in kelvins, is the resistance in ohms, and is the measurement bandwidth in hertz. This relationship shows that noise increases with temperature, resistance, and the range of frequencies included in the measurement. No matter how advanced the electronics, thermal noise provides an irreducible background that must be taken into account.
The bandwidth in the formula represents the range of frequencies over which you measure or amplify the noise. A wider bandwidth lets in more noise power. For example, a radio receiver tuned to a narrow channel only collects noise from that small slice of the spectrum, reducing the total noise voltage. In contrast, wideband instrumentation amplifiers must contend with more noise, often requiring specialized filtering or cooling to suppress it. Careful selection of bandwidth is therefore a key strategy in minimizing the impact of thermal noise.
Suppose you have a 50 Ω resistor at room temperature (about 300 K) and you measure over a 10 kHz bandwidth. Plugging these values into the formula gives , which comes to roughly 0.9 μV RMS. Although tiny, this voltage can still swamp the signal in precision circuits or sensors unless proper amplification and filtering are used.
Instead of voltage, you may be interested in the noise power delivered to a matched load. By the same principles, the available noise power is watts. This expression is independent of resistance when the source and load impedance are equal. Designers of communication systems often use this form to estimate the theoretical noise floor in a receiver.
Achieving extremely low noise figures is essential for radio astronomy, medical imaging, and many scientific instruments. Engineers carefully select resistors with minimal excess noise, cool detectors to cryogenic temperatures, and use narrowband filtering. Despite these efforts, thermal noise remains a hard limit determined by fundamental constants. This calculator helps quantify that limit so you know how close your design approaches the theoretical minimum.
Lowering the temperature decreases thermal agitation. Superconducting circuits operated near absolute zero exhibit virtually no Johnson–Nyquist noise, though such extreme conditions are impractical for most applications. Similarly, reducing the resistance or narrowing the bandwidth reduces the noise, but only at the cost of signal level or system flexibility. The trade-offs between these parameters are central to many electronic design decisions.
Thermal noise cannot be eliminated, but it can be calculated and accounted for. By providing the resistor value, temperature, and bandwidth in this form, you can immediately evaluate how much RMS noise voltage is present. Whether you’re an amateur radio builder, a student learning about noise sources, or an engineer designing cutting-edge instrumentation, knowing the Johnson–Nyquist noise level is essential for understanding how quiet your circuit can be.
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