Editing Resistor (section)

==Electrical and thermal noise==
{{Main article|Noise (electronics)}}

In amplifying faint signals, it is often necessary to minimize [[electronic noise]], particularly in the first stage of amplification.  As a dissipative element, even an ideal resistor naturally produces a randomly fluctuating voltage, or noise, across its terminals.  This [[Johnson–Nyquist noise]] is a fundamental noise source which depends only upon the temperature and resistance of the resistor, and is predicted by the [[fluctuation–dissipation theorem]]. Using a larger value of resistance produces a larger voltage noise, whereas a smaller value of resistance generates more current noise, at a given temperature.

The thermal noise of a practical resistor may also be larger than the theoretical prediction and that increase is typically frequency-dependent. Excess noise of a practical resistor is observed only when current flows through it. This is specified in unit of μV/V/decade – μV of noise per volt applied across the resistor per decade of frequency.  The μV/V/decade value is frequently given in dB so that a resistor with a noise index of 0&nbsp;dB exhibits 1 μV (rms) of excess noise for each volt across the resistor in each frequency decade.  Excess noise is thus an example of [[Flicker noise|1/''f'' noise]].  Thick-film and carbon composition resistors generate more excess noise than other types at low frequencies. Wire-wound and thin-film resistors are often used for their better noise characteristics.  Carbon composition resistors can exhibit a noise index of 0&nbsp;dB while bulk metal foil resistors may have a noise index of −40&nbsp;dB, usually making the excess noise of metal foil resistors insignificant.<ref>{{cite book
| title = Audio Noise Reduction Through the Use of Bulk Metal Foil Resistors – "Hear the Difference"
| url = http://www.c-c-i.com/sites/default/files/vse-an00.pdf
| access-date = 2009-08-03
| archive-date = 2013-01-19
| archive-url = https://web.archive.org/web/20130119120843/http://www.c-c-i.com/sites/default/files/vse-an00.pdf
| url-status = dead
}}, Application note AN0003, Vishay Intertechnology Inc, 12 July 2005.</ref> Thin film surface mount resistors typically have lower noise and better thermal stability than thick film surface mount resistors. Excess noise is also size-dependent: in general, excess noise is reduced as the physical size of a resistor is increased (or multiple resistors are used in parallel), as the independently fluctuating resistances of smaller components tend to average out.

While not an example of "noise" per se, a resistor may act as a [[thermocouple]], producing a small DC voltage differential across it due to the [[thermoelectric effect]] if its ends are at different temperatures. This induced DC voltage can degrade the precision of [[instrumentation amplifier]]s in particular. Such voltages appear in the junctions of the resistor leads with the circuit board and with the resistor body. Common metal film resistors show such an effect at a magnitude of about 20 μV/°C. Some carbon composition resistors can exhibit thermoelectric offsets as high as 400 μV/°C, whereas specially constructed resistors can reduce this number to 0.05 μV/°C. In applications where the thermoelectric effect may become important, care has to be taken to mount the resistors horizontally to avoid temperature gradients and to mind the air flow over the board.<ref>{{cite book
| title      = Op Amp Applications Handbook
| author     = Jung, Walt
| url        = http://www.analog.com/library/analogDialogue/archives/39-05/op_amp_applications_handbook.html
| chapter    = Chapter 7 – Hardware and Housekeeping Techniques
| chapter-url = http://www.analog.com/library/analogDialogue/archives/39-05/Web_Ch7_final_J.pdf
| page       = 7.11
| isbn       = 0-7506-7844-5
| year = 2005
| publisher = Newnes
}}</ref>