Sensitivity (electronics)

The sensitivity of an electronic device, such as a communications system receiver, or detection device, such as a PIN diode, is the minimum magnitude of input signal required to produce a specified output signal having a specified signal-to-noise ratio, or other specified criteria. In general, it is the signal level required for a particular quality of received information.^[1]

In signal processing, sensitivity also relates to bandwidth and noise floor.

It is important to note that in the field of electronics different definitions are used for sensitivity. The IEEE dictionary^[2][3] states: "Definitions of sensitivity fall into two contrasting categories." It also provides multiple definitions relevant to sensors among which 1: "(measuring devices) The ratio of the magnitude of its response to the magnitude of the quantity measured.” and 2: "(radio receiver or similar device) Taken as the minimum input signal required to produce a specified output signal having a specified signal-to-noise ratio.”. The first of these definitions is similar to the definition of responsivity and as a consequence sensitivity is sometimes considered to be improperly used as a synonym for responsivity^[4][5], and it is argued that the second definition, which is closely related to the detection limit, is a better indicator of the performance of a measuring system^[6].

The sensitivity of a microphone is usually expressed as the sound field strength in decibels (dB) relative to 1 V/Pa (Pa = N/m²) or as the transfer factor in millivolts per pascal (mV/Pa) into an open circuit or into a 1 kiloohm load.^{[citation needed]}

The sensitivity of a loudspeaker is usually expressed as dB / 2.83 V_RMS at 1 metre.^{[citation needed]} This is not the same as the electrical efficiency; see Efficiency vs sensitivity. The sensitivity of a hydrophone is usually expressed as dB relative to 1 V/μPa.^[7]

This is an example where sensitivity is defined as the ratio of the sensor's response to the quantity measured. One should realize that when using this definition to compare sensors, the sensitivity of the sensor might depend on components like output voltage amplifiers, that can increase the sensor response such that the sensitivity is not a pure figure of merit of the sensor alone, but of the combination of all components in the signal path from input to response.

Sensitivity in a receiver, such a radio receiver, indicates its capability to extract information from a weak signal, quantified as the lowest signal level that can be useful.^[8] It is mathematically defined as the minimum input signal ${\displaystyle S_{i}}$ required to produce a specified signal-to-noise S/N ratio at the output port of the receiver and is defined as the mean noise power at the input port of the receiver times the minimum required signal-to-noise ratio at the output of the receiver:

${\displaystyle S_{i}=k(T_{a}+T_{rx})B\;\cdot \;{\frac {S_{o}}{N_{o}}}}$

where

${\displaystyle S_{i}}$ = sensitivity [W]

${\displaystyle k}$ = Boltzmann constant

${\displaystyle T_{a}}$ = equivalent noise temperature in [K] of the source (e.g. antenna) at the input of the receiver

${\displaystyle T_{rx}}$ = equivalent noise temperature in [K] of the receiver referred to the input of the receiver

${\displaystyle B}$ = bandwidth [Hz]

${\displaystyle {\frac {S_{o}}{N_{o}}}}$ = Required SNR at output [-]

The same formula can also be expressed in terms of noise factor of the receiver as

${\displaystyle S_{i}=N_{i}\;\cdot \;F\;\cdot \;SNR_{o}=kT_{a}B\;\cdot \;F\;\cdot \;SNR_{o}}$

where

${\displaystyle F}$ = noise factor

${\displaystyle N_{i}}$ = input noise power

${\displaystyle SNR_{o}}$ = required SNR at output.

Because receiver sensitivity indicates how faint an input signal can be to be successfully received by the receiver, the lower power level, the better. Lower power for a given S/N ratio means better sensitivity since the receiver's contribution is smaller. When the power is expressed in dBm the larger the absolute value of the negative number, the better the receive sensitivity. For example, a receiver sensitivity of −98 dBm is better than a receive sensitivity of −95 dBm by 3 dB, or a factor of two. In other words, at a specified data rate, a receiver with a −98 dBm sensitivity can hear signals that are half the power of those heard by a receiver with a −95 dBm receiver sensitivity.^{[citation needed]}.

For electronic sensors the input signal ${\textstyle S_{i}}$ can be of many types, like position, force, acceleration, pressure, or magnetic field. The output signal for an electronic analog sensor is usually a voltage or a current signal ${\textstyle S_{o}}$. The responsivity of an ideal linear sensor in the absence of noise is defined as ${\textstyle R=S_{o}/S_{i}}$, whereas for nonlinear sensors it is defined as the local slope ${\displaystyle \mathrm {d} S_{o}/\mathrm {d} S_{i}}$. In the absence of noise and signals at the input, the sensor is assumed to generate a constant intrinsic output noise ${\textstyle N_{oi}}$. To reach a specified signal to noise ratio at the output ${\displaystyle SNR_{o}=S_{o}/N_{oi}}$, one combines these equations and obtains the following idealized equation for its sensitivity^[5] ${\displaystyle S}$, which is equal to the value of the input signal ${\textstyle S_{i,SNR_{o}}}$ that results in the specified signal-to-noise ratio ${\displaystyle SNR_{o}}$ at the output:

${\displaystyle S=S_{i,SNR_{o}}={\frac {N_{oi}}{R}}SNR_{o}}$

This equation shows that sensor sensitivity can be decreased (=improved) by either reducing the intrinsic noise of the sensor ${\textstyle N_{oi}}$ or by increasing its responsivity ${\textstyle R}$. This is an example of a case where sensivity is defined as the minimum input signal required to produce a specified output signal having a specified signal-to-noise ratio^[2]. This definition has the advantage that the sensitivity is closely related to the detection limit of a sensor if the minimum detectable SNR is specified (Signal-to-noise ratio). The choice for the minimum SNR used in the definition of sensitivity depends on the required confidence level for a signal to be reliably detected (confidence (statistics)), and lies typically between 1-10. The sensitivity depends on parameters like bandwidth and integration time because noise level can be reduced by signal averaging, which increases SNR at constant signal level. A measure of sensitivity independent of bandwidth can be provided by using the spectral density of the input, output and noise signals in the definition, using units like m/Hz^1/2, N/Hz^1/2, W/Hz or V/Hz^1/2.

In some instruments, like spectrum analyzers, a SNR of 1 at a specified bandwidth of 1 Hz is assumed by default when defining their sensitivity^[2]. For instruments that measure power, which also includes photodetectors, this results in the sensitivity becoming equal to the noise-equivalent power and for other instruments it becomes equal to the noise-equivalent-input^[9] ${\displaystyle NEI=N_{oi}/R}$. It is important to note that a lower value of the sensitivity corresponds to better performance (smaller signals can be detected), which seems contrary to the common use of the word sensitivity^[6][10]. It has therefore been argued that it is preferable to use detectivity, which is the reciprocal of the noise-equivalent input, as a metric for the performance of detectors^[9][11] ${\displaystyle D=R/N_{oi}}$.

As an example, assume a piezoresistive force sensor through which a constant current runs, such that it has a responsivity ${\displaystyle R=1.0~\mathrm {V} /\mathrm {N} }$. The Johnson noise of the resistor generates a noise spectral density of ${\displaystyle N_{oi}=10~\mathrm {nV} /{\sqrt {\mathrm {Hz} }}}$. For a specified SNR of 1, this results in a sensitivity and noise-equivalent input of ${\displaystyle S_{i}=NEI=10~\mathrm {nN} /{\sqrt {\mathrm {Hz} }}}$ and a detectivity of ${\displaystyle (10~\mathrm {nN} /{\sqrt {\mathrm {Hz} }})^{-1}}$, such that an input signal of 10 nN generates the same output voltage as the noise does over a bandwidth of 1 Hz.

 This article incorporates public domain material from Federal Standard 1037C. General Services Administration. Archived from the original on 2022-01-22. (in support of MIL-STD-188).

• Microphone sensitivity conversion from dB at 1 V/Pa to transfer factor in mV/Pa