The responsivity of a photodetector is usually expressed in units of either amperes or volts per watt of incident radiant power. For a system that responds linearly to its input, there is a unique responsivity. For nonlinear systems, the responsivity is the local slope (derivative). Many common photodetectors respond linearly as a function of the incident power.
Responsivity is a function of the wavelength of the incident radiation and of the sensor properties, such as the bandgap of the material of which the photodetector is made. One simple expression for the responsivity R of a photodetector in which an optical signal is converted into an electrical current (known as a photocurrent) is
where is the quantum efficiency (the conversion efficiency of photons to electrons) of the detector for a given wavelength, is the electron charge, is the frequency of the optical signal, and is Planck's constant. This expression is also given in terms of, the wavelength of the optical signal, and has units of amperes per watt (A/W).
The term responsivity is also used to summarize input–output relationship in non-electrical systems. For example, a neuroscientist may measure how neurons in the visual pathway respond to light. In this case, responsivity summarizes the change in the neural response per unit signal strength. The responsivity in these applications can have a variety of units. The signal strength typically is controlled by varying either intensity (intensity-response function) or contrast (contrast-response function). The neural response measure depends on the part of the nervous system under study. For example, at the level of the retinal cones, the response might be in photocurrent. In the central nervous system the response is usually spikes per second. In functional neuroimaging, the response measure is usually BOLD contrast. The responsivity units reflect the relevant stimulus and physiological units.
When describing an amplifier, the more common term is gain.
Deprecated synonym sensitivity. A system's sensitivity is the inverse of the stimulus level required to produce a threshold response, with the threshold typically chosen just above the noise level.
Other articles related to "responsivity":
... sensitivity, to supplement their characteristic curves that describe their responsivity ... In sensor systems, where the output is easily quantified, the responsivity can be extended to be wavelength dependent, incorporating the spectral sensitivity ... When the sensor system is linear, its spectral sensitivity and spectral responsivity can both be decomposed with similar basis functions ...
... Spectral responsivity is a similar measurement, but it has different units amperes per watt (A/W) (i.e ... Both the quantum efficiency and the responsivity are functions of the photons' wavelength (indicated by the subscript λ) ... To convert from responsivity (Rλ, in A/W) to QEλ (on a scale 0 to 1) where λ is in nm, h is the Planck constant, c is the speed of light in a vacuum, and e is the ...