Difference between revisions of "Diode and Transistor Noise"

In active devices, aside from the thermal noise due to resistive elements, we have two additional sources of electronic noise: (1) shot noise in PN junctions, and (2) flicker noise in MOSFETs.

Diode Noise

Shot noise is the random movement of quantized charges flowing through a forward-biased PN junction. The shot noise power in a diode, shown in Fig. 1, is given by:

${\displaystyle {\overline {i_{n}^{2}}}=2qI_{D}B}$

(1)

Where ${\displaystyle q=1.602\times 10^{-19}\,\mathrm {C} }$, ${\displaystyle I_{D}}$ is the DC current flowing through the diode, and ${\displaystyle B}$ is the observation bandwidth. Shot noise has a white power spectral density similar to thermal noise, however, it is independent of temperature and instead, is proportional to the DC diode current. Since noise, in general, can be considered a "small signal", we normally include the noise generators in the diode small signal model.

BJT Noise

In a bipolar junction transistor (BJT), both PN junctions produce shot noise, which we model as:

${\displaystyle {\overline {i_{b}^{2}}}=2qI_{B}B}$

(2)

${\displaystyle {\overline {i_{c}^{2}}}=2qI_{C}B}$

(3)

Fig. 2 shows the small signal model of the BJT, showing the shot noise generators, ${\displaystyle {\overline {i_{b}^{2}}}}$ and ${\displaystyle {\overline {i_{c}^{2}}}}$, and the thermal noise generators for the physical terminal resistances, ${\displaystyle r_{b}}$, ${\displaystyle r_{e}}$, and ${\displaystyle r_{c}}$. Note that the small signal resistances ${\displaystyle r_{\pi }}$ and ${\displaystyle r_{o}}$ are not physical resistors. These small signal resistors are used to model mechanisms such as recombination and base-width modulation, and thus, do not generate noise.

MOSFET Noise

The MOSFET has two noise mechanisms present: (1) thermal noise due to the channel and terminal resistances, and (2) flicker noise due to vacant energy levels or surface states or traps in the interface between the channel and the gate oxide layer. These surface states trap charges for a short period of time, and is then released, producing random changes in the current. Since the probability of charges getting trapped in these surface states is (approximately) inversely proportional to frequency, flicker noise is also known as ${\displaystyle {\tfrac {1}{f}}}$ noise.

We can then express the drain current noise of a MOSFET as the sum of the thermal noise and flicker noise components respectively:

${\displaystyle {\overline {i_{d}^{2}}}=4kT\gamma g_{ds0}\delta f+K_{f}{\frac {I_{D}^{a}}{C_{\mathrm {ox} }L_{\mathrm {eff} }^{2}f^{e}}}\delta f}$

(4)

Note that ${\displaystyle \gamma }$ is known as the excess noise coefficient, and is equal to ${\displaystyle {\tfrac {2}{3}}}$ for long channel devices, and ${\displaystyle g_{ds0}}$ is the drain-source conductance in the triode region. The constants ${\displaystyle K_{f}}$, ${\displaystyle a}$, and ${\displaystyle e}$ are process dependent, and are usually determined empirically.