Difference between revisions of "Diode and Transistor Noise"

Revision as of 09:18, 5 October 2020

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:

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

(1)

Where $q=1.602\times 10^{-19}\,\mathrm {C}$ , $I_{D}$ is the DC current flowing through the diode, and $B$ 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:

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

(2)

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

(3)

Fig. 2 shows the small signal model of the BJT, showing the shot noise generators, ${\overline {i_{b}^{2}}}$ and ${\overline {i_{c}^{2}}}$ , and the thermal noise generators for the physical bulk and terminal resistances, $r_{b}$ , $r_{e}$ , and $r_{c}$ . Note that the small signal resistances $r_{\pi }$ and $r_{o}$ 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.

@@ Line 1: / Line 1: @@
 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.
-== Shot Noise ==
+== 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:
@@ Line 8: / Line 8: @@
 Where <math>q = 1.602\times 10^{-19}\,\mathrm{C}</math>, <math>I_D</math> is the DC current flowing through the diode, and <math>B</math> 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:
-{{NumBlk|::|<math>\overline{i^2_{bn}} = 2qI_B B</math>|{{EquationRef|2}}}}
+{{NumBlk|::|<math>\overline{i^2_b} = 2qI_B B</math>|{{EquationRef|2}}}}
-{{NumBlk|::|<math>\overline{i^2_{cn}} = 2qI_C B</math>|{{EquationRef|3}}}}
+{{NumBlk|::|<math>\overline{i^2_c} = 2qI_C B</math>|{{EquationRef|3}}}}
+Fig. 2 shows the small signal model of the BJT, showing the shot noise generators, <math>\overline{i^2_b}</math> and <math>\overline{i^2_c}</math>, and the thermal noise generators for the ''physical'' bulk and terminal resistances, <math>r_b</math>, <math>r_e</math>, and <math>r_c</math>. Note that the small signal resistances <math>r_\pi</math> and <math>r_o</math> 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 ==

Difference between revisions of "Diode and Transistor Noise"

Revision as of 09:18, 5 October 2020

Diode Noise

BJT Noise

MOSFET Noise

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