Lecture 14: Electrical...
Transcript of Lecture 14: Electrical...
EECS 142
Lecture 14: Electrical Noise
Prof. Ali M. Niknejad
University of California, Berkeley
Copyright c© 2008 by Ali M. Niknejad
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 1/20
Introduction to Noise
vo(t)
t
All electronic amplifiers generate noise. This noise originatesfrom the random thermal motion of carriers and thediscreteness of charge.Noise signals are random and must be treated by statisticalmeans. Even though we cannot predict the actual noisewaveform, we can predict the statistics such as the mean(average) and variance.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 2/20
Noise PowerThe average value of the noise waveform is zero
vn(t) =< vn(t) >=1
T
∫T
vn(t)dt = 0
The mean is also zero if we freeze time and take an infinitenumber of samples from identical amplifiers.The variance, though, is non-zero. Equivalently, we may saythat the signal power is non-zero
vn(t)2 =1
T
∫T
v2
n(t)dt �= 0
The RMS (root-mean-square) voltage is given by
vn,rms =
√vn(t)2
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 3/20
Power Spectrum of Noise
S(ω)
ω
“white” noise is flat
The power spectrumof the noise shows theconcentration of noisepower at any givenfrequency. Many noisesources are “white” inthat the spectrum is flat(up to extremely highfrequencies)
In such cases the noise waveform is totally unpredictable as afunction of time. In other words, there is absolutely nocorrelation between the noise waveform at time t1 and somelater time t1 + δ, no matter how small we make δ.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 4/20
Formulation of the problem
• Shot noise in a p-n junction
• Thermal Noise in a p-n junction
• But
Statistical Derivation:
• Forward/Reverse Current Decomposition– Independent and so treated separately for noise
• Arrival of electron (hole) modeled with a Poisson process with arrival rate of λ.
• Variance (and the mean) of a Poisson process is proportional to its rate
• Using Carson’s Rules for this process we obtain:
λ
A Closer Look
• Shot noise at zero bias is same as Johnson noise (junction is at Thermal Eqilibrium)
• With applied bias, the forward or reverse components dominate and we end up with the shot-noise equation again
Noise of a resistor
• Thermal noise as a two-sided shot noise:
• Assume a shorted resistor with just random diffusive motion
• The concentration of carriers is set by electrons in conduction band rather than barrier height– Again we will have a Poisson process with the arrival
rate being a function of concentration, diffusion constant and length of travel.
– Noise Spectrum = 2q (Ir+If)
Decomposition of F/R Current in a resistor
• Diffusion Currents (Brownian Motion Current)
References:
Van der Ziel, A., "Theory of Shot Noise in Junction Diodes and Junction Transistors," Proceedings of the IRE, vol.43, no.11, pp.1639-1646, Nov. 1955
Van der Ziel, A., "Noise in solid-state devices and lasers," Proceedings of the IEEE , vol.58, no.8, pp. 1178-1206, Aug. 1970
Sarpeshkar, R.; Delbruck, T.; Mead, C.A., "White noise in MOS transistors and resistors," Circuits and Devices Magazine, IEEE , vol.9, no.6, pp.23-29, Nov 1993
Rolf Landaeur, “Solid-state shot noise”, Phys. Rev. , Issue 24 – June 1993.
Thermal Noise of a Resistor
R
v2n
G i2n
All resistors generate noise. The noise power generated by aresistor R can be represented by a series voltage source withmean square value v2
n
v2n = 4kTRB
Equivalently, we can represent this with a current source inshunt
i2n = 4kTGB
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 5/20
Resistor Noise Example
Here B is the bandwidth of observation and kT is Boltzmann’sconstant times the temperature of observationThis result comes from thermodynamic considerations, thusexplaining the appearance of kT
Often we speak of the “spot noise”, or the noise in a specificnarrowband δf
v2n = 4kTRδf
Since the noise is white, the shape of the noise spectrum isdetermined by the external elements (L’s and C ’s)
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 6/20
Resistor Noise Example
Suppose that R = 10kΩ and T = 20◦C = 293K.
4kT = 1.62× 10−20
v2n = 1.62× 10−16 ×B
vn,rms =
√vn(t)2 = 1.27× 10−8
√B
If we limit the bandwidth of observation to B = 106MHz, then wehave
vn,rms ≈ 13μV
This represents the limit for the smallest voltage we can resolveacross this resistor in this bandwidth
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 7/20
Combination of Resistors
If we put two resistors in series, then the mean square noisevoltage is given by
v2n = 4kT (R1 + R2)B = v2
n1+ v2
n2
The noise powers add, not the noise voltagesLikewise, for two resistors in parallel, we can add the meansquare currents
i2n = 4kT (G1 + G2)B = i2n1+ i2n2
This holds for any pair of independent noise sources (zerocorrelation)
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 8/20
Resistive Circuits
R1 R2
R3 RLVS
VT,s
RT
v2
Tn
RL
For an arbitrary resistive circuit, we can find the equivalentnoise by using a Thevenin (Norton) equivalent circuit or bytransforming all noise sources to the output by the appropriatepower gain (e.g. voltage squared or current squared)
VT,s = VS
R3
R1 + R3
v2
Tn = 4kTRT B = 4kT (R2 + R1||R3)B
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 9/20
Noise for Passive Circuits (I)
PassiveNoisyCircuit
PassiveNoiseless
CircuitZ(jω)
v2eq
For a general linear circuit, the mean square noise voltage(current) at any port is given by the equivalent input resistance(conductance)
v2eq = 4kT�(Z(f))δf
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 10/20
Noise for Passive Circuits (II)
This is the “spot” noise. If the network has a filtering property,then we integrate over the band of interest
v2
T,eq = 4kT
∫B
�(Z(f))df
Unlike resistors, L’s and C ’s do not generate noise. They doshape the noise due to their frequency dependence.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 11/20
Example: Noise of an RC Circuit
G C
To find the equivalent mean squarenoise voltage of an RC circuit, beginby calculating the impedance
Z =1
Y=
1
G + jωC=
G− jωC
G2 + ω2C2
Integrating the noise over all frequencies, we have
v2n =
4kT
2π
∫∞
0
G
G2 + ω2C2dω =
kT
C
Notice the result is independent of R. Since the noise and BWis proportional/inversely proportional to R, its influence cancelsout
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 12/20
Noise of a Receiving Antenna
v2n
Assume we construct an antenna with ideal conductors soRwire = 0
If we connect the antenna to a spectrum analyzer, though, wewill observe noiseThe noise is also “white” but the magnitude depends on wherewe point our antenna (sky versus ground)
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 13/20
Equivalent Antenna Temperature
v2a = 4kTARradB
Rrad
Va
v2a
Rrad
Va
TA
TA is the equivalent antenna temperature and Rrad is theradiation resistance of the antennaSince the antenna does not generate any of its own thermalnoise, the observed noise must be incident on the antenna. Infact, it’s “black body” radiation.Physically TA is related to the temperature of the externalbodies radiating into space (e.g. space or the ground)
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 14/20
Diode Shot Noise
A forward biased diode exhibits noise called shot noise. Thisnoise arises due to the quantized nature of charge.The noise mean square current is given by
i2d,n = 2qIDCB
The noise is white and proportional to the DC current IDC
Reversed biased diodes exhibit excess noise not related to shotnoise.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 15/20
Noise in a BJT
All physical resistors in a BJT produce noise (rb, re, rc). Theoutput resistance ro, though, is not a physical resistor. Likewise,rπ, is not a physical resistor. Thus these resistances do notgenerate noiseThe junctions of a BJT exhibit shot noise
i2b,n = 2qIBB
i2c,n = 2qICB
At low frequencies the transistor exhibits “Flicker Noise” or 1/f
Noise.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 16/20
BJT Hybrid-ΠModel
v2rb
v2re
v2rc
Cπrπ
Cμ
+vπ
−gmvπi2b i2c
rb
re
rc
ro
The above equivalent circuit includes noise sources. Note that asmall-signal equivalent circuit is appropriate because the noiseperturbation is very small
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 17/20
FET NoiseIn addition to the extrinsic physical resistances in a FET (rg, rs,rd), the channel resistance also contributes thermal noiseThe drain current noise of the FET is therefore given by
i2d,n = 4kTγgds0δf + KIaD
CoxL2
efffeδf
The first term is the thermal noise due to the channel resistanceand the second term is the “Flicker Noise”, also called the 1/f
noise, which dominates at low frequencies.
The factor γ = 2
3for a long channel device.
The constants K, a, and e are usually determined empirically.
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 18/20
FET Channel Resistance
Consider a FET with VDS = 0. Then the channel conductance isgiven by
gds,0 =∂IDS
∂VDS
= μCox
W
L(VGS − VT )
For a long-channel device, this is also equal to the devicetransconductance gm in saturation
gm =∂IDS
∂VGS
= μCox
W
L(VGS − VT )
For short-channel devices, this relation is not true, but we candefine
α =gm
gd0
�= 1
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 19/20
FET Noise Equivalent Circuit
Cgs gmvgs ro
Cgd
+vgs
−
Rg
Rs
Rd
i2d
v2
Rgv2
Rd
v2
Rs
The resistance of the substrate also generates thermal noise. Inmost circuits we will be concerned with the noise due to thechannel i2d and the input gate noise v2
Rg
A. M. Niknejad University of California, Berkeley EECS 142 Lecture 14 p. 20/20