M1 is diode connected (VG = VD)
$$ r_{ds} = \frac{1}{g_{ds}} $$
$$ r_{in} = \frac{v}{i} $$
i = gmv + gdsv
$$ r_{in} = \frac{1}{gm + gds} \approx \frac{1}{gm} $$
| ## Current mirror rout |
| Output voltage does not affect vgs |
| rout = rds |
 |
What is the operating region of M3 and M4?
What is the operating region of M1 and M2?
vgs1 = 0
vgs2 = − vs
i = gds1vs ⇒ vs = irds1
$$r_{out} = \frac{v}{i}$$
$$i = -g_{m2} v_{s} + \frac{v - v_s}{r_{ds2}}$$
$$i = -g_{m2} v_{s} + \frac{v - v_s}{r_{ds2}}$$ insert vs = irds1
$$i = -i g_{m2} r_{ds1} + \frac{v - i r_{ds1}}{r_{ds2}}$$
irds2 + igm2rds1rds2 + irds1 = v
$$ r_{ds2} + g_{m2}r_{ds1}r_{ds2} + r_{ds1} = \frac{v}{i} $$
$$ r_{out} = r_{ds2} \left[1 + r_{ds1} \left( \frac{1}{r_{ds2}} + g_{m2}\right )\right] $$
rout = rds2[1+rds1(gm2+gds2)]
rout = rds2[1+rds1(gm2+gds1)]
Same equation as source degeneration, but M2 is in saturation
rds2(saturation) > rds2(linear)
rout = rds4[1+rds2(gm4+gds2)]
| ## Source follower |
| Input resistance ≈ ∞ |
| Gain $$ A = \frac{v_o}{v_i}$$? |
| Output resistance rout? |
 |
io = vo(gds+gs) − gmvi + vogm
io = 0
gmvi = vo(gm+gs+gds)
$$ A = \frac{v_o}{v_i} = \frac{g_m}{g_m + g_{ds} + g_s} $$
io = vo(gds+gs) − gmvi + vogm
vi = 0
io = vo(gds+gs+gm)
$$ r_{out} = \frac{v_o}{i_o} = \frac{1}{g_m + g_{ds} + g_{s}} $$
$$ r_{out} \approx \frac{1}{g_m}$$
Assume 100 electrons
ΔV = Q/C = − 1.6 × 10−19 × 100/(1×10−15) = − 16 mV
ΔV = Q/C = − 1.6 × 10−19 × 100/(1×10−12) = − 16 uV
Input resistance ?
Gain ?
Output resistance ?
i = gmv + gdsv
$$ r_{in} = \frac{1}{g_m + g_{ds}} \approx \frac{1}{g_m}$$
However, we’ve ignored load resistance.
$$ r_{in} \approx \frac{1}{g_m}\left(1 + \frac{R_L}{r_{ds}}\right) $$
rout = rds
$$ i_{o} = - g_m v_{i} + \frac{v_{o} - v_{i}}{r_{ds}} $$
io = 0
0 = − gmvirds + vo − vi
vi(1+gmrds) = vo
$$ \frac{v_o}{v_i} = 1 + g_m r_{ds} $$
We’ve ignored bulk effect (gs), source resistance (RS) and load resistance (RL)
$$ A = \frac{(g_{m} + g_s + g_{ds})(R_L||r_{ds})}{1 + R_S\left(\frac{g_m + g_s + g_{ds}}{1 + R_L/r_{ds}}\right)}$$
If RL > > rds, RS = 0 and gs = 0
$$ A = \frac{(g_{m} + g_{ds})r_{ds}}{1} = 1+ g_m r_{ds} $$
Input resistance rin ≈ ∞
Output resistance rout = rds, it’s same circuit as the output of a current mirror
Gain ?
| ## Common source - Gain |
| $$ i_{o} = g_m v_i + \frac{v_o}{r_{ds}} $$ |
| io = 0 |
| $$ -g_m v_i = \frac{v_o}{r_{ds}} $$ |
| $$ \frac{v_o}{v_i} = - g_m r_{ds}$$ |
|
| ## Differential pair |
| Input resistance rin ≈ ∞ |
| Gain A = gmrds |
| Output resistance rout = rds |
| Best analyzed with T model of transistor (see CJM page 31) |
 |
Can choose between
vo = gmrdsvi
and
vo = − gmrdsvi
by flipping input (or output) connections
