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G
George Herold
It's been with great enjoyment, that I've been reading this thread.
(Thanks all.) But I lack a complete understanding at times.
I think I've used bootstrapping only twice.
Both driving down capacitance.
In A photodiode and a driven shield in a short cable.
So my simple minded definition of bootstrapping is,
using positive feedback in just the right amount.
(Too much and you get excessive gain.)
Is that correct? Can you add more?
Thanks again, (It's great having a somewhat civil SED.)
George H.
Bootstrapping to me means using a circuit's output to power or drive
one of its earlier stages. That is, to pull yourself up by your
bootstraps.
Here, by using the output to drive the 'high side' of R2, the voltage
seen across R2 is kept roughly the same. That, in turn, keeps i(R2)
fairly constant.
The total effect is that Q1's collector sees a current that doesn't
change much with a.c. changes in Vc(Q1). From Q1's perspective, R2 is
effectively greatly increased, which increases the stage gain
enormously.
I get g ~=23 @ 40KHz without C1, and g ~=230 with C1=22nF, a ten-fold
improvement.
Also, R2's supply can exceed Vcc, such that Q2's emitter can swing
within millivolts of the positive rail.
The real interest for me was the technique of making a resistor into a
pseudo constant-current source, simply. John did it already way back
with his ramp circuit; this was just another example.
J
josephkk
I didn't see any collector bootstraps either. I do see emitter bootstrap.
?-)
G
George Herold
OK, Thanks James. I was rereading AoE on bootstrapping... similar
type 'tricks'.
George H.
I pondered that schematic for some time before realizing what it was.
It's some amateur's attempt at making a band-pass filter
(quasi-gyrator), but it has horrible input impedance...
Looking like 10nF in series with 16K at low frequencies,
4.4nF in series with 1.725K at 10KHz,
and -223nF at 194KHz ;-)
The shunt feedback directly to the base, driven thru the 10nF
capacitor was the clue.
...Jim Thompson
--
| James E.Thompson, CTO | mens |
| Analog Innovations, Inc. | et |
| Analog/Mixed-Signal ASIC's and Discrete Systems | manus |
| Phoenix, Arizona 85048 Skype: Contacts Only | |
| Voice480)460-2350 Fax: Available upon request | Brass Rat |
| E-mail Icon at http://www.analog-innovations.com | 1962 |
I love to cook with wine. Sometimes I even put it in the food.
Yep- the input is garbage.
And thanks for not belittling us with your insightful analysis of the biasing circuit...where is that belittling insight anyway?
Okay, great, you have taken a fundamental misunderstanding of the original circuit operation to new heights
T
Tim Williams
Okay, great, you have taken a fundamental misunderstanding of the
original circuit operation to new heights
How so?
It's no worse than a shunt current source[1],
http://webpages.charter.net/dawill/tmoranwms/Circuits_2010/Shunt_Current_Source.png
and in fact, better than the original: no additional collector current is
required, thanks to the complement.
[1] "This revolutionary (and impressively useless) circuit is the
completion of an analogy. Consider: voltage sources are available in two
flavors, shunt (e.g., TL431) and series-pass (e.g., LM7805). But current
sources are only available in one style, series-pass. These simple
circuits complete the analogy, providing a shunt current source. In both
cases, a resistor provides a current greater than or equal to the desired
output current over the rated range; a current sense resistor, voltage
reference and voltage amplifier (VBE and a BJT in the left example; a
TL431 and differential pair in the right example) adjust a shunt current
to keep the output current constant."
Incidentally, this was drawn in 2010, so, if it were worth copyrighting,
and doesn't appear earlier elsewhere, I won.
Tim
F
Fred Bartoli
Tim Williams a écrit :
Nah, I win. I wrote about that CS back in 2005 in a thread current
source opportunely named... 'Low current source'
And it's not as useless as you might think. That one transistor CS is
very simple good trick, albeit not very accurate...
Okay, great, you have taken a fundamental misunderstanding of the
original circuit operation to new heights
How so?
It's no worse than a shunt current source[1],
http://webpages.charter.net/dawill/tmoranwms/Circuits_2010/Shunt_Current_Source.png
and in fact, better than the original: no additional collector current is
required, thanks to the complement.
[1] "This revolutionary (and impressively useless) circuit is the
completion of an analogy. Consider: voltage sources are available in two
flavors, shunt (e.g., TL431) and series-pass (e.g., LM7805). But current
sources are only available in one style, series-pass. These simple
circuits complete the analogy, providing a shunt current source. In both
cases, a resistor provides a current greater than or equal to the desired
output current over the rated range; a current sense resistor, voltage
reference and voltage amplifier (VBE and a BJT in the left example; a
TL431 and differential pair in the right example) adjust a shunt current
to keep the output current constant."
Incidentally, this was drawn in 2010, so, if it were worth copyrighting,
and doesn't appear earlier elsewhere, I won.
Nah, I win. I wrote about that CS back in 2005 in a thread current
source opportunely named... 'Low current source'
And it's not as useless as you might think. That one transistor CS is
very simple good trick, albeit not very accurate...
I already told you how the circuit works, and in the simplest possible terms. Your comprehension is not my problem. And you keep referring to it as James's circuit when he stated he found it on the web.
J
josephkk
No Bout Adout it, this is an interesting circuit. Of course the much
higher voltage gain will aggravate the Miller capacitance issue hugely and
may also aggravate Early voltage issues as well.
It is an engineering tradeoff.
?-)
G
George Herold
Hi Jim, I'm pretty much a newb, when it comes to transistor level
design.
But the original circuit looks very similar to Figure 2.66 in AoE (2nd
ed.)
"Bootstrapping driver-stage collector load resistor in power amp."
So is it the bootstrapping you don't like or the DC biasing scheme?
(Maybe I can try to simulate it at home tonight.)
A hint might help me find the issue when simming it.
George H.
(Does simming have two m's or one? :^)
F
Fred Bartoli
George Herold a écrit :
It misses the 'w'
It misses the 'w'
Man, somebody sure mangled that. Here's the original post again:
+3.3V
---
|
.-------+-------.
| |
5K R1 C1 |/ Q2
| 100n .------| 2n5089
+---||-|--. |>.
| | | |
15k R2 | '-----+------>
| | |
C2 +------' R3 820R
10n |/ Q1 |
| | | R4 470R
| === | |
| | ===
'-----R5------'
220k
No, that's not the purpose. The purpose of the bootstrap is to
increase voltage gain. The input impedance doesn't matter--the input
source is a low-impedance highly capacitive transducer. This is not a
general-purpose generic IC that needs to do everything.
The IC designer has luxuries the discrete designer doesn't. Jim's got
a sweet little part there, but that circuit has 13 (matched)
transistors, 3 caps and 10 resistors--not a fair comparison to a
littl' ol' two-transistor circuit.
Bootstrapping here increases the voltage gain and output swing--it's
cute. All two-transistor gain-of-220 amplifiers have their
limitations, naturally.
+3.3V
---
|
.-------+-------.
| |
5K R1 C1 |/ Q2
| 100n .------| 2n5089
+---||-|--. |>.
| | | |
15k R2 | '-----+------>
| | |
C2 +------' R3 820R
10n |/ Q1 |
| |>. | |
| | | R4 470R
| === | |
| | ===
'-----R5------'
220k
No, that's not the purpose. The purpose of the bootstrap is to
increase voltage gain. The input impedance doesn't matter--the input
source is a low-impedance highly capacitive transducer. This is not a
general-purpose generic IC that needs to do everything.
The IC designer has luxuries the discrete designer doesn't. Jim's got
a sweet little part there, but that circuit has 13 (matched)
transistors, 3 caps and 10 resistors--not a fair comparison to a
littl' ol' two-transistor circuit.
Bootstrapping here increases the voltage gain and output swing--it's
cute. All two-transistor gain-of-220 amplifiers have their
limitations, naturally.
True. My purpose was to explore the bootstrap, not an optimum
amplifier.
LTSpice says g=220 @ 40kHz.
Aww, if only discrete transistors were matched and free...
I plunked a PNP (in CCS configuration) in instead of the bootstrap
cap--it almost drops right in--but I haven't matched your gain
figures.
For silliness I then a.c. bootstrapped your current source by putting
the boost cap back. Very silly!
Yes, I know, but the PNP's action is imperfect. So, in silly-land, I
used the cap bootstrapping trick to feed _your_ CCS from a cap-
bootstrapped CCS.
Cute. I was going to gripe about the output impedance, but it's
really pretty good.
Using magic SPICE transistors you can change the bias resistors from
220k to 1M, which boosts the gain even more. I wouldn't dare IRL,
natch.
J
josephkk
Ya know what, i may simulate it to see if it is as bad as you say. It
certainly seems to have problems from what i have posted already.
?-)
J
josephkk
Cool, what is the part number? Just the same i would like to experiment
(play) with a few if you are feeling generous this week.
?-)
