Designing a High-Gain Differential Amplifier: How to Meet Specific Requirements

[Rumination]

The figure shows a differential amplifier with a differential input vid = (vin_d_pos - vin_d_neg) between the bases of Q1 and Q2, and an output (out) at the emitter of Q4.

I have to Determine R1, R2, R4, R5 and R6 so that the following requirements are met:

R 1 = R 2
Av = vout / vid = 100 [V / V]
Vout = 0V when Vin_d_pos = Vin_d_neg = 0V.
The output Vout must be able to deliver undistorted peak signal voltage in the range
from vout-min to vout-max with RL armed.
Quiescent current IC = 10 * Q3-Q4 IB

----------
I have been given the values:
Vcc-pos = 21 V
Vcc-neg = 21 V
R3 = 2000 Ohm
RL = 49 Ohm
I1 = 3,56 mA
Vout-max = 8,8 V
Vout-min = -8,8 V
----------
How can I start? For I have difficulty getting started.

 

[berkeman]

The figure shows a differential amplifier with a differential input vid = (vin_d_pos - vin_d_neg) between the bases of Q1 and Q2, and an output (out) at the emitter of Q4.

I have to Determine R1, R2, R4, R5 and R6 so that the following requirements are met:

R 1 = R 2
Av = vout / vid = 100 [V / V]
Vout = 0V when Vin_d_pos = Vin_d_neg = 0V.
The output Vout must be able to deliver undistorted peak signal voltage in the range
from vout-min to vout-max with RL armed.
Quiescent current IC = 10 * Q3-Q4 IB

----------
I have been given the values:
Vcc-pos = 21 V
Vcc-neg = 21 V
R3 = 2000 Ohm
RL = 49 Ohm
I1 = 3,56 mA
Vout-max = 8,8 V
Vout-min = -8,8 V
----------
How can I start? For I have difficulty getting started.

Welcome to the PF.

The rules say that you must show some effort before we can offer tutorial help. What have you learned in class about how to analyze differential amplifiers? How are the bias currents set? How is the gain set?

 

[LvW]

Where is the current I1 and what is the meaning of "quiescent current iC=10 * Q3-Q4 IB"?

 

[Rumination]

My English is not so good. I have found this out:

V_cm = 0 , V_{in_D} = 0
V_B1 = V_B2 = 0 V.

I_c1 = I_E1 = I/2 = 3,65 / 2 = 1,825 mA

V_B3 = 21 V - R₃ * I_c1 = 21 V - 2kΩ * 1,825 mA = 17,35 V.

I_c3 = I_E3 = (24 V - V_B3 - 0,7 V) / R₄

But I don't know the value of R₄?

 

[Rumination]

Where is the current I1 and what is the meaning of "quiescent current iC=10 * Q3-Q4 IB"?

You can see the current I1 under the first set of amplifiers.

 

[LvW]

You can see the current I1 under the first set of amplifiers.

OK - sorry, I have overlooked this current source.

 

[LvW]

But I don't know the value of R₄?

I think, because you have used nearly all information, as a next step you should use the gain requirement.
This gives you a relation involving R4 and R5. Another relation between R4 and R5 can be derived from Q3 and the corresponding DC quiescent voltages/current (you know the DC voltages at the emitter and the collector for Q3)..

 

[Rumination]

I think, because you have used nearly all information, as a next step you should use the gain requirement.
This gives you a relation involving R4 and R5. Another relation between R4 and R5 can be derived from Q3 and the corresponding DC quiescent voltages/current (you know the DC voltages at the emitter and the collector for Q3)..

I don't understand this - "Another relation between R4 and R5 can be derived from Q3 and the corresponding DC quiescent voltages/current".

 

[LvW]

I don't understand this - "Another relation between R4 and R5 can be derived from Q3 and the corresponding DC quiescent voltages/current".

V_B3=17.35V
That means: We know V_E3=(17.35+0.7)V=21-I_C3R₄
We also know: V_B4=+0.7V=-21+I_C3R5.
Eliminating I_C3 gives a second equation for R4 and R5.

 

[Rumination]

V_B3=17.35V
That means: We know V_E3=(17.35+0.7)V=21-I_C3R₄
We also know: V_B4=+0.7V=-21+I_C3R5.
Eliminating I_C3 gives a second equation for R4 and R5.

Oh okay. So we get this by eliminating I_c3:

18,05 = 21 - R₄
R₄ = 2,95

0,7 + 21 = R₅
R₅ = 21,7

Does it mean, that we have found the values of R₄ and R₅ now? And now we can find the value of I_c3?

 

[LvW]

Oh okay. So we get this by eliminating I_c3:

18,05 = 21 - R₄
R₄ = 2,95

0,7 + 21 = R₅
R₅ = 21,7

Does it mean, that we have found the values of R₄ and R₅ now? And now we can find the value of I_c3?

?
Do you substract Ohms and voltages? Why did you neglect I_C3 in the equations ?
"Eliminating I_C3" means: Solving for this current in one equation and inserting it into the other one. This is basic for a system of two equations!

 

[Rumination]

Okay, but when I solve for the current in one equation and inserting it into the other one. I get:

(17.35+0.7)V=21 V -I_C3R₄
(2,95 / R₄ ) = I_C3

21,7 V = (2,95 / R₄ ) * R₅

 

[LvW]

Following my recommendation in post#7 you now have two equations involving R4 and R5.
Two equations with two unknowns can be solved easily.

 

[Rumination]

Following my recommendation in post#7 you now have two equations involving R4 and R5.
Two equations with two unknowns can be solved easily.

I can solve two equations with two unknowns. But my problem is, what those two equations are? That's what I'm confused about. Are these the two equations?:

(17.35+0.7)V=21-I_C3R₄
+0.7V=-21+I_C3R₅

But that's two equations with three unknowns I_c3, R₄ and R₅

 

[LvW]

The first equation is In post#12.
Question: Did you use already the gain information? NO!
Because Q4 provides no additional gain, it is Q1, Q2 and Q3 providing the necessary gain.
Are you able to find a correct gain formula for the first two stages?
This gives you a second equation.

 

[Rumination]

I give up. It's too difficult for me to solve. But thanks for your help

 

[LvW]

I give up. It's too difficult for me to solve. But thanks for your help

Too difficukt?
* You have the DC current and the collector resistor for the first stage. Are you able to find the corresponding gain A1 ?
* The gain of the second stage A2 is determined (primarily) by the two resitors R4 and R5. Do you know the expression?
* A=A1*A2=100 . From this you can derive the necessary gain A2 (A1 is known) and the required second equation for R4 and R5.

 

[Rumination]

* You have the DC current and the collector resistor for the first stage. Are you able to find the corresponding gain A1 ?

ϒ_e is: V_T / I_E = 25 Ω
A_v1= R_c / 2* ϒ_e = 2 / 2* 25 = 40.

* The gain of the second stage A2 is determined (primarily) by the two resistors R4 and R5. Do you know the expression?

ϒ_e4= V_T/I_e4 = 0,025 / 0,01 = 2,5 Ω
I have found R₆ to: (-21*49)/(R6+49) = -8,8 ⇒ R₆ = 67,9.
R_i4= (β₄+1) ( ϒ_e4+R₆) = 401 (2,5Ω+67,9) = 28,2 KΩ
A_v2 = (R₅ II R_i4) / (ϒ_e3+R₄) = ((R₅*28,2 KΩ) / (R₅+28,2 kΩ)) / (25 + R₄)

Is this correct?

 

[LvW]

What is the meaning of ϒe ?
What is the gain formula for the first stage?

 

[Rumination]

What is the meaning of ϒe ?
What is the gain formula for the first stage?

ϒe = re

Gain A1:

ϒ_e1 = ϒ_e2 = V_T / I_E = 0,025/0,001825 = 13,7
A_v1= (R₃ II R_ib3) / (ϒ_e1 + ϒ_e2 + R₁ + R₂)

The gain of the second stage A2:

ϒ_e4= V_T/I_e4 = 0,025 / 0,34 = 0,339
R_i4= (β₄+1) ( ϒ_e4+R₆) = 401*(0,339+62) = 25 KΩ

A_v2 = (R₅ II R_i4) / (ϒ_e3+R₄) = ((R₅*25 KΩ) / (R₅+25 kΩ)) / (25 + R₄)

Better?

 

[LvW]

Sorry, I cannot follow your "calculation".
ϒe = re ?
Ie4=0.34 ?
Resistors without unit?
β4=?

 

[Rumination]

ϒe = re ?

Bipolar transistors have a small internal resistance built into their Emitter region called Re.

Ie4=0.34

I have found R₆ to be:
-21V* 49/(R6 + 49) = -8.8V
R6 = 62 Ω. And Ie4 = 21V/62Ω = 0.34 A

β4=?

I have been given the value of β = 400 for all transistors in the assignment.

 

[LvW]

Bipolar transistors have a small internal resistance built into their Emitter region called Re.

My comment was related to the symbol ϒe and the realtion ϒe = re.
Normally, this symbol is used for a complex admittance.

I have found R₆ to be:
-21V* 49/(R6 + 49) = -8.8V
R6 = 62 Ω. And Ie4 = 21V/62Ω = 0.34 A

Can you explain these equations?

I have been given the value of β = 400 for all transistors in the assignment.

After 22 posts, nice to hear that β is given.
I have tried to give you some help - but I think I should stop now.
At first, you should learn some basics.

 

[Rumination]

I know, I should not have used the symbol ϒ.
re is better.

The emitter resistor and the load resistor form a voltage divider, so the output peak negative swing will be:
-21V* 49/(R6 + 49) = -8.8V and from there I found R6 = 62Ω. And Ie4 = 21V/62Ω = 0.34A.

What to do next?

 

[Rumination]

After 22 posts, nice to hear that β is given.
I have tried to give you some help - but I think I should stop now.
At first, you should learn some basics.

It's up to you, if you want to help. I can't force you.