Questions about npn transistor and operating point of diode

[equalP]

For question 1, it asks me to find the operating point by different methods.
But I have no idea to solve it. Can anyone give some hints for me?
I can just think about the diode can be replaced by an ideal diode, a 0.5V dc source and a 0.2/4=0.05Ω resistor.

For question 3,

I have solved the (a) part Ic=2.33mA.
For the (b) part, I have calculated Ib=Ic/β=0.0292mA
Ie=Ib+Ic=2.3625mA
However, I don't know how to find the value of Rb without Vbe. I have asked the tutor but he said that I do not need to assume Vbe=0.7V in this question.

Thanks for reading my questions.

 

[rude man]

1(a):

Write the linear equation relating vD to iD.
Sum currents to zero at vD. Solve for vD.
Solve for iD.
The rest I leave to you.

3.
I disagree with your instructor. You do need to assume what Vbe is (0.7V is a good assumption) in order to compute Rb.

 

[equalP]

Sum currents to zero at vD.

I do not get the meaning of this sentence...
Besides, should I ignore the ac power source in (a) and (b)?

Then I can convert the circuit into Thevenin equivalent circuit and Norton equivalent circuit to get the load line to solve the problem in (b). Is it right?

 

[rude man]

I do not get the meaning of this sentence...
Besides, should I ignore the ac power source in (a) and (b)?

vd is a node. The sum of all currents entering (or leaving) a node = 0.
No, you should not ignore the ac source. It is a source of current to the node vd, along with Vb.

Then I can convert the circuit into Thevenin equivalent circuit and Norton equivalent circuit to get the load line to solve the problem in (b). Is it right?

I don't know why you would want to convert to thevenin equivalent circuits. For one thing, the id - vd relationship is nonlinear.

Once you have solved part a) you have an expression for vd. You can take this function of time and plot it on the vd axis, then see the id on the y axis.

 

[NascentOxygen]

Then I can convert the circuit into Thevenin equivalent circuit and Norton equivalent circuit to get the load line to solve the problem in (b). Is it right?

Yes, that should work. Thévenin of the source and resistors, you mean? It's best to attempt part (b) first, so you can get a feel for what is really happening.

 

[NascentOxygen]

However, I don't know how to find the value of Rb without Vbe. I have asked the tutor but he said that I do not need to assume Vbe=0.7V in this question.

Hard to say. He may have meant that you shouldn't always assume 0.7V specifically. For example, you may first assume 0.7V and then find that the current is so small that 0.55V would be a more realistic figure, and re-work it with that.

Alternatively, he may have had in mind that since the transistor chemistry is not specified, it may be that it's Germanium where you would assume 0.3V.

 

[equalP]

Is the answer in (a) in terms of cos(ωt) for both vd and id?

Hard to say. He may have meant that you shouldn't always assume 0.7V specifically. For example, you may first assume 0.7V and then find that the current is so small that 0.55V would be a more realistic figure, and re-work it with that.

But in this question, I cannot know whether the current is so small as Rb is not given...

 

[NascentOxygen]

Is the answer in (a) in terms of cos(ωt) for both vd and id?

Parameters comprise a DC value plus a cos(ωt) term.

When you see v_D, that upper-case 'D' means the complete voltage. If it's a lower-case 'd' then it means just the AC component. (I'm assuming the person who wrote the question adhered to the convention, and that's not always guaranteed.)

 

[NascentOxygen]

But in this question, I cannot know whether the current is so small as Rb is not given...

You calculate Ib and Rb using the data given. Your results will be accurate to within a few percent, so you really do know the current (to within a few percent).

 

[equalP]

Does it mean that I can only get the result with no cos(ωt) in (b) but not (a)?
When I use the result in (a) to draw the line, I found that there may be something wrong in my calculation as the my calculated vd is in a small range near 0.5V...
i_D=20v_D-10
\frac{v_s+v_b-v_D}{100}=i_D+\frac{v_D}{100}
0.1cos(\omega t)+2-v_D=2000v_D-1000+v_D
0.1cos(\omega t)+1002=2002v_D
v_D=5.00\times 10^{-5} cos (\omega t)+0.500
i_D=20v_D-10=9.99\times 10^{-4} cos (\omega t)+9.99\times 10^{-3}
Is there any wrong?

You calculate Ib and Rb using the data given. Your results will be accurate to within a few percent, so you really do know the current (to within a few percent).

By the data given, I calculate Ib.
Then I assume Vbe=0.7V to calculate Rb. But with the Rb, how can I find the actual Vbe?

 

[NascentOxygen]

i_D=20v_D-10
\frac{v_s+v_b-v_D}{100}=i_D+\frac{v_D}{100}
0.1cos(\omega t)+2-v_D=2000v_D-1000+v_D
0.1cos(\omega t)+1002=2002v_D
v_D=5.00\times 10^{-5} cos (\omega t)+0.500
i_D=20v_D-10=9.99\times 10^{-4} cos (\omega t)+9.99\times 10^{-3}
Is there any wrong?

Yes, the first line.

By the data given, I calculate Ib.
Then I assume Vbe=0.7V to calculate Rb. But with the Rb, how can I find the actual Vbe?

The actual precise Vbe would have to be calculated using the exponential relationship for that PN junction. But of course, that accuracy is not required here. If IB is a good fraction of a mA or more, then 0.6V - 0.7V is fine. This isn't a maths subject.

 

[equalP]

Yes, the first line.

Oh, I found the problem.
It should be
i_D=0.02v_D-0.01
\frac{v_s+v_b-v_D}{100}=i_D+\frac{v_D}{100}
0.1cos(\omega t)+2-v_D=2v_D-1+v_D
0.1cos(\omega t)+3=4v_D
v_D=0.025cos (\omega t)+0.75
i_D=20v_D-10=5\times 10^{-4} cos (\omega t)+5\times 10^{-3}
Is it right?
If yes, then how can I solve it graphically by the results?

 

[NascentOxygen]

v_D=0.025cos (\omega t)+0.75
i_D=20v_D-10=5\times 10^{-4} cos (\omega t)+5\times 10^{-3}
Is it right?

That's looking better.

If yes, then how can I solve it graphically by the results?

Are you still on (a), or is this going to be (b) now?

 

[equalP]

Are you still on (a), or is this going to be (b) now?

This is going to be (b) now.

 

[NascentOxygen]

This is going to be (b) now.

I thought you already outlined your approach, back in what I quoted here.

 

[equalP]

Should I solve (b) with dc load line only? As the ac part of Vth is quite small...
Vth=0.05cos(ωt)+1V
Rth=50Ω
Or I should draw a line with Vth=0.05+1V and a line with Vth=-0.05+1V?

 

[NascentOxygen]

I think the question would be answered by drawing the DC load line, then showing a swing around it of 0.05V. So that could be thought of as drawing 3 lines―one solid line and a dotted line either side.

 

[equalP]

Thank you very much and I have solved these 2 questions

 

[NascentOxygen]

I was waiting to see how you'd do (c)?

 

[equalP]

In (c), I first consider the dc source only and do the similar with (a) and found
Vo=0.75V, Io=5mA

In small signal model,
r_d=\frac{1}{\frac{d i_d}{d v_d}}=\frac{1}{0.02}=50\Omega
v_p=0.1\times \frac{100||50}{100+100||50}=0.025
i_p=0.02v_p-0.01=5\times 10^{-4}
v_D=v_p cos(ωt)+v_o=0.025cos(ωt)+0.75
i_D=i_p cos(ωt)+i_o=5\times 10^{-4} cos(ωt)+5\times 10^{-3}

 

[NascentOxygen]

I think the question would be answered by drawing the DC load line, then showing a swing around it of 0.05V. So that could be thought of as drawing 3 lines―one solid line and a dotted line either side.

Maybe also draw an expanded graph about the area of interest, so that the magnitude of the output sinusoid can be measured directly off the graph, since this part is supposed to illustrate the graphical method of determining output.

 

[NascentOxygen]

In (c), I first consider the dc source only and do the similar with (a) and found
Vo=0.75V, Io=5mA

In small signal model,
r_d=\frac{1}{\frac{d i_d}{d v_d}}=\frac{1}{0.02}=50\Omega
v_p=0.1\times \frac{100||50}{100+100||50}=0.025
i_p=0.02v_p-0.01=5\times 10^{-4}

Is this ↑[/size] line correct?

 

[equalP]

Is this ↑[/size] line correct?

Because I found the result is same as that I found in (a), I think it should be correct...

 

[NascentOxygen]

I don't follow the - 0.01 bit.

 

[equalP]

I don't follow the - 0.01 bit.

I just get equation from the I-V characteristic graph and find that
i_D=0.02v_D-0.01