Maximum Power Transfer Theorem for AC Circuits (with examples)
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- čas přidán 7. 07. 2024
- In this video, the maximum power transfer theorem for AC circuit has been discussed.
So, in the case of AC circuit, the load will have a resistive as well as a reactive part.
And based on this load there are four different cases are possible for this maximum power transfer theorem.
Timestamps:
0:00 Introduction
3:18 Case 1: when both resistive and reactive part of the load are variable.
3:59 Case 2: when resistive part of the load is fixed and reactive part is variable.
4:26 Case 3: when reactive part of the load is fixed and resistive part is variable.
4:55 Case 4: when a load is purely resistive.
So, all four cases have been discussed in the video. And what should be the value of load impedance for all four cases have been mentioned in the video.
Apart from that, the mathematical derivation for the load impedance for the first case where both resistive and reactive part is variable have been derived.
For the remaining three cases, the derivation has been provided here.
You can download the pdf file here.
drive.google.com/file/d/0B3FO...
And based on this maximum power transfer theorem for AC circuits, few examples have been discussed.
Timestamps for the different topic in the video is given below.
0:00 Introduction
0:27 Quick Revision of Maximum Power Transfer Theorem for DC Circuits.
2:25 Maximum Power Transfer Theorem for AC Circuits.
5:37 Derivation for the load impedance for maximum power transfer when both resistive and reactive part is variable.
8:37 Example 1
10:42 Example 2
This video will be helpful to all students of science and engineering in understanding the concept of maximum power transfer theorem for AC circuits.
#MaximumPowerTransferTheorem
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Downloadable pdf file link for the derivations have been updated in the description. So, you can check that for the derivations.
This video is very helpful.
Thanks a lot.
thank you very much.... these lecs are helping me a lot
Thank you very much I really understanded this lecture
You resuce my😭😭😭😭😭😭😭😭😭😭😭😭
thank you sir..your explanation is just fab..its 2222 nice,,keep on making such videoes ,,we will share and like ur video,,its more helpful for us...thanks once again
Excellent Narration
In case of power systems , what is the alternative for the Maximum Power Transfer theorem ?
Nice sir please give more problems of different type it may help to clear whole concept .
Could you derive efficiency in each case
That step where modulus is taken is not mentioned in many other sources...thank you
Easily understandable👍
Sir if we use AC circuit means
Why he writing voltage values as 100
Thank you sir ❤
Thank you so much 👍
Please do more videos
Thanks
Thank you
While taking the power why did you take only the RL part and did not take the impedance part may i know why
Because the power only gets dissipated across the resistive part of the load.
Thanks🙏
Your explanation is super sir. Sir if you don't mine can you expalin reciprocity,compensation theorms please sir
soon I will cover it.
Thank you sir .
Sir if we use AC circuit means
Would you please let me know the timestamp where you are referring to, so I can answer quickly.
In place of dc
What about efficiency in all the cases sir
X(L) = - X(th)
Negative sign q lagaya hai.
Please tell... Please
What I mean to say is, the load impedance should be complex conjugate of the Thevenin's equivalent impedance of the circuit.
That means if Zth = Rth + j Xth then ZL should be Rth - j Xth
I hope it will clear your doubt.
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Okay thanks
Tq sir ji
sir transient and steady state responses please!Awesome explanation btw.
Next video will be on it soon.
How and why did Xl became equal -Xth
XL is equal to Xth in the context of a maximum power transfer.
Nice
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Waste lecture. Keep it slow and clear.