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Anas Salah Eddin
Registrace 18. 01. 2018
M12 - 18 - Sinusoidal Steady-State Analysis- Example 10 (Op-Amp AC Circuit)
M12 - 18 - Sinusoidal Steady-State Analysis- Example 10 (Op-Amp AC Circuit)
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Video
M12 - 17 - Sinusoidal Steady-State Analysis- Example 9 (Thévenin & Norton)
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M12 - 17 - Sinusoidal Steady-State Analysis- Example 9 (Thévenin & Norton)
M12 - 16 - Sinusoidal Steady-State Analysis- Example 8 (Source Transformation)
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M12 - 16 - Sinusoidal Steady-State Analysis- Example 8 (Source Transformation)
M12 - 15 - Sinusoidal Steady-State Analysis- Example 7 (Superposition)
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M12 - 15 - Sinusoidal Steady-State Analysis- Example 7 (Superposition)
M12 - 14 - Sinusoidal Steady-State Analysis- Example 6 (Mesh Analysis)
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M12 - 14 - Sinusoidal Steady-State Analysis- Example 6 (Mesh Analysis)
M12 - 13 - Sinusoidal Steady-State Analysis- Example 5 (Nodal Analysis)
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M12 - 13 - Sinusoidal Steady-State Analysis- Example 5 (Nodal Analysis)
M12 - 12 - Sinusoidal Steady-State Analysis- Example 4 (Wye-Delta Transformation)
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M12 - 12 - Sinusoidal Steady-State Analysis- Example 4 (Wye-Delta Transformation)
M12 - 11 - Sinusoidal Steady-State Analysis- Example 3 (Voltage Division)
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M12 - 11 - Sinusoidal Steady-State Analysis- Example 3 (Voltage Division)
M12 - 10 - Sinusoidal Steady-State Analysis- Example 2 (Current Division)
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M12 - 10 - Sinusoidal Steady-State Analysis- Example 2 (Current Division)
M12 - 9 - Sinusoidal Steady-State Analysis- Example 1 (Combining Impedances)
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M12 - 9 - Sinusoidal Steady-State Analysis- Example 1 (Combining Impedances)
M12 - 8 - Circuit Laws in the Phasor Domain
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M12 - 8 - Circuit Laws in the Phasor Domain
M12 - 6 - Phasor Relationships for Passive Circuit Elements
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M12 - 6 - Phasor Relationships for Passive Circuit Elements
M12 - 2 - Solution of a First-Order Differential Equation with a Sinusoidal Forcing Function
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M12 - 2 - Solution of a First-Order Differential Equation with a Sinusoidal Forcing Function
M12 - 1 - Sinusoidal Steady-State Analysis: Introduction
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M12 - 1 - Sinusoidal Steady-State Analysis: Introduction
M11 - 2 - A General Solution for Second-Order Transient Circuits
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M11 - 2 - A General Solution for Second-Order Transient Circuits
M11 - 11 - Second-Order Transient Circuits: Example 5
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M11 - 11 - Second-Order Transient Circuits: Example 5
M11 - 10 - Second-Order Transient Circuits: Example 4
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M11 - 10 - Second-Order Transient Circuits: Example 4
M11 - 9 - Second-Order Transient Circuits: Example 3
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M11 - 9 - Second-Order Transient Circuits: Example 3
M11 - 8 - Second-Order Transient Circuits: Example 2
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M11 - 8 - Second-Order Transient Circuits: Example 2
M11 - 7 - Second-Order Transient Circuits: Example 1
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M11 - 7 - Second-Order Transient Circuits: Example 1
M11 - 6 - A Strategy for Solving Second-Order Transient Circuits
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M11 - 6 - A Strategy for Solving Second-Order Transient Circuits
M11 - 5 - Critically Damped Response of Second-Order Circuits
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M11 - 5 - Critically Damped Response of Second-Order Circuits
M11 - 4 - Underdamped Response of Second-Order Circuits
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M11 - 4 - Underdamped Response of Second-Order Circuits
M11 - 3 - Overdamped Response of Second-Order Circuits
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M11 - 3 - Overdamped Response of Second-Order Circuits
M11 - 1 - Second-Order Transient Circuits: Introduction
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M11 - 1 - Second-Order Transient Circuits: Introduction
M10 - 15 - First-Order Transient Circuits: Sequential Switching Example 9
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M10 - 15 - First-Order Transient Circuits: Sequential Switching Example 9
Hello Sir, Why did you decide to not have a FIFO in this design?
First time I see the whole process....gold mine😮
Thank you!
Hello Sir, Shouldn't the driver files go into the platform and application files in application project?
Where can I send you my question? Do you have telegram? Please 😢
Hi, I have a question Please I really have problem Can you help me please?
thakyou 🙂
How pixel clock rate and bandwidth are related??
How to calculate pixel clock rate of HDMI
Sir you just earned one lifelong subscriber
thankyou for this
Great videos Anas. What an effort! Are you planning on creating a series on DSP algo on FPGA? Not many tutorials on it.
according to texas instruments documentation at the below link page 24/51 , I think the waveform of operation modes are exchanged www.ti.com/lit/ug/sprugp2a/sprugp2a.pdf?ts=1719455710938
Thanks for such an awesome explanation. I have a question if you can answer. if there is a timing violation and the output goes to the metastable state but do we get the correct output once it comes out of the metastable state or the output can go to either of the logic high or logic low as can be seen the waveform at 4:57?
You cannot tell the output of the system after the metastability ends, and you cannot tell for how long it will be in metastable condition.
Baud rate is NOT a term of a UART. They work in bit/second!
excellent. thank you for the videos and playlist
Great video!! only if you can upload the verilog code ...
All the code segments I use in my videos can be found on my GitHub page
too helpful u really put a lot of effort into this
Sir, the way you teach is way beyond wht we get to learn in academics, ur videos have essence of partical implementation, which change the way we infer the logic and its implementation in verilog, Thanks for all the resourses that you provided, I wanted to admire your work, thanks for the help.
thanks
Changing D @ the onset of pos edge and it got reflected in Q ; doesn't it violate the hold time condition ? The previous value of D should be reflected @ Q ?
iirc this is without any timing parameters included, so everything is ideal
demonstration of "mixing" blocking and non-blocking assignments could be interesting.
Sorry, but I think there is a mistake in the B part. It’s asking about the left side, not the right one, so the answer should be V(left) = -212.77 mV Correct me if I’m wrong please
Thank you and good luck with the channel, you are doing a great job.
Why 16 times we are considering for oversampling
Logic for done in timer ??
We can get tons of different clock generators to meet various needs from old computers people throw away.
why talking like machine gun, difficult to follow
how can I constraint the generated clock?
En los extremos de un solenoide
10:55 The thing I have trouble understanding is how it could have been a combinational circuit even with blocking assignments. Don't the blocking assignments imply registers, and doesn't that also make it sequential? In my mind always_comb should work just like continuous assignments, so I have trouble wrapping my mind around why so many always block constructs (like switches) demand blocking assignments
25 ns for operture is too big. Usually 100 MHz clock is 10ns time period then how even a single flipflop can work
best teacher you can talk till the morming and I can listen without getting bored
Do we have to write the synchronous part in combinational always block? Wouldn't it work like this: always @(negedge clk,negedge reset_n) begin if(!reset_n) Q_reg <= 1'b0; if(!clear_n) Q_reg <= 1'b0; else Q_reg <= Q_next; end
Yes, that is equivalent, because if "not ~reset_n", that means that the first "always" block was triggered by a negative edge of "clk", thus you're only checking "clear_n" on a clock edge and so it is synchronous. (I also elaborated the design using your suggestion and it results in the same schematic).
How about a video from wye to delta transformation
thank you
Rather than using if else for 4to1 mux can we use case statement ?
Very useful - Thank you very much for putting it "out there" :)
I have a question at 4:11 Can we still write it as (20-V2) - (V2-V3)/4 - (V2/40) since it's a voltage drop from 20 to v2
Thank you this was really helpful. May I know the resource of the questions?
Hi brother, I got a Friend that needs the whole schematic for the M9. We are in Brazil and it's difficult to find it here. He needs to check some parts to be replaced on one of that. Do you know where on internet can I find it? And if you have it, would you share it?
Thank you so much for your videos
thank you for sharing Sir
whats the use of mealy and moore? where do we use them?
There are more videos in the playlist that will answer your question. It might be helpful to watch videos that cover the applications of FSMs first.
Thank yo Dr. please continue the series
Thank you for this explanation! It was very helpful for understanding the difference between synchronous and asynchronous and where to put what in the always blocks to make it one or the other.
Just what I needed to hear to clear up the confusion about why you'd use non-blocking assignments for my digital design class. Thanks!
very helpful thanks
Good
Well explained. Thank you