which nit??

Maybe mizoram Or jammu

I am from iit bhu

The point is we care towards the wnd of the semester. 😇

Hello Fabio, really he explained this in an excellent way.....

Hi

Yes Naurin, really good videos....

Yes Puneeth, really good....

Yes bro, he had explained really good....

Norman Nosher Appreciable? er Appreciated.....

Yes bro, really good....

If you do not require any gain then yes you can connect.

Yes Tarun this is excellent....

Yes Samuel, really good video....

Using Op-amp we can avoid the loading effect. If you simply connect the output of individual filters or to say if you connect them in parallel, then you will see the loading effect. So, it is good practice to add the individual filter responses using Op-amp.

Thanks for the prompt response.

For that, you need to use an optical filter. They are available for different wavelength

Centre frequency doesn't always lie in the middle of fc2 and fc1 . In order to keep it in middle Q factor of circuit must be quite high.

The outputs of the LPF and HPF will get added bu the output will be inverting (will have 180 degrees of phase shift and looks like -(VLP + VHP)) as it is connected at inverting terminal. To get a positive output, one more inverting amplifier will be required. I Hope it will clear your doubt. If you still have any doubt then do let me know here.

@@ALLABOUTELECTRONICS Wouldn't it be the same thing to just connect them to the non inverting input and have both outputs of the filter added?

f_L stands for lower cut-off frequency and f_H stands for higher cut-off frequency. So, irrespective of band-pass of band-stop, when we refer f_H and f_L, f_L is always less than f_H. I hope it will clear your doubt.

@@ALLABOUTELECTRONICS, thanks I had doubts cause in 5:30 minute you calculated fc1 and fc2 and low pass filter is higher than high pass filter. Low pass filter is 106.1 kHz and high pass filter 10.61 kHz. That's why my question :)

The frequency response of the cascaded system is the overlap of the individual frequency response. In case if try to implement the bandstop filter by cascading the low pass and high pass filter then the output would be the overlap of the individual response. If there is no overlapping region, then probably you will not get anything at the output. For the bandstop filter, it should reject only a particular band of frequencies and should pass all other frequencies. So, If you just cascade the LPF and HPF then either you get some overlapping region or nothing at all. And that's not the frequency response of the Bandpass filter. So, to get the desired frequency response for the bandstop filter, you need to use adder. I hope it will clear your doubt.

@@ALLABOUTELECTRONICS Yes i understand now. Thank you very much.

Hello Asha, I hope you got it right....

Yes, very soon I will make it.

@@ALLABOUTELECTRONICS will be eagerly waiting...

Irrespective of the order of the filter, we always look for 3 dB point where the voltage becomes 0.707 of the peak value or the power becomes half. So, depending on the order of the filter, 3 dB frequency will change. I hope, it will clear your doubt.

@@ALLABOUTELECTRONICS Thank you sir...is it is true for both active and passive filters

In case of cascade connection, the output will be the overlapping region of the individual response. Suppose, you cascade the LPF followed by HPF, then after LPF, all high frequencies are already attenuated. So, even if you use HPF, it will not pass high frequencies as there no high frequencies to pass. That's why adder is used. I hope it will clear your doubt.

+ALL ABOUT ELECTRONICS thnx alot

I think you are referring to 10:05 right ?? They are used to provide the gain. -Rf/R1 and -Rf/R2 will be the gain for upper and lower stages respectively. Let's say the output of the upper filter circuit with buffer is Vx and for the lower circuit, it is Vy. Then the overall output will be (-Rf/R1)Vx + (-Rf/R2)Vy. I hope it will clear your doubt.

Yes at 10:05. So it is mandatory put them in the circuit , Rf is not enough, right ?

I thought that to the adder (the circuit on the right ) Rf was enough to work properly.

No, R1, R2 are required. It's basically summer circuit. For more information, you can check the video on op-amp as summer.

@@ALLABOUTELECTRONICS ok thanks , I will check this video. Btw merry Christmas :)

Yes Suraj, really nice videos.....

Its amplitude. If we plot the transfer function then we will get two plots. Phase vs frequency and second is amplitude vs frequency. I hope it will clear your doubt.

IIR*

Thanks, soon I am going to cover it.

ALL ABOUT ELECTRONICS hoping it’s soon enough since my test is in a day lol... thanks for replying love ur channel!

It is frequency dependent. It depends at what frequency we are looking at. But I think you are talking about parallel resonant circuit (which acts like a band stop filter).

Yes, more videos will be uploaded on filters. I will try to cover almost all types filters in the upcoming videos. But next couple of videos will be on different topic (on Network analysis).

sir please complete this filter circuit part as soon as possible because it is very important in competitive exam too and we the aspirants are waiting to learn from you,thank you sir for such contribution........

I will try to complete it now as soon as possible. Next video is on technology. But then after I will try to complete this filter circuit portion as soon as I can.

ALL ABOUT ELECTRONICS@thanks sir for your valuable reply, within this month can it be possible??

At least 2-3 more videos on filters will be covered, which will cover almost all required aspects of the filter.

Since it is cascade connection, you can interchange the blocks.

@@ALLABOUTELECTRONICS sir i was asking whether it will still work as Band Pass Filter or not? If signal is input to that what will happen? What will be output?

Yes, it will work.

It will still work as band pass filter. But you need to carefully select the cut-off frequencies of both filters (to get an overlapping region) for band pass filter.

Yes Raj, this will work...

I have already replied to that question in earlier comments. Here, I am copying that answer: In case of cascade connection, the output will be the overlapping region of the individual response. Suppose, you cascade the LPF followed by HPF, then after LPF, all high frequencies are already attenuated. So, even if you use HPF, it will not pass high frequencies as there no high frequencies to pass. That's why adder is used. I hope it will clear your doubt. If you still have any question then do let me know here.

Add in cascade ..u will find a result whereinn only high pass filter willbe effective then. Similarly in LPF if you parallel them,, nothing would be filtered. Check it

Dear Prathyush, you can refer my channel for more details..

IC741

Sikha, you can use 741 or any other OP-amp

Yes, that's correct. I know it. I am planning make videos on filter design using R, L and C.

Umer Sir, why dont you make one and load for everyones benefit

To get basic idea about filters, electronic principles by Albert Malvino is good book.

Yes Satya Malvino is a good book....

Just apply the sine wave with variable frequency (You can apply it using the signal generator). and measure the output signal amplitude. The ratio of output to the input will give you pass band gain.

Would you please mention the timestamp where you are referring to ?

A notch filter is band stop filter with very narrow stop band. Normally, the band stop filters rejects certain band of frequencies but when you want to remove a specific very narrow band of unwanted frequency then in such cases this notch filter is used.

For filters, you may refer electronics principles by malvino.

Kindly turn off the subtitles for that particular time. I will try to keep that thing in mind so that from now on even if subtitles are used, the values will remain visible.

Dude you can drag the subtitles anywhere in the video screen

papa666 And do something about that impenetrable accent.

Yes Ms. Lukose, this video is very good....

I agree....this video is very good...

Super anniiyya