Thanks for the detailed information. Can you please help to answer this, If we consider a microstrip with specific impedance, which losses dominate as the ground plane gets farther and farther. The width of the microstrip will increase and hence lowering the conductor lossses but the dielectric losses increase as the ground is far.
Thank you for sharing the course. I have a quick question, what is the applicable frequency range for the transmission line equivalent impedance equation at 8:25? Does it work from 1HZ to 100GHz?
It looks a good starter... I didn't see this features in my CAD program though easily available... Can I find also digital RF here? (Like what happens if digital pulse 0/1 is sent to transmission line and how power lines operate in digital RF). This looks more like science class. I guess it need a lot of tools to make it work. Hard to be found tools...
Thanks a lot for this ... you teach in a practical way considering real life. Wish all the college professors were like this
Excellent 👌👌👍👍👍
Thanks for the detailed information. Can you please help to answer this, If we consider a microstrip with specific impedance, which losses dominate as the ground plane gets farther and farther. The width of the microstrip will increase and hence lowering the conductor lossses but the dielectric losses increase as the ground is far.
Thank you for sharing the course. I have a quick question, what is the applicable frequency range for the transmission line equivalent impedance equation at 8:25? Does it work from 1HZ to 100GHz?
It looks a good starter... I didn't see this features in my CAD program though easily available...
Can I find also digital RF here?
(Like what happens if digital pulse 0/1 is sent to transmission line and how power lines operate in digital RF).
This looks more like science class.
I guess it need a lot of tools to make it work. Hard to be found tools...
Thank you sir ,thank you so much
sir,
where can i find this chart?
Thank you so much!
nice stuff
Danke
Brilliant
Thank you very much!!!