Hi Artur, thank you for this lecture. I found really interesting the fact that one can generalize these constructions by taking other group than binary strings of length n or the integers mod 2^n. Do you have a reference where I can look at that. Thanks in advance! :)
why are you writing 2^n instead of n? if n is the number of values for y then the sum of the squares of 1/sqrt(2^n) will not equal 1, but the sum of the squares of 1/sqrt(n) will
“U” Shape Waves This model may be related to the your topic. ua-cam.com/video/wrBsqiE0vG4/v-deo.htmlsi=waT8lY2iX-wJdjO3 Thanks for your informative and well produced video. You and your viewers might find the quantum-like analog interesting and useful. I have been trying to describe the “U” shape wave that is produced in my amateur science mechanical model in the video link. I hear if you over-lap all the waves together using Fournier Transforms, it may make a “U” shape or square wave. Can this be correct representation Feynman Path Integrals? In the model, “U” shape waves are produced as the loading increases and just before the wave-like function shifts to the next higher energy level. Your viewers might be interested in seeing the load verse deflection graph in white paper found elsewhere on my UA-cam channel. Actually replicating it with a sheet of clear folder plastic and tape. Seeing it first hand is worth the effort.
Thanks a lot! I have learnt many things thanks to the way in which the concepts are being presented!
Hi Artur, thank you for this lecture. I found really interesting the fact that one can generalize these constructions by taking other group than binary strings of length n or the integers mod 2^n. Do you have a reference where I can look at that. Thanks in advance! :)
why are you writing 2^n instead of n?
if n is the number of values for y then the sum of the squares of 1/sqrt(2^n) will not equal 1, but the sum of the squares of 1/sqrt(n) will
the number of strings is 2^n, like before. However, its interpretation is changed.
“U” Shape Waves
This model may be related to the your topic.
ua-cam.com/video/wrBsqiE0vG4/v-deo.htmlsi=waT8lY2iX-wJdjO3
Thanks for your informative and well produced video.
You and your viewers might find the quantum-like analog interesting and useful.
I have been trying to describe the “U” shape wave that is produced in my amateur science mechanical model in the video link.
I hear if you over-lap all the waves together using Fournier Transforms, it may make a “U” shape or square wave. Can this be correct representation Feynman Path Integrals?
In the model, “U” shape waves are produced as the loading increases and just before the wave-like function shifts to the next higher energy level.
Your viewers might be interested in seeing the load verse deflection graph in white paper found elsewhere on my UA-cam channel.
Actually replicating it with a sheet of clear folder plastic and tape.
Seeing it first hand is worth the effort.