Gravitational quanta (in digital format) measure the Universe?!❤Кванты гравитации (цифровым способом) измеряют Вселенную?! Для сравнения: Подобных теории как ОТО. Эйнштейна написано 1001, из них, опубликованы только в популярных журналах более 150. Но за 150 лет, не одного прямого опыта для этих теорий (выполненные на 50%, есть опыт или косвенные). Вы готовы посмотреть на обнаженную Вселенную без шумового *загрязнения* для 1001 теории? При детектирование гравитационных волн, детектором LIGO, полезный сигнал 0,2% на шум приходится 99,8%. По другому выразим - используя сепаратор из шаблонов. При случайном совпадают в них шумов (мусор), на двух или трёх детекторах, то выдадут это, как гравитационные волны. На “ГИБРИД оптическом гироскопе" при регистрации, квантов гравитации *оптом*. Возможно полезные сигнал получим 74% и на шумы 26%. - Вам выбирать рулетку, что измеряет Вселенную и из чего, главное она состоит. Итак автотранспорт или самолёт в нём выполним опыты Майкельсона-Морли, определяя им прямолинейную скорость. - О таком опыте мечтал, Эйнштейн. Но мы, *возможно* будем наблюдать постулаты "Свет это упорядоченная вибрация гравитационных квантов. Доминантные гравитационные поля управляют скоростью света в вакууме". Есть предложение на совместное изобретения ГИБРИД гироскопа из некруглых, ДВУХ катушек с новым типом оптического волокна с «полой сердцевиной из фотоно-замещенной вакуумной зоной или (NANF)», где - свет в каждом плече проходит по 250000 метров при этом, не превышает параметры 87/87/87 см., и вес - 24кг. Предприятия по выпуску "Волоконно-оптических гироскопов" может выпускать ГИБРИД гироскопы, для учебно практического применения в школах и для ВУЗ. Рационализатор из Казахстана.
@PTGaonkar
3 ай бұрын
Wow this is my dream series.. thank you very much. This will me very helpful.
@physicsforstudents
3 ай бұрын
Watch out the second part kzitem.info/news/bejne/uaes0nmGqIqEbJwsi=DhNy4HIxjjLhs9VA
@PTGaonkar
3 ай бұрын
Thanks .. for the series
@yopenzo
3 ай бұрын
"The mathematics of general relativity is not at all difficult". That's a very peculiar statement, sir. Therefore, I would kindly know what you consider "difficult" mathematics.
@arielf9587
3 ай бұрын
I had the same reaction when my physics professor said this in a lecture. He told me after studying Quantum Mechanics, General Relativity really does seem easy lol.
@physicsforstudents
3 ай бұрын
Nothing is difficult. It the unknown that we fear.
@FC-BS
3 ай бұрын
Fr. I'm currently reading a book on the introduction to general relativity and I can only understand the physics concepts within in, not most of the equation
@physicsforstudents
3 ай бұрын
@@FC-BS Great 👍 Which book you are reading
@FC-BS
3 ай бұрын
@@physicsforstudents general relativity the theoretical minimum by Leonard Susskind and André Cabannes
@DavidVonR
3 ай бұрын
I would love to study general relativity one day but I lack the time and energy. I have a mathematics and physics background. Do you have a lecture series we can watch?
@physicsforstudents
3 ай бұрын
That's wonderful 👍 👍 Get started.
@ramlimboo3745
3 ай бұрын
I always wanted to know mathematics behind general theory of relativity
@philophysics7423
3 ай бұрын
This video and this entire page is a gift to humanity. So much higher order scientific theoretical work done in bite size is no easy task, but you guys shine magnificently. Thank you!!!
@physicsforstudents
3 ай бұрын
Thank you very much for your wonderful comment. It gives me motivation to do more....
@ramlimboo3745
3 ай бұрын
Thank you so much 🙏...sir for this outstanding information about General theory of relativity
@CandyTesult
3 ай бұрын
I really, really like this big picture approach. It's much different from other youtube videos. Thankyou.
@physicsforstudents
3 ай бұрын
Welcome. Thanks a lot.
@sirknightartorias68
3 ай бұрын
I wish you had been there when I was in my plus two . 😢
@digguscience
3 ай бұрын
General relativity is a great subject to study in the spare time.
@edd.
3 ай бұрын
How can you learn GR wo tensor calculus?
@physicsforstudents
3 ай бұрын
That is True. As I told that, this is the first episode. In subsequent episodes, tensor calculus will come up.
@antonboro5695
3 ай бұрын
Excellent introductory lecture about general relativity. I have two questions I hope you can answer without requiring a knowledge of mathematics to understand the answer If general relativity is the study on the curvature of space-time caused by the presence of mass and energy, 1.) how was Einstein able to accurately measure the deflection of starlight as it passed near the sun. during the 1919 solar eclipse without accurately knowing the mass of the sun? and 2.) how are cosmologists today able to predict space curvature without knowing the existence, size and mass of the many known and unknown heavy objects, affecting the light's path as it reaches our telescopes?
@physicsforstudents
3 ай бұрын
Thank you very much for watching my video. I am putting up the entire series in this playlist:kzitem.info/news/bejne/uaes0nmGqIqEbJw Answer to your first question: From the value of the diurnal parallax, one can determine the distance to the Sun from the geometry of Earth. The first known estimate of the solar mass was by Isaac Newton. So, you see, it was many years before Einstein. Einstein didn't directly measure the deflection of starlight himself; his theory predicted how much the light would bend. According to general relativity, light passing close to a massive object like the Sun would bend due to the curvature of space-time. He calculated the amount of this bending based on the mass of the Sun and the distance from the Sun where the light passed. During a solar eclipse, the Sun is blocked by the Moon, allowing stars near the Sun (in the sky) to be visible. Normally, the Sun's light would outshine these stars. The mass of the Sun cannot be measured directly, and is instead calculated from other measurable factors, using the equation for the orbital period of a small body orbiting a central mass. Based on the length of the year, the distance from Earth to the Sun (an astronomical unit or AU), and the gravitational constant (G), the mass of the Sun is given by solving Kepler's third law. Answer to your second question: Modern cosmologists have more sophisticated tools and data to predict the curvature of space. We know the masses and positions of many stars, planets, galaxies, and other celestial objects through observation and calculation. This helps in predicting how these masses might curve space-time. Although we can’t see dark matter and dark energy directly, we know they exist because of their effects on visible matter and light. For instance, we observe the way galaxies rotate and how light bends around massive objects, which indicates the presence of more mass than we can see. Light from a distant object, like a galaxy, can bend around another massive object, like another galaxy or a cluster of galaxies, before reaching us. By studying these bends (lenses), cosmologists can infer the presence and distribution of mass, even if it’s not visible. Telescopes, satellites, and other instruments provide detailed data about the universe. With sophisticated models and computer simulations, scientists can make very accurate predictions about space-time curvature.
@maloukemallouke9735
3 ай бұрын
thank you
@physicsforstudents
3 ай бұрын
Welcome
@lokeshraybarman7007
2 ай бұрын
Your posts are really getting more and more interesting & 0utstanding day by day ❤❤❤❤
@physicsforstudents
2 ай бұрын
Thank you. Please see the playlist where there are other videos also
@hellenofile
3 ай бұрын
Fantastic! Thanks, and looking forward to the rest!
@physicsforstudents
3 ай бұрын
Here is the second part kzitem.info/news/bejne/uaes0nmGqIqEbJwsi=I75gBSkihDWywLR4
@physicsforstudents
3 ай бұрын
This is the third part kzitem.info/news/bejne/sJV5n6mvp4GQfH4si=hjaV4MxmV0Y2szoT
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