I have no diplomas, --> bad student and lack of maturity when I was a teen. Yet I found a thirst for knowledge in my 20s, decided to start from scratch all the science and math. Two years ago I finally reached the confidence to start learning about quantum physics. I bought the book, did the math on paper It's been my only book for two years I never skipped a page until I was fully able to play and understand the mechanics involved. I watched the lectures many Times. And I come here just to say thank you. Unfortunately I'll never work in physics, I am too old and still without a diploma, I have managed to make a great career in IA and machine learning. To each his own path eh? Living in this era of knowledge, where you can learn from home, find communities to help you improve, is the greatest gift we have. Stanford and Leonard Susskind I thank you again for making this class available and henceforth contributing to what is the best about the world we live in. I felt, even though this video is old, that a heartfelt comment here was needed. Thank you again. (a friendly Swiss fellow)
Lecture 1 0:00:00 to 0:11:35 - Transition from classical to quantum mechanics 0:11:35 to 0:20:00 - The state of a system in classical mechanics 0:20:00 to 1:01:21 - The results of measurements on a qubit 1:01:22 to 1:15:10 - Vector space 1:15:11 to 1:24:12 - Dual of the vector space 1:24:13 to 1:46:31 - Inner products
I'm surprised and pleased that this is online. I bought the Kindle book a few months ago, without knowing there is a set of free online lectures by the author. Thank you to Stanford and Leonard Susskind for making these lectures available.
My path with the Theoretical Minimum is a bit random: I bought the quantum mechanics book at a whim in a bookstore, but then I first watched the classical mechanics video series, ordered the two other books online, then read the classical mechanics book, then started reading the special relativity book, but after a few chapters switched quantum mechanics book and having read the first third I now started watching this video series… On the other hand, I studied all this stuff at university, so it's familiar, but it was over ten years ago and I've forgotten a lot.
Tks Stanford, what a privilege to listen to this. And Susskind is an amazing teacher. I'm blown away by getting a glimpse into the theoretical minimum which I knew little or nothing about.
He really is and it takes one to know one. I totally disagreed with the final outcome of the black hole wars so I had to eat a lot of crow when i finally understood it. Totally worth it to have an insight into string theory.
He is actually quite a knowledgeable man, Leonard Susskind. I can grasp Plato's 'Wax Tablet Hypothesis', Aristotle's 'Theory of Everything' and Goethe's 'Theory of Colours' but these lectures are beyond me. Cheers - Mike.
NOTES: Systems have states A set of states can include subsets Inclusive (union) and exclusive (intersection) propositions can be made The space of the states of a system in QM doesn't follow the set logic It's a vector space An apparatus detects the status of Q-bit that like a coin (with H and T) could be in two states , 1 for pointing up or -1 for down, only one of them at any given time Both the apparatus and the Q-bit have a sense of direction of their own The directions of the apparatus and Q-bit in relation to one another, determines and changes the probability of the results Observing the system once prepares the result and will give you the same answer until the detector has been turned off and on again, If the internal vector of the apparatus lies in the same axis as the Q-bits we get the same answer over and over again, which is its component, meaning if we rotate the apparatus 180 deg, we get -1 in which the negative sign indicates the opposite direction Also even when we start with the apparatus on it's side (internal vector and Q-bit are in different axes) results are the same as long as the system is not disturbed. However 90 deg rotation of the apparatus around any axis makes the results random with probability of 50% for each, averaging at 0 Results of an angled apparatus are also random but they average in the component of the initial axis along the rotated internal vector (Cos of the angle apparatus makes with its initial axis) Mathematical vector space contains objects that aren't ordinary Vector space is a collection of mathematical objects In the vector space numbers are one dimensional and complex numbers are two dimensional Vector a is written as: |a> You can add vectors: |a>+|b>=|c> Vectors could be multiplied with complex numbers in the complex vector space: z|a> = |a'> Vector's components are represented in the form of columns in brackets Addition: n'th row of one column adds to the n'th of the other Multiplication: the number is multiplied with all of the rows in the column Complex conjugate vector that has a one to one correspondence with its elements Complex conjugate vectors lies in complex conjugate vector space Duel of a vector sum is the sum of their individual duels Duel of a vector |a> multiplied with a complex number z is ) = = α1. β1* + α2. β2* = = α1*. β1 + α2*. β2 Using postulate (1) must be true that: = * which means it's always real (its imaginary component is zero so the conjugate doesn't change it) and always positive (the real part is being multiplied by itself), resulting in the square of the vector's length (using Pythagorean theorem) T = * = α1.α1* + α2. α2* The orthogonality causes the inner product to be zero (because: cos 90 deg=0) Maximum number of mutually perpendicular non-zero vectors in a space determines the dimension of it
I really enjoy Susskind's lecture because even as a practitioner and expert, I like how he gets to the heart of the physical idea and it is wonderful that he is taking the time and effort to educate in this venue for continuing education.
I can't say Thank You enough. It's been a year since I started with this course and now I am learning to apply all of this in my Quantum Computing course. To whomever this concerns: the explanations and tricks (not really) that you're gonna learn here will stay with you your whole life. Its THAT clear. Thank You Professor Susskind and Stanford University for this. ALWAYS and FOREVER.
@5:14 what an awesome sermon. I am loving these lectures. I am pissed that, in my far reaches of the world, this exposure and influence has been denied me via my class, cast, socio-econ, and generational & physical demographic. More knowledge. more brains. I am hungry to intuitively know more. I love Educaton X Generation :D Thank you Stanford and Prof+Team
I'm in college rightnow to learn about business, but I'm just doing this in order to become financially independent so that I may afford to learn about quantum physics, and get to solve our greatest mysteries and problems. Science is what I am truly fasinated about! I'm so exstatic to know that I live in an age where I can learn this information from the small technology in my hand. Thank you for posting this lecture!
Well, he is 81 years of age now... so don't expect too much teaching from him. I take that back! Surprise... he is still teaching "PHYSICS 361: Cosmology and Extragalactic Astrophysics". Cool!
the thing I love about these lectures is that he starts with the fundamental concepts, then illustrates how the theories differ, at that fundamental level. IMO, Feynmann didn't really do that...
I agree ErnestYAlumni. I also enjoyProf. Susskind's dry humour like the bit where he says in answer to a question at about 54:50 "They might have got the Qbits from a Qbit store!" . . . humour helps the process of learning. ;-)
Finally, they started to treat vectors as functions. Functions are vectors because then can be added together and scaled. But, functions are also vectors of single variable. The argument is called "index" or "coordinate" in the vector space. Vector a=[a0,a1,a2] is a map a(0)=>a0, a(a)=>a1 and a(x)=>a_x in general. This is a function of single variable. Vectors are just discrete functions in the narrow view.
Hey, sorry for the late reply. The reason you don't hear much about fractals in a class about quantum mechanics is because the quantization of matter prevents true fractals from existing. Approximate fractals appear on cosmological scales through microscopic scales, but eventually there's a fundamental limit, so for example a coastline is not actually infinite. A better place to look for fractal theory would be a course on complex variables or chaos theory, graphics design or fracture mechanics.
This lecture is great. The professor is obviously starting from baby steps to demonstrate the foundation of quantum mechanical statistics, but some of his students are either bored or want to show off their "advanced" knowledge. Actually, this is very similar, if not identical, to Dirac's experiment and treatise on a 45 degree polarizer sandwiched between two polarizers oriented at 90 degrees to each other. Very beautifully prepared lecture.
The 'black' in blackboard does not mean the black colour any longer. A blackboard, whatever its colour, always is a blackboard. Or do you think an atz has to be made of stone just because, since millenia ago, atz means stone?
its not a blackboard, it is a quantum object that your evolutionary structure cannot conceive, so you label it a blackboard, it is both a blackboard and a white board at the same time, it depends on the observer to determine which. 50% of people believe it to be a white board and 50% a blackboard. Although if it is rotated too exactly 45 degrees, the number suddenly spikes to 85% of people bellowing it is one of these but then returns to 50/50 outside that angle.
Bought the book and felt it was a bit too rushed, I wanted to expand more on the maths behind it so I went online to search for further explanations and turns out his lectures are all available on youtube! Thanks for providing these videos to the internet.
Do you think the book adds any more value over these lecture? I'm contemplating buying the book but if it's just a transcript of these lectures, it may be a waste
I strongly agree with his assertion that the abstract intuitions and math are extremely powerful and important to develop. I disagree that that higher dimensional visualization (or lower) are impossible or useless. He is right that most people don't correctly visualize what two or 1 dimension are like though they think they are. The story of flat land is a good place to start.
Dr Susskind is amazingly accessible. I read his "Black Hole War" and found it quite an enjoyable read despite being concerned with physics that are way above my pay grade.
@Abdullah Naeem, The answer is no it doesn't take it out of the quantum world. Or rather, you are only out of the quantum world about that specific axis. If you know the spin around one axis you have maximal uncertainty (i.e. a 50-50 chance of either result) about its spin around an orthogonal axis. That's quantum mechanics. It should become more clear as the lectures go on and he covers more of the mathematics describing this weird situation.
Yes, the q-bit doesn't have to "reset" at a specific angle to come up with the same ratios... I feel like he keeps it that way because it will uphold the integrity of the experiments being "wiped clean" with every new q-bit.
Hello friends- My daughter, in 2nd year of university, gave me The Theoretical Minimum for Christmas, as she knows I appreciate the thought experiments around physics, and can hang in there during a discussion. However, when reading this text, and watching these inspiring videos, I am lost. I can kinda follow, but feel there are some foundations I am missing (I am 62, and I believe I was stoned during an essential class in high school, double entendre). What do you suggest I study/watch/practice to get up to some semblance of understanding to continue this text and lecture? I am willing to put in some time.
a flipped coin is a process that is in motion or not. It is on the edge when in motion and on either side when not. The universe is organized in sets of three gravity medium dimension sets with an observer in the middle. The set of three straddles a force set of four. Both form a process of 12 parts every three cycles. The minimum value of each, is a non event and can only exist within the other as an opposite value, in the opposite direction.
these students....he spent so much time trying to get 2 simple ideas across to them...holy hell. this lecture couldve been 1/3 as long and i wouldve got just as much! sheesh! i cant get enough of these! (the lectures, not the students)
From the course website: January 9, 2012 Professor Susskind opens the course by describing the non-intuitive nature of quantum mechanics. With the discovery of quantum mechanics, the fundamental laws of physics moved into a realm that defies human intuition or visualization. Quantum mechanics can only be understood deeply by studying the abstract mathematics that describe it. Professor Susskind then moves on to describe how the space of states for quantum mechanics, and the rules for updating those states, are fundamentally different from those of classical mechanics. For quantum mechanics, the space of states is a vector space versus a set of states for classical mechanics. He then then describes the basic mathematics of vector spaces. Topics: The non-intuitive logic of quantum mechanics Vector spaces Rules for updating states Quantum preparation and measurement are the same operation Mathematics of abstract vector spaces References Quantum mechanics Vector space
You don't have to believe every bullshit they put out at Stanford. Quantum mechanics is actually quite easy to understand if you aren't falling into the usual traps. Unfortunately for you, the way Susskind teaches the topic, you will.
@@redsix5165 The usual traps are mistaking quanta for particles and the single system for the quantum mechanical ensemble. Not knowing that non-relativistic quantum mechanics is not a self-consistent theory. It's not even physical. Not having a background in atomic physics, not knowing enough (or anything at all) about special relativity. That kind of stuff. Some teach better than others. The best I have seen is Alan Adams from MIT, but even he misses the mark on many of these topics.
Let's imagine the grid structure of Planck pixels (plixels) and how they interact with vectors representing the changing states of hawking radiation over Planck time. We can explore how these vectors, characterized by the cosine of the angle (θ), relate to the speed of light and describe acceleration, which in turn corresponds to gravity. In QIH, the grid structure of plixels represents the fundamental fabric of spacetime at the Planck scale. Each plixel acts as a discrete unit, contributing to the overall information processing and entanglement within the holographic framework. Now, let's consider the vectors that represent the changing states of hawking radiation over Planck time. These vectors describe the properties of the emitted radiation, such as its energy, momentum, and direction. The cosine of the angle (θ) associated with these vectors represents the percentage of the speed of light contained within the hawking radiation. As the angle (θ) changes over successive moments, new hawking radiation is emitted, reflecting the evolving quantum state of the system. This changing angle and the subsequent emission of radiation correspond to acceleration within the QIH framework. Acceleration can be seen as a manifestation of the altering quantum states and entanglement patterns between the plixels and the emitted hawking radiation. In the context of the equivalence between acceleration and gravity, this changing angle and the resulting emission of hawking radiation can be understood as gravitational effects within the QIH framework. The modulation of quantum states and the interaction between the plixels and the emitted radiation encode the gravitational behavior, thereby linking acceleration, hawking radiation, and gravity. Through the lens of QIH, this perspective allows us to explore how the grid structure of plixels, the changing angles of hawking radiation, and their associated acceleration can provide insights into the interplay between quantum information, spacetime, and the gravitational phenomena. It offers a framework for understanding how gravity emerges from the quantum information processing occurring within the holographic structure of spacetime.
or in other words: the degree by which i rotated the aparatus after a measurement defines the likelyhood to get the same measurement at the second measurement of the same quark? so at the third measurement, the outcome of the first measurement has no impact on the result whatsoever anymore? but the outcome of the second measurement has a decisive impact on the probability? this is soo cool!
@ganeshie8 No. Once you get a value for some orientation of the apparatus, you will consistently get the same value while measuring the same system with the same orientation. You have just collapsed its wave function. Until a measurement has collapsed the wave function, the actual orientation of the system doesn't make much sense in QM. You just have the probabilities for each result for the different orientation angles (that's the wave function or the state vector). That's all there is to it.
Jesus, people - they aren’t Stanford students (nor even physics students, to boot). Prof. Susskind gave these lectures to members of the community who wanted to learn more about the subject. Same is true for just about all of his Stanford-sponsored lectures on YT, to my knowledge.
Non-quantitative-number-numeral symbol hyphen, - , concatenated with quantiative-number-numeral one, 1, doesn't result in something from either category and therefore, is excluded from a vector : something with magnitude and direction, space by definition.
The student at 57:28 asked a question that I don't think Professor Susskind quite understood. To put the question another way, if we assumed the system could be any orientation, not just up or down, we would still get the same results because the detector is only capable of giving a binary answer: The binary nature of the system's states is assumed rather than demonstrated; so what's the justification for the assumption? Edit: At 59:52, another student asks the same question and he misunderstands it again. Sigh.
What a beautiful series of lectures!! Actually I bought the book before discovering the lectures were on line on TH-cam!! As a mathematician, my objective was to get in touch with the Quantum Mechanics and to have a higher level understanding of the underneath models. And I really loved Susskind's way to be so clear and consistent without turning into a 100% formal and axiomatic lecture. BTW, are you aware of any online discussion group or forum about those lectures?
dimensions are perpendicular to one another. So technically we cannot visualize more than three spatial dimensions. We can only "see" the shadows of them projected into our world via tesseracts.
If you have a set of "up" qubits prepared... and then turn the messauring device an angle for a random distribution based on the degree. It means you can DECIDE the outcome depending on the angle, if you turn it up you get more +1 and turn it down get more -1, right? And your choice determines the outcome. Makes you wonder if you can "alter" the reality outcome by how you meassure things. "positive thinking gives positive results" sort of speaking... ?
You're misunderstanding. I mean to say, mathematics isn't "built in" to our everyday experience for the same reason we can talk about ultraviolet light even though we can't see it. Evolution didn't give us a way of "understanding" quantum mechanics since few nontrivial macroscopic quantum mechanical effects happen at the temperatures necessary for life.
was slightly patronising response given he gave away what heads come tails could represent half a minute later haha... Quantum spin States, or any other state really, that could be bound by uncertainty principle but he was introducing the abstract logic with a familiar concept
How do we know that the outcome is random? Is it simply a way of saying that we couldn't find any pattern in it no matter how hard we tried or is there some way to prove that there can be no deterministic algorithm that could be generating the sequence of ups and downs?
I don't think we can but we pick such an interpretation as we are at a limit of being able to observe further. If not random then a pseudo random state that is very perfect in its distribution. We can't really find a way into slicing a particle up to see what its thinking then its for all intents and purposes random. The interpretation is the non empirical philosophy, some metaphysics that allows us to proceed. Like Copenhagen interpretation, and most of them. Although others like bohmian mechanics speculated otherwise, it was other elements that sent it out of favour. We can say its non local as experimental data shows it is illogical to infer local causes. But asking about randomness is ontology, its not really a question that can be answered empirically, no less than asking if free will exists or if god controlled the randomness, its just what would seem to look random and we know we can't look further in detail due to limits of observation. So its a unfalsifiable and beyond asking a physicist the answer to that. It just gives random distributions from many repeated experiments and that is considered elementary state of things.
why would Grandi's series give 1/2 but running this experiment give an average of 0? Is there in correlation between the manipulation of groupings in Grandi's series with the fact that the detector itself is also part of the quantum equation?
11:10 you can not visualize quantum machines, our neural network is trained only for the 3d world we experience. But we can try to use mathematics to describe quantum machines (for nano world
Thank you Leonard Susskind. You are a new hero if mine. I am reintroduced the awe that I felt studying physics in university. I absolutely love having these lectures available. Are there lecture notes available anywhere? I often listen while doing other things, and I'd like to be able to review the notation before moving in.
Okay, I'm a math major and I have very little understanding of QM so forgive this question if it is naive. I just saw the part where the professor measures the qubit, which leaves it in the up position. He then inverts the measuring device by ninety degrees and measures the qubit again. That's around the 40th minute. Here, he says that the measuring device will register an up or down, randomly. My question is this: why? The qubit has been measured; doesn't that take it out of the quantum world?
The reason is the qubit in the pure "up" state is in a mixed state when viewed from (expanded in) the rotated basis corresponding to the rotated measurement apparatus that can only output "left" or "right".
Okay I'm halfway through the lecture and I want to raise my hand and asked a question, what a classical analogous system be as follows, imagine a coin flipping experiment in which any time the coin flipper was fasting in the East-West Direction he would get a random 50/50 coin toss. But if he was facing in the north Direction he might always get heads and if facing south always tails?
One thing which confuses me is that the ket vector, |a>, is written before the bra vector, |a>, giving, "ketbra" and not, "braket". I'm guessing that in some other circumstance the bra actually comes first but for now the use of, "braket" feels backwards.
Interesting. So if we turn the detector to 45 degrees, we would measure a sample of 1's and -1's such that the average of the sample was sqrt(2)/2. How can the average ever be an irrational number? It doesn't seem mathematically possible to get some mean values.
this course on quantum mechanics is good but I found the previous series entitled "Modern Physics- Quantum Mechanics" more helpful, these are not bad though..
He said: Detector in standard position, measurement: +1,+1,+1 etc Then detector rotated 90degress: -1,+1,-1,-1,+1 (averages to zero). Now at this point (right after the final +1) we rotate the detector back to its original position. He said we will get a random result, eg.: -1 Now my question is, if I make another measurement at this point, will I continue to get -1's? I hope so, but he didn't mention.
Say you have the experiment at 51:29, so you have a tilted detector at about 30 degree, then you have cos(30) probability of getting a 1, then you take another detector at about 60 degree and measure the same thing, you have the probability of cos(30)*cos(30) for the final result to be 1, this is different from take a detector with tilted degree of 60 degree, it is higher than that, is it true that you can tilt any vectors to any degree with probability 1?
I'm Back!! The membrane we live in is only a blackhole. Uncertain how many exact galaxies there are because the information has been bent and disarranged through gravitational lensing. This is what I know and believe through M-theory. Be careful what you do at the LHC, it is a very powerful machine. My name is Gordon Nigel Golding and I hope to make history one day, if not today.
hence, no real university courses did that, as they were all based, to some degree, on Feynmanns lectures. Not dissing Dickie boy here by the way, but LS stands on the shoulders of giants and teaches further
I have no diplomas, --> bad student and lack of maturity when I was a teen. Yet I found a thirst for knowledge in my 20s, decided to start from scratch all the science and math. Two years ago I finally reached the confidence to start learning about quantum physics. I bought the book, did the math on paper It's been my only book for two years I never skipped a page until I was fully able to play and understand the mechanics involved. I watched the lectures many Times. And I come here just to say thank you.
Unfortunately I'll never work in physics, I am too old and still without a diploma, I have managed to make a great career in IA and machine learning. To each his own path eh?
Living in this era of knowledge, where you can learn from home, find communities to help you improve, is the greatest gift we have. Stanford and Leonard Susskind I thank you again for making this class available and henceforth contributing to what is the best about the world we live in. I felt, even though this video is old, that a heartfelt comment here was needed.
Thank you again. (a friendly Swiss fellow)
That’s…fascinating..!!}
Complete an high school diploma at least
Wow!
Hey that's really interesting! Do you have some sort of contact details? I'd love to see how you are progressing
I've wanna praise your efforts to get more richer knowledges despite any obstacles You've have been through. Good Job! man!
Lecture 1
0:00:00 to 0:11:35 - Transition from classical to quantum mechanics
0:11:35 to 0:20:00 - The state of a system in classical mechanics
0:20:00 to 1:01:21 - The results of measurements on a qubit
1:01:22 to 1:15:10 - Vector space
1:15:11 to 1:24:12 - Dual of the vector space
1:24:13 to 1:46:31 - Inner products
50:00 cookie break
great
@@Haheat thank you for that pearl
Lies again? Take Meds
Thank you 😊
I'm surprised and pleased that this is online. I bought the Kindle book a few months ago, without knowing there is a set of free online lectures by the author. Thank you to Stanford and Leonard Susskind for making these lectures available.
Yeah, but this is quantum mechanics minimum. The book covered classical mechanics.
My path with the Theoretical Minimum is a bit random: I bought the quantum mechanics book at a whim in a bookstore, but then I first watched the classical mechanics video series, ordered the two other books online, then read the classical mechanics book, then started reading the special relativity book, but after a few chapters switched quantum mechanics book and having read the first third I now started watching this video series…
On the other hand, I studied all this stuff at university, so it's familiar, but it was over ten years ago and I've forgotten a lot.
Christopher Plessinger there is a book for quantum mechanics too
Santa is that you?
@@paddymcdoogle6753 Of course, my child, it is me.
I have no clue what any of this means but for some reason I’m fascinated by hearing him talk so I’ve nearly finished the whole thing
Same here
Keep trying to hear and you shall hear. For your effort i say, “
Good Job.”
At least you stayed
Why no share button?
Dom great channel my friend, keep listening that's where I started and now I am learning more science/physics than I ever did in school
Tks Stanford, what a privilege to listen to this. And Susskind is an amazing teacher. I'm blown away by getting a glimpse into the theoretical minimum which I knew little or nothing about.
He really is and it takes one to know one. I totally disagreed with the final outcome of the black hole wars so I had to eat a lot of crow when i finally understood it. Totally worth it to have an insight into string theory.
He is actually quite a knowledgeable man, Leonard Susskind.
I can grasp Plato's 'Wax Tablet Hypothesis', Aristotle's 'Theory of Everything' and Goethe's 'Theory of Colours' but these lectures are beyond me.
Cheers - Mike.
NOTES:
Systems have states
A set of states can include subsets
Inclusive (union) and exclusive (intersection) propositions can be made
The space of the states of a system in QM doesn't follow the set logic
It's a vector space
An apparatus detects the status of Q-bit that like a coin (with H and T) could be in two states , 1 for pointing up or -1 for down, only one of them at any given time
Both the apparatus and the Q-bit have a sense of direction of their own
The directions of the apparatus and Q-bit in relation to one another, determines and changes the probability of the results
Observing the system once prepares the result and will give you the same answer until the detector has been turned off and on again,
If the internal vector of the apparatus lies in the same axis as the Q-bits we get the same answer over and over again, which is its component, meaning if we rotate the apparatus 180 deg, we get -1 in which the negative sign indicates the opposite direction
Also even when we start with the apparatus on it's side (internal vector and Q-bit are in different axes) results are the same as long as the system is not disturbed.
However 90 deg rotation of the apparatus around any axis makes the results random with probability of 50% for each, averaging at 0
Results of an angled apparatus are also random but they average in the component of the initial axis along the rotated internal vector (Cos of the angle apparatus makes with its initial axis)
Mathematical vector space contains objects that aren't ordinary
Vector space is a collection of mathematical objects
In the vector space numbers are one dimensional and complex numbers are two dimensional
Vector a is written as: |a>
You can add vectors: |a>+|b>=|c>
Vectors could be multiplied with complex numbers in the complex vector space: z|a> = |a'>
Vector's components are represented in the form of columns in brackets
Addition: n'th row of one column adds to the n'th of the other
Multiplication: the number is multiplied with all of the rows in the column
Complex conjugate vector that has a one to one correspondence with its elements
Complex conjugate vectors lies in complex conjugate vector space
Duel of a vector sum is the sum of their individual duels
Duel of a vector |a> multiplied with a complex number z is )
= = α1. β1* + α2. β2*
= = α1*. β1 + α2*. β2
Using postulate (1) must be true that: = * which means it's always real (its imaginary component is zero so the conjugate doesn't change it) and always positive (the real part is being multiplied by itself), resulting in the square of the vector's length (using Pythagorean theorem) T
= * = α1.α1* + α2. α2*
The orthogonality causes the inner product to be zero (because: cos 90 deg=0)
Maximum number of mutually perpendicular non-zero vectors in a space determines the dimension of it
good stuff, the ones I took are similar as well
you are legend
Special thanks goes to camera operator, who predicts all the movements not even causing a real headache.
yeah, i would love to see the setup that was done to record this!
and to the sound person too!
I think it is a system guided camera called lecture tracker camera, equipped with sound systems that activate or deactivate mics across the room
I agree, this was really well filmed.
Pretty sure it’s an AI.
I really enjoy Susskind's lecture because even as a practitioner and expert, I like how he gets to the heart of the physical idea and it is wonderful that he is taking the time and effort to educate in this venue for continuing education.
I can't say Thank You enough. It's been a year since I started with this course and now I am learning to apply all of this in my Quantum Computing course. To whomever this concerns: the explanations and tricks (not really) that you're gonna learn here will stay with you your whole life. Its THAT clear. Thank You Professor Susskind and Stanford University for this. ALWAYS and FOREVER.
@5:14 what an awesome sermon. I am loving these lectures. I am pissed that, in my far reaches of the world, this exposure and influence has been denied me via my class, cast, socio-econ, and generational & physical demographic. More knowledge. more brains. I am hungry to intuitively know more. I love Educaton X Generation :D Thank you Stanford and Prof+Team
I'm in college rightnow to learn about business, but I'm just doing this in order to become financially independent so that I may afford to learn about quantum physics, and get to solve our greatest mysteries and problems. Science is what I am truly fasinated about! I'm so exstatic to know that I live in an age where I can learn this information from the small technology in my hand. Thank you for posting this lecture!
Hey bro , would like to know whats up with your physics jopurney?
I'm so happy this is online. He is a great teacher - simplifying as much as possible. Visuals help immensely.
Leonard Susskind lectures help me fall asleep late at night.
Leonard Susskind is A living Legend, you know as students we call "legends" the great or greatest teachers...
Well, he is 81 years of age now... so don't expect too much teaching from him.
I take that back! Surprise... he is still teaching "PHYSICS 361: Cosmology and Extragalactic Astrophysics". Cool!
the thing I love about these lectures is that he starts with the fundamental concepts, then illustrates how the theories differ, at that fundamental level. IMO, Feynmann didn't really do that...
this guy is a legend.
One of the greatest men alive. Without a fringe of doubt!
Sir Leonard suskind wait for me for some years. I will definitely meet you in Stanford. I am currently at 7th. :)
Good luck!
He is quite spry. He moves like a much younger man. Lord willing he will be there when you arrive.
I agree ErnestYAlumni. I also enjoyProf. Susskind's dry humour like the bit where he says in answer to a question at about 54:50 "They might have got the Qbits from a Qbit store!" . . . humour helps the process of learning. ;-)
Finally, they started to treat vectors as functions. Functions are vectors because then can be added together and scaled. But, functions are also vectors of single variable. The argument is called "index" or "coordinate" in the vector space. Vector a=[a0,a1,a2] is a map a(0)=>a0, a(a)=>a1 and a(x)=>a_x in general. This is a function of single variable. Vectors are just discrete functions in the narrow view.
That's a good explanation! Thanks!
So happy that person in the audience mentioned the collapsing of a wave function, because that was the moment all of this made sense to me
Hey, sorry for the late reply.
The reason you don't hear much about fractals in a class about quantum mechanics is because the quantization of matter prevents true fractals from existing. Approximate fractals appear on cosmological scales through microscopic scales, but eventually there's a fundamental limit, so for example a coastline is not actually infinite. A better place to look for fractal theory would be a course on complex variables or chaos theory, graphics design or fracture mechanics.
This lecture is great. The professor is obviously starting from baby steps to demonstrate the foundation of quantum mechanical statistics, but some of his students are either bored or want to show off their "advanced" knowledge. Actually, this is very similar, if not identical, to Dirac's experiment and treatise on a 45 degree polarizer sandwiched between two polarizers oriented at 90 degrees to each other. Very beautifully prepared lecture.
Thnks Stanford and Mr Susskind, his teaching is gold, i guess he learned a lot from mr Feynmann :P
I love that Lenny is so old-school that no matter how white the white board is, he still calls it a "blackboard."
The 'black' in blackboard does not mean the black colour any longer. A blackboard, whatever its colour, always is a blackboard.
Or do you think an atz has to be made of stone just because, since millenia ago, atz means stone?
@@wafikiri_ That may be true but a white board is still called a white board and not a black board
He doesn't see color 😉
its not a blackboard, it is a quantum object that your evolutionary structure cannot conceive, so you label it a blackboard, it is both a blackboard and a white board at the same time, it depends on the observer to determine which. 50% of people believe it to be a white board and 50% a blackboard. Although if it is rotated too exactly 45 degrees, the number suddenly spikes to 85% of people bellowing it is one of these but then returns to 50/50 outside that angle.
Lenny? I thought his name was Mike... :)
Stanford's reputation is reproved by you!
What cookies does he use to eat? I want them.
Somebody asking the right questions.
chocholate chip
Its actually scone. He told that in one of his previous lectures of Classical Mechanics
Thanks so much prof. Susskind as a student and undegraduate in architecture I appreciate . Thanks.
Bought the book and felt it was a bit too rushed, I wanted to expand more on the maths behind it so I went online to search for further explanations and turns out his lectures are all available on youtube! Thanks for providing these videos to the internet.
Do you think the book adds any more value over these lecture? I'm contemplating buying the book but if it's just a transcript of these lectures, it may be a waste
I strongly agree with his assertion that the abstract intuitions and math are extremely powerful and important to develop. I disagree that that higher dimensional visualization (or lower) are impossible or useless. He is right that most people don't correctly visualize what two or 1 dimension are like though they think they are. The story of flat land is a good place to start.
Thank you Stanford for this guy's lectures ❤️❤️❤️
Dr Susskind is amazingly accessible. I read his "Black Hole War" and found it quite an enjoyable read despite being concerned with physics that are way above my pay grade.
@Abdullah Naeem, The answer is no it doesn't take it out of the quantum world. Or rather, you are only out of the quantum world about that specific axis. If you know the spin around one axis you have maximal uncertainty (i.e. a 50-50 chance of either result) about its spin around an orthogonal axis. That's quantum mechanics. It should become more clear as the lectures go on and he covers more of the mathematics describing this weird situation.
I can visualize five dimensional space time.., but don't you Dare ask me what I was doing when I saw it.
✅
Yes, the q-bit doesn't have to "reset" at a specific angle to come up with the same ratios... I feel like he keeps it that way because it will uphold the integrity of the experiments being "wiped clean" with every new q-bit.
I don't know what he is saying sometimes, but I love his voice.
Every second of this lecture reminds me how important Feynman's learning technique is.
What a great professor. Literally feeling this rn. I detect that kid is a brat! I'll leave it at that. So grateful for these free lessons!
"What does heads and tails have to do with it? What's the purpose of using heads or tails?"
Interruptions of this nature make my blood boil.
+Jo Do It's a continuation on the previous lecture series where they talked about it as an example for laws of Physics.
+Jo Do hahaha people are actually answering your question.
Jo Do dude I don't get how someone that would ask such a question got into Stanford university
Jo Do mr. perfection
They aren't students of Stanford. Well, for the most part.
Definition: What is the dimension of a vector space? The max number of orthogonal vectors you can find in the space 1:38:21
You know shit's getting serious when Paul Dirac comes back from beyond the grave to set things straight.
Hello friends- My daughter, in 2nd year of university, gave me The Theoretical Minimum for Christmas, as she knows I appreciate the thought experiments around physics, and can hang in there during a discussion. However, when reading this text, and watching these inspiring videos, I am lost. I can kinda follow, but feel there are some foundations I am missing (I am 62, and I believe I was stoned during an essential class in high school, double entendre). What do you suggest I study/watch/practice to get up to some semblance of understanding to continue this text and lecture? I am willing to put in some time.
a flipped coin is a process that is in motion or not. It is on the edge when in motion and on either side when not. The universe is organized in sets of three gravity medium dimension sets with an observer in the middle. The set of three straddles a force set of four. Both form a process of 12 parts every three cycles. The minimum value of each, is a non event and can only exist within the other as an opposite value, in the opposite direction.
these students....he spent so much time trying to get 2 simple ideas across to them...holy hell. this lecture couldve been 1/3 as long and i wouldve got just as much! sheesh! i cant get enough of these! (the lectures, not the students)
It's much easier to understand stuff behind a screen than irl at least for me
way easier to get stuff when you can pause mate.
From the course website:
January 9, 2012
Professor Susskind opens the course by describing the non-intuitive nature of quantum mechanics. With the discovery of quantum mechanics, the fundamental laws of physics moved into a realm that defies human intuition or visualization. Quantum mechanics can only be understood deeply by studying the abstract mathematics that describe it.
Professor Susskind then moves on to describe how the space of states for quantum mechanics, and the rules for updating those states, are fundamentally different from those of classical mechanics. For quantum mechanics, the space of states is a vector space versus a set of states for classical mechanics. He then then describes the basic mathematics of vector spaces.
Topics:
The non-intuitive logic of quantum mechanics
Vector spaces
Rules for updating states
Quantum preparation and measurement are the same operation
Mathematics of abstract vector spaces
References
Quantum mechanics
Vector space
You don't have to believe every bullshit they put out at Stanford. Quantum mechanics is actually quite easy to understand if you aren't falling into the usual traps. Unfortunately for you, the way Susskind teaches the topic, you will.
@@schmetterling4477 who teaches it better? What are the usual traps?
@@redsix5165 The usual traps are mistaking quanta for particles and the single system for the quantum mechanical ensemble. Not knowing that non-relativistic quantum mechanics is not a self-consistent theory. It's not even physical. Not having a background in atomic physics, not knowing enough (or anything at all) about special relativity. That kind of stuff.
Some teach better than others. The best I have seen is Alan Adams from MIT, but even he misses the mark on many of these topics.
Let's imagine the grid structure of Planck pixels (plixels) and how they interact with vectors representing the changing states of hawking radiation over Planck time. We can explore how these vectors, characterized by the cosine of the angle (θ), relate to the speed of light and describe acceleration, which in turn corresponds to gravity.
In QIH, the grid structure of plixels represents the fundamental fabric of spacetime at the Planck scale. Each plixel acts as a discrete unit, contributing to the overall information processing and entanglement within the holographic framework.
Now, let's consider the vectors that represent the changing states of hawking radiation over Planck time. These vectors describe the properties of the emitted radiation, such as its energy, momentum, and direction. The cosine of the angle (θ) associated with these vectors represents the percentage of the speed of light contained within the hawking radiation.
As the angle (θ) changes over successive moments, new hawking radiation is emitted, reflecting the evolving quantum state of the system. This changing angle and the subsequent emission of radiation correspond to acceleration within the QIH framework. Acceleration can be seen as a manifestation of the altering quantum states and entanglement patterns between the plixels and the emitted hawking radiation.
In the context of the equivalence between acceleration and gravity, this changing angle and the resulting emission of hawking radiation can be understood as gravitational effects within the QIH framework. The modulation of quantum states and the interaction between the plixels and the emitted radiation encode the gravitational behavior, thereby linking acceleration, hawking radiation, and gravity.
Through the lens of QIH, this perspective allows us to explore how the grid structure of plixels, the changing angles of hawking radiation, and their associated acceleration can provide insights into the interplay between quantum information, spacetime, and the gravitational phenomena. It offers a framework for understanding how gravity emerges from the quantum information processing occurring within the holographic structure of spacetime.
1:35:12 inner product of the vector with itself is the square of its length. It is a Real number and positive
My last math class was about 20 years ago. Understood all of lecture one, now I boldly go to lecture two :D
To infinity and beyond 🎉
or in other words: the degree by which i rotated the aparatus after a measurement defines the likelyhood to get the same measurement at the second measurement of the same quark?
so at the third measurement, the outcome of the first measurement has no impact on the result whatsoever anymore? but the outcome of the second measurement has a decisive impact on the probability?
this is soo cool!
Who explained dimensions " Expanse of left and right, above and below, ahead and behind, before and after, good and evil" ?
SUSSKIND = LEGEND!
@ganeshie8 No. Once you get a value for some orientation of the apparatus, you will consistently get the same value while measuring the same system with the same orientation. You have just collapsed its wave function. Until a measurement has collapsed the wave function, the actual orientation of the system doesn't make much sense in QM. You just have the probabilities for each result for the different orientation angles (that's the wave function or the state vector). That's all there is to it.
I can't get over how much this professor looks like Mike from Breaking Bad.
It isn't. You couldn't do linear algebra in preschool, but you could see 3-D space. N dimensional space is abstract maths once N is 4 or greater.
Jesus, people - they aren’t Stanford students (nor even physics students, to boot). Prof. Susskind gave these lectures to members of the community who wanted to learn more about the subject. Same is true for just about all of his Stanford-sponsored lectures on YT, to my knowledge.
I read the book, Quantum Mechanics(The Theoretical Min). Your book was specular parts, matrix math.... Thank you...
Republic of Korea
Thank you Pr. Susskind, Stanford ! As crazy French say: "Chapeau bas, M. Susskind" !!
Non-quantitative-number-numeral symbol hyphen, - , concatenated with quantiative-number-numeral one, 1, doesn't result in something from either category and therefore, is excluded from a vector : something with magnitude and direction, space by definition.
The student at 57:28 asked a question that I don't think Professor Susskind quite understood. To put the question another way, if we assumed the system could be any orientation, not just up or down, we would still get the same results because the detector is only capable of giving a binary answer: The binary nature of the system's states is assumed rather than demonstrated; so what's the justification for the assumption?
Edit: At 59:52, another student asks the same question and he misunderstands it again. Sigh.
What a beautiful series of lectures!! Actually I bought the book before discovering the lectures were on line on TH-cam!!
As a mathematician, my objective was to get in touch with the Quantum Mechanics and to have a higher level understanding of the underneath models.
And I really loved Susskind's way to be so clear and consistent without turning into a 100% formal and axiomatic lecture.
BTW, are you aware of any online discussion group or forum about those lectures?
dimensions are perpendicular to one another. So technically we cannot visualize more than three spatial dimensions. We can only "see" the shadows of them projected into our world via tesseracts.
If you have a set of "up" qubits prepared... and then turn the messauring device an angle for a random distribution based on the degree. It means you can DECIDE the outcome depending on the angle, if you turn it up you get more +1 and turn it down get more -1, right? And your choice determines the outcome. Makes you wonder if you can "alter" the reality outcome by how you meassure things. "positive thinking gives positive results" sort of speaking... ?
You're misunderstanding. I mean to say, mathematics isn't "built in" to our everyday experience for the same reason we can talk about ultraviolet light even though we can't see it. Evolution didn't give us a way of "understanding" quantum mechanics since few nontrivial macroscopic quantum mechanical effects happen at the temperatures necessary for life.
Have you seen the Susskind's lecture? Why you cannot visualize dimensions other than 3? Which tools have you developed to be not able to do that?
Both upper and lower case are valid depending on the frame of reference of the observer.
I was so spooked when the guy asked a question at 30:00
was slightly patronising response given he gave away what heads come tails could represent half a minute later haha... Quantum spin States, or any other state really, that could be bound by uncertainty principle but he was introducing the abstract logic with a familiar concept
I didn't know lord Tywin was a Physics professor.
He is like a fusion of tywin and mike from breaking bad
I was thinking John Malkovich.
1:03:51 quantum system space is vector space: a collection of vectors
What a great fucking gift to humanity. Thank you Stanford and Mr. Susskind.
Right, I purchased it. I think it's the best calculus intro I've ever read.
Does anyone have the notes he talks about in these videos? I can't find them on the internet
How do we know that the outcome is random? Is it simply a way of saying that we couldn't find any pattern in it no matter how hard we tried or is there some way to prove that there can be no deterministic algorithm that could be generating the sequence of ups and downs?
I don't think we can but we pick such an interpretation as we are at a limit of being able to observe further. If not random then a pseudo random state that is very perfect in its distribution. We can't really find a way into slicing a particle up to see what its thinking then its for all intents and purposes random. The interpretation is the non empirical philosophy, some metaphysics that allows us to proceed. Like Copenhagen interpretation, and most of them. Although others like bohmian mechanics speculated otherwise, it was other elements that sent it out of favour. We can say its non local as experimental data shows it is illogical to infer local causes. But asking about randomness is ontology, its not really a question that can be answered empirically, no less than asking if free will exists or if god controlled the randomness, its just what would seem to look random and we know we can't look further in detail due to limits of observation. So its a unfalsifiable and beyond asking a physicist the answer to that. It just gives random distributions from many repeated experiments and that is considered elementary state of things.
When the apparatus is upside down, does the -1 mean that it's pointing opposite to the direction of the apparatus ? Which means it's pointing up.
why would Grandi's series give 1/2 but running this experiment give an average of 0? Is there in correlation between the manipulation of groupings in Grandi's series with the fact that the detector itself is also part of the quantum equation?
Adding components of different nature into the same three dimensional space does not enable you to visualize more dimensions than 3 spacial dimension.
11:10 you can not visualize quantum machines, our neural network is trained only for the 3d world we experience. But we can try to use mathematics to describe quantum machines (for nano world
Thank you Leonard Susskind. You are a new hero if mine. I am reintroduced the awe that I felt studying physics in university. I absolutely love having these lectures available. Are there lecture notes available anywhere? I often listen while doing other things, and I'd like to be able to review the notation before moving in.
I think he has a book he wrote with all the lecture summaries written in it :)
Okay, I'm a math major and I have very little understanding of QM so forgive this question if it is naive. I just saw the part where the professor measures the qubit, which leaves it in the up position. He then inverts the measuring device by ninety degrees and measures the qubit again. That's around the 40th minute. Here, he says that the measuring device will register an up or down, randomly. My question is this: why? The qubit has been measured; doesn't that take it out of the quantum world?
The reason is the qubit in the pure "up" state is in a mixed state when viewed from (expanded in) the rotated basis corresponding to the rotated measurement apparatus that can only output "left" or "right".
at 36.57: when detector is turned 90 degree; how come it records +1, when horizontal component is zero??
Thank you, Stanford and Susskind
Okay I'm halfway through the lecture and I want to raise my hand and asked a question, what a classical analogous system be as follows, imagine a coin flipping experiment in which any time the coin flipper was fasting in the East-West Direction he would get a random 50/50 coin toss. But if he was facing in the north Direction he might always get heads and if facing south always tails?
It might be obvious that I'm not a physics student, but in the universe, are there any truly closed systems given the affect of things like gravity?
This is what the internet is meant for
One thing which confuses me is that the ket vector, |a>, is written before the bra vector, |a>, giving, "ketbra" and not, "braket". I'm guessing that in some other circumstance the bra actually comes first but for now the use of, "braket" feels backwards.
Interesting. So if we turn the detector to 45 degrees, we would measure a sample of 1's and -1's such that the average of the sample was sqrt(2)/2. How can the average ever be an irrational number? It doesn't seem mathematically possible to get some mean values.
look like the dentist of Mr bean
this course on quantum mechanics is good but I found the previous series entitled "Modern Physics- Quantum Mechanics" more helpful, these are not bad though..
stanford,thank you very much for this free knowledge
I love the way Lenny explains the physical phenomena as if he explains to a man in the street.
Lenny? Do you know him?
@@jamesanthony5681 I know him as much as you don't know me.
@@halilibrahimcetin9448 Because you called him by his first name I thought you knew him.
where do i submit my essay on e=mc^2. i am thinking about linking it here, but i haven't started on the paper.
Does this mean im getting a Sanford education
He said:
Detector in standard position, measurement:
+1,+1,+1 etc
Then detector rotated 90degress:
-1,+1,-1,-1,+1
(averages to zero). Now at this point (right after the final +1) we rotate the detector back to its original position. He said we will get a random result, eg.:
-1
Now my question is, if I make another measurement at this point, will I continue to get -1's? I hope so, but he didn't mention.
+kotozna yes you will. You will always get the same result if you don't rotate the detector between measurements.
+Alex Ryzhov clear answer
Say you have the experiment at 51:29, so you have a tilted detector at about 30 degree, then you have cos(30) probability of getting a 1, then you take another detector at about 60 degree and measure the same thing, you have the probability of cos(30)*cos(30) for the final result to be 1, this is different from take a detector with tilted degree of 60 degree, it is higher than that, is it true that you can tilt any vectors to any degree with probability 1?
How comforting that even the smartest people can't visualize more than 3 dimensions. I always felt stupid.
I fell asleep listening to a podcast and I’m here now
Be happening to Me too
I'm Back!! The membrane we live in is only a blackhole. Uncertain how many exact galaxies there are because the information has been bent and disarranged through gravitational lensing. This is what I know and believe through M-theory. Be careful what you do at the LHC, it is a very powerful machine. My name is Gordon Nigel Golding and I hope to make history one day, if not today.
hence, no real university courses did that, as they were all based, to some degree, on Feynmanns lectures. Not dissing Dickie boy here by the way, but LS stands on the shoulders of giants and teaches further
I wish this lecture had existed when I was studying physics.
same man,
When you take the second deterctor, you have perturbed the system...so you will get the randomness again....
Are these lectures are same as his other lecture series named "modern physics quantum mechanics "