10:32 "Free real estate" Awesome video btw!!

For those who had to google what null space is (like me), here's a quick refresher: It is defined as the set of all vectors x that satisfy the equation Ax = 0, where A is a given matrix. Here are some key points about the null space: - The null space contains all solutions to the homogeneous system of linear equations represented by Ax = 0. - It forms a vector space, meaning it is closed under both addition and scalar multiplication. - The null space of a matrix A is a subspace of R^n, where n is the number of columns in A. - If the only solution to Ax = 0 is x = 0, the null space consists of the zero vector alone. This subspace, {0}, is called the trivial subspace. - The null space can provide insights into the properties of the matrix and the system of equations it represents.

No professor of my university was able to explain properly how to determine the eigenvectors. They were just computing the end result and never explained how they came up with this result. Thank you very much, you are a genius.

Dear Khan, You da real MVP.

Great explanation. Now that I have got the theory down, I will somehow need to figure out how to translate all that into Python code 😄.

wow thanks im from university of cape town,i had a problem in reducing ..now im mastering this! you're the real hero!

It could be either (A - lambda*I)v=0 or (lambda*I - A)v=0 . The two are the same, just differing by a multiple of (-1). Because (-1) is a constant, it can multiply into the parentheses and flip the expression inside, leaving the equation unchanged.

The real estate part really helped me out!

Thank you, my lecturer sucks. You made something he made complicated easy again.

Could you possibly do a video of why I am hearing this terminology in my Differential Equations Class?

Thank you - You pushed my Math AND English skill through the roof - Funny that the German word: Eigenvector became a "special" word (It could have been just be translated to "own - vector") =)

Thanks to you I'm going to be able to pass my class.... Thank you soooooo much ;)

I came from precalc, listened to the first minute, and barfed THANK GOD FOR KHAN ACADEMY

Thank you so much!!! This helped me on a problem I was stuck on forever!

Should have put emphasis on v3 being the free variable (row not containing a leading 1) which is why you chose v3=t. other than that very clear explanation!

if i had a nickel for every lab this guys helped me with id have 2 nickels

Oh wow, was stressing about the last step in finding the Eigenvalues but this made it incredibly clear, thanks a lot :)

YOU ARE THE BEST!!! :D You just cleared all the questions I sent to my professor 3 hours ago in 30 minutes ahah!!!.. YOU ARE THE BEST :D

It'd be cool if I had a professor who who any of this stuff.

Sal I'd really enjoy it if the example you made wasn't of nullity 2, as a full matrix probably would've helped me more.

I'll have an exam this morning and you ARE a lot of help. Thank you veeeery much!

Excellent, bad explanation at college, thank you so much for your video!

u just pulled so many knots in my brain

I should had come here earlier, so many tutorials, they avoided taking a 3x3 matrix or explain in detail what's happening, like it is a big deal to work on 2x2 matrix. Thanks a lot! I am sad to say but once again is proven that internet is full of bad quality job (tutorials)!

much better than my books! thanks a lot

@khanacademy I'm looking at my book now, shouldn't the eigenvalue solutions be derived from the equation: det ( A - [lambda] I) = 0 ? @1:50, I can see the equation from which the eigenvalues are derived from as: ([lambda] I - A) V =0 , which is the reverse. The book says to "find the null space of the matrix A - [lambda]I. This is the eigenspace E_lambda, the nonzero vectors of which are the eigenvectors of A..." The book is: "Linear Algebra: A Modern Introduction", 3rd E, Poole, p303

Because elementary row operations change the value of the determinant, so you'd have to "undo" them again anyway; might as well only do them once.

His explanations are pretty clear though he's a little disorded . Very good overall!!

thank u vry mch............nw i feel so gud for the eigen vectors....although i watchd ur video jst before a dy of my EXAM :-)

When finding the eigenvectors, do we really have to do gaussian elimination and reduce one of the rows to all 0's? Because I sometimes I have different results than the book provides.

Jazak allah

8:07 what in the fuq. Bruh. LMAOOO

my exam is good now !!

you saved me on my final last spring.

Thank you! Very clear and comprehensible.

GREAT!!! Really clear and helpful!!!!!!

@unkown1414 totally agree must be tablets man, he's too precise

All respect to your effort man ....wish that all the world is like you :)

Thanks Sal!

What happens if when you row reduce your matrix you get a zero column, how can you find the eigenvectors.

so eigen vectors and eigen space is the same thing?

hi can i ask if it is necessary to reduce the matrix?

you my respected mare r an absolute legend..!SAVIOUR

thanks god..!! you are great!!!

Isn't it |A - (lambda)(I)| -> [determinant of {A minus (lambda x Identity matrix)}]?

I thought for every NxN matrix you have a character polynomial to the Nth degree with N number of eigenvalues that correspond with the same N number of eigenvectors. So wouldnt you need 3 eigenvalues that have 3 eigenvectors each for this example?

is E-3 perpendicular to E3. both span of E-3 is perpendicular to each other, but E3 is not perpendicular to both. this is my thinking. please​ explain me.

Thank you this clear many pictures for me :)

thank you very much

Is it because we have free variables, we don't need to normalize it? Thank you

thank you! my teacher aint got nothin on you

Hallelujah! PRAISE THE LORD!

also why have you overcomplicated the eigenvector for eigenvalue=3? what’s wrong with (1,1,1)

What happens when the reduced row echelon form of a 3 x 3 is

How do i find the eigenvector if when I reduce the nullspace I get the vector [100, 010, 001] instead of [100,010,000]?

thank you

where can I find electricity and magnetism videos which would explain everything just like this.

@ashk0n also eigenmatrices have many applications to number theories aka that if the dominant singular valueso f a matrix P is greater than the dimension of any other matrix then the supremem of P times Q is always equal to the eigenvalues of something

@MartinRyleOShea if the det(A - lambda*identity) = 0 then lambda is an eigenvalue of A.

This is a strange method for solving for the nullspace. It looks like you're arbitrarily picking either v1, v2, or v3 to be equal to 1t. You should specify that v3=1 because it is a pivot variable.

can you explain why it is (lambda I - A) V = A instead of (A - lambda I) v = 0

I LOVE METH!!!!!.....i mean MATH!!!!

you choose v3= t out of free choice! but if i choose v2=t my vector will be completely different. or can the "t" adjust the vector? does it even make a difference? this is the only thing stopping me from understand this subject i math! i understand how to work with it, but i dont understand the outcome!!

YES

don’t understand why you use row reduction when it really isn’t necessary, the eigenvectors are obvious just from looking at A-lamda x identity

totally saving my ass for my exam tomorrow.

Thanks for your useful videos. But can you please get a new microphone the noise sometimes makes it hard to follow the video all the way

The real superman!

Um I don't think you got this right. An eigenvector is not a basis of a subspace. It is a collection of eigenvalues that are spread out from eachother. For example, if the eigvenvalues for a matrix A are 1 and 3, then the eigenspace is 3+1 = 4. The same is true for complex eigenvalues and their corresponding eigenspaces.

this guy is definitely jesus. i mean, his voice doesn't sound exactly like what you'd expect it to, but still, he must be jesus. he has come back to help us with maths!

he's a teacher. he has like 6 degrees, just look him up on wikipedia

Is it just me or is there an actual mistake in the calculations of the rows for the second eigenvector? The second row: -2-(-2)= 0 -5-(-2)= -3 1-(-2)= 3, and not -3 similarly in the third row: -2-(-2)= 0 1-(-2)= 3, and not -3 -5-(-2)= -3, and not 3

Lets just change colours for fun :D

I have a matrix A = {{7,-5,0},{-5,7,0},{0,0,-6}} I have found the Eigenvalues, 2,12,-6 but I'm only getting one Eigenvector, (0,0,1).. Can someone please help?

the gods have answered...

This explanation is not generalizable. Lets say R1 has 1 for X_3. What do you do then? I'm just assuming, which means I get it wrong on the homework and test and it takes me longer to do my homework. You need to explain the edge cases better. Thanks.

eigenkosommak

v1+v3=0 v2=0

I love you.

Not as good as your other videos in the same area.

I love you

didnt understand

I love you

Is this all the same guy? He teaches the Org Chem too. Is this guy just a professor by hobby?

LOL

"V2 is equal to... I'm just gonna put some random number" random number: *A*

Thank You