CHATLAB and Talktave

education in vancouver(or at least where I lived) wasn't too good in comparison... I went to middle school in the valley not knowing what a quadratic equation was

and everyone ridiculed me - that was kind of when I started doubling up on STEM stuff

rayryeng

That's how you spell it!

ohhh... really? Are we that far behind in our education system?

8th grade was when I learned the quadratic equation. Standards must be getting worse.

OneRaynyDay

@rayryeng oh pheww, still proud to be canadian haha

I think it's because, in vancouver

Things don't start to ramp up until IB classes

Also for some reason in my highschool/secondary, we learned math for only half a year

every class was half a year long. It was so strange

rayryeng

2:59 AM

@OneRaynyDay what? that's so weird!

OneRaynyDay

3:15 AM

@rayryeng yeah... Its name was Semiahmoo, which is a weird name too haha

rayryeng

oook then lol

BTW, I'm taking two coursera courses or about to... now that we're on the topic

Audio Signal Processing for Music Applications and Mining Massive Datasets.

The second course is a natural extension to machine learning that I've always wanted to learn. How do you deal with big data right?

The first course is because of pure interest. I have the signal processing background, but I'd like to see where sound comes into play.

OneRaynyDay

@rayryeng Audio Signal Processing?

That sounds interesting!

and also, mining massive datasets... what kind of datasets? Will you be learning R? I heard that language is one of the highest level languages out there :)

rayryeng

I know some R. Dealt with it in the past.

I actually don't know what language it will be... the course description was very vague lol

If it's R that would be great. I'd like a revamp on it

OneRaynyDay

ah I see. I read in the machine learning course's FAQ

"Why don't we use R?"

"Because everything is already implemented in R. You don't need to perform any tasks"

something along those lines haha

rayryeng

hahahah

well technically the Statistics Toolbox in MATLAB also has everything implemented too.

I find R's syntax cryptic though

I could never get used to it

OneRaynyDay

3:27 AM

ahh I see... never used R

but my mom who's also a programmer

dragged me to a big data seminar when I was like.. in 10th grade

and they were preaching like evangelists about R

Like "THIS IS GOING TO BE THE NEXT BIG THING GUYS"

Which I think is probably somewhat accurate :)

hθ(x)=θ0+θ1x
We give to hθ values for θ0 and θ1 to get our output 'y'. In other words, we are trying to create a function called hθ that is able to reliably map our input data (the x's) to our output data (the y's).

Example:

x (input)	y (output)
0	4
1	7
2	7
3	8
Now we can make a random guess about our hθ function: θ0=2 and θ1=2. The hypothesis function becomes hθ(x)=2+2x.

So for input of 1 to our hypothesis, y will be 4. This is off by 3.

Just a quick question, Why does it say it's "off by 3" ?

Shouldn't it be off by two... if hθ = 2 + 2x, and x = 0... 4-2 = 2...

so it should be off by 2 right... these mistakes make me think so unnecessarily hard at these problems haha

rayryeng

Because the expected value of y when x=1 is 7, but your proposed model gives you 4.

it's off by 3 because 7 - 4 = 3.

OneRaynyDay

Oh. derp, I totally read that as x = 0

Sorry, that was a dumb mistake haha

rayryeng

no worries :)

R is used by statisticians. I prefer to stay away from it and use MATLAB

or Octave.

OneRaynyDay

ahh okay. Can R be used to write an OOP program? or scriptbased?

rayryeng

Yes you can certainly use it to make classes.

I've only briefly looked at it but I've never written classes for it

OneRaynyDay

3:33 AM

ahh okay. Interesting :o I don't think I'll be touching it for a while though

rayryeng

ah if you don't, you won't miss it :)

OneRaynyDay

yeah haha

One second, getting out a notepad and doing some gradient descent derivations

rayryeng

oh :)

This Mathematics SE post may help

31

Q: Partial derivative in gradient descent for two variables

I've started taking an online machine learning class, and the first learning algorithm that we are going to be using is a form of linear regression using gradient descent. I don't have much of a background in high level math, but here is what I understand so far. Given $m$ number of items in our...

calculus

OneRaynyDay

ahh thanks for the link!

I think I'm going to try and discover this part out a bit by myself first though :) I always learn better when I write things down

rayryeng

yup, that's there if you want it. But yes, always good to derive it yourself.

OneRaynyDay

3:42 AM

yupyup :) Hmm.. only thing is I'm not sure whether to derive from θ0 or θ1

rayryeng

gradient descent optimizes each parameter independently.

so you do derivatives with respect to each variable separately while leaving the other constants.

OneRaynyDay

ah.. So one dJ/dθ0 and the other dJ/dθ1, leaving θ1 and θ0 constant respectively

gotcha

rayryeng

Correct. That's how partial derivatives work

differentiate with respect to the variable you want, leaving the other ones constant.

So for example, supposing we had a three variable function: F(x,y,z) = xyz

doing dF/dx gives us yz

doing dF/dy gives us xz

and you can guess what dF/dz is.

OneRaynyDay

haha xy

I remember a bit of this :) Thanks for the refresher!

rayryeng

haha sure :)

OneRaynyDay

3:45 AM

oh crap, I'll have to be back in maybe an hour :o I forgot to do something

this class was too interesting to stop LOL

Alright I'll be back! talk to you later!

rayryeng

no worries! ttyl

OneRaynyDay

5:20 AM

@rayryeng hey, back! :)

I went to workout at the local YMCA, got a schedule but forgot to go haha

Plus side on going late is I see different people, including a cute girl ;)

rayryeng

6:01 AM

hahaha sweet.

OneRaynyDay

yeah haha, I'm reading over the linear algebra "refresher" for the machine learning coursera page

hey by the way, I have no idea what a pseudo-inverse is in linear algebra, what's the difference between that and inverse? :/

rayryeng

The inverse only exists for square matrices.

OneRaynyDay

@rayryeng oh, if I don't reply, I'll most likely be in the shower

rayryeng

Pseudo-inverse is used in the context of least-squares minimizatoin.

OneRaynyDay

Right - so it's a way to compensate for non-square matrix right

rayryeng

6:09 AM

the reason why it's called "pseudo" is because you can artificially make the problem so that you're solving the inverse of a square matrix.

OneRaynyDay

but the formula looks... kind of obfuscated

rayryeng

It's actually not bad. Given that we have Ax = b, if you multiplied by A^T on both sides, we get:

OneRaynyDay

and there's two versions from what I can see o_O

rayryeng

A^T*Ax = A^T*b

solving for x gives us x = (A^T*A)^-1 * (A^T) * b

OneRaynyDay

oh.. so multiplying by the transverse gives us.. say a 3x2 instead of a 2x3, and when you multiply you get a 2x2 matrix

rayryeng

6:10 AM

3 x 3, but yes

This is called the "pseudo-inverse" because it finds the solution of x to the system with the least-squared error.

It does not give you the exact solution. Only an approximation.

When you have more rows than columns, this is what we call an overdetermined system.

OneRaynyDay

Oh... Huh

Oh gosh so many terms thrown at me at once

rayryeng

So the solution of x gives you the best approximate that satisfies each constraint to the best of its ability.

OneRaynyDay

I know the least-squared error is the (hypothesis(x) - y)^2

rayryeng

Let me find something that could explain it better.

OneRaynyDay

thank you! Sorry I couldn't really understand - I think I'll go watch some khan academy videos tomorrow for linear algebra so I don't ask stupid questions

rayryeng

6:13 AM

oh lol.

ok, well let's start from the beginning.

Probably in high school, you had to solve a system of linear equations. Right? Something like this

$user image$

You've frequently dealt with the simplest case where there are N equations with N unknowns.

OneRaynyDay

yep!

rayryeng

Ok well that's cool... now let's go back to the case of fitting a straight line through 2 points.

well, going with the above picture, you can turn that into a matrix equation.

Ax = b. A is a N x N matrix and b is a N x 1 vector.

OneRaynyDay

ah yes

so it would be if a is a

m x n matrix

and x is a vector...

rayryeng

Yes.

OneRaynyDay

of n size, leading to the b vector

rayryeng

6:18 AM

Now, in the context of machine learning, you have a bunch of x and y points.

let's say you have like 50 points.

and you want to fit a line through as many points as possible that have the least amount of error.

Well... all you need are 2 points to make a line.

OneRaynyDay

right!

rayryeng

So... which 2 points do you choose?... or should do something else?

You can formulate this into Ax = b quite nicely. Remember, the equation of a line is y = mx + b.

OneRaynyDay

uhmm I don't think you should choose pre-existing points

rayryeng

certainly not! but we'll get there.

OneRaynyDay

Right. Let me see...

rayryeng

6:20 AM

so we have x and y points... and we want to solve for m and b. You can think of m and b as x1 and x2 in the diagram.

OneRaynyDay

ah I see... so b is multiplied by 1 while m is multiplied by x

rayryeng

Correct.

So we can actually put this into matrix form.

So we'd get the following matrix for A

I'm going to LaTeX this out. One moment.

OneRaynyDay

so it's a n by 2(power of the regression +1) matrix multiplied by...

a vector of 2(power of the regression +1) by 1?

rayryeng

latex.codecogs.com/…

oops

OneRaynyDay

well, vectors are always [by 1]

Ahh I see that

OH. is the 1 the derivative

That's the only reason why there would be a 1... I'm only messing around in the dark here haha

rayryeng

6:23 AM

and x would be a vector such that x = [m b]

So if you worked it out, Ax = b gives you y = mx + b pairs for each pair of (x,y) values we have.

OneRaynyDay

right! Yeah that's what I said above :)

rayryeng

So this is what we call an overdetermined linear system.

Overdetermined means that you have more equations than unknowns.

This means that there is more than one possible answer that solves this linear system.

however, each solution will give you some error because not all of the points will fit nicely for a given pair of m,b.

OneRaynyDay

head explodes I think that's where I get confused

rayryeng

That's where the pseudo-inverse comes into play

OneRaynyDay

We have n amount of equations, and 2*n amounts of unknown I guess?

rayryeng

6:25 AM

It solves this linear system in such a way where m and b are determined that will fit a line through the points with the least amount of errors.

no, just two unknowns. m and b.

Let me put it into a better form

m and b are unknown. A is a N x 2 matrix. The total number of columns in A are how many variables you are solving for.

the total number of rows is how many points / equations you have.

we want to find the best value of m and b that will make each equation in our system roughly equal on the left and right hand side.

With an overdetermined system, there's more than one possible m and b that can satisfy most of the equations exactly, but not all of them.

OneRaynyDay

so you have n equations and 2 variables. I see

rayryeng

Which is why we turn to the pseudo-inverse. This finds the best value of m and b that will make most equations generally happy.

there will obviously be some errors, but these errors are for the most part as small as possible.

OneRaynyDay

So it's like saying 3x+2 = 5, but 2x+3 = 10 as well, and a ton more... which means the x has multiple answers

rayryeng

correct.

so the pseudo-inverse finds the solution to x that will satisfy most equations.

OneRaynyDay

Ahhh I see it now.

rayryeng

6:29 AM

because there will bound to be some equations where the chosen solution x does not satisfy the equation.

it's bound to happen. You have more equations than you have variables.

OneRaynyDay

right.

rayryeng

so that's where the pseudo-inverse comes into play.

OneRaynyDay

So would you rather get more equations exactly right, or would you get it so that the error of each equation is the minimum?

rayryeng

Correct.

OneRaynyDay

wait.. so.. both?

rayryeng

6:30 AM

oh sorry. The second.

The first one will give you bad results. When you study machine learning, this is what is called overfitting

you'll know about that stuff later.

OneRaynyDay

Ahh I've heard of it

gotcha.

Okay... so the pseudo-inverse turns the 3x2 into a 3x3 by multiplying the transposed version

and inversed because it's moving to the other side of the equation to find X

and in the process of doing the pseudo-inverse, I'm guessing it does a type of averaging out effect where

each number's stdev is slightly decreased?

So it's not referring to the original value, and then you're trying to find X with this not-so-precise-because-averaged matrix which is why it's not 100% accurate

brb shower!

Adriaan

Morning you happy people!

Hoppa! Reached the 1k rep!

rayryeng

6:47 AM

@Adriaan - yay!

Adriaan

Seeing the votebreakdown is rather useless though :P

might as well set it to default view imho

rayryeng

@OneRaynyDay - Yes. I won't prove it here, but the solution of x from the pseudo-inverse finds the parameters that best minimize the error of the overall equations.

OneRaynyDay

@rayryeng mkay :) thank you ray!

rayryeng

Think of it this way. Suppose we have a parabola, and we want to fit a straight line through it. One way of thinking is to fit as many points as possible through the lines... so you'd think that drawing a line through the first half or second half of the parabola may be nice

but the errors on the other side of the parabola are bad.

if you try and draw a straight line from one side of the parabola to the other side... choosing perhaps the middle of the two sections, you could say this would be better at minimizing the error.

@Adriaan - I agree!

Adriaan

well, time to get the next 1000 rep. At least I can do something useful then

OneRaynyDay

6:54 AM

@rayryeng Right, I understand that :)

Thank you so much by the way! Do you use venmo by the way?

rayryeng

Now... why would you want to use gradient descent, rather than the pseudo-inverse you may ask?

Well for problems that require 1000s of variables... storing the data in matrix form will prove to quickly run out of memory

gradient descent is more memory friendly.

OneRaynyDay

Ahh I see

rayryeng

@OneRaynyDay - I don't actually.

OneRaynyDay

But it takes a lot more steps to get to the bottom of the gradient slope though

rayryeng

Correct.

So you have to make a decision.

OneRaynyDay

6:55 AM

so it takes longer time to compute but less memory taken - ah!

rayryeng

Do you want more data?... or do you want it to compute faster?

Things like this factor in when designing a ML system.

OneRaynyDay

That just totally clicked in my head - I thought they were two completely different processes

rayryeng

Both of them are finding the right parameters of your line to minimize the error.

Gradient Descent is an iterative method to minimize the objective function

the pseudo-inverse does it as well, but does it in one step

Gradient descent requires iterations.

OneRaynyDay

Thank you so much! Want to consider making a venmo so I can tip you a donation? haha I don't have a paypal since my friend used my gmail to buy things online

rayryeng

oh :D lol

that's really nice of you. Sure, let me see.

OneRaynyDay

6:57 AM

Gotcha - I understand gradient descent much better than this linear algebra stuff, but

I kind of get the gist from your explanation now :)

rayryeng

haha well kind of is good

OneRaynyDay

haha yeah, I'm the kind of learner that needs the click to put everything together

rayryeng

that's fine with me :)

OneRaynyDay

yeah haha :) Well anyways, let me know when you make the account!

rayryeng

Sure :)

@Adriaan - Divakar answered lol

Adriaan

7:10 AM

that use of bsxfun is magic to me :P

rayryeng

@OneRaynyDay - Venmo not available in my area.

@Adriaan - It just takes practice :)

OneRaynyDay

what?! Errrrm.. I'll think of some way :)

Adriaan

@OneRaynyDay send him an envelope with Rubels

OneRaynyDay

@Adriaan I'll get a crane to fly over to Toronto with 3 zillion zimbabwe cash

rayryeng

which I will see ZERO of.

damn corrupt government.

Adriaan

7:13 AM

Ah, he appreciates that very much!

rayryeng

@Adriaan

Suggestion. You don't need to use find. Use logical operations and sum: C(ii,1) = sum(A > B(ii,1) & A < B(ii,2));. — rayryeng 8 mins ago

Adriaan

I implemented it?

rayryeng

I didn't see it!

oop see it now

it didn't refresh

Adriaan

I even mentioned your name

rayryeng

yes it didn't refresh lol

OneRaynyDay

7:17 AM

LOL hey at least you can flaunt around zimbabwe dollars in public

rayryeng

money that I will never see. There's nothing to flaunt!

OneRaynyDay

7:34 AM

haha trueee

don't worry ;) I'll find some way to send you usd

Adriaan

Brr, American money

Adriaan

7:50 AM

@rayryeng grmph, I don't like OPs accepting an answer and then asking additional requirements ...

OneRaynyDay

hmm... interesting - so the mean square error function is a function 1 degree higher than the regression

In univariate linear regression you'd get a parabolic function for the error bound

cool! :)

(Or at least fom my speculation)

rayryeng

@Adriaan - Yes. It's a sneaky way for them to entice you to do more work.

@OneRaynyDay - Yes that's correct.

OneRaynyDay

ah - so for a 3rd degree regression, you'd get a mean square error function of a x^4 function...

Adriaan

at least it was an easy fix. Not sure how to edit the second solution though, except for adding another forloop indexing C = [1 C]; and then using that to collect A

OneRaynyDay

but then it would have 2 minimums...?

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