You take a function of x and you call it y, Take any x0 that you care to try, Make a little change and call it delta-x, The corresponding change in y is what you find nex', And then you take the quotient, and now carefully Send delta-x to zero and I think you'll see, That what the limit gives us, if our work all checks, Is what we call dy/dx, it's just dy/dx.
S'il y a un matheux bilingue qui peut traduire l'intégralité du texte du Klein 4 Group...
The path of love is never smooth But mine's continuous for you You're the upper bound in the chains of my heart You're my Axiom of Choice, you know it's true
But lately our relation's not so well-defined And I just can't function without you I'll prove my proposition and I'm sure you'll find We're a finite simple group of order two
I'm losing my identity I'm getting tensor every day And without loss of generality I will assume that you feel the same way
Since every time I see you, you just quotient out The faithful image that I map into But when we're one-to-one you'll see what I'm about 'Cause we're a finite simple group of order two
Our equivalence was stable, A principal love bundle sitting deep inside But then you drove a wedge between our two-forms Now everything is so complexified
When we first met, we simply connected My heart was open but too dense Our system was already directed To have a finite limit, in some sense
I'm living in the kernel of a rank-one map From my domain, its image looks so blue, 'Cause all I see are zeroes, it's a cruel trap But we're a finite simple group of order two
I'm not the smoothest operator in my class, But we're a mirror pair, me and you, So let's apply forgetful functors to the past And be a finite simple group, a finite simple group, Let's be a finite simple group of order two (Oughter: "Why not three?")
I've proved my proposition now, as you can see, So let's both be associative and free And by corollary, this shows you and I to be Purely inseparable. Q. E. D.