Here is my big number.
Lets start with g1 which is 3^^^^3 click on this link for mor info
g2 is 3(g1 number of ^ s)3
g3 is 3(g2 number of ^ s)3
etc.
Balgonkah
Inferior Balgongkah
what about g(g(1))? that is (g(3^^^^3)) = 3(g(3^^^^3-1) number of arrows)3 which is very big.
i could say g(g(g(g(g(g(2)))))) is my number but i'm not done here yet.
lets define the number of gs.
remember g(g(1)) from earlier? well in the new notation it is r(2,1).
i will define the inferior balgongkah as being r(A(g64,g64),A(g64,g64)) let's name A(g64,g64) xkcd for reasons.
let's layer up the functions like so.
Regular Balgongkah
r1 = our r function
r2 = r(r(1)) = r2(2,1)
r3 = r2(r2(1)) = r3(2,1)
balgongkah is r(xkcd)(xkcd,xkcd)
these numbers are getting big.
Balgongkah Magnus
let's get some ackermann recursion into the mix. (note from 2023 Chembudwikipedian: this is not actually Ackerman recursion)
b for the balgongkah function.
b(m,0) = m
b(0,m) = m+1
b(m+1,n+1) = b(b(r(m,2),n-1),b(m-1,r(n,2))
ok, now balgonkah magnus is b(xkcd,xkcd).
The Lumbonkers series.
lets "bunker" the function like so.
bb(m+1,n+1) = bb(bb(r(n)(m,2),n-1),bb(m-1,r(m)(n,2))
i feel like this number is big enough that it desrves a new name,
lumbonkers is bb(xkcd,xkcd)
lumbonkers is mind-bogglingly large, but we can go further.
Mega Lumbonkers
lets layer up bb's the same way we made balgongkah.
so,
bb1 = our r function
bb2 = bb(bb(1,1)) = r2(2,1)
bb3 = bb2(bb2(1,1)) = r3(2,1)
etc.
mega lumbonkers is bb(xkcd)(xkcd,xkcd).
Giga lumbonkers
let's recurse what we did.
more ackermann recursion,
bb1 > bbi1 is congruent to r1 > bb1. Now layer it up.
bbi1 > bb1 is congruent to bb1 > bb2
etc.
Giga Lumbonkers is bbbalgonkah (balgonkah,balgonkah)
brief interlude
Lets define a function for functions, because we're gonna need it.
bb1 > bb2 is congruent to fff.
or, in other words,
fff(bb1) = bb2.
Tera lumbonkers
Let's apply fff on fff.
So,
fff(fff) = fff2(2,1).
Now, lets apply fffbalgonkah(balgongkah,balgongkah) to the bb function, giving the mega(m,n) fuction.
Let's define tera lumbonkers as mega(balgongkah,balgongkah)
Bluzzalimbo series
Hyperfactorial
Everybody knows the factorial, right?
5! = 5*4*3*2*1
Not enough. How about this?
5!2 = 5^4^3^2^1
Screw it, let's use the mega function,
5? = mega(5,mega(4,mega(3,mega(2,mega(1,1)))))
Bluzzalimbo
Here's the definition,
Lumbonkers? = Bluzzalimbo.
Yes,that's it.
Mega Bluzzalimbo
Let's define giga as a function.
giga(m,0) = m
giga(0,m) = m+1
giga (m+1,n+1) = giga(m?,giga(m?,giga...(n layers)...m?,n? ))
Mega bluzzalimbo = ffflumbonkers(giga)(lumbonkers,lumbonkers)
Super Bluzzalimbo
Giga and the balgonkah function both use m+1 for (0,m).
The IGiga function is simply the giga function but IGiga(0,m) is BB(m).
ffflumbonkersIGiga(lumbomkers,lumbonkers) is Super Bluzzalimbo.
Super-duper Bluzzalimbo
Let's shorthand ffflumbonkers as bfff.
Here is Big arrow notation.
m→n is bfff(IGiga(m,n))
Any ones at the ends become deleted
Any ones in the middle become subtracted i.e. x→1 is x-1
...→xn-1→xn becomes ...→xn-1-1→(...→xn-1→xn-1)
ok now super-duper bluzzalimbo is IGiga(lumbonkers→lumbonkers→(repeated lumbonkers times),(the same number again))
Ultra Bluzzalimbo
Let's do this.
m→→n = m→m→m→(with n arrows)→m→m.
Ultra bluzzalimbo is lumbonkers→→(with lumbonkers arrows)→→lumbonkers.
Sumbapliboop series
Let us now appreciate the great bigness of sumbapliboop
IGiga(lumbonkers→→→(with lumbonkers arrows)→→→lumbonkers(with lumbonkers lumbonkers')lumbonkers,(the same number again))
As you can see this is much bigger than lumbonkers or even giga lumbonkers. We are racing higher and higher!
Grand sumbapliboop
Let's make a shorthand function.
IGiga(x→→→(with x arrows)→→→x(with x x's)x,(the same number again))
Is all tidied up into tera(x)
Now we do our fancy layering...
tera(tera((With y layers)X))) = tera2(x,y)
And so on...
Grand sumbapliboop is defined as tera(bluzzalimbo)(bluzzalimbo,bluzzalimbo)
Mollosogrifgh and tremendogrifgh coming soon!
note from future 2023 Chembudwikipedian: no mollosogrigh is never ever coming and also I used if u use that sort of recursion on the Ackerman function then it literally just adds ordinal w to the growth rate.
Here is my big number.
Lets start with g1 which is 3^^^^3 click on this link for mor info
g2 is 3(g1 number of ^ s)3
g3 is 3(g2 number of ^ s)3
etc.
Balgonkah
Inferior Balgongkah
what about g(g(1))? that is (g(3^^^^3)) = 3(g(3^^^^3-1) number of arrows)3 which is very big.
i could say g(g(g(g(g(g(2)))))) is my number but i'm not done here yet.
lets define the number of gs.
remember g(g(1)) from earlier? well in the new notation it is r(2,1).
i will define the inferior balgongkah as being r(A(g64,g64),A(g64,g64)) let's name A(g64,g64) xkcd for reasons.
let's layer up the functions like so.
Regular Balgongkah
r1 = our r function
r2 = r(r(1)) = r2(2,1)
r3 = r2(r2(1)) = r3(2,1)
balgongkah is r(xkcd)(xkcd,xkcd)
these numbers are getting big.
Balgongkah Magnus
let's get some ackermann recursion into the mix. (note from 2023 Chembudwikipedian: this is not actually Ackerman recursion)
b for the balgongkah function.
b(m,0) = m
b(0,m) = m+1
b(m+1,n+1) = b(b(r(m,2),n-1),b(m-1,r(n,2))
ok, now balgonkah magnus is b(xkcd,xkcd).
The Lumbonkers series.
lets "bunker" the function like so.
bb(m+1,n+1) = bb(bb(r(n)(m,2),n-1),bb(m-1,r(m)(n,2))
i feel like this number is big enough that it desrves a new name,
lumbonkers is bb(xkcd,xkcd)
lumbonkers is mind-bogglingly large, but we can go further.
Mega Lumbonkers
lets layer up bb's the same way we made balgongkah.
so,
bb1 = our r function
bb2 = bb(bb(1,1)) = r2(2,1)
bb3 = bb2(bb2(1,1)) = r3(2,1)
etc.
mega lumbonkers is bb(xkcd)(xkcd,xkcd).
Giga lumbonkers
let's recurse what we did.
more ackermann recursion,
bb1 > bbi1 is congruent to r1 > bb1. Now layer it up.
bbi1 > bb1 is congruent to bb1 > bb2
etc.
Giga Lumbonkers is bbbalgonkah (balgonkah,balgonkah)
brief interlude
Lets define a function for functions, because we're gonna need it.
bb1 > bb2 is congruent to fff.
or, in other words,
fff(bb1) = bb2.
Tera lumbonkers
Let's apply fff on fff.
So,
fff(fff) = fff2(2,1).
Now, lets apply fffbalgonkah(balgongkah,balgongkah) to the bb function, giving the mega(m,n) fuction.
Let's define tera lumbonkers as mega(balgongkah,balgongkah)
Bluzzalimbo series
Hyperfactorial
Everybody knows the factorial, right?
5! = 5*4*3*2*1
Not enough. How about this?
5!2 = 5^4^3^2^1
Screw it, let's use the mega function,
5? = mega(5,mega(4,mega(3,mega(2,mega(1,1)))))
Bluzzalimbo
Here's the definition,
Lumbonkers? = Bluzzalimbo.
Yes,that's it.
Mega Bluzzalimbo
Let's define giga as a function.
giga(m,0) = m
giga(0,m) = m+1
giga (m+1,n+1) = giga(m?,giga(m?,giga...(n layers)...m?,n? ))
Mega bluzzalimbo = ffflumbonkers(giga)(lumbonkers,lumbonkers)
Super Bluzzalimbo
Giga and the balgonkah function both use m+1 for (0,m).
The IGiga function is simply the giga function but IGiga(0,m) is BB(m).
ffflumbonkersIGiga(lumbomkers,lumbonkers) is Super Bluzzalimbo.
Super-duper Bluzzalimbo
Let's shorthand ffflumbonkers as bfff.
Here is Big arrow notation.
m→n is bfff(IGiga(m,n))
Any ones at the ends become deleted
Any ones in the middle become subtracted i.e. x→1 is x-1
...→xn-1→xn becomes ...→xn-1-1→(...→xn-1→xn-1)
ok now super-duper bluzzalimbo is IGiga(lumbonkers→lumbonkers→(repeated lumbonkers times),(the same number again))
Ultra Bluzzalimbo
Let's do this.
m→→n = m→m→m→(with n arrows)→m→m.
Ultra bluzzalimbo is lumbonkers→→(with lumbonkers arrows)→→lumbonkers.
Sumbapliboop series
Let us now appreciate the great bigness of sumbapliboop
IGiga(lumbonkers→→→(with lumbonkers arrows)→→→lumbonkers(with lumbonkers lumbonkers')lumbonkers,(the same number again))
As you can see this is much bigger than lumbonkers or even giga lumbonkers. We are racing higher and higher!
Grand sumbapliboop
Let's make a shorthand function.
IGiga(x→→→(with x arrows)→→→x(with x x's)x,(the same number again))
Is all tidied up into tera(x)
Now we do our fancy layering...
tera(tera((With y layers)X))) = tera2(x,y)
And so on...
Grand sumbapliboop is defined as tera(bluzzalimbo)(bluzzalimbo,bluzzalimbo)
Mollosogrifgh and tremendogrifgh coming soon!
note from future 2023 Chembudwikipedian: no mollosogrigh is never ever coming and also I used if u use that sort of recursion on the Ackerman function then it literally just adds ordinal w to the growth rate.