@janecheoh546:

Jane Cheoh
Jane Cheoh
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Region: MY
Tuesday 14 July 2026 15:43:15 GMT
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kelly_1668
Neil :
太折磨人了,我竟然看完了
2026-07-16 02:29:17
31
user9326267054751
砂鍋魚頭 :
浪費時間
2026-07-16 10:04:14
12
tay.kim.swee
Tay Kim Swee :
hahaha..I actually do not understand... hahaha...
2026-07-16 03:31:46
1
user773940268111
同學~你很屌? :
轉了三個小時還沒有停
2026-07-17 13:34:31
2
leo.george0001
George. :
有意思
2026-07-15 23:51:18
0
user9049051072437
湘湘 :
這湯匙哪裡能下單啊?想買🤣🤣🤣🤣🤣🤣🤣
2026-07-16 14:59:23
1
leechangkeong
leechangkeong :
所以我是看了個寂寞?😅
2026-07-17 09:15:41
1
oo67241
૮o̴̶̷᷄ﻌo̴̶̷̥᷅ა小脆脆 :
答案是不買
2026-07-16 06:12:45
3
dylan_12128
DW|魷魚🦑 :
轉太久了吧😂😂
2026-07-17 08:15:58
0
abbbbbbbbbbbbbbbbbk
Allen :
怎么不从盘古开天开始播?
2026-07-15 23:48:54
3
boone0988
安靜 :
湯鍉反過來有剪頭➡️指向不買😅
2026-07-16 00:38:26
4
jaydenmonkeyhaha
KC_happycat :
這比遊戲抽卡還久
2026-07-17 07:57:36
1
user354851785562
霜 :
快買快買
2026-07-17 04:16:08
1
user79537354926841
可愛的無名 :
如果覺得太久的話,你直接跳到1分17秒
2026-07-17 04:09:22
2
kissdog1351666
ķïßßđöğ良🗽⃢⃢🗿 :
已減少1分25秒生命
2026-07-17 10:43:51
1
kuo75129604
昇 :
這地板蠟在哪買的
2026-07-15 18:32:28
3
user7977813819008
潘美瑜 :
轉這麼久是......😂
2026-07-15 08:57:19
3
user4869360829954
🎐👀你又礙眼了🙈🎐 :
我竟然看完😩
2026-07-15 15:23:42
1
user3303585818501
平安 :
少30秒會更吸引人
2026-07-15 03:41:45
8
user6567638233246
雷伊 :
轉到沒耐心了😂
2026-07-15 01:37:25
9
tantan2309
tantan :
继承了老祖宗的优良基因:太能玩了!哈哈哈哈😂我以为汤匙柄指的算!
2026-07-16 04:18:52
1
nakomokayoufbgh7
藏行者 :
哎呀 急死人 到底買不買
2026-07-15 11:55:04
2
user3738575100248
明日琞 :
湯匙哪買的
2026-07-15 03:43:03
2
b6451875
名字刚好七个字 :
有買嗎
2026-07-15 05:58:39
2
s.102924
飼料🎏 :
不買最後
2026-07-15 07:49:52
1
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Other Videos

my brother caleb gives 3 hugs to my friend cain in san diego #tcc #truecrime #zeroday #ongezellig #xzybca  THIS IS ALL FROM A DOCUMENTARY fypfypfyp followme blowthisup blowmeup likethisvideo siliyone popular trending ongezelligedit ongezelligmymy unsociable Graham's number is an unimaginably large number that arose in a branch of mathematics called Ramsey theory. It was once certified by the Guinness Book of World Records as the largest number ever used in a serious mathematical proof. Even though mathematicians have since defined even larger numbers (like TREE(3)), Graham's number remains famous because of how quickly it escapes our physical reality. Why Was It Created? In 1971, mathematician Ronald Graham was working on a problem involving hypercubes (multidimensional cubes). Imagine an N-dimensional hypercube.  * You connect every single corner (vertex) of this cube to every other corner with a line. This gives you a complete graph.  * Now, you color every single one of those lines using only two colors: red or blue. > The Question: What is the smallest number of dimensions (N) your hypercube must have so that, no matter how you color the lines, there will always be at least one single-colored (all red or all blue) flat 4-vertex plane? >  Graham couldn't find the exact number, but he proved that the answer was between 6 and a mind-bogglingly massive upper bound. That upper bound is what we now call Graham's number. (Note: In 2014, mathematicians showed the actual answer is likely much smaller, perhaps even 13, but the upper bound remains a legendary piece of math history!) How Big Is It? It is so large that we cannot write it down using standard scientific notation (10^x), nor can we represent it by filling the entire observable universe with microscopic digits. To write it, we have to use a special system called Knuth's up-arrow notation, which is a way to write hyper-operations (operations beyond addition, multiplication, and exponentiation). Understanding Up-Arrows (\uparrow)  * Single Arrow (\uparrow): This is just regular exponentiation.      * Double Arrow (\uparrow\uparrow): This is a
my brother caleb gives 3 hugs to my friend cain in san diego #tcc #truecrime #zeroday #ongezellig #xzybca THIS IS ALL FROM A DOCUMENTARY fypfypfyp followme blowthisup blowmeup likethisvideo siliyone popular trending ongezelligedit ongezelligmymy unsociable Graham's number is an unimaginably large number that arose in a branch of mathematics called Ramsey theory. It was once certified by the Guinness Book of World Records as the largest number ever used in a serious mathematical proof. Even though mathematicians have since defined even larger numbers (like TREE(3)), Graham's number remains famous because of how quickly it escapes our physical reality. Why Was It Created? In 1971, mathematician Ronald Graham was working on a problem involving hypercubes (multidimensional cubes). Imagine an N-dimensional hypercube. * You connect every single corner (vertex) of this cube to every other corner with a line. This gives you a complete graph. * Now, you color every single one of those lines using only two colors: red or blue. > The Question: What is the smallest number of dimensions (N) your hypercube must have so that, no matter how you color the lines, there will always be at least one single-colored (all red or all blue) flat 4-vertex plane? > Graham couldn't find the exact number, but he proved that the answer was between 6 and a mind-bogglingly massive upper bound. That upper bound is what we now call Graham's number. (Note: In 2014, mathematicians showed the actual answer is likely much smaller, perhaps even 13, but the upper bound remains a legendary piece of math history!) How Big Is It? It is so large that we cannot write it down using standard scientific notation (10^x), nor can we represent it by filling the entire observable universe with microscopic digits. To write it, we have to use a special system called Knuth's up-arrow notation, which is a way to write hyper-operations (operations beyond addition, multiplication, and exponentiation). Understanding Up-Arrows (\uparrow) * Single Arrow (\uparrow): This is just regular exponentiation. * Double Arrow (\uparrow\uparrow): This is a "power tower" of exponents (tetration). * Triple Arrow (\uparrow\uparrow\uparrow): This is a tower of towers (pentation). The height of this tower is over 7.6 trillion levels. This number is already too big to write down in normal form. Constructing Graham's Number (G) Graham's number is built in 64 steps, or "layers." We start with a number called g_1: This is 3 connected by four up-arrows to 3. Even g_1 is far larger than the number of atoms in the observable universe. But we are only on step one. We use the result of each step to define the number of arrows in the next step: * Layer 1: g_1 = 3 \uparrow\uparrow\uparrow\uparrow 3 * Layer 2: g_2 = 3 \underbrace{\uparrow\dots\dots\dots\uparrow}_{g_1 \text{ arrows}} 3 * Layer 3: g_3 = 3 \underbrace{\uparrow\dots\dots\dots\uparrow}_{g_2 \text{ arrows}} 3 * * Layer 64: G = 3 \underbrace{\uparrow\dots\dots\dots\uparrow}_{g_{63} \text{ arrows}} 3 Graham's number (G) is the final value, g_{64}. Fun Fact: The End of the Number While we can't possibly know or write out the entire sequence of digits of Graham's number, mathematicians do know its ending. Because of the way powers of 3 behave in modular arithmetic, the last few digits are completely locked in. The last ten digits of Graham's number are:

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