@ngoibuoncaolongchim: 爱情就像火焰,如果不懂珍惜,它很快就会熄灭。“Tình yêu giống như ngọn lửa, nếu không biết trân trọng, nó sẽ sớm lụi tàn.” #camxuccuaem #tamtrang #viral #xuhuong

baby blue 🛞
baby blue 🛞
Open In TikTok:
Region: VN
Tuesday 09 September 2025 05:07:13 GMT
252108
35407
135
4522

Music

Download

Comments

buon38797
?! :
đã từng yêu
2025-09-09 13:39:53
77
baouyny
️mua dong co em :
人的眼睛是黑的,心是红的,但有时眼睛一红,心也 Con người có đôi mắt màu đen, trái tim màu đỏ, nhưng đôi khi mắt đỏ, trái tim lại trở nên tối tăm..!
2025-09-09 09:46:12
30
_hun.gian.xingai_
huonggiang 𝜗𝜚 :
buonn🥺
2025-09-14 09:29:48
10
fan_nha1
USER 🫀 :
xhhh🥰
2025-09-09 10:50:38
3
tri.huan.2011
𝙼𝚊𝚒 𝙷𝚞â𝚗 :
Yên bình vậy
2025-09-14 08:29:43
2
donchancutes1
chang :
hộ tớ 2vd đc kh ạa
2025-09-10 15:37:56
6
duowq_tuzq06
𝐃𝐮̛𝐨̛𝐧𝐠 𝐓𝐮̀𝐧𝐠❄️ :
Xhh nhé 🥰
2025-09-09 10:45:57
2
bibon8882
chip_chip❤️‍🩹 :
đã từng iu... rất nhiều❤️‍🩹
2025-09-22 04:31:31
3
caubehaybuon188
Q :
tt
2025-09-09 11:33:20
1
6a1.thcsmongduong
A1-k29 :
"Yêu không cần lời hứa, chỉ cần mỗi giây phút bên nhau." "愛不需要承諾,只需要每分每秒在一起。"
2025-09-20 04:00:59
7
ducchuyo6
Huy chienn🥰 :
chưa dc ai ai yeu tht lòng bao giờ 😔🥰
2025-10-27 05:22:50
1
phuctran0411288
Tít tít shoppp :
Đâu còn thương đâu còn yéu đối vois1 người
2025-09-21 07:12:23
2
love_h73
h :
buồn lắm😊
2025-09-18 16:08:54
3
dungquetma
Đang sống Lại .... :
Xin vd nha
2025-09-15 03:55:12
1
_khanhhduyy1_
KhanhDuyy✈️ :
hộ vd ghim vs aaa
2025-09-14 02:02:54
1
trang.y08
Trang nè :
tim hộ video
2025-09-13 15:36:30
1
lvdatt09
Lê Văn Đạt :
Đã từng yêu
2025-09-13 11:22:41
1
vbao10ver1
. :
“爱情就像天空,有晴天,也有雨天。爱情也是如此,如果我们互相让步,就能熬过雨天,也能接受晴天的相守。” Tình yêu giống như bầu trời. Bầu trời có ngày nắng và ngày mưa. Tình yêu cũng giống như vậy nếu chúng ta nhường nhịn nhau, chúng ta sẽ vượt qua những ngày mưa và chấp nhận ở bên nhau vào những ngày nắng
2025-09-15 08:10:41
15
qhuy_2901
qhuy 06 :
Cho mình xin vd nha🥰
2025-09-14 05:34:17
1
quetcaimaa
Ai Là Thần Hu :
Cũng chỉ là đã từng💔🥹
2025-09-18 10:05:52
1
boo.ynn30
byy :
cho xin video gốc vs
2025-09-14 03:24:11
1
phuonqlan014
🤎 :
Moi chuyen cung da ket thuc...
2025-09-12 04:47:02
1
ney123ok
Ánh Tuyết :
họi vs ạ
2025-09-19 15:43:00
1
chang3217
🤍 :
Đau
2025-09-20 08:15:45
1
To see more videos from user @ngoibuoncaolongchim, please go to the Tikwm homepage.

Other Videos

#CapCut #tcd #jews #israel GRAHAM'S NUMBER Graham's Number is one of the largest numbers ever used in a serious mathematical proof. It was introduced by the mathematician Ronald Graham while working on a problem in an area of mathematics known as Ramsey Theory. At first glance, Graham's Number may seem like just another very large number. However, it is so unimaginably huge that ordinary methods of writing numbers become completely useless. Even scientific notation, which can easily express numbers such as 10^100 or 10^1000, is far too small to describe Graham's Number directly. WHY IS IT FAMOUS? Graham's Number became famous because it was once listed in the Guinness Book of World Records as the largest number ever used in a mathematical proof. Although mathematicians have since encountered even larger numbers, Graham's Number remains one of the most well-known examples of an extremely large finite number. HOW BIG IS IT? To understand how large Graham's Number is, consider the following: 1. One million = 1,000,000 2. One billion = 1,000,000,000 3. A googol = 10^100 4. A googolplex = 10^(10^100) Even a googolplex is tiny compared with Graham's Number. If every atom in the observable universe were turned into ink and used to write digits, there would still not be enough space to write all the digits of Graham's Number. In fact, the number of digits in Graham's Number is itself unimaginably enormous. UP-ARROW NOTATION Graham's Number is defined using Knuth's Up-Arrow Notation. Examples: 3 ↑ 3 = 27 3 ↑↑ 3 = 3^(3^3)          = 3^27          = 7,625,597,484,987 The double-arrow operation grows much faster than ordinary exponentiation. Next: 3 ↑↑↑ 3 This means repeated use of the double-arrow operation and produces a number so large that it is already beyond ordinary comprehension. As more arrows are added, the numbers grow explosively: 3 ↑↑↑↑ 3 3 ↑↑↑↑↑ 3 3 ↑↑↑↑↑↑ 3 Each additional arrow creates a level of growth that dwarfs all previous levels. HOW GRAHAM'S NUMBER IS CONSTRUCTED Graham's Number is built through a sequence of numbers: g1 = 3 ↑↑↑↑ 3 Then: g2 = 3 ↑^(g1) 3 where the number of arrows between the 3s is equal to g1. Next: g3 = 3 ↑^(g2) 3 This process continues repeatedly. Eventually: Graham's Number = g64 This means the process is repeated 64 times, with each stage becoming vastly larger than the previous one. CAN WE CALCULATE IT? No computer could ever store Graham's Number completely. Even if a computer used every particle in the observable universe as memory, it would still be nowhere near enough to represent the entire number. Interestingly, mathematicians do know the final digits of Graham's Number. Through advanced mathematical techniques, it has been determined that the last digits are: ...2464195387 This does not mean we know the whole number; only certain properties of it. IS IT INFINITE? No. Graham's Number is finite. Although it is unbelievably large, it still has a specific value and is therefore not infinite. Infinity is a completely different concept that represents something without bound. COMPARISON TO THE UNIVERSE Estimated atoms in the observable universe: Approximately 10^80 A googol: 10^100 A googolplex: 10^(10^100) Graham's Number: So much larger that even the above numbers are effectively negligible in comparison. MATHEMATICAL IMPORTANCE Graham's Number was not invented merely to be huge. It appeared as an upper bound in a legitimate mathematical problem involving high-dimensional geometry and combinatorics. Later research found much smaller upper bounds, but Graham's Number remains historically important. SUMMARY - Graham's Number is a finite number. - It was introduced by mathematician Ronald Graham. - It is defined using Knuth's Up-Arrow Notation. - It is vastly larger than a googol or googolplex. - The observable universe is far too small to write it out. - It became famous as one of the largest numbers ever used in a   mathematical proof. - Despite its enormous size, it is still finite and not infinite. Graham's Number remains one of the most astonishing examples of how large numbers can bec
#CapCut #tcd #jews #israel GRAHAM'S NUMBER Graham's Number is one of the largest numbers ever used in a serious mathematical proof. It was introduced by the mathematician Ronald Graham while working on a problem in an area of mathematics known as Ramsey Theory. At first glance, Graham's Number may seem like just another very large number. However, it is so unimaginably huge that ordinary methods of writing numbers become completely useless. Even scientific notation, which can easily express numbers such as 10^100 or 10^1000, is far too small to describe Graham's Number directly. WHY IS IT FAMOUS? Graham's Number became famous because it was once listed in the Guinness Book of World Records as the largest number ever used in a mathematical proof. Although mathematicians have since encountered even larger numbers, Graham's Number remains one of the most well-known examples of an extremely large finite number. HOW BIG IS IT? To understand how large Graham's Number is, consider the following: 1. One million = 1,000,000 2. One billion = 1,000,000,000 3. A googol = 10^100 4. A googolplex = 10^(10^100) Even a googolplex is tiny compared with Graham's Number. If every atom in the observable universe were turned into ink and used to write digits, there would still not be enough space to write all the digits of Graham's Number. In fact, the number of digits in Graham's Number is itself unimaginably enormous. UP-ARROW NOTATION Graham's Number is defined using Knuth's Up-Arrow Notation. Examples: 3 ↑ 3 = 27 3 ↑↑ 3 = 3^(3^3) = 3^27 = 7,625,597,484,987 The double-arrow operation grows much faster than ordinary exponentiation. Next: 3 ↑↑↑ 3 This means repeated use of the double-arrow operation and produces a number so large that it is already beyond ordinary comprehension. As more arrows are added, the numbers grow explosively: 3 ↑↑↑↑ 3 3 ↑↑↑↑↑ 3 3 ↑↑↑↑↑↑ 3 Each additional arrow creates a level of growth that dwarfs all previous levels. HOW GRAHAM'S NUMBER IS CONSTRUCTED Graham's Number is built through a sequence of numbers: g1 = 3 ↑↑↑↑ 3 Then: g2 = 3 ↑^(g1) 3 where the number of arrows between the 3s is equal to g1. Next: g3 = 3 ↑^(g2) 3 This process continues repeatedly. Eventually: Graham's Number = g64 This means the process is repeated 64 times, with each stage becoming vastly larger than the previous one. CAN WE CALCULATE IT? No computer could ever store Graham's Number completely. Even if a computer used every particle in the observable universe as memory, it would still be nowhere near enough to represent the entire number. Interestingly, mathematicians do know the final digits of Graham's Number. Through advanced mathematical techniques, it has been determined that the last digits are: ...2464195387 This does not mean we know the whole number; only certain properties of it. IS IT INFINITE? No. Graham's Number is finite. Although it is unbelievably large, it still has a specific value and is therefore not infinite. Infinity is a completely different concept that represents something without bound. COMPARISON TO THE UNIVERSE Estimated atoms in the observable universe: Approximately 10^80 A googol: 10^100 A googolplex: 10^(10^100) Graham's Number: So much larger that even the above numbers are effectively negligible in comparison. MATHEMATICAL IMPORTANCE Graham's Number was not invented merely to be huge. It appeared as an upper bound in a legitimate mathematical problem involving high-dimensional geometry and combinatorics. Later research found much smaller upper bounds, but Graham's Number remains historically important. SUMMARY - Graham's Number is a finite number. - It was introduced by mathematician Ronald Graham. - It is defined using Knuth's Up-Arrow Notation. - It is vastly larger than a googol or googolplex. - The observable universe is far too small to write it out. - It became famous as one of the largest numbers ever used in a mathematical proof. - Despite its enormous size, it is still finite and not infinite. Graham's Number remains one of the most astonishing examples of how large numbers can bec

About