"코흐의 눈송이 곡선"의 두 판 사이의 차이

수학노트
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==이 항목의 스프링노트 원문주소==
 
 
 
 
 
 
 
 
 
==개요==
 
==개요==
  
 
 
 
 [/pages/4485597/attachments/2376371 sdfsdf.jpg]
 
 
 
 
 
(1)  왼쪽 위의 삼각형의 둘레를 P1 그 옆의 삼각형을 P2, 왼쪽아래를 P3, .... 로 한다면
 
 
     <math>P_{n+1}=\frac{4}{3}(P_{n})</math> 의 점화식이 성립되며, 따라서 n 을 무한대로 보내면 둘레는 무한으로 발산한다.
 
 
 
 
 
(2) (1)의 순서로 삼각형의 넓이를 S1, S2, ... 라 하자. 정확한 식을 위해 처음 한 변의 길이를 a 라고 하면, <math>S_{1} = \frac{\sqrt3}{4}a^2</math> 이다.
 
 
     S2에서 원래 삼각형과 늘어난 삼각형의 길이비는 3:1 이고 넓이비는 9:1 이다. 따라서  <math>S_{2} = S_{1} + \frac{3}{9}S_{1}</math>
 
 
    마찬가지로 <math>S_{3} = S_{2} + \frac{12}{81}S_{1}</math>, <math>S_{4} = S_{3} + \frac{48}{729}S_{1}</math>
 
 
 즉, 둘째 항부터 등비수열을 이루는 수열이다. 무한등비수열의 공식을 쓰면  <math>\lim_{n \to \infty} S_{n}=\frac{8}{5}S_{1}</math> 로 수렴한다.
 
 
 
 
 
이상의 프랙탈은 [[코흐의 눈송이 곡선]]으로 , 이외에도 시어핀스키 프랙탈 등이 있다. 프랙탈의 시작은 해안선의 길이를 측정하면서부터라고 전해진다.
 
 
 
 
 
(3) 프랙탈의 차원(수학적 매개변수) 유클리드 차원과는 다르게 프랙탈 차원은 대개 정수가 아닌 분수로 표현. 프랙탈을 n개의 완전히 똑같은 부분으로
 
 
     나누었을 때 전체 도형과 한 부분 사이의 닮음비가 m:1이면 프랙탈 도형의 차원 d는 다음과 같이 정의한다.
 
 
  <math>d = \frac{logn}{logm}</math> (안합쳐지네요 ㅠㅠ)
 
 
코흐의 눈송이 곡선을 예로 들어 차원을 계산하면, 4개의 똑같은 부분의 닮음비가 3:1 이므로 차원 d 는 <math>\frac{log4}{log3}</math>
 
 
 
 
 
 
 
 
==재미있는 사실==
 
 
 
 
 
* Math Overflow http://mathoverflow.net/search?q=
 
* 네이버 지식인 http://kin.search.naver.com/search.naver?where=kin_qna&query=
 
 
 
 
 
 
 
 
==역사==
 
 
 
 
 
* http://www.google.com/search?hl=en&tbs=tl:1&q=
 
* [[수학사연표 (역사)|수학사연표]]
 
*  
 
 
 
 
 
 
 
 
==메모==
 
 
 
 
 
 
 
 
==관련된 항목들==
 
 
 
 
 
 
 
 
==수학용어번역==
 
 
* 단어사전 http://www.google.com/dictionary?langpair=en|ko&q=
 
* 발음사전 http://www.forvo.com/search/
 
* [http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=&fstr= 대한수학회 수학 학술 용어집]<br>
 
** http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=eng_term&fstr=
 
* [http://www.nktech.net/science/term/term_l.jsp?l_mode=cate&s_code_cd=MA 남·북한수학용어비교]
 
* [http://kms.or.kr/home/kor/board/bulletin_list_subject.asp?bulletinid=%7BD6048897-56F9-43D7-8BB6-50B362D1243A%7D&boardname=%BC%F6%C7%D0%BF%EB%BE%EE%C5%E4%B7%D0%B9%E6&globalmenu=7&localmenu=4 대한수학회 수학용어한글화 게시판]
 
 
 
 
 
 
 
 
==사전 형태의 자료==
 
 
* http://ko.wikipedia.org/wiki/
 
* http://en.wikipedia.org/wiki/
 
* http://www.wolframalpha.com/input/?i=koch+snowflake
 
* [http://dlmf.nist.gov/ NIST Digital Library of Mathematical Functions]
 
* [http://www.research.att.com/~njas/sequences/index.html The On-Line Encyclopedia of Integer Sequences]<br>
 
** http://www.research.att.com/~njas/sequences/?q=
 
  
 
+
(1)  왼쪽 위의 삼각형의 둘레를 P1 그 옆의 삼각형을 P2, 왼쪽아래를 P3, .... 로 한다면
  
 
+
<math>P_{n+1}=\frac{4}{3}(P_{n})</math> 의 점화식이 성립되며, 따라서 n 을 무한대로 보내면 둘레는 무한으로 발산한다.
  
==관련논문==
+
  
* http://www.jstor.org/action/doBasicSearch?Query=
+
(2) (1)의 순서로 삼각형의 넓이를 S1, S2, ... 라 하자. 정확한 식을 위해 처음 한 변의 길이를 a 라고 하면, <math>S_{1} = \frac{\sqrt3}{4}a^2</math> 이다.
* http://www.ams.org/mathscinet
 
* http://dx.doi.org/
 
  
 
+
S2에서 원래 삼각형과 늘어난 삼각형의 길이비는 3:1 이고 넓이비는 9:1 이다. 따라서  <math>S_{2} = S_{1} + \frac{3}{9}S_{1}</math>
  
 
+
마찬가지로 <math>S_{3} = S_{2} + \frac{12}{81}S_{1}</math>, <math>S_{4} = S_{3} + \frac{48}{729}S_{1}</math>
  
==관련도서==
+
즉, 둘째 항부터 등비수열을 이루는 수열이다. 무한등비수열의 공식을 쓰면  <math>\lim_{n \to \infty} S_{n}=\frac{8}{5}S_{1}</math> 로 수렴한다.
 +
  
*  도서내검색<br>
+
이상의 프랙탈은 [[코흐의 눈송이 곡선]]으로, 이외에도 시어핀스키 프랙탈 등이 있다. 프랙탈의 시작은 해안선의 길이를 측정하면서부터라고 전해진다.
** http://books.google.com/books?q=
 
** http://book.daum.net/search/contentSearch.do?query=
 
*  도서검색<br>
 
** http://books.google.com/books?q=
 
** http://book.daum.net/search/mainSearch.do?query=
 
** http://book.daum.net/search/mainSearch.do?query=
 
  
 
+
  
 
+
(3) 프랙탈의 차원(수학적 매개변수) 유클리드 차원과는 다르게 프랙탈 차원은 대개 정수가 아닌 분수로 표현. 프랙탈을 n개의 완전히 똑같은 부분으로 나누었을 때 전체 도형과 한 부분 사이의 닮음비가 m:1이면 프랙탈 도형의 차원 d는 다음과 같이 정의한다.
  
==관련기사==
+
<math>d = \frac{\log n}{\log m}</math>
  
*  네이버 뉴스 검색 (키워드 수정)<br>
+
코흐의 눈송이 곡선을 예로 들어 차원을 계산하면, 4개의 똑같은 부분의 닮음비가 3:1 이므로 차원 d 는 <math>\frac{log4}{log3}</math>
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
  
 
+
== 노트 ==
  
 
+
===말뭉치===
 +
# The Koch snowflake is noteworthy in that it is continuous but nowhere differentiable; that is, at no point on the curve does there exist a tangent line.<ref name="ref_cf8112b9">[https://www.britannica.com/science/Von-Kochs-snowflake-curve Von Koch’s snowflake curve | mathematics]</ref>
 +
# The Koch snowflake can be built up iteratively, in a sequence of stages.<ref name="ref_887886fb">[https://en.wikipedia.org/wiki/Koch_snowflake Koch snowflake]</ref>
 +
# The Koch snowflake is the limit approached as the above steps are followed indefinitely.<ref name="ref_887886fb" />
 +
# The Koch curve originally described by Helge von Koch is constructed using only one of the three sides of the original triangle.<ref name="ref_887886fb" />
 +
# In other words, three Koch curves make a Koch snowflake.<ref name="ref_887886fb" />
 +
# The Koch snowflake is a very well-known shape among mathematicians!<ref name="ref_8d1a6fc1">[https://towardsdatascience.com/the-three-dimensional-koch-snowflake-fun-fractals-at-home-4f69a646c7a0 The Three-Dimensional Koch Snowflake — Fun Fractals at Home]</ref>
 +
# The 2D Koch snowflake is super cool … are you curious to see what it looks like in 3D?<ref name="ref_8d1a6fc1" />
 +
# The Koch snowflake can be simply encoded as a Lindenmayer system with initial string "F--F--F" , string rewriting rule "F" -> "F+F--F+F" , and angle .<ref name="ref_bb11a4ce">[https://mathworld.wolfram.com/KochSnowflake.html Koch Snowflake -- from Wolfram MathWorld]</ref>
 +
# Each fractalized side of the triangle is sometimes known as a Koch curve.<ref name="ref_bb11a4ce" />
 +
# Some beautiful tilings, a few examples of which are illustrated above, can be made with iterations toward Koch snowflakes.<ref name="ref_bb11a4ce" />
 +
# In addition, two sizes of Koch snowflakes in area ratio 1:3 tile the plane, as shown above.<ref name="ref_bb11a4ce" />
 +
# d must satisfy As shown above, the Koch snowflake is self-similar with six pieces scaled by 1/3 and one piece scaled by \(1/\sqrt{3}\).<ref name="ref_46f667a6">[https://larryriddle.agnesscott.org/ifs/ksnow/ksnow.htm Koch Snowflake]</ref>
 +
# Notice, however, that the boundary of the Koch snowflake consists of three copies of the Koch curve, which has a fractal dimension of 1.26186.<ref name="ref_46f667a6" />
 +
# Therefore the Koch snowflake has a perimeter of infinite length.<ref name="ref_46f667a6" />
 +
# This variation on the Koch snowflake was created by William Gosper.<ref name="ref_46f667a6" />
 +
# The Koch curve is named after the Swedish mathematician Niels Fabian Helge von Koch (25 January 1870 – 11 March 1924).<ref name="ref_8a5323e3">[https://datagenetics.com/blog/january12016/index.html Koch Snowflake]</ref>
 +
# Here is an animation showing the effect of zooming in to a Koch curve.<ref name="ref_8a5323e3" />
 +
# To generate a Koch curve we start off with a line of unit length.<ref name="ref_8a5323e3" />
 +
# If you look closely at the formulae you will see that the limit area of a Koch snowflake is exactly 8/5 of the area of the initial triangle.<ref name="ref_8a5323e3" />
 +
# The Koch snowflake is sometimes called the Koch star or the Koch island.2.<ref name="ref_991e5df5">[https://nrich.maths.org/10972 Koch Snowflake Fractals]</ref>
 +
# The rule for generating the Koch snowflake: start with an equilateral triangle.<ref name="ref_991e5df5" />
 +
# It is a member of the fractal family.the Koch snowflake growing here.t more about fractals.<ref name="ref_991e5df5" />
 +
# If you’ve doodled in math class, you might have stumbled on a Koch snowflake accidentally.<ref name="ref_d22110c2">[https://blogs.scientificamerican.com/roots-of-unity/a-few-of-my-favorite-spaces-the-koch-snowflake/ A Few of My Favorite Spaces: The Koch Snowflake]</ref>
 +
# The Koch curve also has no tangents anywhere, but von Koch’s geometric construction makes it a lot easier to understand.<ref name="ref_d22110c2" />
 +
# Like many fractals, the Koch snowflake falls through the cracks of our normal conception of dimension.<ref name="ref_d22110c2" />
 +
# Serendipitously, as I was writing this post, my pal Katie Mann, a mathematician at Brown University, shared an important practical application of the Koch snowflake: the Koch pecan pie.<ref name="ref_d22110c2" />
 +
# It can be shown that the Koch curve is continuous at every point, but it is not derivable at any point.<ref name="ref_19b40517">[https://www.gameludere.com/2019/12/11/introduction-to-fractals-koch-snowflake/ Introduction to fractals – Koch snowflake]</ref>
 +
# Therefore we can conclude that the perimeter of the Koch curve and consequently also of the flake has an infinite value, even though the two curves are contained in a bounded region.<ref name="ref_19b40517" />
 +
# At each iteration step, each segment of the Koch curve is replaced by 4 small segments, each of length equal to \(\frac{1}{3}\) of the initial one.<ref name="ref_19b40517" />
 +
# This shape that we're describing right here is called a Koch snowflake.<ref name="ref_cb3cc4d7">[https://www.khanacademy.org/math/geometry-home/geometry-volume-surface-area/koch-snowflake/v/koch-snowflake-fractal Koch snowflake fractal (video)]</ref>
 +
# A Koch snowflake, and it was first described by this gentleman right over here, who is a Swedish mathematician, Niels Fabian Helge von Koch, who I'm sure I'm mispronouncing it.<ref name="ref_cb3cc4d7" />
 +
# So even if you do this an infinite number of times, this shape, this Koch snowflake will never have a larger area than this bounding hexagon.<ref name="ref_cb3cc4d7" />
 +
# And this Koch snowflake will always be bounded.<ref name="ref_cb3cc4d7" />
 +
# In this post, I talk about my personal obsession: the Koch snowflake tessellation.<ref name="ref_6aebc82c">[https://piratefsh.github.io/2020/08/07/koch-tesselation-uncommon-fractal-implementations.html Rare implementations: Koch Snowflake Tessellation]</ref>
 +
# It’s no secret that the Koch snowflake is my favorite fractal and one that got me into computer graphics to start with.<ref name="ref_6aebc82c" />
 +
# There are also a lot of articles on the Koch snowflake out there so I’m not gonna do too much into it.<ref name="ref_6aebc82c" />
 +
# But did you know that the Koch snowflake shape (not just the curve) can be recursed upon?<ref name="ref_6aebc82c" />
 +
# Repeat the above steps on each of the twelve sides of curve 2 to get curve 3, the second iteration of the Koch snowflake.<ref name="ref_2530dfdf">[http://www.cmath.info/html/kochPerimeter.html Resources for Undergraduate Mathematics Students]</ref>
 +
# You should be able to see the similarity between this third iteration of the Koch curve and an actual snowflake.<ref name="ref_2530dfdf" />
 +
# Repeat the process ad infinitum to complete the Koch snowflake curve.<ref name="ref_2530dfdf" />
 +
# Our next fractal is the Koch Snowflake, based on the Koch curve, one of the first fractals ever described.<ref name="ref_7ff15e63">[https://bentrubewriter.com/2012/04/24/fractals-you-can-draw-the-koch-snowflake/ Fractals You Can Draw (The Koch Snowflake or Did It Really Snow In Cleveland In Late April?)]</ref>
 +
# Though it would be difficult, the Koch curve can be drawn as a single line, without lifting your pencil, and without connecting the two ends.<ref name="ref_7ff15e63" />
 +
# The Koch snowflake is the limit approached as the above steps are followed over and over again.<ref name="ref_9b4efbae">[https://handwiki.org/wiki/Koch_snowflake Koch snowflake]</ref>
 +
# The Koch curve originally described by Helge von Koch is constructed with only one of the three sides of the original triangle.<ref name="ref_9b4efbae" />
 +
# A three-dimensional fractal constructed from Koch curves.<ref name="ref_9b4efbae" />
 +
# The Koch snowflake (also known as the Koch curve, Koch star, or Koch island) is a mathematical curve and one of the earliest fractal curves to have been described.<ref name="ref_12d35c37">[https://www.geeksforgeeks.org/koch-curve-koch-snowflake/ Koch Curve or Koch Snowflake]</ref>
 +
# It is based on the Koch curve, which appeared in a 1904 paper titled “On a continuous curve without tangents, constructible from elementary geometry” by the Swedish mathematician Helge von Koch.<ref name="ref_12d35c37" />
 +
# To create the Koch snowflake, one would use F++F++F (an equilateral triangle) as the axiom.<ref name="ref_12d35c37" />
 +
# Complete this recursive procedure to draw one side of the Koch snowflake.<ref name="ref_21f8b86f">[https://bjc.edc.org/June2017/bjc-r/cur/programming/6-recursion/2-projects/2-snowflake.html?topic=nyc_bjc%2F6-recursion-trees-fractals.topic&course=bjc4nyc.html&novideo&noassignment Unit 6 Lab 2: Recursion Projects, Page 2]</ref>
 +
# The Koch snowflake can be simply encoded as a Lindenmayer System with initial string "F-F-F" , String Rewriting rule "F" -> "F+F-F+F" , and angle 60°.<ref name="ref_cb6c717b">[https://archive.lib.msu.edu/crcmath/math/math/k/k116.htm Koch Snowflake]</ref>
 +
# Some beautiful Tilings, a few examples of which are illustrated above, can be made with iterations toward Koch snowflakes.<ref name="ref_cb6c717b" />
 +
# In addition, two sizes of Koch snowflakes in Area ratio 1:3 Tile the Plane, as shown above (Mandelbrot).<ref name="ref_cb6c717b" />
 +
# Basically the Koch Snowflake are just three Koch curves combined to a regular triangle.<ref name="ref_71c983bb">[http://www.fractal-explorer.com/kochsnowflake.html Fractal Explorer]</ref>
 +
# Now each line segment has become a Koch curve.<ref name="ref_2479ae6b">[https://python-with-science.readthedocs.io/en/latest/koch_fractal/koch_fractal.html The Koch Snowflake — python-with-science Ed 0.3.2 documentation]</ref>
 +
# As such, the Koch snowflake offers a pictorial glimpse into the intrinsic unity between finite and infinite realms.<ref name="ref_a708db6d">[https://www.fractalteapot.com/portfolio/koch-curve/ Koch Snowflake]</ref>
 +
# For more details on Koch snowflakes and what I the program does, check out my original article.<ref name="ref_2aa27d6a">[https://smist08.wordpress.com/tag/koch-snowflake/ Stephen Smith's Blog]</ref>
 +
# This tool draws Koch curves that look like snowflakes and stars.<ref name="ref_0c6668e1">[https://onlinemathtools.com/generate-koch-snowflake Generate a Koch Star]</ref>
 +
# The Koch curve is one of the earliest known fractals.<ref name="ref_0c6668e1" />
 +
# Because of its shape, it's also known as Koch island.<ref name="ref_0c6668e1" />
 +
# Renders a simple fractal, the Koch snowflake.<ref name="ref_5e8e6aed">[https://processing.org/examples/koch.html Koch \ Examples \ Processing.org]</ref>
 +
# The one shown in the picture is a Koch snowflake of the 4th iteration.<ref name="ref_c03fce58">[https://www.wikihow.com/Draw-the-Koch-Snowflake How to Draw the Koch Snowflake]</ref>
 +
# In this Grasshopper tutorial, we will study the Koch snowflake Fractal Pattern and how we can model it from scratch.<ref name="ref_69b49b5b">[https://parametrichouse.com/koch-snowflake-fractal-pattern/ Koch snowflake Fractal Pattern]</ref>
 +
# Artwork showing the first four steps (iterations) of the sequence used to generate a Koch snowflake fractal.<ref name="ref_cf872996">[https://www.sciencesource.com/archive/Image/Koch-snowflake-fractal--artwork-SS2768082.html Koch snowflake fractal, artwork]</ref>
 +
===소스===
 +
<references />
  
==블로그==
+
== 메타데이터 ==
  
*  구글 블로그 검색<br>
+
===위키데이터===
** http://blogsearch.google.com/blogsearch?q=
+
* ID : [https://www.wikidata.org/wiki/Q223137 Q223137]
* [http://navercast.naver.com/science/list 네이버 오늘의과학]
+
===Spacy 패턴 목록===
* [http://math.dongascience.com/ 수학동아]
+
* [{'LOWER': 'koch'}, {'LEMMA': 'snowflake'}]
* [http://www.ams.org/mathmoments/ Mathematical Moments from the AMS]
+
* [{'LOWER': 'koch'}, {'LEMMA': 'curve'}]
* [http://betterexplained.com/ BetterExplained]
+
* [{'LOWER': 'koch'}, {'LEMMA': 'star'}]
[[분류:수학노트비공개]]
+
* [{'LOWER': 'koch'}, {'LEMMA': 'island'}]
[[분류:migrate]]
 

2021년 2월 17일 (수) 05:21 기준 최신판

개요

(1) 왼쪽 위의 삼각형의 둘레를 P1 그 옆의 삼각형을 P2, 왼쪽아래를 P3, .... 로 한다면

\(P_{n+1}=\frac{4}{3}(P_{n})\) 의 점화식이 성립되며, 따라서 n 을 무한대로 보내면 둘레는 무한으로 발산한다.


(2) (1)의 순서로 삼각형의 넓이를 S1, S2, ... 라 하자. 정확한 식을 위해 처음 한 변의 길이를 a 라고 하면, \(S_{1} = \frac{\sqrt3}{4}a^2\) 이다.

S2에서 원래 삼각형과 늘어난 삼각형의 길이비는 3:1 이고 넓이비는 9:1 이다. 따라서 \(S_{2} = S_{1} + \frac{3}{9}S_{1}\)

마찬가지로 \(S_{3} = S_{2} + \frac{12}{81}S_{1}\), \(S_{4} = S_{3} + \frac{48}{729}S_{1}\)

즉, 둘째 항부터 등비수열을 이루는 수열이다. 무한등비수열의 공식을 쓰면 \(\lim_{n \to \infty} S_{n}=\frac{8}{5}S_{1}\) 로 수렴한다.


이상의 프랙탈은 코흐의 눈송이 곡선으로, 이외에도 시어핀스키 프랙탈 등이 있다. 프랙탈의 시작은 해안선의 길이를 측정하면서부터라고 전해진다.


(3) 프랙탈의 차원(수학적 매개변수) 유클리드 차원과는 다르게 프랙탈 차원은 대개 정수가 아닌 분수로 표현. 프랙탈을 n개의 완전히 똑같은 부분으로 나누었을 때 전체 도형과 한 부분 사이의 닮음비가 m:1이면 프랙탈 도형의 차원 d는 다음과 같이 정의한다.

\(d = \frac{\log n}{\log m}\)

코흐의 눈송이 곡선을 예로 들어 차원을 계산하면, 4개의 똑같은 부분의 닮음비가 3:1 이므로 차원 d 는 \(\frac{log4}{log3}\)

노트

말뭉치

  1. The Koch snowflake is noteworthy in that it is continuous but nowhere differentiable; that is, at no point on the curve does there exist a tangent line.[1]
  2. The Koch snowflake can be built up iteratively, in a sequence of stages.[2]
  3. The Koch snowflake is the limit approached as the above steps are followed indefinitely.[2]
  4. The Koch curve originally described by Helge von Koch is constructed using only one of the three sides of the original triangle.[2]
  5. In other words, three Koch curves make a Koch snowflake.[2]
  6. The Koch snowflake is a very well-known shape among mathematicians![3]
  7. The 2D Koch snowflake is super cool … are you curious to see what it looks like in 3D?[3]
  8. The Koch snowflake can be simply encoded as a Lindenmayer system with initial string "F--F--F" , string rewriting rule "F" -> "F+F--F+F" , and angle .[4]
  9. Each fractalized side of the triangle is sometimes known as a Koch curve.[4]
  10. Some beautiful tilings, a few examples of which are illustrated above, can be made with iterations toward Koch snowflakes.[4]
  11. In addition, two sizes of Koch snowflakes in area ratio 1:3 tile the plane, as shown above.[4]
  12. d must satisfy As shown above, the Koch snowflake is self-similar with six pieces scaled by 1/3 and one piece scaled by \(1/\sqrt{3}\).[5]
  13. Notice, however, that the boundary of the Koch snowflake consists of three copies of the Koch curve, which has a fractal dimension of 1.26186.[5]
  14. Therefore the Koch snowflake has a perimeter of infinite length.[5]
  15. This variation on the Koch snowflake was created by William Gosper.[5]
  16. The Koch curve is named after the Swedish mathematician Niels Fabian Helge von Koch (25 January 1870 – 11 March 1924).[6]
  17. Here is an animation showing the effect of zooming in to a Koch curve.[6]
  18. To generate a Koch curve we start off with a line of unit length.[6]
  19. If you look closely at the formulae you will see that the limit area of a Koch snowflake is exactly 8/5 of the area of the initial triangle.[6]
  20. The Koch snowflake is sometimes called the Koch star or the Koch island.2.[7]
  21. The rule for generating the Koch snowflake: start with an equilateral triangle.[7]
  22. It is a member of the fractal family.the Koch snowflake growing here.t more about fractals.[7]
  23. If you’ve doodled in math class, you might have stumbled on a Koch snowflake accidentally.[8]
  24. The Koch curve also has no tangents anywhere, but von Koch’s geometric construction makes it a lot easier to understand.[8]
  25. Like many fractals, the Koch snowflake falls through the cracks of our normal conception of dimension.[8]
  26. Serendipitously, as I was writing this post, my pal Katie Mann, a mathematician at Brown University, shared an important practical application of the Koch snowflake: the Koch pecan pie.[8]
  27. It can be shown that the Koch curve is continuous at every point, but it is not derivable at any point.[9]
  28. Therefore we can conclude that the perimeter of the Koch curve and consequently also of the flake has an infinite value, even though the two curves are contained in a bounded region.[9]
  29. At each iteration step, each segment of the Koch curve is replaced by 4 small segments, each of length equal to \(\frac{1}{3}\) of the initial one.[9]
  30. This shape that we're describing right here is called a Koch snowflake.[10]
  31. A Koch snowflake, and it was first described by this gentleman right over here, who is a Swedish mathematician, Niels Fabian Helge von Koch, who I'm sure I'm mispronouncing it.[10]
  32. So even if you do this an infinite number of times, this shape, this Koch snowflake will never have a larger area than this bounding hexagon.[10]
  33. And this Koch snowflake will always be bounded.[10]
  34. In this post, I talk about my personal obsession: the Koch snowflake tessellation.[11]
  35. It’s no secret that the Koch snowflake is my favorite fractal and one that got me into computer graphics to start with.[11]
  36. There are also a lot of articles on the Koch snowflake out there so I’m not gonna do too much into it.[11]
  37. But did you know that the Koch snowflake shape (not just the curve) can be recursed upon?[11]
  38. Repeat the above steps on each of the twelve sides of curve 2 to get curve 3, the second iteration of the Koch snowflake.[12]
  39. You should be able to see the similarity between this third iteration of the Koch curve and an actual snowflake.[12]
  40. Repeat the process ad infinitum to complete the Koch snowflake curve.[12]
  41. Our next fractal is the Koch Snowflake, based on the Koch curve, one of the first fractals ever described.[13]
  42. Though it would be difficult, the Koch curve can be drawn as a single line, without lifting your pencil, and without connecting the two ends.[13]
  43. The Koch snowflake is the limit approached as the above steps are followed over and over again.[14]
  44. The Koch curve originally described by Helge von Koch is constructed with only one of the three sides of the original triangle.[14]
  45. A three-dimensional fractal constructed from Koch curves.[14]
  46. The Koch snowflake (also known as the Koch curve, Koch star, or Koch island) is a mathematical curve and one of the earliest fractal curves to have been described.[15]
  47. It is based on the Koch curve, which appeared in a 1904 paper titled “On a continuous curve without tangents, constructible from elementary geometry” by the Swedish mathematician Helge von Koch.[15]
  48. To create the Koch snowflake, one would use F++F++F (an equilateral triangle) as the axiom.[15]
  49. Complete this recursive procedure to draw one side of the Koch snowflake.[16]
  50. The Koch snowflake can be simply encoded as a Lindenmayer System with initial string "F-F-F" , String Rewriting rule "F" -> "F+F-F+F" , and angle 60°.[17]
  51. Some beautiful Tilings, a few examples of which are illustrated above, can be made with iterations toward Koch snowflakes.[17]
  52. In addition, two sizes of Koch snowflakes in Area ratio 1:3 Tile the Plane, as shown above (Mandelbrot).[17]
  53. Basically the Koch Snowflake are just three Koch curves combined to a regular triangle.[18]
  54. Now each line segment has become a Koch curve.[19]
  55. As such, the Koch snowflake offers a pictorial glimpse into the intrinsic unity between finite and infinite realms.[20]
  56. For more details on Koch snowflakes and what I the program does, check out my original article.[21]
  57. This tool draws Koch curves that look like snowflakes and stars.[22]
  58. The Koch curve is one of the earliest known fractals.[22]
  59. Because of its shape, it's also known as Koch island.[22]
  60. Renders a simple fractal, the Koch snowflake.[23]
  61. The one shown in the picture is a Koch snowflake of the 4th iteration.[24]
  62. In this Grasshopper tutorial, we will study the Koch snowflake Fractal Pattern and how we can model it from scratch.[25]
  63. Artwork showing the first four steps (iterations) of the sequence used to generate a Koch snowflake fractal.[26]

소스

메타데이터

위키데이터

Spacy 패턴 목록

  • [{'LOWER': 'koch'}, {'LEMMA': 'snowflake'}]
  • [{'LOWER': 'koch'}, {'LEMMA': 'curve'}]
  • [{'LOWER': 'koch'}, {'LEMMA': 'star'}]
  • [{'LOWER': 'koch'}, {'LEMMA': 'island'}]