Interpreting images representing geometric series The 2019 Stack Overflow Developer Survey Results Are InFind the common ratio of the geometric series with the sum and the first termGeometric Series, finding the r valueGeometric Series of $a = 2$, $r = 2$Unexpected result while calculation geometric series sumWhen is a Power Series a Geometric Series?Name for Finite Geometric Series Summing to 1Geometric Series Question Variable answerGeometric series : Find common ration 'r'In what sense is a geometric series geometric?Substitution in Infinite Geometric Series
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Interpreting images representing geometric series
The 2019 Stack Overflow Developer Survey Results Are InFind the common ratio of the geometric series with the sum and the first termGeometric Series, finding the r valueGeometric Series of $a = 2$, $r = 2$Unexpected result while calculation geometric series sumWhen is a Power Series a Geometric Series?Name for Finite Geometric Series Summing to 1Geometric Series Question Variable answerGeometric series : Find common ration 'r'In what sense is a geometric series geometric?Substitution in Infinite Geometric Series
$begingroup$
I understand the formula for infinite geometric series as
$$S = fraca_11-r$$ if $0<r<1$
However I'm having trouble applying it to these images 
It seems to me that in the first image, the first square represents 1/4 of the entire square
For the second and third images, the respective rectangle and triangle make up 1/2 of the entire square.
Not sure what to do with this. Does it mean that for the first image for example, the image is $$sum_n=0^infty left(frac14right)^n$$
sequences-and-series algebra-precalculus geometric-series
edited Apr 7 at 5:43
Blue
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
$endgroup$
add a comment |
$begingroup$
I understand the formula for infinite geometric series as
$$S = fraca_11-r$$ if $0<r<1$
However I'm having trouble applying it to these images
It seems to me that in the first image, the first square represents 1/4 of the entire square
For the second and third images, the respective rectangle and triangle make up 1/2 of the entire square.
Not sure what to do with this. Does it mean that for the first image for example, the image is $$sum_n=0^infty left(frac14right)^n$$
sequences-and-series algebra-precalculus geometric-series
edited Apr 7 at 5:43
Blue
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
$endgroup$
add a comment |
$begingroup$
I understand the formula for infinite geometric series as
$$S = fraca_11-r$$ if $0<r<1$
However I'm having trouble applying it to these images
It seems to me that in the first image, the first square represents 1/4 of the entire square
For the second and third images, the respective rectangle and triangle make up 1/2 of the entire square.
Not sure what to do with this. Does it mean that for the first image for example, the image is $$sum_n=0^infty left(frac14right)^n$$
sequences-and-series algebra-precalculus geometric-series
edited Apr 7 at 5:43
Blue
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
$endgroup$
I understand the formula for infinite geometric series as
$$S = fraca_11-r$$ if $0<r<1$
However I'm having trouble applying it to these images
It seems to me that in the first image, the first square represents 1/4 of the entire square
For the second and third images, the respective rectangle and triangle make up 1/2 of the entire square.
Not sure what to do with this. Does it mean that for the first image for example, the image is $$sum_n=0^infty left(frac14right)^n$$
sequences-and-series algebra-precalculus geometric-series
sequences-and-series algebra-precalculus geometric-series
edited Apr 7 at 5:43
Blue
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
edited Apr 7 at 5:43
Blue
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
edited Apr 7 at 5:43
Blue
49.6k870158
edited Apr 7 at 5:43
Blue
49.6k870158
edited Apr 7 at 5:43
Blue
49.6k870158
49.6k870158
asked Apr 7 at 4:00
user477465user477465
152114
asked Apr 7 at 4:00
user477465user477465
152114
asked Apr 7 at 4:00
user477465user477465
152114
152114
add a comment |
add a comment |
5 Answers
5
active
oldest
votes
$begingroup$
In your first example, with the squares, you color in $(frac14)^n$ with each new square. These squares add to $sum_n=1^infty (frac14)^n = fracfrac141-frac14=frac13.$
In your second example, with the rectangles, the first rectangle is $frac12$ of the square, but your second rectangle is $frac14cdotfrac12$, so this sum is $frac12 sum_n=0^infty (frac14)^n = frac12cdotfrac11-frac14=frac12cdotfrac43=frac23.$
Your triangles also sum in the same way to $frac23.$
answered Apr 7 at 4:18
mjwmjw
3037
$endgroup$
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
add a comment |
$begingroup$
You are correct, in the first image the largest gray square is $frac 12 times frac 12$ of the original square area. Now what is the area of the next gray square? It might help to continue the sides of the first gray square to the other side of the original square. The idea is that the sides of the gray squares form a geometric progression, as does the area of the gray squares. What is the sum of the progression of the sides? What is the ratio of that progression? What is the ratio of the progression of the areas?
The same ideas will solve the others.
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
$endgroup$
add a comment |
$begingroup$
You can solve these without geometric series.
Say the proportion of coverage of the first image is $s$. Split the first image up into four squares. The topleft and bottomright are not covered at all. The bottomleft square is fully covered. And the topright square? Well it's covered in exactly the same way as $s$ itself. So we find:
[s = frac14(0 + s + 1 + 0)]
[4s = 1 + s]
[s = frac13]
Similarly for the other images we find equations $s = frac14(1 + s + 1 + 0)$ and $s = frac14(frac12 + s + 1 + frac12)$.
answered Apr 7 at 11:34
orlporlp
7,6491433
$endgroup$
add a comment |
$begingroup$
The first terms are $1/4; 1/2; 1/2$, respectively.
The second and following terms are $1/4$ times the previous. To see this: take next smaller figure and place it inside previous figure to check four of them can fill it.
Knowing the first term $a_1$ and the ratio $r$, you can use the sum formula $S=fraca_11-r$.
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
$endgroup$
add a comment |
$begingroup$
1) The area of the first shaded square is a fourth part of the original square: $frac14$. The area of the second shaded square is a fourth of a fourth of the original area: $frac14cdotfrac14$. The area of the third square would be a fourth of that: $frac14cdotfrac14cdotfrac14$. Do you see the pattern?
$$
frac14+left(frac14cdotfrac14right)+left(frac14cdotfrac14cdotfrac14right)+...=\
left(frac14right)^1+left(frac14right)^2+left(frac14right)^3+...=\
sum_n=1^inftyleft(frac14right)^n=
sum_n=0^inftyleft(frac14right)^n-1=
frac11-frac14-1=frac43-1=frac13.
$$
2) The first rectangle is area $frac12$. The second is a half of the original area divided by four $frac12cdotfrac14$. The third part is one fourt of that $frac12cdotfrac14cdotfrac14$:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
3) The first triangle is area $frac12$. The second triangle is area $frac12cdotfrac14$ (a fourth part of a half of the original triangle). The third triangle is going to have area $frac12cdotfrac14cdotfrac14$. I think you see that the pattern is the same as in the previous case:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
$endgroup$
add a comment |
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5 Answers
5
active
oldest
votes
5 Answers
5
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
In your first example, with the squares, you color in $(frac14)^n$ with each new square. These squares add to $sum_n=1^infty (frac14)^n = fracfrac141-frac14=frac13.$
In your second example, with the rectangles, the first rectangle is $frac12$ of the square, but your second rectangle is $frac14cdotfrac12$, so this sum is $frac12 sum_n=0^infty (frac14)^n = frac12cdotfrac11-frac14=frac12cdotfrac43=frac23.$
Your triangles also sum in the same way to $frac23.$
answered Apr 7 at 4:18
mjwmjw
3037
$endgroup$
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
add a comment |
$begingroup$
In your first example, with the squares, you color in $(frac14)^n$ with each new square. These squares add to $sum_n=1^infty (frac14)^n = fracfrac141-frac14=frac13.$
In your second example, with the rectangles, the first rectangle is $frac12$ of the square, but your second rectangle is $frac14cdotfrac12$, so this sum is $frac12 sum_n=0^infty (frac14)^n = frac12cdotfrac11-frac14=frac12cdotfrac43=frac23.$
Your triangles also sum in the same way to $frac23.$
answered Apr 7 at 4:18
mjwmjw
3037
$endgroup$
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
add a comment |
$begingroup$
In your first example, with the squares, you color in $(frac14)^n$ with each new square. These squares add to $sum_n=1^infty (frac14)^n = fracfrac141-frac14=frac13.$
In your second example, with the rectangles, the first rectangle is $frac12$ of the square, but your second rectangle is $frac14cdotfrac12$, so this sum is $frac12 sum_n=0^infty (frac14)^n = frac12cdotfrac11-frac14=frac12cdotfrac43=frac23.$
Your triangles also sum in the same way to $frac23.$
answered Apr 7 at 4:18
mjwmjw
3037
$endgroup$
In your first example, with the squares, you color in $(frac14)^n$ with each new square. These squares add to $sum_n=1^infty (frac14)^n = fracfrac141-frac14=frac13.$
In your second example, with the rectangles, the first rectangle is $frac12$ of the square, but your second rectangle is $frac14cdotfrac12$, so this sum is $frac12 sum_n=0^infty (frac14)^n = frac12cdotfrac11-frac14=frac12cdotfrac43=frac23.$
Your triangles also sum in the same way to $frac23.$
answered Apr 7 at 4:18
mjwmjw
3037
edited 2 days ago
answered Apr 7 at 4:18
mjwmjw
3037
answered Apr 7 at 4:18
mjwmjw
3037
answered Apr 7 at 4:18
mjwmjw
3037
3037
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
add a comment |
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
im having trouble understanding the difference between the first image and the second and third
$endgroup$
– user477465
Apr 7 at 4:37
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
i dont understand how you get the formula for the second image as different from the first one
$endgroup$
– user477465
Apr 7 at 4:39
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
In Image 1, the largest square is $frac14$ the total area. In Image 2, the largest rectangle is $frac12$ the total area.
$endgroup$
– mjw
Apr 7 at 4:40
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
$begingroup$
Before doing the calculation: Clearly, the total gray area in Image 1 is less than $frac12$ and the gray areas in Images 2 & 3 are each greater than $frac12$.
$endgroup$
– mjw
Apr 7 at 4:43
add a comment |
$begingroup$
You are correct, in the first image the largest gray square is $frac 12 times frac 12$ of the original square area. Now what is the area of the next gray square? It might help to continue the sides of the first gray square to the other side of the original square. The idea is that the sides of the gray squares form a geometric progression, as does the area of the gray squares. What is the sum of the progression of the sides? What is the ratio of that progression? What is the ratio of the progression of the areas?
The same ideas will solve the others.
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
$endgroup$
add a comment |
$begingroup$
You are correct, in the first image the largest gray square is $frac 12 times frac 12$ of the original square area. Now what is the area of the next gray square? It might help to continue the sides of the first gray square to the other side of the original square. The idea is that the sides of the gray squares form a geometric progression, as does the area of the gray squares. What is the sum of the progression of the sides? What is the ratio of that progression? What is the ratio of the progression of the areas?
The same ideas will solve the others.
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
$endgroup$
add a comment |
$begingroup$
You are correct, in the first image the largest gray square is $frac 12 times frac 12$ of the original square area. Now what is the area of the next gray square? It might help to continue the sides of the first gray square to the other side of the original square. The idea is that the sides of the gray squares form a geometric progression, as does the area of the gray squares. What is the sum of the progression of the sides? What is the ratio of that progression? What is the ratio of the progression of the areas?
The same ideas will solve the others.
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
$endgroup$
You are correct, in the first image the largest gray square is $frac 12 times frac 12$ of the original square area. Now what is the area of the next gray square? It might help to continue the sides of the first gray square to the other side of the original square. The idea is that the sides of the gray squares form a geometric progression, as does the area of the gray squares. What is the sum of the progression of the sides? What is the ratio of that progression? What is the ratio of the progression of the areas?
The same ideas will solve the others.
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
answered Apr 7 at 4:05
Ross MillikanRoss Millikan
301k24200375
301k24200375
add a comment |
add a comment |
$begingroup$
You can solve these without geometric series.
Say the proportion of coverage of the first image is $s$. Split the first image up into four squares. The topleft and bottomright are not covered at all. The bottomleft square is fully covered. And the topright square? Well it's covered in exactly the same way as $s$ itself. So we find:
[s = frac14(0 + s + 1 + 0)]
[4s = 1 + s]
[s = frac13]
Similarly for the other images we find equations $s = frac14(1 + s + 1 + 0)$ and $s = frac14(frac12 + s + 1 + frac12)$.
answered Apr 7 at 11:34
orlporlp
7,6491433
$endgroup$
add a comment |
$begingroup$
You can solve these without geometric series.
Say the proportion of coverage of the first image is $s$. Split the first image up into four squares. The topleft and bottomright are not covered at all. The bottomleft square is fully covered. And the topright square? Well it's covered in exactly the same way as $s$ itself. So we find:
[s = frac14(0 + s + 1 + 0)]
[4s = 1 + s]
[s = frac13]
Similarly for the other images we find equations $s = frac14(1 + s + 1 + 0)$ and $s = frac14(frac12 + s + 1 + frac12)$.
answered Apr 7 at 11:34
orlporlp
7,6491433
$endgroup$
add a comment |
$begingroup$
You can solve these without geometric series.
Say the proportion of coverage of the first image is $s$. Split the first image up into four squares. The topleft and bottomright are not covered at all. The bottomleft square is fully covered. And the topright square? Well it's covered in exactly the same way as $s$ itself. So we find:
[s = frac14(0 + s + 1 + 0)]
[4s = 1 + s]
[s = frac13]
Similarly for the other images we find equations $s = frac14(1 + s + 1 + 0)$ and $s = frac14(frac12 + s + 1 + frac12)$.
answered Apr 7 at 11:34
orlporlp
7,6491433
$endgroup$
You can solve these without geometric series.
Say the proportion of coverage of the first image is $s$. Split the first image up into four squares. The topleft and bottomright are not covered at all. The bottomleft square is fully covered. And the topright square? Well it's covered in exactly the same way as $s$ itself. So we find:
[s = frac14(0 + s + 1 + 0)]
[4s = 1 + s]
[s = frac13]
Similarly for the other images we find equations $s = frac14(1 + s + 1 + 0)$ and $s = frac14(frac12 + s + 1 + frac12)$.
answered Apr 7 at 11:34
orlporlp
7,6491433
answered Apr 7 at 11:34
orlporlp
7,6491433
answered Apr 7 at 11:34
orlporlp
7,6491433
answered Apr 7 at 11:34
orlporlp
7,6491433
7,6491433
add a comment |
add a comment |
$begingroup$
The first terms are $1/4; 1/2; 1/2$, respectively.
The second and following terms are $1/4$ times the previous. To see this: take next smaller figure and place it inside previous figure to check four of them can fill it.
Knowing the first term $a_1$ and the ratio $r$, you can use the sum formula $S=fraca_11-r$.
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
$endgroup$
add a comment |
$begingroup$
The first terms are $1/4; 1/2; 1/2$, respectively.
The second and following terms are $1/4$ times the previous. To see this: take next smaller figure and place it inside previous figure to check four of them can fill it.
Knowing the first term $a_1$ and the ratio $r$, you can use the sum formula $S=fraca_11-r$.
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
$endgroup$
add a comment |
$begingroup$
The first terms are $1/4; 1/2; 1/2$, respectively.
The second and following terms are $1/4$ times the previous. To see this: take next smaller figure and place it inside previous figure to check four of them can fill it.
Knowing the first term $a_1$ and the ratio $r$, you can use the sum formula $S=fraca_11-r$.
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
$endgroup$
The first terms are $1/4; 1/2; 1/2$, respectively.
The second and following terms are $1/4$ times the previous. To see this: take next smaller figure and place it inside previous figure to check four of them can fill it.
Knowing the first term $a_1$ and the ratio $r$, you can use the sum formula $S=fraca_11-r$.
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
answered Apr 7 at 5:36
farruhotafarruhota
21.9k2942
21.9k2942
add a comment |
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$begingroup$
1) The area of the first shaded square is a fourth part of the original square: $frac14$. The area of the second shaded square is a fourth of a fourth of the original area: $frac14cdotfrac14$. The area of the third square would be a fourth of that: $frac14cdotfrac14cdotfrac14$. Do you see the pattern?
$$
frac14+left(frac14cdotfrac14right)+left(frac14cdotfrac14cdotfrac14right)+...=\
left(frac14right)^1+left(frac14right)^2+left(frac14right)^3+...=\
sum_n=1^inftyleft(frac14right)^n=
sum_n=0^inftyleft(frac14right)^n-1=
frac11-frac14-1=frac43-1=frac13.
$$
2) The first rectangle is area $frac12$. The second is a half of the original area divided by four $frac12cdotfrac14$. The third part is one fourt of that $frac12cdotfrac14cdotfrac14$:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
3) The first triangle is area $frac12$. The second triangle is area $frac12cdotfrac14$ (a fourth part of a half of the original triangle). The third triangle is going to have area $frac12cdotfrac14cdotfrac14$. I think you see that the pattern is the same as in the previous case:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
$endgroup$
add a comment |
$begingroup$
1) The area of the first shaded square is a fourth part of the original square: $frac14$. The area of the second shaded square is a fourth of a fourth of the original area: $frac14cdotfrac14$. The area of the third square would be a fourth of that: $frac14cdotfrac14cdotfrac14$. Do you see the pattern?
$$
frac14+left(frac14cdotfrac14right)+left(frac14cdotfrac14cdotfrac14right)+...=\
left(frac14right)^1+left(frac14right)^2+left(frac14right)^3+...=\
sum_n=1^inftyleft(frac14right)^n=
sum_n=0^inftyleft(frac14right)^n-1=
frac11-frac14-1=frac43-1=frac13.
$$
2) The first rectangle is area $frac12$. The second is a half of the original area divided by four $frac12cdotfrac14$. The third part is one fourt of that $frac12cdotfrac14cdotfrac14$:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
3) The first triangle is area $frac12$. The second triangle is area $frac12cdotfrac14$ (a fourth part of a half of the original triangle). The third triangle is going to have area $frac12cdotfrac14cdotfrac14$. I think you see that the pattern is the same as in the previous case:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
$endgroup$
add a comment |
$begingroup$
1) The area of the first shaded square is a fourth part of the original square: $frac14$. The area of the second shaded square is a fourth of a fourth of the original area: $frac14cdotfrac14$. The area of the third square would be a fourth of that: $frac14cdotfrac14cdotfrac14$. Do you see the pattern?
$$
frac14+left(frac14cdotfrac14right)+left(frac14cdotfrac14cdotfrac14right)+...=\
left(frac14right)^1+left(frac14right)^2+left(frac14right)^3+...=\
sum_n=1^inftyleft(frac14right)^n=
sum_n=0^inftyleft(frac14right)^n-1=
frac11-frac14-1=frac43-1=frac13.
$$
2) The first rectangle is area $frac12$. The second is a half of the original area divided by four $frac12cdotfrac14$. The third part is one fourt of that $frac12cdotfrac14cdotfrac14$:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
3) The first triangle is area $frac12$. The second triangle is area $frac12cdotfrac14$ (a fourth part of a half of the original triangle). The third triangle is going to have area $frac12cdotfrac14cdotfrac14$. I think you see that the pattern is the same as in the previous case:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
$endgroup$
1) The area of the first shaded square is a fourth part of the original square: $frac14$. The area of the second shaded square is a fourth of a fourth of the original area: $frac14cdotfrac14$. The area of the third square would be a fourth of that: $frac14cdotfrac14cdotfrac14$. Do you see the pattern?
$$
frac14+left(frac14cdotfrac14right)+left(frac14cdotfrac14cdotfrac14right)+...=\
left(frac14right)^1+left(frac14right)^2+left(frac14right)^3+...=\
sum_n=1^inftyleft(frac14right)^n=
sum_n=0^inftyleft(frac14right)^n-1=
frac11-frac14-1=frac43-1=frac13.
$$
2) The first rectangle is area $frac12$. The second is a half of the original area divided by four $frac12cdotfrac14$. The third part is one fourt of that $frac12cdotfrac14cdotfrac14$:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
3) The first triangle is area $frac12$. The second triangle is area $frac12cdotfrac14$ (a fourth part of a half of the original triangle). The third triangle is going to have area $frac12cdotfrac14cdotfrac14$. I think you see that the pattern is the same as in the previous case:
$$
frac12+left(frac12cdotfrac14right)+left(frac12cdotfrac14cdotfrac14right)+...=\
frac12left(frac14right)^0+frac12left(frac14right)^1+
frac12left(frac14right)^2+...=\
sum_n=0^inftyfrac12left(frac14right)^n=frac12cdotfrac11-frac14=frac23.
$$
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
answered Apr 7 at 4:43
Michael RybkinMichael Rybkin
4,279422
4,279422
add a comment |
add a comment |
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