MCQ Questions for Class 11 Engineering Maths Sequences And Series Quiz 7

The value of the sum $$1.2.3+2.3.4+3.4.5+.......$$ upto n terms=

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$$\frac{1}{6}n^{2}(2n^{2}+1)$$
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$$\frac{1}{6}n^{2}(n^{2}-1)(2n-1)(2n+3)$$
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$$\frac{1}{8}(n^{2}+1)(n^{2}+5)$$
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$$\frac{1}{4}(n)(n+1)(n+2)(n+3)$$

If the coefficients of $$x^9,x^{10},x^{11}$$ in the expansion of $$(1+x)^n $$ are in arithmetic progression then $$n^2-41n=$$

0%
$$398$$
0%
$$298$$
0%
$$-398$$
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$$198$$

The value of $$\cfrac { 1 }{ \left( 2n-1 \right) !0! } +\cfrac { 1 }{ \left( 2n-3 \right) !2! } +\cfrac { 1 }{ \left( 2n-5 \right) !4! } +....+\cfrac { 1 }{ 1!\left( 2n-2 \right) ! } $$ equal to

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$${ 2 }^{ 2n-1 }$$
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$${ 2 }^{ 2n-2 }$$
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$${ 2 }^{ 2n-3 }$$
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$$\cfrac { { 2 }^{ 2n-2 } }{ \left( 2n-1 \right) ! } $$

If $$x\in R$$, find the minimum value of the expression $$3^x+3^{1-x}$$.

0%
$$3 \sqrt 2$$
0%
$$2 \sqrt 3$$
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$$3 \sqrt 3$$
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none of these

Sum of the series
$${ \left( ^{ 100 }C_{ 1 } \right) }^{ 2 }+2{ \left( ^{ 100 }C_{ 2 } \right) }^{ 2 }+3{ \left( ^{ 100 }C_{ 3 } \right) }^{ 2 }+.....100{ \left( ^{ 100 }C_{ 100 } \right) }^{ 2 }$$ equals:

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$$\dfrac { { 2 }^{ 99 }\left[ 1.3.5.....\left( 199 \right) \right] }{ \left( 99 \right) ! }$$
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$$100.^{ 100 }C_{ 100 }$$
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$$50.^{ 200 }C_{ 100 }$$
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$$100.^{ 199 }C_{ 99 }$$

The sum of the first n terms of the series $$1^2 + 2.2^2 + 3^2 + 2.4^2 + 5^2 + 2.6^2 +$$ ...... is $$\dfrac{n(n + 1)^2}{2}$$ when n is even.When n is odd the sum is -

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$$\displaystyle\frac{3n(n + 1)}{2}$$
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$$ \cfrac { 8{ n }^{ 3 }+6{ n }^{ 2 }+n }{ 3 } $$
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$$\displaystyle\frac{n(n + 1)^2}{4}$$
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$$\displaystyle\left [ \frac{n(n + 1)}{4} \right ]^2$$

Let $$A$$ be the sum of the first $$20$$ terms and $$B$$ be the sum of the first $$40$$ terms of the series $$1^{2} + 2.2^{2} + 3^{2} + 2.4^{2} + 5^{2} + 2.6^{2} + .....$$ If $$B - 2A = 100\lambda$$, then $$\lambda$$ is equal to

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$$464$$
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$$496$$
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$$232$$
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$$248$$

If $$z^2-2z+4=0$$ then the value of $$\left(\displaystyle\frac{z}{2}+\frac{2}{z}\right)^2+\left(\displaystyle\frac{z^2}{4}+\frac{4}{z^2}\right)^2+\left(\displaystyle\frac{z^3}{8}+\frac{8}{z^3}\right)^2+........+\left(\displaystyle\frac{z^{24}}{2^{24}}+\frac{2^{24}}{Z^{24}}\right)^2$$ is equal to.

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$$24$$
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$$32$$
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$$48$$
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None of these

The odd natural numbers have been divided in groups as $$(1, 3); (5, 7, 9, 11); (13, 15, 17, 19, 21, 23); .....$$ Then the sum of numbers in the $$10^{th}$$ group is

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$$4000$$
0%
$$4003$$
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$$4007$$
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$$4008$$

If $$9@ 3 = 12, 15 @ 4 = 22, 16 @ 14 = 4$$, then what is the value of $$6 @ 2 = ?$$

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$$26$$
0%
$$1$$
0%
$$30$$
0%
$$8$$

5	2	7
?	3	1
4	5	2
-15	7	13

Select the missing number from the given alternatives.

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$$1$$
0%
$$5$$
0%
$$9$$
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$$7$$

Select the missing number from the given alternatives.

$$3$$	$$4$$	$$2$$	$$14$$
$$6$$	$$5$$	$$4$$	$$44$$
$$5$$	$$2$$	$$7$$	?

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$$58$$
0%
$$14$$
0%
$$49$$
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$$4$$

If $$12\times 16 = 188$$ and $$14\times 18 = 248$$, then find the value of $$16\times 20 = ?$$

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$$320$$
0%
$$360$$
0%
$$316$$
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$$318$$

Select the missing number from the given alternatives.

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110
0%
115
0%
121
0%
54

If $$28\div 11 = 8, 39\div 21 = 7, 45\div 27 = 4$$, then $$95\div 25 = ?$$

0%
$$11$$
0%
$$9$$
0%
$$16$$
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$$5$$

In a row of girls, Mridula is $$18^{th}$$ from the right and Sanjana is $$18^{th}$$ from the left. If both of them interchange their position, Sanjana becomes $$25^{th}$$ from the left, how many girls are there in the row?

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$$40$$
0%
$$41$$
0%
$$42$$
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$$35$$

Choose the correct answer from the alternatives given :
The sum of $$\dfrac{1}{\sqrt 2 + 1} \, + \, \dfrac{1}{\sqrt 3 + \sqrt 2} \, + \, \dfrac{1}{\sqrt 4 + \sqrt 3} \, + \, ..... \, + \dfrac{1}{\sqrt {100} + \sqrt {99}}$$ is

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$$9$$
0%
$$10$$
0%
$$11$$
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None of these

Choose the correct answer alternatives given.
Select the missing number from the given alternatives.

0%
18
0%
21
0%
5
0%
17

If $$1^{3} + 2^{3} + .... + 10^{3} = 3025$$, then the value of $$2^{3} + 4^{3} + ..... + 20^{3}$$ is

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$$7590$$
0%
$$5060$$
0%
$$24200$$
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$$12100$$

In our number system the base is ten. If the base were changed to four you would count as follows: $$1, 2, 3, 10, 11, 12, 13, 20, 21, 22, 23, 30,....$$ The twentieth number would be:

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$$20$$
0%
$$38$$
0%
$$44$$
0%
$$104$$
0%
$$110$$

The value of the product
$${ 6 }^{ \frac { 1 }{ 2 } }\times { 6 }^{ \frac { 1 }{ 4 } }\times { 6 }^{ \frac { 1 }{ 8 } }\times { 6 }^{ \frac { 1 }{ 16 } }\times ..$$ up to infinite terms is

0%
$$6$$
0%
$$36$$
0%
$$216$$
0%
$$512$$

If a and b are two unequal positive numbers, the:

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$$\frac{2ab}{a+b}>\sqrt{ab}>\frac{a+b}{2}$$
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$$\sqrt{ab}>\frac{2ab}{a+b}>\frac{a+b}{2}$$
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$$\frac{2ab}{a+b}>\frac{a+b}{2}>\sqrt{ab}$$
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$$\frac{a+b}{2}>\frac{2ab}{a+b}>\sqrt{ab}$$
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$$\frac{a+b}{2}>\sqrt{ab}>\frac{2ab}{a+b}$$

If $$y = x+x^2+x^3+...$$ up to infinite terms, where $$ x<1$$, then which one of the following is correct?

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$$x=\dfrac { y }{ 1+y } $$
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$$x=\dfrac { y }{ 1-y } $$
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$$x=\dfrac {1+ y }{ y }$$
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$$x=\dfrac { 1-y }{ y } $$

If $$1.3 + 2.3^2 + 3.3^3 +...+ n.3^n $$= $$\dfrac { (2n-1)3^ a+b }{ 4 }$$ then $$a$$ and $$b$$ are respectively

0%
$$n,2$$
0%
$$n,3$$
0%
$$n +1,2$$
0%
$$n + 1,3$$

The value of $$\dfrac { 1 }{ \log _{ 3 }{ e } } +\dfrac { 1 }{ \log _{ 3 }{ e^2 } } +\dfrac { 1 }{ \log _{ 3 }{ e^4 } } +...$$ up to infinite terms is

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$$\log _{ e }{ 9 } $$
0%
$$0$$
0%
$$1$$
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$$\log _{ e }{ 3 } $$

If $$x =1-y+{ y }^{ 2 }-{ y }^{ 3 }+...$$ upto infinite terms, where |y| < 1, then which one of the following is correct?

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$$x =\frac { 1 }{ 1+y } $$
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$$x =\frac { 1 }{ 1-y } $$
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$$x = \frac { y }{ 1+y }$$
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$$x=\frac { y }{ 1-y } $$

$$\displaystyle \sum _{ k=1 }^{ 6 }{ \left[ sin\frac { 2k\pi }{ 7 } -i\quad cos\quad \frac { 2k\pi }{ 7 } \right] } =$$

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$$-1$$
0%
$$0$$
0%
$$-i$$
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$$i$$

Arrange these numbers in ascending order.
$$756, 567, 657, 676$$

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$$657, 567, 756, 676$$
0%
$$567, 657, 676, 756$$
0%
$$756, 676, 657, 567$$
0%
$$676, 756, 567, 657$$

For some natural $$N$$ , the number of positive integral $$x$$ satisfying the equation,
$$1!+2!+3!+......+(x)!=(N)^2$$ is :

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None
0%
One
0%
Two
0%
Infinite

State True or False.

$$1 \, + \, \dfrac{1}{5} \, + \, \dfrac{3}{5^2} \, + \, \dfrac{5}{5^3} \, + \, ..... \infty$$ = $$\dfrac {13}{8}$$

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True
0%
False

State true or false.
$$ 199.1 + 197.3 + 195.5 +.....3.197 + 1.397 = 666700 $$

0%
True
0%
False

The sum of the given series $$1+3+5+7+9+......+53$$ is $$729$$.

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True
0%
False

If $$S_n=\sum\limits_{r=1}^n \dfrac{2r+1}{r^4+2r^3+r^2}$$ then $$S_{20}$$ =

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$$\dfrac{220}{221}$$
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$$\dfrac{420}{441}$$
0%
$$\dfrac{439}{221}$$
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$$\dfrac{440}{441}$$

The sum to $$50$$ terms of the series $$\dfrac {1}{2} + \dfrac {3}{4} + \dfrac {7}{8} + \dfrac {15}{16} + ....$$ is equal to

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$$2^{50} - 51$$
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$$1 - 2^{-50}$$
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$$2^{-50}+49$$
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$$2^{50} - 1$$

$$\sum\limits_{r=1}^{50}\Big[ \dfrac{1}{49+r}-\dfrac{1}{2r(2r-1)}\Big]=$$

0%
$$\dfrac{1}{50}$$
0%
$$\dfrac{1}{99}$$
0%
$$\dfrac{1}{100}$$
0%
$$\dfrac{1}{101}$$

The value of $$x$$ satisfying the equation $$\dfrac{5050-\left(\dfrac{1}{2}+\dfrac{2}{3}+\dfrac{3}{4}+......+\dfrac{5049}{5050}\right)}{1+\dfrac{1}{2}+\dfrac{1}{3}+......+\dfrac{1}{5050}}=\dfrac{x}{5050}$$ is

0%
$$1$$
0%
$$5049$$
0%
$$5050$$
0%
$$5051$$

If $$1 + {x^2} = \sqrt {3}x $$, then $$\displaystyle \prod\limits_{n = 1}^{24} {\left( {x^n} + \dfrac {1} {x^n} \right)} $$ is equal to

0%
$$48$$
0%
$$-48$$
0%
$$ \pm 48\left( {\omega - {\omega ^2}} \right)$$
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none of these

If $$\left| a \right| < 1$$ and $$\left| b \right| < 1$$ then $$s = 1 + \left( {1 + a} \right)b + \left( {1 + a + {a^2}} \right){b^2} + \left( {1 + a + {a^2} + {a^3}} \right){b^3} + ...is - .$$

0%
$${\dfrac 1 {\left( {1 - b} \right)\left( {1 - ab} \right)}}$$
0%
$${\dfrac 1 {\left( {1 + b} \right)\left( {1 - ab} \right)}}$$
0%
$${\dfrac 1 {\left( {1 - b} \right)\left( {1 + ab} \right)}}$$
0%
$${\dfrac 1 {\left( {1 + b} \right)\left( {1 + ab} \right)}}$$

The sum of the series $$\dfrac{1}{(1\times 2)}+\dfrac{1}{(2\times 3)}+\dfrac{1}{(3\times 4)}+.......+\dfrac{1}{(100\times 101)}$$ is equal to

0%
$$\dfrac{200}{101}$$
0%
$$\dfrac{100}{101}$$
0%
$$\dfrac{50}{101}$$
0%
$$\dfrac{25}{101}$$

If $$\left| a \right| < 1$$ and $$\left| b \right| < 1$$ then $$\eqalign{ & \cr & S = 1 + \left( {1 + a} \right)b + \left( {1 + a + {a^2} } \right){b^2} + ...} $$=

0%
$${1 \over {\left( {1 - b} \right)\left( {1 - ab} \right)}}$$
0%
$${1 \over {\left( {1 + b} \right)\left( {1 - ab} \right)}}$$
0%
$${1 \over {\left( {1 - b} \right)\left( {1 + ab} \right)}}$$
0%
$${1 \over {\left( {1 + b} \right)\left( {1 + ab} \right)}}$$

If $$(1+3+5+....+p)+(1+3+5+....+q)=(1+3+5+.....+r),$$ where each set of parentheses contains the sum of consecutive odd integers as shown, the smallest possible value of $$p+q+r$$, (where $$P>6$$ ) is :

0%
$$12$$
0%
$$21$$
0%
$$27$$
0%
$$24$$

Let $$T_{n}=\displaystyle \sum _{ r=1 }^{ n }{ \dfrac { n }{ { r }^{ 2 }-2r.n+2{ n }^{ 2 } } ,{ S }_{ n }=\displaystyle \sum _{ r=0 }^{ n-1 }{ \dfrac { n }{ { r }^{ 2 }-2r.n+{ 2n }^{ 2 } } } }$$, then

0%
$$T_{n} > S_{n} \forall n \epsilon N$$
0%
$$T_{n} > \dfrac{\pi}{4}$$
0%
$$S_{n} < \dfrac{\pi}{4}$$
0%
$$\displaystyle \lim _{ n-\infty }{ { S }_{ n }=\dfrac { \pi }{ 4 } }$$

If $$S_{n}=\dfrac {3}{2}+\dfrac {33}{2^{2}}+\dfrac {333}{2^{2}}+....$$ upto $$n$$ terms $$=\dfrac {a^{n+1}+b^{b-n}-c}{d}$$ (where $$a,b,c,d \epsilon\ N$$), then ?

0%
$$a+b+c+d=28$$
0%
$$b+d=a+c$$
0%
$$a-c=b+d$$
0%
$$d-c=a-b$$

Sum of the series $$1+2.2+3.2^{2}+4.2^{3}+..+100.2^{99}$$ is

0%
$$100.2^{100}+1$$
0%
$$99.2^{100}+1$$
0%
$$99.2^{100}-1$$
0%
$$100.2^{100}-1$$

The value of sum $$\sum _{ n=1 }^{n=\infty }{ \frac { 2 }{ { 3 }^{ n } } is\ equal\ to: } $$

0%
1
0%
3
0%
15/4
0%
7/3

Pam likes the numbers 1689 and 6891. Knowing this, which pair of numbers will she like among the ones below?

0%
1981 and 1891
0%
19 and 91
0%
190 and 160
0%
1198911 and 1168611

Let $${S_n} = \frac{3}{{{1^2}}} + \frac{5}{{{1^2} + {2^3}}} + \frac{7}{{{1^2} + {2^3} + {3^3}}} + \frac{9}{{{1^2} + {2^3} + {3^3} + {4^3}}} + .......{\text{ up to n terms, then }}\mathop {\lim }\limits_{n \to \infty } {S_n}{\text{ }}$$ is equal to

0%
2
0%
3
0%
6
0%
1

$$A = (2 + 1)({2^2} + 1)({2^4} + 1).....\left( {{2^{2016}} + 1} \right)$$. The value of $${\left( {A + 1} \right)^{\frac{1}{{2016}}}}$$ is

0%
$$4$$
0%
$$2016$$
0%
$$^{{2^{4032}}}$$
0%
$$2$$

Let $${n}^{th}$$ term of sequence $$1,2,2,3,3,3,4,4,4,4,5,5,5,5,5,.....$$ is given by $${t}_{n}$$ , then ?

0%
$${t}_{100}=14$$
0%
$${t}_{200}=20$$
0%
$${t}_{300}=24$$
0%
$${t}_{400}=28$$

given relation is $$\frac{1}{n+1} + \frac{1}{n+2}+.....+ \frac{1}{2n}
> \frac{13}{24}$$< for all natural numbers $$n>1$$

0%
True
0%
False

CBSE Questions for Class 11 Engineering Maths Sequences And Series Quiz 7 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Maths Sequences And Series Quiz 7 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

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