All categories

2 years ago

Find the value of cosAcos2Acos3A...........cos998Acos999A where A=2π/1999

2 answers:

7 0

Hello,

Here is the demonstration in the book Person Guide to Mathematic by Khattar Dinesh.

Let's assume
P=cos(a)*cos(2a)*cos(3a)*....*cos(998a)*cos(999a)
Q=sin(a)*sin(2a)*sin(3a)*....*sin(998a)*sin(999a)

As sin x *cos x=sin (2x) /2

P*Q=1/2*sin(2a)*1/2sin(4a)*1/2*sin(6a)*....
   *1/2* sin(2*998a)*1/2*sin(2*999a) (there are 999 factors)
= 1/(2^999) * sin(2a)*sin(4a)*...
   *sin(998a)*sin(1000a)*sin(1002a)*....*sin(1996a)*sin(1998a)
as sin(x)=-sin(2pi-x) and 2pi=1999a

sin(1000a)=-sin(2pi-1000a)=-sin(1999a-1000a)=-sin(999a)
sin(1002a)=-sin(2pi-1002a)=-sin(1999a-1002a)=-sin(997a)
...
sin(1996a)=-sin(2pi-1996a)=-sin(1999a-1996a)=-sin(3a)
sin(1998a)=-sin(2pi-1998a)=-sin(1999a-1998a)=-sin(a)

So sin(2a)*sin(4a)*...
   *sin(998a)*sin(1000a)*sin(1002a)*....*sin(1996a)*sin(1998a)
= sin(a)*sin(2a)*sin(3a)*....*sin(998)*sin(999) since there are 500 sign "-".

Thus
P*Q=1/2^999*Q or Q!=0 then
P=1/(2^999)

wel2 years ago

3 0

Answer:

The value of given expression is $\frac{1}{2^{999}}$ .

Step-by-step explanation:

The given expression is

$\cos A\cos 2A\cos 3A...........\cos 998A\cos 999A$

where, $A=\frac{2\pi}{1999}$

Let as assume,

$P=\cos A\cos 2A\cos 3A...........\cos 998A\cos 999A$

$Q=\sin A\sin 2A\sin 3A...........\sin 998A\sin 999A$

$2^{999}PQ=2^{999}(\cos A\cos 2A.........\cos 999A)$ $(\sin A\sin 2A........\sin 999A)$

$2^{999}PQ=(2\cos A\sin A)(2\cos 2A\sin 2A)...........(2\cos 998A\sin 998A)(2\cos 999A\sin 999A)$

Using the formula, $2\sin x\cos x=\sin 2x$ , we get

$2^{999}PQ=\sin 2A\sin 4A......\sin 1998A$

$2^{999}PQ=[\sin 2A\sin 4A......\sin 998A][-\sin(2\pi -1000A)][-\sin(2\pi -1002A)]...[-\sin(2\pi -1998A)]$ .... (1)

Now,

$-\sin(2\pi -1000A)=-\sin(2\pi -1000(\frac{2\pi}{1999}))$

$-\sin(2\pi -1000A)=-\sin(\frac{2\pi\cdot 999}{1999})$

$-\sin(2\pi -1000A)=-\sin 999A$

So, equation (1) can be written as

$2^{999}PQ=[\sin 2A\sin 4A......\sin 998A][\sin 999A\sin 997...\sin A]$

$2^{999}PQ=\sin A\sin 2A\sin 3A...........\sin 998A\sin 999A$

$2^{999}PQ=Q$

Divide both sides by Q.

$2^{999}P=1$

Divide both sides by $2^{999}$

$P=\frac{1}{2^{999}}$

Therefore the value of given expression is $\frac{1}{2^{999}}$ .

You might be interested in

Given ED, DB which statements about the figure are true? Check all that apply.

Klio2033 [76]

Answer: EB is bisected by DF

A is the midpoint DF

EB is a segment bisector

FA=1/2FC.

Step-by-step explanation:

6 0

2 years ago

Henry has quarters, dimes, nickels and pennies in a coin jar. He says that the total amount of money is two dollars and forty-on

Gala2k [10]

Answer: D

Step-by-step explanation:

All would add up to 241 instead of 2.41 because you are not using decimals for the constants (Example: 25q not .25q)

7 0

2 years ago

Complete the statement to describe the expression ab+cd+ef+ghab+cd+ef+gha, b, plus, c, d, plus, e, f, plus, g, h. The expression

solmaris [256]

Answer:

The expression contains FOUR terms and each term contains TWO factors.

Step-by-step explanation:

In algebra, the word term refers to single numbers(10), variables(y) also the product of the two(10y).

In the given expression : ab+cd+ef+gh .

We have four terms;

A factor is part of a product. For the given equation we Four terms each term will have two factors.

ab- is a product of factor a and b
cd- is a product of factor c and d

ef-is a product of factor e and f
gh-is a product of factor g and h

5 0

2 years ago

Peter is at a lumber yard. He gets 2 free boxes of nails for every 10 boards he buys. Write an expression for the number of boxe

Sati [7]

A. The number of 10-boards Peter bought is equal to n divided by 10. Then, each of the 10-boxes will get two boxes of nails. The number of boxes of nails that Peter will have after buying n boards will be,

N = (2)(n/10)

Simplifying,

 N = n/5

b. If the number of boards are 90 then,

N2 = (90/10)(2)(100 nails/box)
N2 = 1800

Answer: 1800

7 0

2 years ago

Read 2 more answers

Find two complex numbers that have a sum of i10 a different of -4and a product of -29

lianna [129]

Step-by-step explanation:

Let the complex numbers be $a+ib\textrm{ and }c+id$ .