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Solution 4.4:6b

From Förberedande kurs i matematik 1

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(Ny sida: {{NAVCONTENT_START}} <center> Bild:4_4_6b-1(2).gif </center> {{NAVCONTENT_STOP}} {{NAVCONTENT_START}} <center> Bild:4_4_6b-2(2).gif </center> {{NAVCONTENT_STOP}})
Current revision (14:38, 13 October 2008) (edit) (undo)
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After moving the terms over to the left-hand side, so that
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<center> [[Bild:4_4_6b-1(2).gif]] </center>
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{{NAVCONTENT_STOP}}
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{{Displayed math||<math>\sqrt{2}\sin x\cos x-\cos x=0</math>}}
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{{NAVCONTENT_START}}
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<center> [[Bild:4_4_6b-2(2).gif]] </center>
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we see that we can take out a common factor <math>\cos x</math>,
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{{NAVCONTENT_STOP}}
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{{Displayed math||<math>\cos x (\sqrt{2}\sin x-1) = 0</math>}}
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and that the equation is only satisfied if at least one of the factors <math>\cos x</math> or <math>\sqrt{2}\sin x - 1</math> is zero. Thus, there are two cases:
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<math>\cos x=0:</math>
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This basic equation has solutions <math>x=\pi/2</math> and <math>x=3\pi/2</math> in the unit circle, and from this we see that the general solution is
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{{Displayed math||<math>x=\frac{\pi}{2}+2n\pi\qquad\text{and}\qquad x=\frac{3\pi }{2}+2n\pi\,,</math>}}
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where ''n'' is an arbitrary integer. Because the angles <math>\pi/2</math> and
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<math>3\pi/2</math> differ by <math>\pi</math>, the solutions can be summarized as
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{{Displayed math||<math>x=\frac{\pi}{2}+n\pi\,,</math>}}
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where ''n'' is an arbitrary integer.
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<math>\sqrt{2}\sin x - 1 = 0:</math>
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If we rearrange the equation, we obtain the basic equation as <math>\sin x = 1/\!\sqrt{2}</math>, which has the solutions <math>x=\pi/4</math> and <math>x=3\pi /4</math> in the unit circle and hence the general solution
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{{Displayed math||<math>x=\frac{\pi}{4}+2n\pi\qquad\text{and}\qquad x=\frac{3\pi }{4}+2n\pi\,,</math>}}
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where ''n'' is an arbitrary integer.
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All in all, the original equation has the solutions
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{{Displayed math||<math>\left\{\begin{align}
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x &= \frac{\pi}{4}+2n\pi\,,\\[5pt]
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x &= \frac{\pi}{2}+n\pi\,,\\[5pt]
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x &= \frac{3\pi}{4}+2n\pi\,,
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\end{align}\right.</math>}}
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where ''n'' is an arbitrary integer.

Current revision

After moving the terms over to the left-hand side, so that

2sinxcosxcosx=0 

we see that we can take out a common factor cosx,

cosx(2sinx1)=0 

and that the equation is only satisfied if at least one of the factors cosx or 2sinx1  is zero. Thus, there are two cases:


cosx=0:

This basic equation has solutions x=2 and x=32 in the unit circle, and from this we see that the general solution is

x=2+2nandx=23+2n

where n is an arbitrary integer. Because the angles 2 and 32 differ by , the solutions can be summarized as

x=2+n

where n is an arbitrary integer.


2sinx1=0: 

If we rearrange the equation, we obtain the basic equation as sinx=12 , which has the solutions x=4 and x=34 in the unit circle and hence the general solution

x=4+2nandx=43+2n

where n is an arbitrary integer.


All in all, the original equation has the solutions

xxx=4+2n=2+n=43+2n

where n is an arbitrary integer.

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