Problems about trigonometry

READ THIS FIRST
Identities
Geometric problems
Equations
Other problems

READ THIS FIRST

These exercises are based on the theory treated on the page Trigonometry

If a problem is solved. It is not 'the' answer.
No attempt is made to search for the most elegant answer.
I highly recommend that you at least try to solve the problem before you read the solution.

Identities

 

prove that :

cos(t)+sin(t)      cos(2t)
------------- = -------------
cos(t)-sin(t)     1- sin(2t)

 
  cos(2t)
---------- =
 1- sin(2t)


cos²(t)-sin²(t)
---------------    =
1-2sin(t)cos(t)

     (cos(t)-sin(t))(cos(t)+sin(t))
------------------------------------------ =
  cos(t)cos(t)-2sin(t)cos(t)+sin(t)sin(t)

(cos(t)-sin(t))(cos(t)+sin(t))
------------------------------- =
(cos(t)-sin(t))(cos(t)-sin(t))

cos(t)+sin(t)
------------
cos(t)-sin(t)

 

show that

sin(p)-sin(q)         p+q
-------------- = cot(-----)
cos(q)-cos(p)          2

 

sin(p)-sin(q)
-------------- =
cos(q)-cos(p)

2cos((p+q)/2)sin((p-q)/2)
-------------------------- =
-2sin((p+q)/2)sin((q-p)/2)

cos((p+q)/2)
------------ =
sin((p+q)/2)

      p+q
 cot(-----)
       2

Three real numbers a,b,c are successive terms of an arithmetic sequence. Show that

 
sin(a)+sin(b)+sin(c)
--------------------- = tan(b)
cos(a)+cos(b)+cos(c)

We can represent the tree terms by b-v,b,b+v . Then we have to show that

 
sin(b-v)+sin(b)+sin(b+v)
------------------------- = tan(b) <=>
cos(b-v)+cos(b)+cos(b+v)


2sin(b)cos(v)+sin(b)
--------------------- = tan(b) <=>
2cos(b)cos(v)+cos(b)


sin(b)(2cos(v)+1)
----------------- = tan(b) <=>
cos(b)(2cos(v)+1)


sin(b)
------- = tan(b)
cos(b)

 
Given: a+b+c=pi
Prove that cos(2a)+cos(2b)+cos(2c)+1=-4cos(a)cos(b)cos(c)

 
cos(2a)+cos(2b)+cos(2c)+1=

2cos(a+b)cos(a-b)+2cos² (c) =

        but     a+b=pi-c =>cos(a+b)=-cos(c)

-2cos(c)cos(a-b)+2cos²(c) =

-2cos(c).(cos(a-b)-cos(c)) =

-2cos(c).(cos(a-b)-cos(a+b)) =

-2cos(c).2cos(a)cos(b) =

-4cos(a)cos(b)cos(c)

Prove that tan(pi/8) = sqrt(2) - 1

We know that tan(pi/4) = 1.
Let tan(pi/8) = x .
We know that

 
              2 tan(u)
tan(2u)  = ---------------
            1- tan(u)tan(u)

Make u = pi/8

 
               2 x
        1  = -------
              1- x.x

<=>     x² + 2x - 1 = 0

Since tan(pi/8) is positive, we only take the positive root.

        x = sqrt(2) - 1

a+b+c=pi . Prove that tan(a)+tan(b)+tan(c) =tan(a).tan(b).tan(c)

 
        b+c = pi - a

=>      tan(b+c) = tan(pi - a)

        tan(b) + tan(c)
=>      ----------------- = -tan(a)
        1 - tan(b).tan(c)


=>      tan(b) +tan(c) = -tan(a).(1 - tan(b).tan(c))

=>      tan(a)+tan(b)+tan(c) =tan(a).tan(b).tan(c)

 
Prove that sin(7.pi/12) = (sqrt(6) +sqrt(2))/4

 
sin(7.pi/12) = sin (pi/3 + pi/4)

= sin(pi/3).cos(pi/4) + cos(pi/3).sin(pi/4)

= sqrt(3)/2 .sqrt(2)/2 + 1/2 . sqrt(2)/2

= (sqrt(6) +sqrt(2))/4

 
a+b+c=pi. Prove that
 

cos(a).cos(a) + cos(b).cos(b) + cos(c).cos(c) + 2cos(a).cos(b).cos(c) =1

 
        a+b = pi - c

=>      cos(a+b) = cos(pi - c)

=>      cos(a+b) = -cos(c)

=>      cos(a).cos(b) - sin(a).sin(b) = - cos(c)

=>      cos(a).cos(b) + cos(c) = sin(a).sin(b)

=>      (cos(a).cos(b) + cos(c))²  = (sin(a).sin(b))²


=>      (cos(a).cos(b))² +2.cos(a).cos(b).cos(c) + cos²(c)

                        = (1 -  cos²(a)).(1 - cos²(b))

=>      ...


=> cos(a).cos(a) + cos(b).cos(b) + cos(c).cos(c) + 2cos(a).cos(b).cos(c) =1

 
Prove that

sin(a) + sin(b) + sin(c)

  = sin(a + b + c) + 4sin((b+c)/2) sin((c+a)/2) sin((a+b)/2)

 
                        a + b      a - b
sin(a) + sin(b) = 2 sin(-----) cos(-----)
                          2          2

                                a + b + 2 c     a + b
sin(a + b + c) - sin(c) = 2 cos ----------- sin(-----)
                                     2            2

Then

        sin(a)+ sin(b) + sin(c) - sin(a + b + c)

                a + b       a - b        a + b + 2 c
        = 2 sin(-----) (cos(-----) - cos ----------- )
                  2           2               2

                a + b         a + c     b + c
        = 2 sin(-----).2  sin(-----)sin(-----)
                  2             2         2

               b + c      c + a      a + b
        = 4sin(-----) sin(-----) sin(-----)
                 2          2          2

 
Show that  sin(2 arctan(x)) = 2x/(1 + x²)

 
Let a = arctan(x)  then tan(a) = x

sin(2 arctan(x)) = sin(2a) = 2sin(a)cos(a) = 2 tan(a).cos(a).cos(a)

           2 tan(a)
        = -------------------
          1 + tan²(a)

        = 2x/(1 + x²)

 
tan(a) and  tan(b) are the roots of x² + p.x + q = 0

Prove that

sin(a+b).sin(a+b) + p.sin(a+b).cos(a+b) + q.cos(a+b).cos(a+b) = q

 
tan(a) + tan(b) = -p and tan(a).tan(b) = q

sin(a+b).sin(a+b) + p.sin(a+b).cos(a+b) + q.cos(a+b).cos(a+b)

  sin(a+b).sin(a+b) + p.sin(a+b).cos(a+b) + q.cos(a+b).cos(a+b)
= -------------------------------------------------------------
           sin(a+b).sin(a+b) + cos(a+b).cos(a+b)

    divide numerator and denominator by cos(a+b).cos(a+b)

  tan(a+b).tan(a+b)+ p.tan(a+b) +q
= ---------------------------------
  tan(a+b).tan(a+b) + 1


   tan(a) + tan(b)    tan(a) + tan(b)     tan(a) + tan(b)
   -----------------. --------------- + p ----------------  +q
   1 - tan(a)tan(b)   1 - tan(a)tan(b)    1 - tan(a)tan(b)
= ----------------------------------------------------------------
   tan(a) + tan(b)    tan(a) + tan(b)
   ---------------- . ---------------- + 1
   1 - tan(a)tan(b)   1 - tan(a)tan(b)

    - p     - p         - p
   ------. ------ + p. ------ + q
   1 - q   1 - q       1 - q
= ----------------------------------
    - p     - p
   ------ .------  + 1
   1 - q   1 - q

= .... a little algebra

= q

 
 The angles of a triangle ABC are a,b and c. Prove that

The triangle is rectangular if and only if

           sin(4a) + sin(4b) + sin(4c) = 0

Part 1: if the triangle is rectangular then sin(4a)+sin(4b)+sin(4c) = 0.

 
        triangle is rectangular => a or b or c is pi/2

Suppose a = pi/2, then  sin(4a) = 0 and  b = pi/2 -c

        => 4 b = 2 pi - 4c  => sin(4b) = sin(-4c)

        => sin(4b) + sin(4c) = 0

So      sin(4a) + sin(4b) + sin(4c) = 0

Similar proof for b = pi/2 or c = pi/2

Part 2: if sin(4a)+sin(4b)+sin(4c) = 0 then the triangle is rectangular.

 
        a + b + c = pi

=>      4a + 4b + 4c = 4 pi

=>      4a = 4 pi - (4b + 4c)

=>      sin(4a) = sin( -(4b + 4c)) = - sin(4b + 4c)

=>      sin(4a) = - (sin(4b)cos(4c) + cos(4b)sin(4c))

Thus,

   sin(4a)+sin(4b)+sin(4c)

        = sin(4b) - sin(4b)cos(4c) + sin(4c) - cos(4b)sin(4c)
<=>
        0 = sin(4b) (1 - cos(4c)) + sin(4c) (1 - cos(4b))
<=>
        0 = sin(4b) 2 sin² (2c) + sin(4c).2sin² (2b)
<=>
        0 = 2.sin(2b).cos(2b).2 sin² (2c) +  2.sin(2c).cos(2c).2 sin² (2b)
<=>
        0 = 4.sin(2b).sin(2c).sin(2b + 2c)
<=>
        sin(2b) = 0  or sin(2c) = 0  or sin(2b + 2c) = 0
<=>
        b = pi/2     or c = pi/2     or b + c = pi/2
<=>
        b = pi/2     or c = pi/2     or  a = pi/2

Show that sin(7 pi/12) sin(pi/12) = 1/4

We use the fact that (7 pi/12 + pi/12) and (7 pi/12 - pi/12) are special angles and we use a formula so that sin(7 pi/12) sin(pi/12) occurs.

 
   cos(7 pi/12) cos(pi/12) + sin(7 pi/12) sin(pi/12)

  = cos(pi/2)

  = 0                                (1)

and

   cos(7 pi/12) cos(pi/12) - sin(7 pi/12) sin(pi/12)

  = cos(8 pi/12)

  = cos(2 pi/3)

  = -1/2                             (2)

We calculate (1) - (2)

   2  sin(7 pi/12) sin(pi/12)  = 1/2
<=>
      sin(7 pi/12) sin(pi/12)  = 1/4

Geometric problems

In the figure below the angles in A and B are 60 degrees. Find x.

Let O = the center of the left circle.
Call l the perpendicular to AB through O. l intersects AB in S.
In the triangle AOS, the angle A = 30 degrees. |OS| = 10.
tan(30°)= 10/|AS|. From this we calculate |AS|.
x = |AB| - 2.|AS| - 2.10 = 35.4
In the figure we see a triangle and a hexagon inscribed in the same circle.
Calculate the ratio of the areas of the two figures.
1. First Method:
  The ratio of the areas of the two figures is independent of the radius of the circle. We can therefore assume that the radius is 1.
  Area of the hexagon:
  Connect the center of the circle with the vertices. There arise 6 equilateral triangles with side 1. The area of the hexagon is 6.(1/2).1.1.sin(60°) = 3.sin(60°)
  Area of the triangle:
  Connect the center of the circle with the vertices. There arise 3 isosceles triangles. The area of the triangle is 3.(1/2).1.1.sin(120°) = (3/2) sin(60°)
  We see that the ratio of the areas of the two figures is 2.
2. Second method :
  The ratio of the areas of the two figures is independent of the mutual position of the polygons. We rely on this property to put the triangle in a favorable position. We connect the center with the vertices of the triangle.
  
  There are 6 congruent triangles. Then it is immediately clear that the ratio of the areas of the two figures is 2.

On the unit circle, with center O, we take the fixed points A(1,0) , A'(-1,0) and the variabele point P. The tangent lines in P and A to the circle, intersect in S.
Show that: OS is parallel to A'P.

 
   P(cos(t) , sin(t))

   The triangles OPS and OAS are congruent

=> The slope of OS is tan(t/2)           (*)

                        sin(t) - 0
   The slope of A'P =  ------------
                        cos(t) + 1

                   2 sin(t/2) cos(t/2)
               = -------------------------
                    2 cos²(t/2)

               =  tan(t/2)                  (**)

From (*) and (**) it follows that  A'P // OS

The centers of six congruent circles, with radius 1, are the vertices of a regular hexagon. A red thread is stretched to the circles. Find the area inside the thread.
We divide the area inside the thread into parts, such that the area of each part is easy to calculate.

So, we get :
-> 6 congruent rectangles
-> a regular hexagon
-> 6 congruent circle sectors
The area of a rectangle is 2
The side of the regular hexagon is 2.
```
 
  The area of the  regular hexagon

  = 6. ( area of an equilateral triangle with side = 2)

  = 6. ( (1/2).2.2.sin(60°) )

  = 6. sqrt(3)
```
The 6 circle sectors form together one circle with radius = 1. The area is pi.
The area inside the thread is 12 + 6. sqrt(3) + pi

In a triangle ABC, we have |A,B| = c = 6; |B,C| = a = sqrt(52) ; |C,A| = b = 8.

Find the distance from vertex B to the line AC.

A convex hexagon is inscribed in a circle. The successive sides have a length of 4,4,6,4,4,6 inches.
Find the radius r of the circle and the area of the hexagon.

Make a sketch. Call t the central angle corresponding to a side of 4 inches, and t' is the central angle corresponding to a side of 6 inches.

 
    4t + 2t' = 2 pi , so  t + t'/2  = pi/2

    t and  t'/2 are  complementary angles, so  sin(t'/2) = cos(t)


    sin(t/2) = 2/r and  sin(t'/2) = 3/r

      sin(t/2)      2
=>  ----------- = -----
      sin(t'/2)     3

      sin(t/2)        2
<=>  -----------  = ----
       cos(t)         3

               we know that  1 - cos(t) = 2 sin²(t/2)

       sin(t/2)            2
<=>   ---------------- =  ---
      1 - 2sin²(t/2)      3

<=>   4 sin²(t/2) + 3 sin(t/2) - 2 = 0

  From this, it is easy to find sin(t/2) and t.  t = 50.35°
  Then  t'= 79.30° and  r = 4.7 inches

  The area of the hexagon

= the area of 4 small triangles + the area of 2 bigger triangles

= 4((1/2) r² sin(t)) + 2((1/2) r² sin(t')) = 55.76 square inches.

Equations

 
Solve the quadratic equation in x

    (sin(2a)).x² - 2.x.(sin(a)+cos(a)) +2 =0

 
Discriminant = 4(sin(a)+cos(a))²  - 8.sin(2a)

        = 4.( sin² (a) + 2.sin(a).cos(a) + cos² (a) - 4 sin(a)cos(a) )

        = 4.(sin(a) - cos(a))²

So, the roots are
            sin(a) + cos(a) + sin(a) - cos(a)         1
        x = --------------------------------- =...= ------
                        sin(2a)                     cos(a)
                   1
and     x = ... = ------
                  sin(a)

Solve

 
  cos(2x) + sin²(x) = 1/2

 
<=> cos²(x) - sin²(x) + sin²(x) = 1/2

<=> cos²(x) = 1/2

<=> cos(x) = 1/sqrt(2)  or cos(x) = -1/sqrt(2)

<=> cos(x) = cos(pi/4)  or cos(x) = cos(pi - pi/4)

     ......             or    ......

Solve

 
    2 sin²(3x) + sin²(6x) = 2

 
   2 sin²(3x) + sin²(6x) = 2
<=>
   2 sin²(3x) + 4 sin²(3x).cos²(3x) = 2
<=>
   4 sin²(3x).cos²(3x) - 2 cos²(3x) = 0
<=>
   cos²(3x) ( 2 sin²(3x) -1) = 0
<=>
   cos(3x) = 0  or sin(3x) = 1/sqrt(2) or sin(3x) = -1/sqrt(2)
<=>
    ....   or  .... or ....

Solve

 
   sin³(x) - sin²(x) - sin(x)/4 +1/4 =0

 
<=> sin²(x) . (sin(x) -1) - (sin(x) - 1)/4 = 0

<=>  (sin(x) -1) . ( sin²(x) - 1/4) = 0

<=> sin(x) = 1  or sin(x) = 1/2  or sin(x) = -1/2

<=>  ......     or    ......     or    .....

Solve

 
    1 + sin(x) + cos(x) = 0

 
<=> sin(x) + ( 1+ cos(x))  = 0

<=> 2 sin(x/2).cos(x/2) + 2 cos²(x/2) = 0

<=> 2 cos(x/2) ( sin(x/2) + cos(x/2) ) =0

First case

  cos(x/2) = 0

<=> ....

<=> x = pi + 2.k.pi

Second case

     sin(x/2) = - cos(x/2)

<=>  sin(x/2) = cos( pi - x/2 )

<=>  sin(x/2) = sin(pi/2 - pi + x/2)

<=>  sin(x/2) = sin(-pi/2 + x/2)

<=>   ....

Solve
3sin(x) + cos(x) = 5
Since sin(x) and cos(x) have 1 as an absolute maximum, the equation has no solutions.

 
Solve:

     2.tan(x) = sin(4x) - 2.sin(2x)tan(x)cos(2x)tan(x)

 

<=>      2.tan(x) = sin(4x) - sin(4x).tan² (x)

<=>      2.tan(x) = sin(4x)(1 - tan²(x))

        2.sin(x)    sin(4x).(cos²(x) - sin²(x))
<=>     --------- = ----------------------------
         cos(x)          cos(x).cos(x)

<=>     2.sin(x). cos(x) = sin(4x).(cos² (x) - sin² (x))  and cos(x) not 0

<=>     sin(2x) - 2.sin(2x). cos(2x).cos(2x)  and cos(x) not 0

<=>     sin(2x) .(1 - 2.cos² (2x)) = 0 and cos(x) not 0

<=>     2.sin(x). cos(x).(1 - 2.cos² (2x)) = 0 and cos(x) not 0

<=>     sin(x) = 0  or cos(2x) = 1/sqrt(2) or cos(2x) =-1/sqrt(2)

<=>     x = k.pi  or 2x = pi/4 + k(pi/2)

<=>     x = k.pi  or x = pi/8 + k(pi/4)

 
Given :  cos(2x) = a (cos(x) - sin(x))   (a is a real parameter)

Solve this equation and discuss.

 
        cos(2x) = a (cos(x) - sin(x))

<=>     cos² (x) - sin² (x) = a (cos(x) - sin(x))

<=>     (cos(x) + sin(x))(cos(x) - sin(x)) = a (cos(x) - sin(x))

<=>     (cos(x) - sin(x))(cos(x) + sin(x) -a) = 0

<=>     cos(x) = sin(x)     or   cos(x) + sin(x) -a = 0

<=>    x = pi/4 + k.pi  or      cos(x) + tan(u).sin(x) = a with u = pi/4

<=>    x = pi/4 + k.pi  or cos(u).cos(x)+sin(u).sin(x)=a.cos(u) with u = pi/4

<=>    x = pi/4 + k.pi  or cos(x - u) = a/sqrt(2)         (*)

        The last part has solutions if and only if

                a in [-sqrt(2) , sqrt(2) ]
Case 1 :   a is not in [-sqrt(2) , sqrt(2) ]
        The solutions are x = pi/4 + k.pi

Case 2 :   a in [-sqrt(2) , sqrt(2) ]
        Now it is possible to choose t = arccos(a/sqrt(2))  then (*) gives

        x = pi/4 + k.pi   or
        x = pi/4 + t + 2.k.pi or
        x = pi/4 - t + 2.k.pi

Solve

F = ( 2 sin(2 x) - 1 ) / (cos(2 x) - 3 cos(x) + 2) > 0

with x in [0,2.pi]

 
First we investigate  N = 2 sin(2 x) - 1

        2 sin(2 x) - 1 > 0

<=>     sin(2 x) > 1/2

<=>     pi/6 + 2.k.pi < 2x < 5.pi/6 + 2.k.pi

<=>     pi/12 + k.pi < x < 5.pi/12 + k.pi

Now we investigate  D = cos(2 x) - 3 cos(x) + 2

        cos(2 x) - 3 cos(x) + 2 > 0

<=>     2 cos² (x) - 3 sin(x) + 1 > 0

<=>     2(cos(x) - 1/2)(cos(x) - 1) > 0

                since (cos(x) - 1) =< 0 we have

<=>     cos(x) < 1/2

<=>     pi/3 + 2.k.pi < x < 5.pi/3 + 2.k.pi

Now we see that

          1         4          5          13       17       20
         --pi       --pi       --pi       --pi     --pi     --pi      2pi
x  0     12         12         12         12       12       12
---------------------------------------------------------------------------
T  -   -   0    +    +    +     0     -    0    +   0    -   -     -   -
N  0   -   -    -    0    +     +     +    +    +   +    +   0     -   0
F  |   +   0    -    |    +     0     -    0    +   0    -   |     +   |

From this table we can easily find the solutions of F > 0 in [0, 2.pi].

 
 Solve
            x               1         1          1
        cot(-) - cot(x) = ------ + -------- + --------
            2             sin(x)   sin(2 x)   sin(4 x)

        with x in [0, 2pi]

 
            x
        cot(-) - cot(x)
            2

               x
           cos(-)
               2    cos(x)
        =  ------ - ------
               x    sin(x)
           sin(-)
               2

               x       2 x       2 x
           cos(-)   cos (-) - sin (-)
               2         2         2
        =  ------ - ------------------
               x           x      x
           sin(-)    2 sin(-) cos(-)
               2           2      2



        = ...


                  1
        = -----------------
                  x      x
            2 sin(-) cos(-)
                  2      2
             1
        = --------
           sin(x)

With this result the equation is

            1          1
         -------- + -------- = 0
         sin(2 x)   sin(4 x)

            1            1
<=>      -------- = - --------
         sin(2 x)     sin(4 x)

<=>
        sin(2 x) = - sin(4 x)           with sin(4 x) not 0
<=>
        sin(2 x) = sin(- 4 x)           with sin(4 x) not 0
<=>
        2x = -4x + 2.k.pi  or 2x = pi + 4x + 2.k.pi  with sin(4 x) not 0
<=>
        6x = 2.k.pi or -2x = pi + 2.k.pi        with sin(4 x) not 0
<=>
        x = k.pi/3  or x = -pi/2 - k.pi         with sin(4 x) not 0

The solutions in [0, 2pi] are

        pi/3 ; 2pi/3 ; 4pi/3 ; 5pi/3

 
Solve the equation
         ___
        V 2  (sin(x) + cos(x)) + 2 cos⁴ (x - pi/4 ) = 0

 
First   sin(x) + cos(x)

                       pi
        = sin(x) + sin(-- - x)
                       2
                pi          pi
        = 2 sin(--) cos(x - ---)
                4            4
          ___          pi
        =V 2   cos(x - ---)
                        4

With this, the equation becomes

                  pi          4     pi
        2 cos(x - ---) + 2 cos (x - --- ) = 0
                   4                 4

<=>
                pi                   3     pi
        cos(x - ---) = 0  or  1 + cos (x - --- ) = 0
                 4                          4

<=>          3 pi                       pi
        x =  ---- + k.pi   or   cos(x - ---) = -1
              4                          4

<=>          3 pi                   3 pi
        x =  ---- + k.pi   or   x = ---- + 2.k.pi
              4                      4

<=>
             3 pi
        x =  ---- + k.pi
              4

Solve the equation cos⁶(x) + sin⁶(x) = 5/8

 
       cos⁶(x) + sin⁶(x) = 5/8
<=>

(sin²(x) + cos²(x))³ - 3 sin⁴(x).cos²(x) -3  cos⁴(x).sin²(x) = 5/8

<=>

   1 - 3 sin²(x).cos²(x).(cos²(x) + sin²(x)) = 5/8

<=>

        -3  sin²(x).cos²(x) = - 3/8

<=>       sin²(x).cos²(x) = 1/8

<=>       4  sin²(x).cos²(x) = 1/2

<=>         sin²( 2 x )  = 1/2

Take first sin (2x) = sin (pi/4)
The solutions are :

 
  2x = pi/4 + 2 k pi  or  2x = 3 pi/4 + 2 kpi

<=>

  x = pi/8 + kpi    or   x = 3 pi/8 + k pi

Take now the case sin (2x) = sin (- pi/4)
The solutions are :

 
  2x = -pi/4 + 2 k pi  or  2x = 5 pi/4 + 2 kpi

<=>

  x = - pi/8 + kpi    or    x = 5 pi/8 + k pi

All these sets of solutions can be gathered in one expression

 
 x = pi/8 + k pi/4

Solve the equation
sin(x) + sin(2x) + sin(3x) = cos(x) + cos(2x) + cos(3x)

 
  sin(x) + sin(2x) + sin(3x) = cos(x) + cos(2x) + cos(3x)
<=>
  sin(x) - cos(x) +  sin(2x) - cos(2x) + sin(3x) - cos(3x) = 0

First we construct a formula for sin(u) - cos(u)

  sin(u) - cos(u)
        = sin(u) - sin(pi/2 - u)
        = 2 cos(pi/4) sin(u - pi/4)
        = 2 sqrt(2) sin(u - pi/4)

So,


  sin(x) - cos(x) +  sin(2x) - cos(2x) + sin(3x) - cos(3x) = 0
<=>
   sin(x - pi/4) + sin(2x - pi/4) + sin(3x - pi/4) = 0
<=>
   2 sin(2x - pi/4) cos(x) + sin(2x - pi/4) = 0
<=>
   sin(2x - pi/4) ( 2 cos(x) +1) = 0
<=>
   2x - pi/4 = k pi  of  cos(x) = cos(2pi/3)
<=>
   x = pi/8 + k pi/2   of  x = ± 2 pi/3 + 2 k pi

Solve the system
/ 2 sin(pi - 2x) = 2 | 3 sin(4x) = cot(5 pi/2) \ 6 pi/5 < x < 11 pi/5

 
  /   2 sin(pi - 2x) = 2
  |   3 sin(4x) = cot(5 pi/2)
  \   6 pi/5 < x < 11 pi/5

<=>

  /   sin(2x) = 1
  |   sin(4x) = 0
  \   6 pi/5 < x < 11 pi/5

<=>

  /   sin(2x) = 1
  |   2 sin(2x) cos(2x) = 0
  \   6 pi/5 < x < 11 pi/5
<=>

  /   sin(2x) = 1
  |   cos(2x) = 0
  \   6 pi/5 < x < 11 pi/5

<=>

  /  2x = pi/2 + 2 k pi
  \  6 pi/5 < x < 11 pi/5

<=>
  /  x = pi/4 + k pi
  \ 6 pi/5 < x < 11 pi/5

<=>
    x = 5 pi/4

Solve
sin(x + pi/5) sin(x - pi/5) = cos²(x)

 
   sin(x + pi/5) sin(x - pi/5) = cos²(x)
<=>
  (sin(x) cos(pi/5) + cos(x) sin(pi/5)).(sin(x) cos(pi/5) - cos(x) sin(pi/5)) = cos²(x)
<=>
  (sin²(x) cos²(pi/5) - cos²(x) sin²(pi/5)) = cos²(x)
<=>
  (1 - cos²(x)) cos²(pi/5) - cos²(x) (1 - cos²(pi/5)) = cos²(x)
<=>
   cos²(pi/5) - cos²(x) = cos²(x)
<=>
   2 cos²(x) =  cos²(pi/5)
<=>
   cos(x) = ± 0.57
<=>
     x = ± 0.96 + k pi

Other problems

cot(x) = 1 + 1/m and cot(y) = 2m + 1
Find tan(x + y)

 
    tan(x + y)

      tan(x) + tan (y)
  = -------------------
     1 - tan(x) tan (y)

      m/(m+1) + 1/(2m+1)
  = --------------------------
      1 -  m / ((m+1)(2m+1))

     m(2m+1) + m + 1
  = ----------------------
     (m+1)(2m+1)  - m

  = ...

  = 1

Calculate cos(3u) in terms of cos(u)

 
cos(2u+u) =

cos(2u)cos(u)-sin(2u)sin(u) =

(cos²(u)-sin²(u))cos(u)-2sin(u)cos(u)sin(u) =

cos³(u) - sin²(u)cos(u)-2sin²(u)cos(u) =

cos³(u) -3sin²(u)cos(u)

cos³(u) -3cos(u)+3cos³(u)

4cos³(u) -3cos(u)

In the same way
sin(3u) =

-4sin³(u) + 3sin(u)

factorize
1 1 --------- - -------- sin(a) tan(a)

 
         1            1
     ---------  -  --------
      sin(a)        tan(a)

         1          cos(a)
  =  ---------  -  --------
      sin(a)        sin(a)

       1 - cos(a)
  =  ------------
       sin(a)

        2 sin²(a/2)
  =   --------------------
       2 sin(a/2)cos(a/2)


  =   tan(a/2)

factorize
tan(a+b) - tan(a-b) --------------------- tan(a+b) + tan(a-b)

 
     tan(a+b) - tan(a-b)

     sin(a+b)      sin(a-b)
  = ---------  -  -----------
     cos(a+b)      cos(a-b)


     sin(a+b)  cos(a-b) - cos(a+b) sin(a-b)
  = ----------------------------------------------
           cos(a+b) cos(a-b)

        sin(2b)
  = ---------------------
      cos(a+b) cos(a-b)


In the same way

       tan(a+b) + tan(a-b)

    =  .....

           sin(2a)
    =  ---------------------
         cos(a+b) cos(a-b)

Conclusion

    tan(a+b) - tan(a-b)   sin(2b)
    ------------------- = ------
    tan(a+b) + tan(a-b)   sin(2a)

Given :
x² cos²(p) - 2 x (1 - sin(p) sin(q) ) + cos²(q) = 0
Find the condition such that the equation in x has two equal roots.
Simplify this condition.

 
     The equation has two equal roots.

<=>  The discriminant is zero

<=>  4(1 - sin(p) sin(q))² - 4 cos²(p)cos²(q) = 0

<=> (1 - sin(p) sin(q))² - cos²(p)cos²(q) = 0

<=>  1 - 2 sin(p) sin(q) + sin²(p) sin²(q) - cos²(p)cos²(q) = 0

<=>  1-2 sin(p)sin(q)+sin²(p)sin²(q)-(1-sin²(p))(1-sin²(q)) = 0

<=>  -2 sin(p)sin(q) +  sin²(q) +  sin²(p) = 0

<=>  (sin(p) - sin(q))² = 0

<=>   sin(p) = sin(q)

A plane is approaching your home, and you assume that it is traveling at approximately 550 miles per hour.
If the angle of elevation of the plane is 16 degrees at one time and one minute later the angle is 57 degrees, approximate the altitude.

We assume that the altitude is constant.

The red line is the plane. First the plane is at point Q and one minute later the plane is at point R. Point H is my home.

The distance |QR| is 550/60 = 55/6 miles.
Let D = the distance |PH|.

 
In triangle QPH,

      tan(16°) = A/D   => D = A.cot(16°)

In triangle RSH

      tan(57°) = A/(D - 55/6)

                        A
      tan(57°) = --------------------
                  A.cot(16°) - 55/6


      (A.cot(16°) - 55/6 ).tan(57°) = A

      A.(cot(16°).tan(57°) - 1 ) = (55/6) .tan(57°)

      A = 3.23 miles.

The altitude is 3.23 miles.

Given:
2. sqrt(x) y = arcsin --------------- 1 + x
Calculate:
1) domain 2) range of the function 3) asymptotes
```
 
  The image y exists if and only if  2.sqrt(x)/(1+x) is in  [-1,1].

<=>

       4x
   ----------   is in  [0,1]
    (1 + x)²

<=>
       4x
   ----------  =< 1    and  ( x>0 or x=0)
    (1 + x)²
<=>

   4x  =< (1 + x)²   and  ( x>0 or x=0)

<=>

   (1 + x)² - 4x >= 0   and  ( x>0 or x=0)

<=>

    (1 - x)²  >= 0   en  ( x>0 or x=0)

<=>   ( x>0 or x=0)
```
The domain is the set of all non-negative real numbers.
------------
arcsin(u) has pi/2 as absolute maximum for u = 1.
2.sqrt(x)/(1+x) = 1 for x = 1.
So, the image y is maximum for x = 1 en that maximum image is pi/2.
An x value, in the domain, is non-negative. So, 2.sqrt(x)/(1+x) has 0 as minimum and this happens for x=0.
The arcsin-function is rising. So, the minimum value of y happens for x=0. And then, the image is 0.
Conclusion : the range is [0,pi/2] .
--------------
Since the range is [0,pi/2], there are no vertical and no horizontal asymptotes.
If x -> infty
```
 
 Say  u = sqrt(x) ; then:   x -> infty <=> u -> infty

      2. sqrt(x)           2 u
 lim -----------  =  lim ----------- = 0
       1 + x              1 + u²
```
So the x-axis is the only horizontal asymptote

 
Find the period of 3.sin² (3x/4) - cos² (2x/3)

 
2.sin²(3x/4) = 1 - cos(3x/2) and this part has period 4.pi/3


So 3.sin²(3x/4) has period 4.pi/3              (1)


2. cos²(x/3) = 1 + cos(2x/3) and this part has period 3.pi


So  cos²(x/3) has period 3.pi                  (2)


From (1) and (2) we have


the period of  3.sin² (3x/4) - cos² (2x/3)   is 12.pi

Calculate the range of the function f(x) = arctan(x²+ 1).

The range of (x²+ 1) is [1, infty[ .
Let the arctan function act on that range.
Then, the set of all images is [pi/4, pi/2 [ . The range of f(x) = [pi/4, pi/2 [ .

Prove that for all x > 1

2 arctan(x) + arcsin ( 2x/ (1 + x²) ) is constant

 
Let arctan(x) = y. Then, x = tan(y) with y in ]pi/4 , pi/2[

  2x        2 tan(y)
-------- = ----------------- = sin(2y) with 2y in ]pi/2 , pi[
1 + x²    1 + tan(y).tan(y)

<=>

  2x
-------- = sin(pi - 2y) with (pi - 2y) in ]-pi/2 , 0 [
1 + x²

<=>
          2x
arcsin( -------- ) = pi - 2y
        1 + x²

Hence,
                              2x
        2 arctan(x) + arcsin --------  = 2y + pi - 2y = pi
                             1 + x²

 
 Given: in  a triangle ABC with sides a,b and c

              A - C            A + C
        b cos(-----) - 3 c cos(-----) = 0
                2                2

Prove that a = 2 c

 
Proof:
Appealing to the sine rule we can write

              A - C            A + C
        b cos(-----) - 3 c cos(-----) = 0
                2                2
<=>
                   A - C                 A + C
        sin(B) cos(-----) - 3 sin(C) cos(-----) = 0
                     2                     2


Now,    A + B + C = pi

         A + C    pi   B
=>      (-----) = -- - -
           2      2    2

=>          A + C        B
        cos(-----) = sin -
              2          2

Hence
                   A - C                 A + C
        sin(B) cos(-----) - 3 sin(C) cos(-----) = 0
                     2                     2

<=>
                   A - C                 B
        sin(B) cos(-----) - 3 sin(C) sin - = 0
                     2                   2
<=>
            B     B     A - C                 B
      2 sin - cos - cos(-----) - 3 sin(C) sin - = 0
            2     2       2                   2
<=>
            B         B     A - C
        sin - .(2 cos - cos(-----) - 3 sin(C))= 0
            2         2       2
                    B
                sin - = 0 is impossible in a triangle,
                    2
                            B       A + C
                and     cos - = sin(-----) , hence
                            2         2

              A + C     A - C
<=>     2(sin(-----)cos(-----) = 3 sin(C)
                2         2

<=>     sin(A) + sin (C) =  3 sin(C)

<=>     sin(A) = 2 sin(C)

<=>     a = 2 c

 
 Given: in  a triangle ABC

        a cos(B) + b cos(C) = A tan(A) tan(B/2) cos(B) + b tan(B/2) sin(C)


Prove that the triangle is isosceles.

 
Proof:
        a cos(B) + b cos(C) = A tan(A) tan(B/2) cos(B) + b tan(B/2) sin(C)

<=>
        a cos(B)(1 - tan(A) tan(B/2)) = b(tan(B/2) sin(C) - cos(C))

<=>     a   tan(B/2) sin(C) - cos(C)
        - = -----------------------------
        b   cos(B)(1 - tan(A) tan(B/2))

        sin(A)     tan(B/2) sin(C) - cos(C)
<=>     ------- = ---------------------------
        sin(B)     cos(B)(1 - tan(A) tan(B/2))


<=>     sin(A) cos(B)(1 - tan(A) tan(B/2)) =sin(B)(tan(B/2) sin(C) - cos(C))

multiplying through by cos(B/2)


<=>sin(A)cos(B)(cos(B/2)-tan(A)sin(B/2))=sin(B)(sin(B/2)sin(C)-cos(C)cos(B/2))


      sin(A)cos(B)
<=>   ------------(cos(A)cos(B/2)-sin(A)sin(B/2)) = -sin(B)cos(C+B/2)
         cos(A)

<=>     tan(A)cos(B)cos(A + B/2) = - sin(B)cos(C+B/2)


            Now (A + B/2) + (C+B/2) = pi => cos(A + B/2)  = - cos(C+B/2)


<=>     tan(A)cos(B)cos(A + B/2) = sin(B)cos(A + B/2)

<=>     tan(A)cos(B)cos(A + B/2) - sin(B)cos(A + B/2) = 0

<=>     cos(A + B/2) = 0  or tan(A)cos(B) - sin(B) = 0

<=>     A + B/2 = pi/2          or      tan(A)cos(B) = sin(B)

<=>     2A + B = pi             or      tan(A) = tan(B)

<=>     2A + B = A + B + C      or      A = B

<=>     A = C

<=>     the triangle is isosceles.

Given : sin⁴x + cos⁴x + sin²x cos²x = m cos(4x) Find: sin²(2x) as a function of m

 

    sin⁴x + cos⁴x + sin²x cos²x = m cos(4x)
<=>
    (sin²x + cos²x)² =  m cos(4x)  + sin²x cos²x
<=>
      1 =  m cos(4x) + (1/4) sin²(2x)

                    but  1- cos(4x) = 2 sin²(2x)
<=>
      1 =  m (1 - 2 sin²(2x)) + (1/4) sin²(2x)
<=>
      1 - m = -2m  sin²(2x)) + (1/4) sin²(2x)
<=>
     4( 1 - m) = (1 - 8m) sin²(2x)
<=>
      4( 1 - m)
     ------------ = sin²(2x)
       (1 - 8m)

Consider the quadratic equation
2(2 cos(t) + 1) x² - 4 x + (2 cos(t) -1) = 0
With 0 < t < pi/2
Find the t-values such that the quadratic equation has different real roots.

The quadratic equation has different real roots if and only if the discriminant is strictly positive.

 
       D >0
<=>
      16 - 8 (2 cos(t) + 1) (2 cos(t) -1)  > 0
<=>
      3 - 4 cos²(t)  > 0
<=>
       4 cos²(t) -3  < 0
<=>
        cos²(t) < 3/4

                  and  since  0 < t < pi/2

<=>     pi/6 < t < pi/2

Show that cosec(x) = cot(x/2) - cot(x)
Show that cosec(2x) + cosec(4x) + cosec(8x) = sin(7x)/ ( sin(x) sin(8x) )
Solve the equation: cosec(2x) + cosec(4x) + cosec(8x) = cosec(8x) cosec(x)

Part 1:

 
   cosec(x) = cot(x/2) - cot(x)
<=>
        1          cos(x)
   ----------- + ---------  = cot(x/2)
     sin(x)        sin(x)
<=>
     1 + cos(x)
   ------------- = cot(x/2)
      sin(x)
<=>
      2 cos²(x/2)
     --------------------- =  cot(x/2)
      2 sin(x/2) cos(x/2)
<=>
        cos²(x/2)
      ------------------- =  cot(x/2)
        sin(x/2)

Part 2: We rely on the result of Part 1

 
cosec(2x) + cosec(4x)  + cosec(8x)

     = cot(x) - cot(2x) + cot(2x) - cot(4x) + cot(4x) - cot(8x)

     = cot(x) -  cot(8x)

        cos(x)      cos(8x)
     = -------  -  --------
        sin(x)      sin(8x)

        cos(x) sin(8x) -  sin(x)  cos(8x)
    = --------------------------------------------
              sin(x)  sin(8x)

         sin(7x)
    = ----------------
        sin(x)  sin(8x)

Part 3: We rely on the result of Part 2

 
         sin(7x)
      ---------------- = cosec(8x)  cosec(x)
        sin(x)  sin(8x)

<=>
       sin(7x) = 1
<=>
       7x = pi/2 + 2.k.pi
<=>
       x = pi/14 + 2 k pi/7

Show that:
If 5 sin(a) = sin(a+2b) then 2 tan(a+b) = 3 tan(b)

 
  sin(a + 2b) = sin( (a+b) + b) = sin(a+b) cos(b) + cos(a+b) sin(b)
  5 sin(a) = 5 sin((a+b) - b) = 5 sin(a+b) cos(b) - 5 cos(a+b) sin(b)
So,

     5 sin(a) = sin(a+2b)

=>   5 sin(a+b) cos(b) - 5 cos(a+b) sin(b)  =  sin(a+b) cos(b) + cos(a+b) sin(b)

                dividing each term by cos(a+b). cos(b)

=>   5 tan(a+b) - 5 tan(b) = tan(a+b) + tan(b)

=>    2 tan(a+b) = 3 tan(b)

The positive numbers a, b, c and d satisfy the conditions:
/ a + b + c + d = 2 pi | tan(b) - 2 tan(a) = -1 | tan(c) + tan(a) = 0 \ tan(d) + 3 tan(a) = 2
Find tan(a)

 
Let x=  tan(a) ; then

/ (a + b) + (c + d) = 2 pi   (1)
| tan(b)  = 2x - 1
| tan(c)  =  -x
\ tan(d)  = 2 - 3x

From  (1)

   tan(a+b) = - tan(c+d)
<=>
    tan(a) + tan(b)            tan(c) + tan(d)
   -------------------  = -  --------------------
     1 - tan(a) tan(b)         1 -  tan(c) tan(d)
<=>
   (tan(a) + tan(b)).(1 -  tan(c) tan(d)) = -(1 - tan(a) tan(b)).(tan(c) + tan(d))
<=>
    ...
<=>
     -x³ + x² - x + 1 = 0
<=>
     (x - 1)(x²+1) = 0
<=>
      tan(a) = 1

The roots of the quadratic equation x² + p x + q = 0 are tan(a) and tan(b). These roots are different from 1 an -1. Find a quadratic equation with roots tan(2a) and tan(2b). The coefficients of the new quadratic equation are functions of p and q.

 
Let  t= tan(a) and  t'=tan(b)
Then  t + t' = -p and  t t'= q

            2 t
tan(2a) = --------
          1 - t²

            2 t'
tan(2b) = ---------
          1 - t'²

                        t(1-t'²)+ t'(1-t²)
tan(2a) + tan(2b) = 2  ----------------------
                          (1-t²) (1-t'²)

           t + t' - t t' (t'+t)
      = 2 ----------------------------------
            1 - (t+t')² +2 t t' + t² t'²

             -p + qp
      = 2 -----------------------
           1 - p² + 2q + q²

         2p (q-1)
      = --------------
        (1-q)² - p²


                             4q
tan(2a) tan(2b) = ... =  --------------
                         (1-q)² - p²

The new quadratic equation is

    ((1-q)² - p²) x² + 2p(1-q) x + 4q = 0

Find the domain of the function
x + 1 y = arccos -------- x - 1

 
     x is in the domain of the function
<=>
      x + 1                      x + 1
    -------  > or = -1   and   -------- < of = 1
      x - 1                      x - 1
<=>
       x + 1                      x + 1
     ------- + 1 > or = 0   and  ------- -1 < of = 0
       x - 1                      x - 1
<=>
       2 x                        2
     --------  > or = 0   and  ------- < 0
       x - 1                    x - 1

sign investigation

     x       0     1          x     1
    ------------------- and  ----------------
          +  0  -  | +           -  |   +
              XXXXXX                XXXXXXXXX

Conclusion: The domain of the function = ] -infty , 0 ]

The angles of a triangle are a-b, a and a+b.
cos(a-b).cos(a).cos(a+b) = -1/8.
Find the angles of the triangle.
The sum of the angles is 180 degrees. So 3a = 180 degrees and a is 60 degrees.
```
 
   cos(a) = 1/2 and sin(a) = sqrt(3)/2
 

   cos(a - b) cos(a + b)

=  (cos(a) cos(b) + sin(a) sin(b)) (cos(a) cos(b) - sin(a) sin(b))

=  (cos²(a) cos²(b) - sin²(a) sin²(b))

=  0.25 cos²(b) - 0.75 (1 - cos²(b))

=  cos²(b) - 0.75

So,    0.5 (cos²(b) - 0.75) = -1/8

  <=>  cos²(b) = 1/2
```
1. First case : cos(b) = -sqrt(2)/2
  Now b = 135 degrees. This is impossible because a - b must be positive.
2. Second case : cos(b) = sqrt(2)/2
  b = 45 degrees.
  The angles of the triangle are 15 degrees ; 60 degrees ; 105 degrees .

Given

 
   sin(x) + cos(x) + sin(x) cos(x) = 1.5

Find sin(2x)

 
     sin(x) + cos(x) + sin(x) cos(x) = 1.5

=>  sin(x) + cos(x) = 3/2 -  sin(x) cos(x)

=>    (sin(x) + cos(x)  =(1/2) (3 - 2 sin(x)cos(x))

=>   (sin(x) + cos(x))² = (1/4) (3 - sin(2x))²

=>   1 + 2 sin(x)cos(x) = (1/4) ( 9 - 6 sin(2x) + sin²(2x))

=>   4 + 4 sin(2x) =  9 - 6 sin(2x) + sin²(2x)

=>   sin²(2x) - 10 sin(2x) + 5 = 0

=>   sin(2x) = 5 - 2 sqrt(5)

Given : cos(a+b) = cos(a) cos(b)
Prove that : sin²(a+b) = (sin(a) + sin(b))²

 
  / cos(a+b) = cos(a) cos(b)
  \ cos(a+b) = cos(a) cos(b) - sin(a) sin(b)

=> sin(a) sin(b) = 0

First case:  sin(a) = 0

   a = k.pi

  sin²(a+b) = sin²(b+ k.pi) = sin²(b) = (0 + sin(b))² =(sin(a) + sin(b))²

Second case: sin(b) = 0

   b = k.pi

  sin²(a+b) = sin²(a+ k.pi) = sin²(a) = (sin(a) + 0)² =(sin(a) + sin(b))²

In a triangle ABC is A = 120°.
The ratio b/c of the sides b and c is (sqrt(3)-1)/2.
Find the angles B and C.

 
     b    sqrt(3)-1
    --- = ----------
     c       2

     There is a number r such that  b = r(sqrt(3)-1) and c = 2r.
     If we choose  r = 1 , this has no influence on the angles of the triangle.

     So, we choose    b = (sqrt(3)-1) and  c = 2.

     Now,   a² = b² + c² - 2 b c cos(120°)

     From this, we calculate a and we find  a = sqrt(6).

     Since  A is obtuse,  B and C are sharp angles.

        a          2
     -------- = -------   =>  sin(C) = sqrt(2)/2  => C = 45°
      sin(A)     sin(C)

      B = 180° - A - C = 15°

Topics and Problems

MATH-abundance home page - tutorial

MATH-tutorial Index

The tutorial address is http://home.scarlet.be/math/

Copying Conditions

Send all suggestions, remarks and reports on errors to Johan.Claeys@ping.be The subject of the mail must contain the flemish word 'wiskunde' because other mails are filtered to Trash