To solve this equation, we will first expand both sides using the properties of trigonometric functions.
Starting with the left side:1 - ctg(2a)
We know that cotangent is the reciprocal of tangent, so we can rewrite this as:
1 - 1/tan(2a)
We can take the reciprocal of tan(2a) by using the identity tan(x) = sin(x)/cos(x):
1 - cos(2a)/sin(2a)
Next, we will multiply both the numerator and denominator by sin(2a) to get a common denominator:
sin(2a)/sin(2a) - cos(2a)/sin(2a)
This simplifies to:
sin(2a) - cos(2a)/sin(2a)
Now moving on to the right side:(1 + ctg(2a))(sin(2a) - cos(2a))
Expanding this using the same steps as above, we get:
(1 + 1/tan(2a))(sin(2a) - cos(2a))(sin(2a) - cos(2a) + sin(2a) - cos(2a)/sin(2a))
Simplifying this further:
2sin(2a) - 2cos(2a)/sin(2a)
Therefore, the equation simplifies to:
sin(2a) - cos(2a)/sin(2a) = 2sin(2a) - 2cos(2a)/sin(2a)
To solve this equation, we will first expand both sides using the properties of trigonometric functions.
Starting with the left side:
1 - ctg(2a)
We know that cotangent is the reciprocal of tangent, so we can rewrite this as:
1 - 1/tan(2a)
We can take the reciprocal of tan(2a) by using the identity tan(x) = sin(x)/cos(x):
1 - cos(2a)/sin(2a)
Next, we will multiply both the numerator and denominator by sin(2a) to get a common denominator:
sin(2a)/sin(2a) - cos(2a)/sin(2a)
This simplifies to:
sin(2a) - cos(2a)/sin(2a)
Now moving on to the right side:
(1 + ctg(2a))(sin(2a) - cos(2a))
Expanding this using the same steps as above, we get:
(1 + 1/tan(2a))(sin(2a) - cos(2a))
(sin(2a) - cos(2a) + sin(2a) - cos(2a)/sin(2a))
Simplifying this further:
2sin(2a) - 2cos(2a)/sin(2a)
Therefore, the equation simplifies to:
sin(2a) - cos(2a)/sin(2a) = 2sin(2a) - 2cos(2a)/sin(2a)