Solve the equation

a) To solve the equation, we can use the Trigonometric identities.

First, let's rearrange the equation:

cos(2x + 35) = sin(3x - 10)

Now, using the identity cos(A) = sin(90 - A), we get:

sin(90 - (2x + 35)) = sin(3x - 10)

Next, we know that sine function is an odd function, which means sin(-x) = -sin(x). Therefore, we can rewrite the equation as:

-sin(2x + 35) = sin(3x - 10)

Now, using the identity sin(A) = -sin(-A), we get:

sin(-(2x + 35)) = sin(3x - 10)

Since sine function is also a periodic function with period of 2π, we can say:

-(2x + 35) = 3x - 10 + 2kπ (where k is an integer)

Now, simplify the equation:

2x + 35 = -3x + 10 - 2kπ

Add 3x to both sides:

5x + 35 = 10 - 2kπ

Subtract 35 from both sides:

5x = -25 - 2kπ

Divide by 5:

x = (-25 - 2kπ)/5

So the general solution to the equation is x = (-25 - 2kπ)/5, where k is an integer.

b) To find tan(2x + 4), we can use the identity:

tan(A) = sin(A) / cos(A)

From the previous equation, we know that cos(2x + 35) = sin(3x - 10). So, substitute this into the equation:

tan(2x + 4) = sin(2x + 35) / cos(2x + 35)

Using the trigonometric identities, we can rewrite:

tan(2x + 4) = -sin(3x - 10) / sin(2x + 35)

Since sin(A) / sin(B) = tan(A - B), we get:

tan(2x + 4) = -tan(3x - 10)

So, the value of tan(2x + 4) is equal to the negative of tan(3x - 10).