Solve the equation for 0<x<2π

√(2) sin(x)+√(2) cos(x)>0

divide by √2

sinx + cosx > 0
sinx > -cosx
sinx/cosx > -1
tanx > -1

from the graph of the standard tangent curve of y = sinx and y = -cosx

in the domain 0 < x < 2π we see that sinx is above -cosx for
0 < x < 3π/4 OR 7π/4 < x < 2π

revised solution:

divide by √2
sinx + cosx > 0
sinx > -cosx

from the graph of the standard curve of y = sinx and y = -cosx

in the domain 0 < x < 2π we see that sinx is above -cosx for
0 < x < 3π/4 OR 7π/4 < x < 2π

I originally went with tanx, as seen in my first attempt,
obtained by dividing both sides by cosx
However, since division by cosx would result in worrying about positive and negatives divisors giving me reversals of the inequality sign, I just went with the second version of my solution

or, recognize that what you have is

2sin(x+pi/4) > 0

so, x+pi/4 must be in QI or QII
-pi/4 < x < 3pi/4
But, we want x>0, so add 2pi to make it positive:
-pi/4 < x is the same as 7pi/4 < x < 2pi

answer is as shown above.

To solve the equation √(2) sin(x) + √(2) cos(x) > 0 for 0 < x < 2π, we can use a trigonometric identity and then use the properties of sine and cosine.

First, let's rewrite the equation by factoring out √(2):

√(2) (sin(x) + cos(x)) > 0

Now let's simplify further. We divide both sides of the equation by √(2):

sin(x) + cos(x) > 0

Next, we can use the trigonometric identity sin(π/4) = cos(π/4) = √(2)/2. This means that the equation sin(x) + cos(x) is positive in the first and second quadrants of the unit circle.

So, for 0 < x < 2π, the equation sin(x) + cos(x) > 0 is satisfied when x lies in the intervals [0, π/2) and (3π/2, 2π).