Solving equations Solve each equation.
√2 sin 3Θ + 1 = 2...

Question

Solving equations Solve each equation.

√2 sin 3Θ + 1 = 2, 0 ≤ Θ ≤ π

Accepted Answer

Hello there. Today we're gonna solve the following practice problem together. So first off, let us read the problem and highlight all the key pieces of information that we need to use in order to solve this problem. Solve the equation 2 multiplied by the cosine of 4 multiplied by the minus 1 is equal to 0, 40 is less than or equal to theta and theta is less than or equal to 2 pi. Awesome. So ultimately our final answer that we're trying to solve for is we're trying to figure out what how to solve the equation that is provided to us by the promise. So we're trying to solve the equation 2 multiplied by cosine of 4, theta minus 1 is equal to 0, given the specific range. Awesome. So with that said, our first step in order to solve this problem is we need to define the known variables and our target variable that we're trying to solve for. So we know our known variable is theta. And our target variable. There's also theta. And our equation, as we should note, is that we are dealing with 2 multiplied by cosine of 4 theta minus 1 is equal to 0. So our first step now when we're trying to solve this specific equation is we need to isolate the trigontric function, so we need to take 2 multiplied by cosine of 4 theta minus 1 is equal to 0. And when we isolate it, we need to take. This function and we need to. Move the one over to the other side so we could write 2 multiplied by cosine of 4 theta is equal to 1. So, essentially what we're gonna be ultimately trying to do is we're trying to isolate and solve for theta all by itself. So our first step to do that is we need to take And start moving, we need to move the 2 over to the other side, so we need to get, when we move 2 over to the other side, we'll get cosine of 4 beta is equal to 12, because we need to take 1 divided by 2, which is 1/2. So now our next step. we need to solve for 4 theta, and when we solve for 4 theta, we should recall and note that 4 theta in this case is going to be equal to plus or minus pi divided by 3 + 2 multiplied by K. Multiplied by pi, and this is for the condition where K, where K represents an integer value, is an element of the set. So once again, so this is for K is an element of the set of all integers. And once again, just a quick reminder, K is an integer is some integer value, and K in this case is an element of the set of all integers. So now we could just solve for theta. So when we solve for just theta. We will get that theta in this case is going to be equal to + or minus pi divided by 12. Plus K multiplied by pi divided by 2, and once again, this is 4. K, where K is an element of the set of all the integers. Awesome. So, once again now, our last and final step. As we need to determine. All the values of theta within our given range, and let us recall that our range states that 0 is less than or equal to theta and theta is less than or equal to 2 pi. So considering our range, we can go ahead and write that theta is equal to pi divided by 12. 5 divided by 12 7 divided by 1211 pi divided by 1213 divided by 1217 pi divided by 12. 19 i divided by 12, and finally 23 pie divided by 12. So that will mean That are final. Solution. So when we list our final solution, that will mean that pie. So that will mean that theta is going to be equal to pi divided by 12, 5 pi divided by 12, 7 pi divided by 1211 pi divided by 1213 pi divided by 1217 pi divided by 1219 pi divided by 12, and 23 pi divided by 12. That is our final answer, this big old long line of values, and that's it. That's how you solve for this problem. Thank you so much for watching. Hopefully that helped, and I can't wait to see you in the next video. Bye.

Solving equations Solve each equation.
√2 sin 3Θ + 1 = 2, 0 ≤ Θ ≤ π

Key Concepts

Trigonometric Functions

Inverse Trigonometric Functions

Interval Notation

Watch next