BQ#4: Unit T Concepts 1-3-Why is a "normal" tangent graph uphill, but a "normal" cotangent graph downhill?

Photocredits: desmos.com

Yes, tangent and cotangent are inverses of each other but, that does not fully explain why exactly a tangent graph is uphill and a cotangent graph is downhill. Let's start off with tangent first and why it's uphill. Tan=sin/cos in order for tan to be undefined and have asymptotes cos must be zero in certain points of the unit circle: pi/2 (90degrees) and 3pi/2 (270degrees). Co-tan, unlike tan, has asymptotes in other points on the unit circle, it's asymptotes are on: 0pi, pi (180 degrees), 2pi (360 degrees). And that completely answers our question. Tangent graphs and cotangent graphs go in two different directions because of the different asymptotes, they are undefined in different areas, so, therefore, they go in different directions.

Photocredits: desmos.com

BQ#3:Unit T-How do graphs of sine and cosine relate to each of the others?

a. Tangent?

                                                         Photocredits: desmos.com

In order to fully understand how all trig functions seen on this graph relate, lets go quadrant by quadrant. In the first quadrant, sin, cos and tan are positive. So, therefore, all of the graphs at this point are above the x-axis showing they are positive. In the second quadrant, it's quite different sin is the only trig function that's positive in this quadrant the other two are negative. In quadrant three, tan is the only positive trig and the other two are negative. Lastly, in quadrant four, cos is the only positive and the other two are negative.

So, what's the big deal with these asymptotes and why are they placed in the places they are placed? Tangent has asymptotes because at certain points such as pi/2(90 degrees) and 3pi/2 (270 degrees) tan's ratio (x/y) is undefined. That is why the tangent graph looks split in between sections, the tangent periods don't touch the asymptotes but do get very close. 

b. Co-tangent?

                                                                                   Photocredits: desmos.com

Cotangent's graph is very similar to tangent, positive at all the same parts and negative at all the same parts, except that they go in two different directions. Why? Well, because yes they're inverses of each other but they have asymptotes at different points on the unit circle. In the Unit Circle tan's ratio is undefined at 0, pi (180 degrees) and 2pi (360 degrees). Therefore, the co-tangent graph goes downhill.

c. Secant?

                                                                                   Photocredits: desmos.com

Secant, the beautiful secant. So, what's up with this so-called secant? In the first quadrant, all three, sin, cos and secant are positive. In the second quadrant, sin is the only one positive, the other two are negative. Furthermore, the third quadrant, all (sin, cosine and secant) are negative in this quadrant. Lastly, in the fourth quadrant, both cos and secant are positive, and the only one negative is sin.

The asymptotes for secant are on pi/2(90 degrees) and 3pi/2 (270 degrees). Those are the specific asymptotes for secant because that is where secant's ratio is undefined.

What seems so odd is that the asymptote of secant is connected with cos, why is that? That is because in simple words secant is the inverse of cosine! 

d. co-secant?

                                 Photocredits: desmos.com

Co-secant is the inverse of sine. In the first quadrant, all three, sin, cosine and co-secant are positive. In the second quadrant, sin and co-secant are positive and cos is negative. Moreover, in the third quadrant, all the three trig functions are negative. And lastly, in the fourth quadrant cos is the only one positive, the other two (sin, co-secant) are negative.

Much like co-tangent, co-secant has certain asymptotes because that is where its ratio is undefined. Co-secant is undefined at at 0, pi (180 degrees) and 2pi (360 degrees).

And just like secant, co-secant is attached to sin because its the inverse of co-secant!

Thank you for reading my blog. Comments, concerns, questions? Feel free to call me *wink*. Just kidding, comment below..

BQ#5: Unit T Concepts1-3-Why do sine and cosine NOT have asymptotes, but the other four trig graphs do?

First question that should be answered is: how can you get an asymptote? When a trig function is undefined is where an asymptote would appear on a graph. (Okay, got that cleared.) We must know that in the Unit Circle r=1. So therefore, sine and cosine can never be undefined because they would always have a one underneath in their ratio. Unlike sine and cosine, co-secant, secant, tangent and cotangent CAN have asymptotes. Why? Well for one, they do not have "r" underneath as their denominator in their ratio. Meaning, they can possibly have one of their values on the bottom as 0. For instance with secant, its ratio is r/x, we know that "r" is 1 and possibly if "x" is 0, our answer would be undefined. For co-secant, secant, tangent, and cotangent there are many possibilities that an answer can be undefined and that is why these trig functions have asymptotes and, sine and cosine do not. Sine and cosine will never be undefined nor have an asymptote. 

ANY QUESTIONS? FEEL FREE TO COMMENT BELOW, THANK YOU.

BQ#2: Unit T Intro-How do the trig graphs relate to the Unit Circle?

Terms to help for the reading below:

         PERIOD-graphs are cyclical and once completion of one cycle its called a period.

         AMPLITUDES-are half the distance between the highest and lowest points on the graph.

Photo-credit: Fabulous and Beautiful Victoria Ventura

Photo-credit: Fabulous and Beautiful Victoria Ventura

A. Period?-Why is the period for sine and cosine 2pi, whereas the period for tangent and cotangent is pi? Interesting question. As seen from the lovely drawn pictures from above, we notice that both in sine and cosine we have repeating patterns: +,+,-,- and +, -, -,+. In order to complete a period we must go all around the unit circle. Keep in mind our graphs are just the unit circle unfolded and repeated with the same period. From 0 degrees to 360 degrees is 2pi. So that is why sine and cosine are 2pi. Seen from the picture below, we see that the pattern is +,-,+,-. The reason why tangent and cotangent's period is only pi is because the pattern is already completed by pi, unlike sine and cosine, in which one has to go all around in order to complete the period. Life is much easier doing tangent and cotangent, to be honest. 

Photo-credit: Fabulous and Beautiful Victoria Ventura

B. Amplitude?- How does the fact that sine and cosine have amplitudes of one (and the other trig functions don't have amplitudes) relate to what we know about the Unit Circle? In the Unit Circle all the other trig functions could be greater than one (YAY, for them) but for sine and cosine, they couldn't be greater than one. Which makes complete sense why the amplitude for sine and cosine is restricted to one and the others CAN be greater than one (such rebels.)


ANY QUESTIONS FEEL FREE TO COMMENT BELOW, THANK YOU FOR YOUR TIME.

Reflection #1: Unit Q Verifying Trig Identities

1. What does it actually mean to verify a trig identity?
What verifying a trig function actually means is to prove that the answer given can actually be solved out from the equation given. There are multiple ways to verify a trig function. It might, at first, seem easy but because we are given an answer, we have to make sure to get the exact answer. There are multiple ways to verifying a trig identity but one must be cautious in what other trig identity is being used.

2. What tips and tricks have you found helpful?
Definitely memorizing all trig identities is very helpful. Using reciprocal identities come very handy when solving. If you see a sin, cos or tan squared, figure out if you can use a Pythagorean identity! It will honestly save your life. Sometimes ratio identities can save your life too. Although it is important to know the identities off the top of your head, while doing pq's, or homework it is also helpful to have a list of the identities out in front of you.

3. Explain your thought process and steps you take in verifying a trig identity.
First thing is DO NOT FREAK OUT. I freak out all the time and instead of doing the identity I stare at it and how hard it looks instead of doing it! Then I figure out I can use the reciprocal identities, cross multiply and BOOM, I get the answer. A trig identity might look extremely complex but all it might take is replacing one of the parts with a Pythagorean identity, another with a reciprocal identity and that can lead to your answer. Remember, do not freak out, be calm and solve your life away!