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hey friends
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so we're gonna start our new unit today
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uh which is on trick now uh for those of
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you who are with me at school
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um this is our last unit of 20-1
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if you are joining us from a different
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school this may not be your last unit uh
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but for us uh in my class this was how
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we are going to end our time together so
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pretty exciting uh you guys have come a
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long way and you've journeyed
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really well
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so pat yourself on the back
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um okay so
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the purpose of the first half of this
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lesson is just to kind of review some of
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the things we did in grade 10 in
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tennessee uh to make sure that you're
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okay with everything make sure we're all
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kind of going um starting off on the
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same page okay um the back half of this
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lesson we're gonna talk about angles in
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standard position and kind of introduce
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that concept but first um we just need
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to go back to sokatoa make sure
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everybody's uh cool with that um most of
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you no matter what school you would have
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gone to uh in grade 10 you would have
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had a formula sheet for math 10c that
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would have included the primary
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trigonometric ratios so sine
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is opposite over hypotenuse cosine is
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adjacent over hypotenuse and tangent is
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opposite over
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adjacent
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those aren't given to you anymore in
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grade 11. um so
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a very helpful acronym is sohcahtoa see
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how
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uh neat i can make my mouse writing be
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today sokatoa now this is just a quick
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little acronym to help you remember
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um
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who goes
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ah that was really bad oh okay who goes
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with what okay so if i just start at the
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left here and read with me the s is for
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sign and then the first uh
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or the next letter would be the one on
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top of the fraction for the ratio and
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then the third letter would be the one
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on the bottom of the fraction for the
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ratio so sine is opposite over
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hypotenuse
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cosine is adjacent over hypotenuse and
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then tangent is opposite over adjacent
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okay so sohcahtoa just a quick way to
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help you remember
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okay
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so
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um
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let's give it a quick go here we're
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gonna start with a very brief history
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and won't take too long on this but i
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think it's important that you know where
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some of the stuff comes from okay
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let's begin with a history of
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trigonometry which doesn't begin
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actually with triangles it actually
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begins with circles the study of
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trigonometry dates back to ancient
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babylon we're talking around 2000 bc
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as scholars attempted to understand the
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motion of the stars across the night sky
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really a lot of trigonometry was birthed
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from them trying to chart these stars
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and trying to say okay if the stars are
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in this position where am i sitting on a
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boat in the ocean or where am i sitting
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on this land mass and that's how we
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actually started mapping out the world
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they conjectured that the stars lie on a
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great sphere about the earth
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and consequently assume that their
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motions across the sky were along great
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circular arcs
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a natural question might be where on
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this circle
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must the star be if i'm viewing it at a
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particular angle of x so you can kind of
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see a person there staring up at the
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star um and thinking about what angle
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that forms
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okay
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uh and that's this the uh study of
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circle geometry was born
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trigonometry is actually one of the most
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used mathematical concepts um ever okay
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um
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it's used a lot in trades it's used in
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programming it's used in
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triangulation of
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cell phone data like the very fact that
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your cell phone can pinpoint where you
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are in the world up to about a meter
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um it's because your cell phone connects
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to three different towers okay
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and then how um
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how it connects to those three tower
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towers how it forms that triangle
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actually
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allows satellites to figure out exactly
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where that cell phone is
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in the vast world that's pretty
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incredible when you stop and think about
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it
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okay so the first thing we want to do is
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just review how to label triangles so
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i've given you a right triangle here and
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you know it's right because of the
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box down here by a
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we label angles as capital letters and
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we put those capital letters just on the
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outside edge so inside here is angle a
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and so we put a capital a on the corner
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inside here is angle b so we have a
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capital b on the corner and inside here
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is angle c and we have a capital c
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on the corner okay we also have this
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symbol here this symbol is called theta
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um and it's just used often in math for
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an unknown angle okay
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um
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so theta often used for an angle we
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don't know the measure
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now
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what we want to do is we want to put
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some words on here and we want to label
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these guys with lower case letters okay
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and the way we do lower case letters is
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we do the same letters as the
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angles so
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what i want you to do is i want you to
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put your pencil on a
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and i want you to just go away from it
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okay
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that will point to little a
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okay when we say go away we're talking
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actually about opposites okay so we say
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opposite angle a is little a
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opposite angle b well i put my pen on b
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and i go away from it
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it will point to the opposite side of b
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so that would be little b right here and
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then for c i put my angle at c and i go
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away from it well it's going to point to
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little c right here
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okay
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then we also have words for these guys
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um this one here you should know because
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he's opposite the 90 degree angle and
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you were introduced to that concept um a
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little while ago probably back in grade
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8.
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um that's called the hypotenuse okay the
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hypotenuse in grade 8 you would have
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been introduced to the pythagorean
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theorem which says that the hypotenuse
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squared
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will equal the two legs squared and
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added together so the two other sides
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squared and added together okay
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now we also have words of opposite and
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adjacent that we need to talk about and
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they go depending on
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the non-ninety degree angle you're
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looking at so that's why i've stuck
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theta here
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okay
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um opposite theta is the opposite side
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okay
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and then
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so i've got the opposite i've got the
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hypotenuse over here i didn't actually
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label that sorry i talked about it but i
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didn't label it
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and then this guy here is adjacent
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adjacent means to
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be the side
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okay so the adjacent side is the one
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that helps form where that angle is but
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it's not the hypotenuse
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okay
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so now i'm going to clear that drawing
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and i'm just going to bring it a little
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neater
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okay here's everything i said there
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don't let me just go back for one sec
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sorry um
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previous okay and i'm just gonna hide my
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face here so you can see the word theta
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if you don't have the book at home
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okay
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awesome now
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um these are called the primary
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trigonometric ratios the sohcahtoa that
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i started you with
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the sine ratio the cosine ratio and the
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tangent ratio okay
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so the sine ratio is abbreviated sin on
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the on our calculator you'll see an sin
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button it's not a sin button we try not
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to sing
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it's a sine button so sine of theta is
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opposite over hypotenuse the cosine of
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theta is the ratio of the adjacent side
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over the hypotenuse side
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and then the tangent of theta is the
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ratio of the opposite divided by dg
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okay
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and the pythagorean theorem a squared is
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my hypotenuse for this guy be careful
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with the letters right the letters
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themselves don't matter
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what matters is whatever has been
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labeled as the hypotenuse that has to be
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by its side so it might be a in another
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situation it might be c then another
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situation might be w it doesn't really
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matter okay
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it's the hypotenuse squared
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equals the square of the other two legs
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the b and the c here
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um added together
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okay
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again i'm just gonna hide myself for a
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second so that you guys can see that at
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home
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um and then the other thing i need to
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remind you guys about is that you need
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to be in degree mode so there are
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two um
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ways we can measure
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just like if i showed you the messy desk
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that you can't see because it's right
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underneath the screen right now but i
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promise you it's messy there's piles of
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stuff everywhere um if i wanted to
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measure the length of my messy desk i
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have two options with which to measure
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it in i could measure it in centimeters
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or i could measure it in inches those
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would be two very different numbers but
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that doesn't change the length of my
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desk
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okay it's the same with angles when i go
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to measure an angle i have two different
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measurements i could use i could use or
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units of measure i should say i could
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use
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degrees or i could use radians now by
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default calculators graphing calculators
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are set in radians because radians is
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actually the much better mathematical
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um
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way to
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use the unit of measure for angles okay
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but we're not going to deal with that
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until grade 12. so for grade 11 we need
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to make sure your calculator is always
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in degree mode so that we can talk in
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degrees
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okay
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now to do that i've given some
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instructions here just to make sure
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everybody's good
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if you are a child of casio you'll go
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shift menu to get into your setup scroll
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down to angle and press f1 for degree
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if you are a child of ti
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you will press the mode button and
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go down three over one you'll notice if
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you go down three you have the words
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radian and degree and by default radian
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will be highlighted so then if you go
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over one
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um you'll be on the word degree and if
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you hit just hit enter it'll highlight
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degree instead
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as a check especially if you have one of
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these guys or if you have a scientific
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calculator and you want to make sure
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you're absolutely in the right mode 10
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45 should equal exactly one okay the tan
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of 45 should be one
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now uh kids get really uh stressed out
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about
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modes
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um
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so just for clarification
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the mode you're in doesn't matter unless
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you are pressing the sign the cosine or
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the tangent button okay
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no matter what mode you're in two plus
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two is going to equal four all the
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regular features of your calculator are
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going to work the only difference is
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when you go to press the sine the cosine
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or the tangent button okay
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all right now this phrase would have
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been introduced to you in uh grade 10 to
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solve a triangle means to determine the
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measure of the missing angles and the
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lengths of the missing sides
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in order to determine the unknown
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measures we use primary trigonometric
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ratios or the pythagorean theorem
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essentially
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um last year i could give you any right
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triangle
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there are six things is the first thing
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i need you to understand there right
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there's three angles and three sides so
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last year i could give you any right
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triangle um and i could give you three
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items so the 90 degree and maybe a side
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and an angle or the 90 degree and two
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sides or whatever
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and you could solve for the other three
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okay
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um this year we will actually be able to
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extend that to say it doesn't even have
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to be a 90 degree angle anymore there
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are other tools that we will learn in
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grade 11
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where i can give you any three items and
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you'll be able to get me the other three
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whether there's a 90 degree angle there
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or not
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okay
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all right so let's try a couple
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solve the following angle round side
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lengths to the nearest tenth and angles
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to the nearest degree it's super
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important that you pay attention to
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um
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rounding instructions okay
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side lengths have to be to the nearest
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tenth angles have to be to the nearest
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degree if you don't round this proper
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i'll take off half a point okay
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you have to follow the directions if you
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forget your units i'll take off half a
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point okay you have to talk about what
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unit of measure you're in so all of
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those things are super important okay
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so you have been given the 90 degree
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angle here you've been given little t
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here
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and you've been given
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a little w
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here
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so what you have to now do is find me
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angle f
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find me angle t
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and find me little f
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side f okay i'm gonna actually start
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with side f um i know
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two sides of a right triangle so i can
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get the third using the pythagorean
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theorem okay uh if i'm going to use the
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pythagorean theorem i need to think
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about the fact that i have the
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hypotenuse here so it's going to be f
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squared plus 7 squared equals 14 squared
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some of you from your junior high days
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may want to go directly to 14 squared
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minus 7 squared equals f squared that's
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totally fine as well okay
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so 14 squared equals seven and up seven
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squared plus f squared
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um so then
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14 squared is 196 7 squared is 49 i'll
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subtract 49 from both sides to get f
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squared and then the last step will be i
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need to uh square root it and follow the
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proper rounding construction so that's
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going to give me 12.1 centimeters okay
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12.1 centimeters for uh psi f
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now
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i could go ahead and solve for angle t
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or angle f
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if possible i'm not going to use this in
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my next step okay i could use it but
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what if i'm wrong
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if i'm wrong by default the next guy is
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going to be wrong right so try to only
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use what's been given to you
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uh whenever possible okay so if i wanted
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to get angle f
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okay the 7
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would be adjacent
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and
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i'm just going to put an a there
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and the 14
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would be
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the hypotenuse
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if i wanted to get angle
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t
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the 7
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would be my opposite
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yeah
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and the 14
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would be my hypotenuse okay so i'm going
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to set myself up
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to solve for f and to solve for angle t
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using
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cosine for angle f
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adjacent and hypotenuse that's what
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pairs adjacent and hypotenuse together
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is cosine
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and then sine for angle t because i need
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to pair up opposite end
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hypotenuse
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okay
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so i started with cos of f is 7 over 14.
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remember when i want to get f by itself
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i will arc cos or inverse cos this
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so f will be the inverse cose of one
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half i just reduced my seven over
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fourteen
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okay
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and then
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that gives me sixty degrees then for t
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i'm going to use sine
00:15:58
sine of t is 7 over 14.
00:16:01
so then i'm going to arc
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sine
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or
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inverse sine one half and get 30 degrees
00:16:09
and of course as a check these two
00:16:12
numbers added together should give me 90
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because i need 90 plus this 90 to get
00:16:17
the 180 that all
00:16:19
angles in a triangle have to add up to
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okay
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so
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i'm on a good path here
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um okay let me clear this ink and we'll
00:16:28
do another example together
00:16:32
so this time
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i have triangle drw
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where r angle r is 90 degrees
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little r is 12
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and the little w is 7. now the
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orientation doesn't matter okay
00:16:46
you can orient orientate orient
00:16:49
orientate you can orientate this
00:16:52
triangle however you want okay
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um
00:16:56
what matters is wherever you put that 90
00:16:59
degrees you have to label that as r
00:17:02
opposite that so the hypotenuse has to
00:17:04
be labeled as 12.
00:17:06
and then wherever you chose to write w
00:17:09
opposite w has to be a seven
00:17:11
okay
00:17:12
so
00:17:13
here's mine
00:17:15
but again you have you may have your
00:17:17
setup slightly different and that's
00:17:19
totally fine
00:17:20
okay
00:17:21
so now
00:17:22
i need to get
00:17:24
a little d
00:17:29
and i need to get angle w and i need to
00:17:31
get angle d
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okay
00:17:34
so a little d i'm going to use the
00:17:35
pythagorean theorem again
00:17:41
so i'll go 12 squared minus 7 squared
00:17:43
essentially okay 12 squared's 144 7
00:17:47
squared's 49 i'll subtract the 49 from
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both sides
00:17:52
and then i'll square root it i got to
00:17:53
follow rounding instructions this one
00:17:55
said all answers should be to one
00:17:57
decimal place so i've got 9.7
00:18:01
okay
00:18:02
now if i want angle w
00:18:06
um i'm going to be looking at opposite
00:18:10
and hypotenuse
00:18:13
so that's going to use sine
00:18:16
if i'm looking at angle d i'm going to
00:18:19
look at adjacent
00:18:23
and hypotenuse
00:18:25
so that's going to be cosine okay
00:18:31
so
00:18:32
i started with
00:18:34
angle d
00:18:35
cosine of d is 7 over 12 i'm going to
00:18:38
inverse cos or arc cos that's what gets
00:18:41
rid of the coast that's attached to the
00:18:43
d and allows d to be by itself
00:18:46
so arc cos 7 over 12 and that's going to
00:18:49
give me 54.3 again be careful with your
00:18:51
rounding instructions it said all
00:18:53
answers to one decimal place don't get
00:18:55
caught into thinking that
00:18:57
angles have to always be rounded to the
00:18:58
nearest whole number you just do
00:19:00
whatever the rounding instructions tell
00:19:01
you to do
00:19:03
okay
00:19:05
and then for angle w
00:19:07
we'll have sine of w is 7 over 12
00:19:11
um and then we'll arc sine
00:19:14
7 over 12
00:19:16
and get 35.7
00:19:19
again as a check
00:19:22
we know that
00:19:24
35.7
00:19:26
plus
00:19:27
the
00:19:28
54.3
00:19:29
should give me 19. okay
00:19:32
these two here should give me 90 and
00:19:34
then when i add that to the other 90
00:19:36
over here
00:19:38
i'll get 180
00:19:40
okay
00:19:43
awesome
00:19:46
okay
00:19:48
so the triangles we had above i'm just
00:19:51
going to kill my face here for sex so
00:19:53
that you guys can read this with me the
00:19:55
triangles we had above were drawn in any
00:19:57
orientation that we wanted now we want
00:20:00
to start being more precise
00:20:02
and bring in more of the history of
00:20:03
trigonometry
00:20:05
we will start to draw all of our
00:20:06
triangles on the cartesian plane and
00:20:08
when we do this
00:20:09
we end up drawing in what's called
00:20:11
standard position
00:20:13
now here's what standard position is i'm
00:20:15
going to start off with just a regular
00:20:16
old angle okay here's an angle
00:20:19
and we often say that that's a
00:20:20
rotational angle so i start right here
00:20:24
and i rotate to here this first guy is
00:20:26
called the initial arm it's where i
00:20:28
start and then where i end up after the
00:20:30
rotation that's called my terminal arm
00:20:33
okay so to do something in standard
00:20:36
position
00:20:38
what we're going to do is we're going to
00:20:39
put our initial arm
00:20:42
on the positive x-axis so that's going
00:20:45
to look like that
00:20:47
the vertex goes at the origin
00:20:50
and then our terminal arm is going to be
00:20:52
wherever else wherever it ends up okay
00:20:54
could end up in any quadrant
00:20:57
and then we have to put the rotational
00:20:59
arrow in as well to say how we're
00:21:01
rotating so a positive rotation is
00:21:04
counterclockwise
00:21:06
a negative rotation would be in a
00:21:08
clockwise motion okay
00:21:12
so this is called angles in standard
00:21:14
position this guy here was just a
00:21:16
regular old angle it wasn't in standard
00:21:18
position
00:21:19
once i shift it so that the terminal arm
00:21:22
or sorry the initial arms on the
00:21:24
positive x-axis the vertex is at the
00:21:27
origin and the terminal arm is in one of
00:21:30
the other quadrants
00:21:32
now
00:21:32
it would be called an angle in standard
00:21:34
position
00:21:35
okay
00:21:39
okay so draw the following angles in
00:21:42
standard position on the cartesian plane
00:21:44
now when i ask you to do this i'm not
00:21:46
looking for perfection okay i'm looking
00:21:49
for just a rough sketch i want to know
00:21:50
you're in the right quadrant and for
00:21:53
instance 60 degrees if you did something
00:21:55
like this for 60 degrees i would say
00:21:58
yeah you're a little off right like that
00:22:00
very much is not 60 degrees but if you
00:22:03
did something like this
00:22:07
okay i would feel yeah you have a good
00:22:09
idea of where 60 degrees is
00:22:11
okay
00:22:12
so that's what we're looking for
00:22:14
um just as a clarification while we're
00:22:16
talking about this just in case you
00:22:18
don't remember the quadrants this would
00:22:19
be quadrant one quadrant two they are
00:22:22
often done in roman numerals okay
00:22:24
quadrant three
00:22:27
it's a lot of eyes to whoops sorry
00:22:29
that's a lot of ice to do and then
00:22:31
quadrant four is id
00:22:36
okay so it would be like that
00:22:40
so
00:22:41
here's my 60 degrees
00:22:45
200 well i know from here to here
00:22:48
is 180 so 200 will be just a little
00:22:50
farther than that
00:22:52
don't forget your rotational angle here
00:22:54
guys
00:22:55
um that's important right
00:22:59
110 i'd end up in quadrant two
00:23:03
and then negative 330 well you got to
00:23:05
watch with the negative that means i'm
00:23:07
going in a clockwise direction so i'm
00:23:08
going to be heading this way right so
00:23:09
this would be negative 90 i'm still
00:23:11
starting on the positive x so this would
00:23:13
be negative 90
00:23:15
negative 180
00:23:16
and then negative 270 so negative 330
00:23:20
actually puts me into quadrant 1 there
00:23:22
okay
00:23:26
perfect
00:23:28
now
00:23:29
state the measure of the acute angle
00:23:32
acute means less than 90 degrees
00:23:34
uh to the x-axis this is known as the
00:23:37
reference angle and the reference angle
00:23:39
is going to become very important to
00:23:41
your life over the next couple of days
00:23:43
okay
00:23:44
so let's look at quadrant one
00:23:47
uh when our terminal arm was in quadrant
00:23:49
one the reference angle and the angle
00:23:50
are actually the same thing okay so
00:23:53
there's no difference there
00:23:56
so it'd be 60 degrees in quadrant two
00:23:59
the quickest way back to the x-axis is
00:24:01
right here okay this angle here that i'm
00:24:04
drawing now i know from here to here is
00:24:07
180 and i know from here to here is 200
00:24:10
so that missing piece which is the
00:24:12
reference angle
00:24:13
um i would just go 200 minus 180
00:24:16
and get uh 20 there okay
00:24:22
um
00:24:23
very very important as we go through
00:24:24
this the reference angles are formed
00:24:26
with the x-axis
00:24:28
never the y-axis okay be very very
00:24:30
careful of that okay so for instance in
00:24:33
this third example don't look at this
00:24:35
and say oh there's my reference angle
00:24:36
nope it's not because you formed that
00:24:38
with the y-axis not with the x-axis
00:24:42
okay
00:24:43
so for this guy the reference angle is
00:24:45
actually right here
00:24:47
but again i know that this is 180 and
00:24:50
110 took me to the terminal arm so how
00:24:53
much do i have left to go to get to 180
00:24:55
that reference angle would have to be
00:24:56
70.
00:24:58
okay and then finally
00:25:00
here for the negative 330 i've almost
00:25:03
gone a full circle now just because my
00:25:05
angle is negative my reference angles
00:25:07
are never negative okay reference angles
00:25:09
are always considered positive
00:25:11
so i'm thinking to myself okay well
00:25:13
that's almost a full circle how much do
00:25:15
i have left to get to that full circle
00:25:17
well i'm missing that 30 degrees so 30
00:25:19
degrees there would be the reference
00:25:20
angle
00:25:21
okay
00:25:23
awesome
00:25:27
okay so
00:25:29
what would happen
00:25:30
uh to any of our angles above if we
00:25:32
rotated them another 360 or a negative
00:25:37
360 degrees
00:25:39
so here's the concept i want you to
00:25:41
think about let's just pick on this
00:25:42
angle here that i've drawn below for a
00:25:44
sec
00:25:45
um if i was to start at this terminal
00:25:48
arm
00:25:49
and rotate it another negative or
00:25:52
another positive 360 degrees sorry okay
00:25:57
the point i want to make is i end up
00:25:58
right where i started right because 360
00:26:01
degrees is a full circle
00:26:03
um so i'll end up right back there
00:26:06
that's the red line that i just drew
00:26:09
what if i started here
00:26:11
and i rotated
00:26:13
uh negative 360.
00:26:16
well that would end up right here
00:26:18
right right back where i started
00:26:21
so
00:26:23
what i want you to start thinking about
00:26:25
is for this one picture this one angle
00:26:28
and standard position that i've given
00:26:30
you there are actually multiple ways of
00:26:33
representing that angle okay the only
00:26:36
thing that would be different is the
00:26:38
specific rotational
00:26:41
angle that they show you there okay this
00:26:43
one is
00:26:45
uh just from here straight to here but i
00:26:48
could have started here
00:26:50
and gone and done a rotational angle
00:26:53
like that
00:26:54
okay
00:26:55
or i could have
00:26:57
started here
00:26:59
and done a rotational angle
00:27:02
like that
00:27:04
okay
00:27:05
i can do this multiple multiple times
00:27:08
and end up back where i started all of
00:27:10
those angles are called
00:27:12
coterminal to each other okay coterminal
00:27:15
whenever you see the word co
00:27:18
in front of a word in the english
00:27:20
language co means with so if you
00:27:22
cohabitate
00:27:24
uh you
00:27:25
live with someone
00:27:27
if you cooperate you work with someone
00:27:32
usually you work well with someone okay
00:27:35
um so all those angles are called
00:27:37
coterminal angles
00:27:38
now to get them i add 360 or i subtract
00:27:43
360 from the angle in question
00:27:46
[Music]
00:27:47
so name a positive angle and a negative
00:27:49
angle that are coterminal with 300
00:27:51
degrees
00:27:52
okay
00:27:53
uh then we'll write an equation to
00:27:55
represent all coterminal angles because
00:27:57
i'm hoping after that conversation we
00:27:59
just had that you're thinking hey isn't
00:28:01
there an infinite amount of ways to do
00:28:03
that and there is we'll talk about how
00:28:05
we write that in just one second let's
00:28:07
get the positive and the negative first
00:28:09
though so i want to start with the 300
00:28:12
degrees
00:28:13
so if i add 360 to that i'm right back
00:28:16
where i was for the 300. so 300 plus 360
00:28:21
that's going to give me 660.
00:28:23
okay or i could go 300 degrees minus
00:28:27
360. that would still give me a
00:28:29
coterminal angle of negative 60. okay so
00:28:32
in these examples i added one circle and
00:28:35
i subtracted one circle
00:28:37
but i could add five circles i could
00:28:39
subtract 20 circles i could add 18
00:28:42
billion circles okay
00:28:44
so
00:28:45
when we say we want to write an equation
00:28:48
to represent all coterminal angles this
00:28:51
is how we do it we start with the first
00:28:53
guy now that first guy by the way is
00:28:54
called a principal angle that's the
00:28:57
smallest positive angle we got okay
00:29:00
then we're going to say okay i want to
00:29:02
add multiples of a circle well a circle
00:29:05
is 360 degrees
00:29:07
and if i want any multiple of that i can
00:29:10
do that by putting an n there so 360
00:29:12
degrees n
00:29:14
okay
00:29:14
now
00:29:15
once i put a letter there i have to
00:29:18
establish the parameters around that
00:29:20
variable okay
00:29:22
for instance n can't be 1.2 if i went
00:29:26
1.2
00:29:28
circles
00:29:29
i'm not going to end up where i started
00:29:32
right it has to be a full circle so what
00:29:35
we do is we qualify that by saying okay
00:29:39
n has to be a member of the integer
00:29:41
family okay so it could be five it could
00:29:44
be ten it could be negative eighteen
00:29:45
billion but it can't be negative
00:29:47
eighteen billion point three
00:29:49
okay it has to be a full
00:29:52
circle
00:29:53
okay so that's gonna look like this
00:29:56
now you will see sometimes um
00:29:59
it said plus or minus here instead and
00:30:01
that's fine too okay often when it's
00:30:03
plus or minus they'll change the integer
00:30:06
family to the whole family because the
00:30:08
plus minus takes care of the negatives
00:30:12
so i don't need to say integers here um
00:30:14
it doesn't matter both are perfectly
00:30:16
acceptable
00:30:18
okay
00:30:20
okay so terminology i should now know or
00:30:24
soon know
00:30:25
well the initial arm um that is where we
00:30:29
start
00:30:30
um our rotational angle okay now if i'm
00:30:34
an angle in standard position
00:30:36
the initial arm would have to be on the
00:30:39
positive x-axis
00:30:41
okay so i'm just going to draw that
00:30:43
right here there's my initial arm
00:30:46
okay
00:30:47
and then the terminal arm would be
00:30:50
somewhere else
00:30:51
with the
00:30:53
vertex at the origin there okay now i
00:30:57
should i was using a straight line so
00:30:59
i'm just going to add arrowheads there
00:31:02
whoops that's a bad arrowhead but there
00:31:04
well that arrives that so i have an
00:31:06
angle in standard position um which is
00:31:08
the third one i need to talk about
00:31:10
anyway but don't forget you also have to
00:31:11
have the rotation
00:31:13
the angle of rotation on an angle of
00:31:16
standard position okay so we've checked
00:31:18
off initial arm we've checked off
00:31:20
terminal arm we've checked off standard
00:31:22
position now what i've just drawn you is
00:31:24
an angle in standard position okay
00:31:27
coterminal means they share the same
00:31:30
terminal arm okay so we could do the one
00:31:33
i just drew you but if i switched colors
00:31:36
we could also have represented it like
00:31:38
that and said it was the negative
00:31:41
version
00:31:42
or if i switched to another color i
00:31:44
could have said it was that spun around
00:31:47
a whole circle and then got there
00:31:49
okay that's what coterminal means
00:31:53
and then the primary trigonometric
00:31:54
ratios are
00:31:56
sine cosine and tangent and again it
00:31:58
might be very helpful to commit to
00:32:00
memory at this stage of your life the
00:32:02
sohcahtoa okay
00:32:04
that's just an acronym that means sine
00:32:07
is opposite over hypotenuse
00:32:10
cosine is adjacent over
00:32:12
hypotenuse and tangent is opposite over
00:32:16
adjacent
00:32:18
okay
00:32:19
so
00:32:20
that's our first lesson intrigue i've
00:32:23
written your homework there for those of
00:32:25
you who are with me at school
00:32:27
um and then we will get into some more
00:32:30
deeper level stuff um as we go through
00:32:33
the next couple of lessons the next
00:32:34
couple of lessons
00:32:36
kind of go
00:32:37
like
00:32:39
really closely together
00:32:41
so you know if you find one confusing
00:32:43
it's almost like you gotta get through
00:32:46
two to three of them before it kind of
00:32:48
all clicks um so don't stress if it
00:32:51
doesn't click right away
00:32:53
um just keep going through things keep
00:32:56
reviewing
00:32:57
um and give yourself a processing time
00:32:58
to click okay so uh get your homework
00:33:01
done be nice and neat communicate well
00:33:04
and check with me if you have any
00:33:05
questions okay take care guys bye
