1 00:00:07,440 --> 00:00:09,600 PROFESSOR: Welcome back to recitation. 2 00:00:09,600 --> 00:00:12,910 In this segment I'm going to actually show-- well, 3 00:00:12,910 --> 00:00:15,700 you're actually going to show-- the derivative of tangent 4 00:00:15,700 --> 00:00:17,300 x using the quotient rule. 5 00:00:17,300 --> 00:00:20,170 So what I'd like you to do, I wanted to remind you 6 00:00:20,170 --> 00:00:21,810 of what the quotient rule is. 7 00:00:21,810 --> 00:00:23,750 So u and v are functions of x. 8 00:00:23,750 --> 00:00:26,040 We want to take the derivative of u divided 9 00:00:26,040 --> 00:00:29,020 by v. I've written the formula that you 10 00:00:29,020 --> 00:00:31,420 were given in class for this. 11 00:00:31,420 --> 00:00:35,850 And I'm asking for you to take d/dx of tangent x 12 00:00:35,850 --> 00:00:37,240 using the quotient rule. 13 00:00:37,240 --> 00:00:39,810 And the hint I will give you is the reason we can obviously 14 00:00:39,810 --> 00:00:42,640 use the quotient rule is because tangent x is 15 00:00:42,640 --> 00:00:44,640 equal to a quotient of two functions of x. 16 00:00:44,640 --> 00:00:47,050 It's sine x divided by cosine of x. 17 00:00:47,050 --> 00:00:49,240 So I'm going to give you a minute to work this out 18 00:00:49,240 --> 00:00:52,390 for yourself, and then when we come back I will do it for you. 19 00:00:55,001 --> 00:00:55,500 OK. 20 00:00:55,500 --> 00:00:58,220 So we want to find the derivative of tangent x. 21 00:00:58,220 --> 00:01:02,200 So let me-- let me work on this side of the board. 22 00:01:02,200 --> 00:01:09,370 So I'm actually going to take d/dx of sine x divided 23 00:01:09,370 --> 00:01:11,481 by cosine of x. 24 00:01:11,481 --> 00:01:11,980 OK. 25 00:01:11,980 --> 00:01:15,160 So in this case, sine x is u. 26 00:01:15,160 --> 00:01:20,419 Cosine x is v. So using my quotient rule I know that first 27 00:01:20,419 --> 00:01:21,960 I have to take the derivative of sine 28 00:01:21,960 --> 00:01:25,140 x-- that's cosine x-- and then I multiply it 29 00:01:25,140 --> 00:01:28,000 by the denominator, the v, which is cosine x. 30 00:01:28,000 --> 00:01:33,320 So my first term in the numerator is cosine squared x. 31 00:01:33,320 --> 00:01:37,210 Again, one cosine x comes from the derivative of sine x, 32 00:01:37,210 --> 00:01:41,630 one cosine x is the v. It's the cosine x in the denominator. 33 00:01:41,630 --> 00:01:45,250 Then I have to subtract v prime u. 34 00:01:45,250 --> 00:01:48,270 The derivative of cosine x is negative sine x. 35 00:01:48,270 --> 00:01:52,710 I'll actually just write that one down. 36 00:01:52,710 --> 00:01:55,520 And then I bring the u along for the ride. 37 00:01:55,520 --> 00:01:57,580 So I multiply by sine x here. 38 00:02:00,120 --> 00:02:03,460 And then I take v squared in the denominator from the formula. 39 00:02:03,460 --> 00:02:06,470 v, again, is cosine x, so I take cosine 40 00:02:06,470 --> 00:02:08,125 squared x in the denominator. 41 00:02:08,125 --> 00:02:10,000 Now this at this point is a little bit messy, 42 00:02:10,000 --> 00:02:11,620 but the nice thing is that we can 43 00:02:11,620 --> 00:02:14,820 use some trigonometric identities to simplify this. 44 00:02:14,820 --> 00:02:19,820 So let me first write out what it is a little more clearly. 45 00:02:19,820 --> 00:02:22,770 Minus a negative gives you a positive. 46 00:02:22,770 --> 00:02:24,540 And then here I get sine x times sine 47 00:02:24,540 --> 00:02:28,700 x, so I get the sine squared x. 48 00:02:28,700 --> 00:02:33,320 And then I keep divided by cosine squared x. 49 00:02:33,320 --> 00:02:35,080 Now at this point some of you might 50 00:02:35,080 --> 00:02:37,990 have divided by cosine squared x here 51 00:02:37,990 --> 00:02:40,870 and gotten 1, and divided by cosine squared x here 52 00:02:40,870 --> 00:02:42,890 and gotten tangent squared x. 53 00:02:42,890 --> 00:02:45,600 And then from there you could simplify 54 00:02:45,600 --> 00:02:47,430 to another trigonometric function. 55 00:02:47,430 --> 00:02:50,250 I'm going to go straight a different way to show you 56 00:02:50,250 --> 00:02:52,140 what that actually also equals. 57 00:02:52,140 --> 00:02:53,830 So there, at this point I want to stress 58 00:02:53,830 --> 00:02:57,640 there are sort of two ways you can get to the same place. 59 00:02:57,640 --> 00:02:59,910 But I'm going to use the fact that the numerator is 60 00:02:59,910 --> 00:03:02,950 a very nice trigonometric identity that we know. 61 00:03:02,950 --> 00:03:06,890 We know cosine squared x plus sine squared x always equals 1. 62 00:03:06,890 --> 00:03:11,470 So this is quite lovely, the numerator simplifies to 1, 63 00:03:11,470 --> 00:03:15,460 the denominator stays cosine squared x. 64 00:03:15,460 --> 00:03:16,980 What is this function? 65 00:03:16,980 --> 00:03:20,070 1 over cosine x is actually secant x. 66 00:03:20,070 --> 00:03:25,260 So if you need, at this point, to rewrite the whole thing 67 00:03:25,260 --> 00:03:27,180 like this, right? 68 00:03:27,180 --> 00:03:29,430 1 squared is 1 and in the denominator we still 69 00:03:29,430 --> 00:03:34,170 get cosine squared x-- this tells you that 1 over cosine 70 00:03:34,170 --> 00:03:40,100 squared x is actually just equal to secant squared x. 71 00:03:40,100 --> 00:03:41,660 So again, what I want to point out 72 00:03:41,660 --> 00:03:44,500 is we've now taken the derivative of tangent x 73 00:03:44,500 --> 00:03:47,400 and we got that that's secant squared x. 74 00:03:47,400 --> 00:03:50,110 Now using this quotient rule, you 75 00:03:50,110 --> 00:03:52,720 can do the same kind of thing with cotangent x, 76 00:03:52,720 --> 00:03:54,760 with cosecant x, with secant x. 77 00:03:54,760 --> 00:03:56,230 You can find all these derivatives 78 00:03:56,230 --> 00:03:59,750 of these trigonometric functions using the quotient rule. 79 00:03:59,750 --> 00:04:03,250 So if you want to know what the derivative of secant x is, 80 00:04:03,250 --> 00:04:06,640 you should take d(dx of 1 divided by cosine x and use 81 00:04:06,640 --> 00:04:07,710 the quotient rule. 82 00:04:07,710 --> 00:04:11,780 Or, in fact, the chain rule would work well there also, 83 00:04:11,780 --> 00:04:12,780 to find that derivative. 84 00:04:12,780 --> 00:04:16,200 So we are building up the number of derivatives 85 00:04:16,200 --> 00:04:18,540 we can find using these different rules. 86 00:04:18,540 --> 00:04:20,761 So we'll stop there.