1. Limits & Continuity 1

2. The limit of f(x) as x approaches c from the left.

3. Limits & Continuity 2

4. The limit of f(x) as x approaches c from the right.

5. Limits & Continuity 3

6. The y-value that the graph is approaching on both sides of the x-value c.

7. Limits & Continuity 4 The Limit D.oes N.ot E.xist

8. 1.Oscillating 2.Approaching + or - 3.The function does not approach the same value from the left as the right.

9. Limits & Continuity 5 Limits of Rational Functions at Vertical Asymptotes 4 Cases: (c is located at the vertical asymptote x = c) ABCDABCD

10. ABCDD.N.E. onlyor D.N.E.

11. Limits & Continuity 6 Evaluating Limits Using Direct Substitution

12. Plug it in!

13. Limits & Continuity 7 Evaluating Limits Using Factor & Simplify

15. Limits & Continuity 8 Evaluating Limits Using Conjugates

17. Limits & Continuity 9 Evaluating Limits Using Common Denominators

19. Limits & Continuity 10

21. Limits & Continuity 11

23. Limits & Continuity 12

24. Limits & Continuity

25. 13

27. Limits & Continuity 14

29. Limits & Continuity 15

31. Limits & Continuity 16 Limits of Rational Functions as x approaches infinity 3 cases

33. Limits & Continuity 17

34. Definition of “e”

35. Limits & Continuity 18

36. Definition of “e”

37. Limits & Continuity 19

38. 1

39. Limits & Continuity 20

40. 0

41. Limits & Continuity 21 Continuity A function is continuous at the point x = a if and only if: 1) 2) 3)

43. Limits & Continuity 22 Open Interval

44. (a, b) *endpoints not included

45. Limits & Continuity 23 Closed Interval

46. [a, b] *endpoints are included

47. Limits & Continuity 24 Continuity on a Closed Interval

48. A function is continuous on the closed interval [a, b] if it is continuous on the open interval (a, b) and

49. Limits & Continuity 25

51. Limits & Continuity 26

53. Limits & Continuity 27

55. Limits & Continuity 28

57. Basic Derivative Mechanics 29 Average Rate of Change

58. Basic Derivative Mechanics 29 (same as average velocity, different from average value)

59. Derivatives 30 Definition of Derivative

60. Derivatives 30 Slope of the tangent line

61. Derivatives 31 Definition of Derivative at a specific x value

62. Derivatives 31

63. Derivatives 32 Point-Slope form of a Line

64. Derivatives 32

65. Derivatives 33 Normal Line

66. Derivatives 33 Perpendicular to the tangent line at the point of tangency (slope is opposite sign and reciprocal)

67. Derivatives 34 Situations in which the Derivative fails to exist 1) 2) 3) 4)

68. Derivatives 34 1)The function does not exist. (ex: holes, asymptotes, gaps, discontinuities) 2) 3) Cusps (Sharp Corners – the function isn’t “smooth,” ex: absolute value) 4) Points of Vertical Tangency

69. Derivatives 35

70. Derivatives 35

71. Derivatives 36

72. Derivatives 36

73. Derivatives 37 Power Rule

74. Derivatives 37

75. Derivatives 38

76. Derivatives 38

77. Derivatives 39

78. Derivatives 39

79. Derivatives 40

80. Derivatives 40

81. Derivatives 41

82. Derivatives 41

83. Derivatives 42

84. Derivatives 42

85. Derivatives 43

86. Derivatives 43

87. Derivatives 44

88. Derivatives 44

89. Derivatives 45

90. Derivatives 45

91. Derivatives 46

92. Derivatives 46

93. Derivatives 47 Product Rule Product Rule with 3 factors

94. Derivatives 47 Product Rule with 3 factors

95. Derivatives 48 Quotient Rule

96. Derivatives 48

97. Derivatives 49

98. Derivatives 49

99. Derivatives 50

100. Derivatives 50

101. Derivatives 51

102. Derivatives 51

103. Derivatives 52

104. Derivatives 52

105. Derivatives 53 Chain Rule Derivative of a composition of functions where f is the outside function and g is the inside function

106. Derivatives 53 1)Take the derivative of the outside function. 2)Copy the inside function. 3)Multiply by the derivative of the inside function.

107. Advanced Derivative Mechanics Implicit Differentiation 54

108. Advanced Derivatives 1.Differentiate both sides with respect to x. (When you take the derivative of something with a y in it you do the derivative as normal, but then multiply it by the derivative of y with respect to x (dy/dx). 2.Collect all dy/dx terms on one side. 3.Factor dy/dx out. 4.Solve for (isolate) dy/dx.

109. Advanced Derivatives Logarithmic Differentiation 55

110. Advanced Derivatives

111. 56

112. Advanced Derivatives

113. 57

114. Advanced Derivatives

115. 58

116. Advanced Derivatives

117. 59

118. Advanced Derivatives

119. 60

120. Advanced Derivatives

121. 61

122. Advanced Derivatives

123. 62

124. Advanced Derivatives

125. 63

126. Advanced Derivatives

127. 64

128. Advanced Derivatives

129. 65

130. Advanced Derivatives

131. If f and g are inverse functions, 66

132. 1. Find the derivative of f(x). 2. The derivative of its inverse is

133. Advanced Derivatives Indeterminate Forms 67

134. Advanced Derivatives

135. L’Hôpital’s Rule 68

136. Advanced Derivatives If the limit yields an indeterminate form, *Can be repeated on same problem if you get indeterminate forms again!

137. Graphical Analysis Critical Number And Critical Point 69

138. Graphical Analysis Critical Numbers: x values where Critical Point:

139. Graphical Analysis Increasing 70

140. Graphical Analysis

141. Decreasing 71

142. Graphical Analysis

143. Relative or Local Minimum 72

144. Graphical Analysis

145. Relative or Local Maximum 73

146. Graphical Analysis

147. Extrema Extremum 74

148. Graphical Analysis Extrema: (plural) maximums and minimums Extremum: (singular) a maximum or minimum

149. Graphical Analysis First Derivative Test 75

150. Graphical Analysis

151. Concave Up (Positive Curvature) 76

152. Graphical Analysis Like a Bowl

153. Graphical Analysis Concave Down (Negative Curvature) 77

154. Graphical Analysis Like a Rainbow

155. Graphical Analysis P.oints O.f I.Nflection (P.O.I.) 78

156. Graphical Analysis The curvature changes

157. Graphical Analysis Second Derivative Test 79

158. Graphical Analysis

159. Absolute or Global Maximum 80

160. Graphical Analysis The BIGGEST y-coordinate on a graph (cannot be infinity, so sometimes there are none) *Check all critical points and endpoints to find the absolute maximum!

161. Graphical Analysis Absolute or Global Minimum 81

162. Graphical Analysis The smallest y-coordinate on a graph (cannot be negative infinity, so sometimes there are none) *Check all critical points and endpoints to find the absolute minimum!

163. Graphical Analysis Intermediate Value Theorem 82

164. Graphical Analysis If a function is continuous and y is between f(a) and f(b), there exists at least one number x=c in (a,b) such that f(c) = y.

165. Graphical Analysis Mean Value Theorem 83

166. Graphical Analysis If a function is continuous and differentiable on (a,b) there is at least one number x=c in (a,b) such that

167. Graphical Analysis Rolle’s Theorem 84

168. Graphical Analysis If a function is continuous and differentiable on (a,b) and f(a) = f(b) there is at least one number x=c in (a,b) such that

169. Graphical Analysis Extreme Value Theorem 85

170. Graphical Analysis If a function is continuous on a closed interval [a, b], Then it has both an absolute minimum and an absolute maximum.

171. Derivative Applications Related Rates 86

172. Derivative Applications *Plugging in non-constant quantities before differentiating is a NO-NO! Draw a picture. Make a list of all known and unknown rates and quantities. Label each quantity that changes with time. Relate the variables in an equation. Differentiate with respect to time. *EVERY VARIABLE WILL GENERATE A RATE!* Substitute the known quantities and rates in and solve.

173. Derivative Applications Local Linearity (Tangent to a Curve) 87

174. Derivative Applications Given:

175. Derivative Applications Differential dy 88

176. Derivative Applications

177. Maximum and Minimum Application Problems 89

178. Derivative Applications 1.Find a formula for the quantity to be maximized/ minimized (only 2 variables). 2.Find an interval of possible values based on restrictions. 3.Set f ’(x) = 0 and solve. 4.The max/min will be at the answer to step 3 (or at one of the endpoints of the interval, if applicable).

179. Derivative Applications: Motion Position Function 90

180. Derivative Applications: Motion Tells where a particle is along a straight line

181. Derivative Applications: Motion Velocity Function 91

182. Derivative Applications: Motion Describes the change in position Positive Velocity is moving to the right or up Negative Velocity is moving to the left or down

183. Derivative Applications: Motion Acceleration Function 92

184. Derivative Applications: Motion Describes the change in velocity

185. Derivative Applications: Motion Speed

186. Derivative Applications: Motion Absolute Value of Velocity Always Positive!

187. Derivative Applications: Motion Displacement ***We will learn another method for this in the Spring Semester!*** 94

188. Derivative Applications: Motion Final Position – Initial Position

189. Derivative Applications: Motion Total Distance Traveled ***We will learn another method for this in the Spring Semester!*** 95

190. Derivative Applications: Motion Add the absolute values of the differences in position between all resting points.

191. Derivative Applications: Motion Average Velocity Or Average Rate of Change 96

192. Derivative Applications: Motion Notice the similarity to the slope formula!

193. Derivative Applications: Motion Average Speed 97

194. Derivative Applications: Motion

195. Average Acceleration 98

196. Derivative Applications: Motion Notice the similarity to the slope formula!

197. Derivative Applications: Motion Speeding Up 99

198. Derivative Applications: Motion Velocity and Acceleration have the same sign. Both Positive or Both Negative

199. Derivative Applications: Motion Slowing Down 100

200. Derivative Applications: Motion Velocity and Acceleration have opposite signs.

201. Derivative Applications: Motion The Free-Fall Model ***You do not have to memorize this one!*** (It will be provided to you. Just be sure you know what the parts mean and how to use it!) 101

202. Derivative Applications: Motion The height s(t) of the object in free-fall is given by the formula: By taking the derivative of the Free-Fall Model, you obtain: And, by taking the second derivative of the Free-Fall Model, you obtain:

203. Integration Right Hand Riemann Sum 102

204. Integration Add up the following for each subinterval:

205. Integration Left Hand Riemann Sum 103

206. Integration Add up the following for each subinterval:

207. Integration Midpoint Riemann Sum 104

208. Integration Add up the following for each subinterval:

209. Integration Trapezoid Riemann Sum 105

210. Integration Add up the following for each subinterval:

211. Integration 106

212. Integration

213. 107

214. Integration

215. 108

216. Integration

217. 109

218. Integration

219. 110

220. Integration

221. 111

222. Integration

223. 112

224. Integration

225. 113

226. Integration

227. 114

228. Integration

229. 115

230. Integration

231. 116

232. Integration

233. 117

234. Integration

235. 118

236. Integration

237. 119

238. Integration

239. 120

240. Integration

241. 121

242. Integration

243. 122

244. Integration

245. 123

246. Integration

247. 124

248. Integration

249. 125

250. Integration

251. 126

252. Integration

253. 127

254. Integration

255. 128

256. Integration

257. 129

258. Integration

259. 130

260. Integration

261. 131

262. Integration

263. 132

264. Integration

265. 133

266. Integration

267. 134

268. Integration

269. 135

270. Integration

271. 136

272. Integration

273. The Fundamental Theorem of Calculus 137

274. Integration To evaluate a definite integral, find the antiderivative of the integrand. (Omit the +C.) Substitute the upper limit of integration into the antiderivative, and then substitute the lower limit of integration into the antiderivative. Calculate the difference of the two quantities.

275. Integration New y-value 138

276. Integration

277. Average Value (Like average temperature or average distance, NOT average rate of change!) 139

278. Integration

279. The 2 nd Fundamental Theorem of Calculus 140

280. Integration

281. The 2 nd Fundamental Theorem of Calculus with the Chain Rule 141

282. Integration

283. U-Substitution 142

284. Integration U-Substitution is used to integrate compositions of functions (like Substitution is the most powerful tool we have to find anti-derivatives when inspection for common rules fails. How to do U-Substitutions 1.Choose the “inside function” of a composition of functions to be called u. 2.Calculate the derivative of u, called 3. Get du by itself. (Multiply by dx). ** Our goal is to replace the entire integrand with an expression (or expressions) in terms of u. When done correctly, the new integral is a much easier one to evaluate. 4. It is often helpful to get dx by itself, although sometimes the problem already has part of your du in it, so you may not need to completely isolate dx to do your substitution. 5. Replace the inside function with u. Replace dx with whatever you got for dx in the previous step. 6. Integrate. 7. Replace u with the inside function.

285. Integration Functions Defined By Integrals Find the new y-value. 143

286. Integration

287. Integration Applications Area Between 2 Curves 144

288. Integration Applications

289. Volume of Solids of Known Cross Sections 145

290. Integration Applications

291. Volume of Solids of Revolution Cross section is a circle 146

292. Integration Applications

293. Volume of Solids of Revolution Cross section is a washer 147

294. Integration Applications

295. Arc Length 148

296. Integration Applications

297. Integration: Motion Displacement 149

298. Integration: Motion Change in position

299. Integration: Motion Total Distance Traveled 149

300. Integration: Motion

301. New Position 150

302. Integration: Motion

303. New Velocity 151

304. Integration: Motion

305. Differential Equations & More Slope Fields 152

306. Differential Equations & More Given a dy/dx formula, substitute in x and y from each marked point to determine the slope there. 152

307. Differential Equations & More Differential Equations 153

308. Differential Equations & More 1)Cross Multiply 2)Get all x’s & dx’s on one side. Get all y’s and dy’s on the other side. 3)Remember to put +C on the x side. 4)Substitute in the given point (initial condition) and solve for C. 5)Rewrite equation including C and solve for y. 153

309. Differential Equations & More Exponential Growth 154

310. Differential Equations & More

311. Euler’s Method (for approximation) 155 BC Only

312. Differential Equations & More

313. Logistics 156 BC Only

314. Differential Equations & More BC Only

315. Differential Equations & More Integration By Parts 157 BC Only

316. Differential Equations & More 157 BC Only

317. Differential Equations & More Integration with Partial Fractions 158 BC Only

318. Differential Equations & More 1)If deg. Num.> deg. Denom., do long division 1 st 2)Factor denom. 3)Write eq’n w/ A, B, C, … to set up partial fractions. 4)Mult. Both sides by denom. Of orig. function. 5)Simplify both sides. 6)On right side, group like terms (ie: x 2, x, constant) BC Only 7) On the right side, factor out x 2, x, constant 8) Set up a system of equations & solve for A, B, C, etc. 9) Rewrite integral using partial fractions 10) Integrate each partial fraction individually.

319. Differential Equations & More Improper Integrals 159 BC Only

320. Differential Equations & More Function is undefined at upper &/or lower limit 159 BC Only

321. Convergence Tests Geometric Series Test 160 BC Only

322. Convergence Tests If, the series converges to If, the series diverges. 160 BC Only

323. Convergence Tests Sum of an Infinite Geometric Series 161 BC Only

324. Convergence Tests 161 BC Only

325. Convergence Tests Telescoping Series 162 BC Only

326. Convergence Tests If you write out the first few terms of the series and see them “cancelling” out, the series will converge to 162 BC Only

327. Convergence Tests Divergence Test Or nth Term Test for Divergence 163 BC Only

328. Convergence Tests 163 BC Only *This test CANNOT be used to show that a series converges!

329. Convergence Tests Harmonic Series 164 BC Only

330. Convergence Tests Diverges 164 BC Only

331. Convergence Tests How do you find the sum of a series? 165 BC Only

332. Convergence Tests 165 BC Only

333. Convergence Tests Integral Test 166 BC Only

334. Convergence Tests 166 BC Only

335. Convergence Tests p-Series Test 167 BC Only

336. Convergence Tests 167 BC Only

337. Convergence Tests Direct Comparison Test 168 BC Only

338. Convergence Tests If the bigger converges, the smaller converges. If the smaller diverges, the bigger diverges. 168 BC Only

339. Convergence Tests Limit Comparison Test 169 BC Only

340. Convergence Tests 169 BC Only

341. Convergence Tests Ratio Test 170 BC Only

342. Convergence Tests 170 BC Only

343. Convergence Tests Root Test 171 BC Only

344. Convergence Tests 171 BC Only

345. Convergence Tests Ratio Test for Absolute Convergence 172 BC Only

346. Convergence Tests 172 BC Only

347. Convergence Tests Alternating Series Test 173 BC Only

348. Convergence Tests An alternating series converges if a)The absolute values of the terms decrease and b) 173 BC Only NOTE: Do not use alternating series test on a non-alternating series!

349. Convergence Tests Error Bound for Alternating Series 174 BC Only

350. Convergence Tests The absolute value of the first term left out of the partial sum 174 BC Only

351. Series Maclaurin Series 175 BC Only

352. Series A Taylor Series centered about x = 0 175 BC Only

353. Series Taylor Series 176 BC Only

354. Series 176 BC Only

355. Series Lagrange Error Bound/ Remainder of a Taylor Polynomial 177 BC Only

356. Series Given 177 BC Only

357. Series Interval of Convergence 178 BC Only

358. Series 1)Do the Ratio Test for Absolute Convergence. 2)Set the answer to the limit from step one < 1 and solve. 3)Check endpoints to see if they’re included. Plug them each in for x in the original series and test for convergence. 178 BC Only

359. Series Radius of Convergence 179 BC Only

360. Series Distance from center of interval of convergence to either end of interval. If interval is (a,b), 179 BC Only

361. Series Maclaurin Series for 180 BC Only

362. Series 180 BC Only

363. Series Maclaurin Series for 181 BC Only

364. Series 181 BC Only

365. Series Maclaurin Series for 182 BC Only

366. Series 182 BC Only

367. Series Maclaurin Series for 183 BC Only

368. Series 183 BC Only

369. Series Binomial Series Formula 184 BC Only

370. Series Remember, the number of factors in the numerator is the same as the degree of the term. 184 BC Only

371. Analytic Geometry in Calculus Parametric Equations 185 BC Only

372. Analytic Geometry in Calculus 185 BC Only

373. Analytic Geometry in Calculus Arc Length (Parametric) 186 BC Only

374. Analytic Geometry in Calculus 186 BC Only

375. Analytic Geometry in Calculus Polar Curves – 4 conversions 187 BC Only

376. Analytic Geometry in Calculus 187 BC Only

377. Analytic Geometry in Calculus Slope of a Polar Curve 188 BC Only

378. Analytic Geometry in Calculus 188 BC Only

379. Analytic Geometry in Calculus Area of a Polar Curve 189 BC Only

380. Analytic Geometry in Calculus Inside one petal 189 BC Only Set r = Θ to help you find the upper and lower limits.

381. Analytic Geometry in Calculus Power Reducing Formula (from Precalculus!) 190 BC Only

382. Analytic Geometry in Calculus 190 BC Only

383. Analytic Geometry in Calculus Power Reducing Formula (from Precalculus!) 191 BC Only

384. Analytic Geometry in Calculus 191 BC Only

385. Analytic Geometry in Calculus Area of Intersections of Polar Curves 192 BC Only

386. Analytic Geometry in Calculus 192 BC Only

387. Analytic Geometry in Calculus Position Vector 193 BC Only

388. Analytic Geometry in Calculus 193 BC Only

389. Analytic Geometry in Calculus Velocity Vector 194 BC Only

390. Analytic Geometry in Calculus 194 BC Only

391. Analytic Geometry in Calculus Acceleration Vector 195 BC Only

392. Analytic Geometry in Calculus 195 BC Only

393. Analytic Geometry in Calculus Speed (parametric) 196 BC Only

394. Analytic Geometry in Calculus 196 BC Only

395. Analytic Geometry in Calculus Total Distance Traveled (parametric) *same as arc length for parametric! 197 BC Only

396. Analytic Geometry in Calculus 197 BC Only