Solution Manual for Introduction to Engineering Analysis 4/E 4th Edition Kirk D. Hagen

This is completed downloadable of Solution Manual for Introduction to Engineering Analysis, 4/E 4th Edition Kirk D. Hagen

 

Product Details:

• ISBN-10 ‏ : ‎ 9780133485080
• ISBN-13 ‏ : ‎ 978-0133485080
• Author:  Kirk D. Hagen

For use in the first-year engineering course. This text is also suitable for individuals interested in adopting a problem-solving approach to engineering problems.

The goal of this text is to introduce a general problem-solving approach for the beginning engineering student. Thus, Introduction to Engineering Analysis focuses on how to solve (any) kind of engineering analytical problem in a logical and systematic way. The book helps to prepare the students for such analytically oriented courses as statics, strength of materials, electrical circuits, fluid mechanics, thermodynamics, etc.

 

Table of Content:

1. Chapter 1 The Role of Analysis in Engineering
2. Objectives
3. 1.1 Introduction
4. 1.2 Analysis and Engineering Design
5. 1.3 Analysis and Engineering Failure
6. Key Terms
7. References
8. Problems
9. Analysis and engineering design
10. Analysis and engineering failure
11. Chapter 2 Dimensions and Units
12. Objectives
13. 2.1 Introduction
14. 2.2 Dimensions
15. Example 2.1
16. Solution
17. Example 2.2
18. Solution
19. Example 2.3
20. Solution
21. Practice!
22. 2.3 Units
23. 2.4 SI Units
24. Practice!
25. 2.5 English Units
26. 2.6 Mass and Weight
27. Example 2.4
28. Solution
29. Example 2.5
30. Solution
31. Practice!
32. 2.7 Unit Conversions
33. Key Terms
34. References
35. Problems
36. Dimensions
37. Units
38. Mass and weight
39. Unit conversions
40. Chapter 3 Analysis Methodology
41. Objectives
42. 3.1 Introduction
43. 3.2 Numerical Calculations
44. 3.2.1 Approximations
45. Example 3.1
46. Solution
47. 3.2.2 Significant Figures
48. Example 3.2
49. Solution
50. Example 3.3
51. Solution
52. Practice!
53. 3.3 General Analysis Procedure
54. 3.4 The Computer as an Analysis Tool
55. 3.4.1 Spreadsheets
56. 3.4.2 Equation Solvers and Mathematics Software
57. 3.4.3 Programming Languages
58. 3.4.4 Specialty Software
59. 3.4.5 Finite Element Software
60. Practice!
61. Key Terms
62. References
63. Problems
64. Order-of-magnitude analysis
65. Significant figures
66. General analysis procedure
67. Chapter 4 Mechanics
68. Objectives
69. 4.1 Introduction
70. 4.2 Scalars and Vectors
71. 4.2.1 Vector Operations
72. 4.2.2 Vector Components
73. 4.2.3 Unit Vectors
74. Example 4.1
75. Solution
76. (a) Parallelogram law
77. (b) Vector components
78. Example 4.2
79. Solution
80. 4.3 Forces
81. Example 4.3
82. Solution
83. Practice!
84. 4.4 Free-Body Diagrams
85. Practice!
86. 4.5 Equilibrium
87. Example 4.4
88. Problem statement
89. Diagram
90. Assumptions
91. Governing equations
92. Calculations
93. Solution Check
94. Discussion
95. Example 4.5
96. Problem statement
97. Diagram
98. Assumptions
99. Governing equations
100. Calculations
101. Solution check
102. Discussion
103. Practice!
104. 4.6 Stress and Strain
105. 4.6.1 Stress
106. 4.6.2 Strain
107. 4.6.3 Hooke’s Law
108. 4.6.4 Stress–Strain Diagram
109. Example 4.6
110. Problem statement
111. Diagram
112. Assumptions
113. Governing equations
114. Calculations
115. Solution check
116. Discussion
117. Practice!
118. 4.7 Design Stress
119. Problem statement
120. Diagram
121. Assumptions
122. Governing equations
123. Calculations
124. Solution check
125. Discussion
126. Practice!
127. Key Terms
128. References
129. Problems
130. Forces
131. Free-body diagrams
132. Equilibrium
133. Stress and strain
134. Design stress
135. Chapter 5 Electrical Circuits
136. Objectives
137. 5.1 Introduction
138. 5.2 Electric Charge And Current
139. Example 5.1
140. Solution
141. Practice!
142. 5.3 Voltage
143. Practice!
144. 5.4 Resistance
145. Example 5.2
146. Solution
147. Practice!
148. 5.5 Ohm’S Law
149. Practice!
150. 5.6 Simple DC Circuits
151. Example 5.3
152. Problem Statement
153. Diagram
154. Assumptions
155. Governing equations
156. Calculations
157. Solution check
158. Discussion
159. Example 5.4
160. Problem statement
161. Diagram
162. Assumptions
163. Governing equations
164. Calculations
165. Solution check
166. Discussion
167. Practice!
168. 5.7 Kirchhoff’s Laws
169. 5.7.1 Kirchhoff’s Current Law
170. 5.7.2 Kirchhoff’s Voltage Law
171. Example 5.5
172. Problem statement
173. Diagram
174. Assumptions
175. Governing equations
176. Calculations
177. Solution check
178. Discussion
179. Practice!
180. Key Terms
181. References
182. Problems
183. Electric charge and current
184. Voltage
185. Resistance
186. Ohm’s law
187. Simple DC circuits
188. Kirchhoff’s Laws
189. Chapter 6 Thermodynamics
190. Objectives
191. 6.1 Introduction
192. 6.2 Pressure and Temperature
193. 6.2.1 Pressure
194. 6.2.2 Temperature
195. Example 6.1
196. Solution
197. Example 6.2
198. Solution
199. Practice!
200. 6.3 Forms of Energy
201. 6.3.1 Potential Energy
202. 6.3.2 Kinetic Energy
203. 6.3.3 Internal Energy
204. 6.3.4 Total Energy
205. 6.4 Work and Heat
206. 6.4.1 Mechanical Work
207. Gravitational work
208. Acceleration work
209. Boundary work
210. Shaft work
211. Spring work
212. 6.4.2 Heat
213. Example 6.3
214. Problem statement
215. Diagram
216. Assumptions
217. Governing equations
218. Calculations
219. Solution check
220. Discussion
221. Practice!
222. 6.5 The First Law of Thermodynamics
223. Example 6.4
224. Problem statement
225. Diagram
226. Assumptions
227. Governing equations
228. Calculations
229. Solution check
230. Discussion
231. Example 6.5
232. Problem statement
233. Diagram
234. Assumptions
235. Governing equations
236. Calculations
237. Solution check
238. Discussion
239. Practice!
240. 6.6 Heat Engines
241. Example 6.6
242. Solution
243. 6.7 The Second Law of Thermodynamics
244. Practice!
245. Key Terms
246. References
247. Problems
248. Pressure and temperature
249. Work and heat
250. First law of thermodynamics
251. Heat engines
252. Second law of thermodynamics
253. Chapter 7 Fluid Mechanics
254. Objectives
255. 7.1 Introduction
256. 7.2 Fluid Properties
257. 7.2.1 Density, Specific Weight, and Specific Gravity
258. 7.2.2 Bulk Modulus
259. 7.2.3 Viscosity
260. Example 7.1
261. Solution
262. Example 7.2
263. Solution
264. Example 7.3
265. Solution
266. Practice!
267. 7.3 Fluid Statics
268. 7.3.1 Pressure–Elevation Relationship
269. 7.3.2 Forces on Submerged Surfaces
270. Example 7.4
271. Solution
272. Practice!
273. 7.4 Flow Rates
274. Example 7.5
275. Solution
276. Practice!
277. 7.5 Conservation of Mass
278. Example 7.6
279. Problem Statement
280. Diagram
281. Assumptions
282. Governing equations
283. Calculations
284. Solution check
285. Discussion
286. Practice!
287. Key Terms
288. References
289. Problems
290. Fluid properties
291. Fluid statics
292. Flow rates
293. Conservation of mass
294. Chapter 8 Renewable Energy
295. Objectives
296. 8.1 Introduction
297. 8.1.1 Environmental Considerations
298. 8.2 Solar
299. 8.2.1 Solar Energy Systems
300. 8.2.2 Photovoltaic Systems
301. Example 8.1
302. Solution
303. Example 8.2
304. Solution
305. linePractice!
306. 8.3 Wind
307. 8.3.1 Basic Energy Analysis of a Horizontal Axis Wind Turbine
308. Example 8.3
309. Solution
310. Practice!
311. 8.4 Hydro
312. 8.4.1 Basic Energy Analysis of a Hydropower Plant
313. Example 8.4
314. Solution
315. Practice!
316. 8.5 Geothermal
317. 8.5.1 Basic Energy Analysis of a Binary Plant
318. Example 8.5
319. Solution
320. Practice!
321. 8.6 Marine
322. 8.6.1 Tidal
323. 8.6.2 Ocean
324. 8.6.2.1 Ocean Currents
325. Example 8.6
326. Solution
327. 8.6.2.2 Ocean Waves
328. Example 8.7
329. Solution
330. 8.6.2.3 Ocean Thermal Energy
331. Example 8.8
332. Solution
333. Practice!
334. 8.7 Biomass
335. Key Terms
336. References
337. Problems
338. Solar
339. Wind
340. Hydro
341. Geothermal
342. Marine
343. Biomass
344. Chapter 9 Data Analysis: Graphing
345. Objectives
346. 9.1 Introduction
347. 9.2 Collecting and Recording Data
348. 9.2.1 Data Identification and Association
349. 9.2.2 Accuracy, Precision, and Error
350. 9.2.3 Recording Data
351. Practice!
352. 9.3 General Graphing Procedure
353. 9.3.1 Dependent and Independent Variables
354. 9.3.2 Variable Ranges
355. 9.3.3 Graph Paper
356. 9.3.4 Location of Axes
357. 9.3.5 Graduation and Calibration of Axes
358. 9.3.6 Axis Labels
359. 9.3.7 Data Point Plotting
360. 9.3.8 Curves
361. 9.3.9 Legends and Titles
362. 9.3.10 Graphing with Computer Software
363. Practice!
364. 9.4 Curve Fitting
365. 9.4.1 Common Mathematical Functions
366. 9.4.2 Method of Selected Points
367. Example 9.1
368. Solution
369. Example 9.2
370. Solution
371. Example 9.3
372. Solution
373. 9.4.3 Least Squares Linear Regression
374. Example 9.4
375. Solution
376. Example 9.5
377. Solution
378. Practice!
379. 9.5 Interpolation and Extrapolation
380. Practice!
381. Key Terms
382. References
383. Problems
384. Collecting and recording data
385. General graphing procedure
386. Curve fitting
387. Interpolation and extrapolation
388. Chapter 10 Data Analysis: Statistics
389. Objectives
390. 10.1 Introduction
391. 10.2 Data Classification and Frequency Distribution
392. Practice!
393. 10.3 Measures of Central Tendency
394. 10.3.1 Mean
395. 10.3.2 Median
396. 10.3.3 Mode
397. Example 10.1
398. Solution
399. 10.4 Measures of Variation
400. Example 10.2
401. Solution
402. 10.5 Normal Distribution
403. Example 10.3
404. Solution
405. Key Terms
406. References
407. Problems
408. Data classification and frequency distribution
409. Measures of central tendency
410. Measures of variation
411. Normal distribution
412. Appendix A Mathematical Formulas
413. A.1 Algebra
414. A.2 Geometry
415. A.3 Trigonometry
416. A.4 Calculus
417. Appendix B Unit Conversions
418. Appendix C Physical Properties of Materials
419. Appendix D Areas Under the Standard Normal Curve from 0 to z
420. Appendix E Greek Alphabet
421. Appendix F Answers to Selected Problems
422. Index
423. A
424. B
425. C
426. D
427. E
428. F
429. G
430. H
431. I
432. J
433. K
434. L
435. M
436. N
437. O
438. P
439. Q
440. R
441. S
442. T
443. U
444. V
445. W
446. Y
447. Z