Fundamentals of Biomechanics: Equilibrium, Motion, and DeformationSpringer Science & Business Media, 14 mars 2013 - 393 sidor Biomechanics applies the principles and rigor of engineering to the mechanical properties of living systems. This book integrates the classic fields of mechanics--statics, dynamics, and strength of materials--using examples from biology and medicine. Fundamentals of Biomechanics is excellent for teaching either undergraduates in biomedical engineering programs or health care professionals studying biomechanics at the graduate level. Extensively revised from a successful first edition, the book features a wealth of clear illustrations, numerous worked examples, and many problem sets. The book provides the quantitative perspective missing from more descriptive texts, without requiring an advanced background in mathematics. It will be welcomed for use in courses such as biomechanics and orthopedics, rehabilitation and industrial engineering, and occupational or sports medicine. |
Innehåll
VI | 3 |
VII | 5 |
VIII | 6 |
X | 7 |
XI | 8 |
XII | 10 |
XIII | 11 |
XIV | 12 |
CXXIII | 206 |
CXXIV | 211 |
CXXV | 213 |
CXXVI | 214 |
CXXVII | 216 |
219 | |
CXXX | 221 |
CXXXIII | 222 |
XV | 13 |
XVII | 14 |
17 | |
XX | 19 |
XXIII | 20 |
XXVI | 21 |
XXX | 22 |
XXXII | 23 |
XXXIII | 24 |
XXXIV | 27 |
29 | |
XXXVI | 31 |
XXXIX | 32 |
XL | 33 |
XLI | 34 |
XLII | 39 |
XLIV | 40 |
XLV | 44 |
47 | |
XLVII | 49 |
XLIX | 51 |
L | 53 |
LI | 54 |
LII | 55 |
LIII | 56 |
LIV | 58 |
LV | 63 |
LVI | 65 |
LVII | 71 |
LVIII | 73 |
LIX | 77 |
81 | |
LXI | 83 |
LXII | 84 |
LXIII | 85 |
LXV | 86 |
LXVI | 91 |
LXVII | 95 |
LXVIII | 100 |
LXIX | 107 |
LXX | 111 |
LXXI | 113 |
LXXII | 115 |
117 | |
LXXIV | 119 |
LXXV | 120 |
LXXVI | 121 |
LXXVII | 122 |
LXXVIII | 123 |
125 | |
LXXXII | 127 |
LXXXV | 128 |
LXXXVI | 130 |
LXXXVII | 132 |
LXXXVIII | 133 |
LXXXIX | 134 |
XC | 135 |
XCI | 136 |
XCIII | 137 |
XCVI | 138 |
XCVII | 139 |
XCVIII | 140 |
XCIX | 147 |
153 | |
CI | 155 |
CII | 156 |
CIII | 161 |
CV | 163 |
CVI | 166 |
CVII | 168 |
CVIII | 169 |
CX | 171 |
CXI | 173 |
CXII | 179 |
CXIII | 189 |
CXIV | 191 |
195 | |
CXVII | 197 |
CXVIII | 198 |
CXIX | 199 |
CXX | 202 |
CXXI | 203 |
CXXII | 205 |
CXXXIV | 223 |
CXXXVII | 224 |
CXL | 225 |
227 | |
CXLII | 229 |
CXLIV | 231 |
CXLV | 232 |
CXLVI | 233 |
CXLVII | 234 |
CXLVIII | 240 |
CL | 242 |
CLI | 243 |
CLII | 246 |
CLIII | 251 |
253 | |
CLV | 255 |
CLVII | 257 |
CLVIII | 259 |
CLIX | 261 |
CLXI | 264 |
CLXIV | 265 |
CLXVI | 266 |
CLXVII | 271 |
273 | |
CLXIX | 275 |
CLXXI | 276 |
CLXXIII | 277 |
CLXXV | 285 |
CLXXVI | 287 |
CLXXVII | 288 |
CLXXX | 291 |
295 | |
CLXXXII | 297 |
CLXXXIII | 303 |
CLXXXIV | 304 |
CLXXXV | 305 |
CLXXXVI | 306 |
CLXXXVIII | 311 |
315 | |
CXCI | 317 |
CXCIII | 319 |
CXCIV | 325 |
CXCV | 326 |
CXCVI | 327 |
CXCVII | 331 |
CXCVIII | 334 |
CC | 335 |
337 | |
CCII | 339 |
CCVI | 340 |
CCVIII | 341 |
343 | |
CCX | 345 |
CCXII | 346 |
CCXV | 347 |
CCXVIII | 348 |
CCXX | 349 |
CCXXII | 353 |
CCXXIII | 354 |
CCXXIV | 355 |
CCXXV | 357 |
359 | |
CCXXVII | 361 |
CCXXVIII | 362 |
CCXXX | 363 |
CCXXXI | 364 |
CCXXXII | 365 |
CCXXXIII | 366 |
CCXXXV | 367 |
CCXXXVI | 368 |
CCXXXVII | 369 |
CCXXXVIII | 370 |
CCXXXIX | 372 |
CCXLI | 373 |
CCXLII | 374 |
CCXLIII | 375 |
CCXLIV | 377 |
CCXLV | 378 |
CCXLVI | 379 |
CCXLVII | 381 |
385 | |
Andra upplagor - Visa alla
Fundamentals of Biomechanics: Equilibrium, Motion, and Deformation Nihat Özkaya,Margareta Nordin Begränsad förhandsgranskning - 1999 |
Fundamentals of Biomechanics: Equilibrium, Motion, and Deformation Nihat Özkaya,Margareta Nordin Fragmentarisk förhandsgranskning - 1991 |
Fundamentals of Biomechanics: Equilibrium, Motion, and Deformation Dawn L. Leger Ingen förhandsgranskning - 2013 |
Vanliga ord och fraser
acceleration analyses angle angular applied Assume axis ball beam block body bone calculated called center of gravity collision components compressive concepts Consider constant coordinate cross-sectional curve defined deformation derivative determined direction displacement distance effects elastic element energy equal equation equilibrium example expressed force force applied forces acting friction function given hand horizontal illustrated in Figure integral joint kinetic known length line of action linear load located lower magnitude mass material maximum measured mechanical method moment moments motion moving muscle negative normal Note object occurs person plane position Problem properties quantity reaction force relative represents respect resultant rotational shear stress shown in Figure side Solution specimen speed strain strength structure subjected Substituting surface tensile tension tion torque translational unit values vector velocity vertical weight yield zero