- Page 1: GRAVITATIONAL WAVES
- Page 5 and 6: ContentsPrefacexiii1 Gravitational
- Page 7 and 8: ContentsviiPART 2Gravitational-wave
- Page 9 and 10: ContentsixPART 4Theoretical develop
- Page 11: Contentsxi18.5.1 The computational
- Page 14 and 15: Chapter 1Gravitational waves, theor
- Page 16 and 17: Gravitational waves, theory and exp
- Page 18 and 19: Gravitational waves, theory and exp
- Page 20 and 21: Gravitational waves, theory and exp
- Page 22 and 23: References 9in especially simple ca
- Page 24: PART 1GRAVITATIONAL WAVES, SOURCESA
- Page 27 and 28: 14 SynopsisThe final lecture (chapt
- Page 29 and 30: 16 Elements of gravitational wavesp
- Page 31 and 32: 18 Elements of gravitational waves
- Page 33 and 34: 20 Elements of gravitational wavesI
- Page 35 and 36: 22 Elements of gravitational waves2
- Page 37 and 38: Chapter 3Gravitational-wave detecto
- Page 39 and 40: 26 Gravitational-wave detectorstech
- Page 41 and 42: 28 Gravitational-wave detectors3.2
- Page 43 and 44: 30 Gravitational-wave detectorsTher
- Page 45 and 46: 32 Gravitational-wave detectorsthos
- Page 47 and 48: 34 Gravitational-wave detectorsNois
- Page 49 and 50: 36 Gravitational-wave detectorsThis
- Page 51 and 52: 38 Gravitational-wave detectorsfreq
- Page 53 and 54:
40 Gravitational-wave detectorsLISA
- Page 55 and 56:
42 Gravitational-wave detectorsTabl
- Page 57 and 58:
44 Astrophysics of gravitational-wa
- Page 59 and 60:
46 Astrophysics of gravitational-wa
- Page 61 and 62:
48 Astrophysics of gravitational-wa
- Page 63 and 64:
Chapter 5Waves and energyHere we di
- Page 65 and 66:
52 Waves and energygeometries consi
- Page 67 and 68:
54 Waves and energyAs in linearized
- Page 69 and 70:
56 Waves and energyFinally, what is
- Page 71 and 72:
Chapter 6Mass- and current-quadrupo
- Page 73 and 74:
60 Mass- and current-quadrupole rad
- Page 75 and 76:
62 Mass- and current-quadrupole rad
- Page 77 and 78:
64 Mass- and current-quadrupole rad
- Page 79 and 80:
66 Mass- and current-quadrupole rad
- Page 81 and 82:
68 Mass- and current-quadrupole rad
- Page 83 and 84:
70 Mass- and current-quadrupole rad
- Page 85 and 86:
72 Source calculationsIn this case
- Page 87 and 88:
74 Source calculationsthat the loss
- Page 89 and 90:
76 Source calculationswhen looking
- Page 91 and 92:
78 Source calculations,,3 .3,
- Page 93 and 94:
80 Source calculationsand questions
- Page 95 and 96:
82 ReferencesSources of gravitation
- Page 97 and 98:
Solutions to exercisesChapter 2Exer
- Page 99 and 100:
86 Solutions to exercisesThe integr
- Page 101:
PART 2GRAVITATIONAL-WAVE DETECTORSG
- Page 104 and 105:
92 Resonant detectors for gravitati
- Page 106 and 107:
94 Resonant detectors for gravitati
- Page 108 and 109:
96 Resonant detectors for gravitati
- Page 110 and 111:
98 Resonant detectors for gravitati
- Page 112 and 113:
100 Resonant detectors for gravitat
- Page 114 and 115:
102 Resonant detectors for gravitat
- Page 116 and 117:
104 The Earth-based large interfero
- Page 118 and 119:
106 The Earth-based large interfero
- Page 120 and 121:
108 The Earth-based large interfero
- Page 122 and 123:
110 The Earth-based large interfero
- Page 124 and 125:
112 The Earth-based large interfero
- Page 126 and 127:
114 The Earth-based large interfero
- Page 128 and 129:
116 LISA: A proposed joint ESA-NASA
- Page 130 and 131:
118 LISA: A proposed joint ESA-NASA
- Page 132 and 133:
120 LISA: A proposed joint ESA-NASA
- Page 134 and 135:
122 LISA: A proposed joint ESA-NASA
- Page 136 and 137:
124 LISA: A proposed joint ESA-NASA
- Page 138 and 139:
126 LISA: A proposed joint ESA-NASA
- Page 140 and 141:
128 LISA: A proposed joint ESA-NASA
- Page 142 and 143:
130 LISA: A proposed joint ESA-NASA
- Page 144 and 145:
132 LISA: A proposed joint ESA-NASA
- Page 146 and 147:
134 LISA: A proposed joint ESA-NASA
- Page 148 and 149:
136 LISA: A proposed joint ESA-NASA
- Page 150 and 151:
138 LISA: A proposed joint ESA-NASA
- Page 152 and 153:
140 LISA: A proposed joint ESA-NASA
- Page 154 and 155:
142 LISA: A proposed joint ESA-NASA
- Page 156 and 157:
144 LISA: A proposed joint ESA-NASA
- Page 158 and 159:
146 LISA: A proposed joint ESA-NASA
- Page 160 and 161:
148 LISA: A proposed joint ESA-NASA
- Page 162 and 163:
150 LISA: A proposed joint ESA-NASA
- Page 164 and 165:
Chapter 11Detection of scalar gravi
- Page 166 and 167:
154 Detection of scalar gravitation
- Page 168 and 169:
156 Detection of scalar gravitation
- Page 170 and 171:
158 Detection of scalar gravitation
- Page 172 and 173:
160 Detection of scalar gravitation
- Page 174 and 175:
162 Detection of scalar gravitation
- Page 176 and 177:
164 Detection of scalar gravitation
- Page 178 and 179:
166 Detection of scalar gravitation
- Page 180 and 181:
168 Detection of scalar gravitation
- Page 182 and 183:
170 Detection of scalar gravitation
- Page 184 and 185:
172 Detection of scalar gravitation
- Page 186 and 187:
174 Detection of scalar gravitation
- Page 188 and 189:
176 Detection of scalar gravitation
- Page 190:
PART 3THE STOCHASTICGRAVITATIONAL-W
- Page 193 and 194:
182 Generalities on the stochastic
- Page 195 and 196:
184 Generalities on the stochastic
- Page 197 and 198:
186 Generalities on the stochastic
- Page 199 and 200:
188 Generalities on the stochastic
- Page 201 and 202:
190 Generalities on the stochastic
- Page 203 and 204:
192 Generalities on the stochastic
- Page 205 and 206:
194 Generalities on the stochastic
- Page 207 and 208:
196 Generalities on the stochastic
- Page 209 and 210:
198 Generalities on the stochastic
- Page 211 and 212:
200 Generalities on the stochastic
- Page 213 and 214:
202 Generalities on the stochastic
- Page 215 and 216:
204 Generalities on the stochastic
- Page 217 and 218:
206 Generalities on the stochastic
- Page 219 and 220:
208 Generalities on the stochastic
- Page 221 and 222:
210 Generalities on the stochastic
- Page 223 and 224:
212 Sources of SGWBV (Τ φ)High TL
- Page 225 and 226:
214 Sources of SGWB13.1.1 StringsTo
- Page 227 and 228:
216 Sources of SGWBThese two proces
- Page 229 and 230:
218 Sources of SGWB-5-6-7-8-9-10 0
- Page 231 and 232:
220 Sources of SGWBapart from a shi
- Page 233 and 234:
222 Sources of SGWBbang nucleosynth
- Page 235 and 236:
224 Sources of SGWBalso a stochasti
- Page 237 and 238:
226 Sources of SGWBR 2MDR(η) (arbi
- Page 239 and 240:
228 Sources of SGWB−6−9−12−
- Page 241 and 242:
230 Sources of SGWBwhich is a suita
- Page 243 and 244:
232 Sources of SGWBdominated phase
- Page 245 and 246:
234 Sources of SGWBgeneral feature
- Page 247 and 248:
236 Sources of SGWBa consequence of
- Page 249 and 250:
238 Sources of SGWBof interferomete
- Page 251 and 252:
240 Sources of SGWB[11] Thorne K S
- Page 253 and 254:
242 Sources of SGWB[67] Postnov K 1
- Page 256 and 257:
Chapter 14Infinite-dimensional symm
- Page 258 and 259:
The Riemann tensor (the curvature t
- Page 260 and 261:
Einstein theory 249Repeating the sa
- Page 262 and 263:
Einstein theory 251where δ ˜g µ
- Page 264 and 265:
Nonlinear σ -models 253Example: G
- Page 266 and 267:
Nonlinear σ -models 25514.2.2 The
- Page 268 and 269:
14.3 Symmetries of nonlinear σ -mo
- Page 270 and 271:
The Geroch group 259a nonlinear way
- Page 272 and 273:
The linear system 261Using the know
- Page 274 and 275:
The linear system 263and then the f
- Page 276 and 277:
The linear system 265where we consi
- Page 278 and 279:
Acknowledgments 267From (14.161) we
- Page 280 and 281:
Splitting formalism and test partic
- Page 282 and 283:
Splitting formalism and test partic
- Page 284 and 285:
The spacetime metric 273with h AB =
- Page 286 and 287:
Searching for an operational frame
- Page 288 and 289:
Precession of a gyroscope in geodes
- Page 290 and 291:
References 279References[1] Taylor
- Page 292 and 293:
Introduction 281the so-called pre-b
- Page 294 and 295:
Motivations: duality symmetry 283co
- Page 296 and 297:
Motivations: duality symmetry 285Ex
- Page 298 and 299:
Motivations: duality symmetry 287Th
- Page 300 and 301:
Kinematics: shrinking horizons 289s
- Page 302 and 303:
and the S-frame action (16.20) beco
- Page 304 and 305:
Kinematics: shrinking horizons 293s
- Page 306 and 307:
Open problems and phenomenological
- Page 308 and 309:
Cosmological perturbation theory 29
- Page 310 and 311:
Cosmological perturbation theory 29
- Page 312 and 313:
Cosmological perturbation theory 30
- Page 314 and 315:
Cosmological perturbation theory 30
- Page 316 and 317:
Cosmological perturbation theory 30
- Page 318 and 319:
Cosmological perturbation theory 30
- Page 320 and 321:
The relic graviton background 309Ta
- Page 322 and 323:
The relic graviton background 311Fi
- Page 324 and 325:
The relic graviton background 313Fi
- Page 326 and 327:
The relic graviton background 315th
- Page 328 and 329:
Appendix A. The string effective ac
- Page 330 and 331:
Appendix A. The string effective ac
- Page 332 and 333:
Appendix A. The string effective ac
- Page 334 and 335:
Appendix B. Duality symmetry 323we
- Page 336 and 337:
Appendix B. Duality symmetry 325By
- Page 338 and 339:
Appendix B. Duality symmetry 327By
- Page 340 and 341:
Appendix C. The string cosmology eq
- Page 342 and 343:
Appendix C. The string cosmology eq
- Page 344 and 345:
References 333Finally, equation (16
- Page 346 and 347:
References 335[26] Maggiore M and S
- Page 348 and 349:
References 337[78] Prodi G 1998 Tal
- Page 350 and 351:
Introduction 339breaks down at this
- Page 352 and 353:
Summary of optimal signal filtering
- Page 354 and 355:
Newtonian binary polarization wavef
- Page 356 and 357:
Newtonian binary polarization wavef
- Page 358 and 359:
Newtonian orbital phase evolution 3
- Page 360 and 361:
17.5 Post-Newtonian wave generation
- Page 362 and 363:
Post-Newtonian wave generation 351s
- Page 364 and 365:
to transform the coordinates accord
- Page 366 and 367:
Inspiral binary waveform 355H + (1)
- Page 368 and 369:
References 357[6] Cutler C et al 19
- Page 371 and 372:
Chapter 18Numerical relativityGener
- Page 373 and 374:
Einstein equations for relativity 3
- Page 375 and 376:
Einstein equations for relativity 3
- Page 377 and 378:
Einstein equations for relativity 3
- Page 379 and 380:
Still newer formulations: towards a
- Page 381 and 382:
ADM evolutionsStill newer formulati
- Page 383 and 384:
Still newer formulations: towards a
- Page 385 and 386:
Still newer formulations: towards a
- Page 387 and 388:
Still newer formulations: towards a
- Page 389 and 390:
Still newer formulations: towards a
- Page 391 and 392:
Still newer formulations: towards a
- Page 393 and 394:
Tools for analysing the numerical s
- Page 395 and 396:
Tools for analysing the numerical s
- Page 397 and 398:
Tools for analysing the numerical s
- Page 399 and 400:
Cactus computational toolkit 389cap
- Page 401 and 402:
Cactus computational toolkit 39118.
- Page 403 and 404:
Recent applications and progress 39
- Page 405 and 406:
Recent applications and progress 39
- Page 407 and 408:
Recent applications and progress 39
- Page 409 and 410:
Summary 399these techniques are use
- Page 411 and 412:
Further reading 401the above that s
- Page 413 and 414:
References 403Physics that can be e
- Page 415 and 416:
References 405[65] Gustafsson B, Kr
- Page 417 and 418:
References 407[138] Berger M and Ol
- Page 419 and 420:
Indexaction, 50Einstein-Hilbert, 24
- Page 421 and 422:
Index 411Kaluza-Klein, 7, 153, 247,