Advances in Space Research

Preface
pp. 1189-1189(1)
Authors: Everitt F.; Reinhard R.

Fundamental physics in space in ESA and COSPAR
pp. 1191-1196(6)
Authors: Southwood D.J.; Reinhard R.

Fundamental physics from space and in space
pp. 1197-1202(6)
Author: Jacob M.

Where do we stand in testing general relativity?
pp. 1203-1208(6)
Author: Schafer G.

General relativity experiments in space
pp. 1209-1219(11)
Author: Keiser G.M.

Drag-free control for fundamental physics missions
pp. 1221-1226(6)
Author: DeBra D.B.

Ultralow-temperature resonant gravitational wave detectors, present state and future prospects
pp. 1227-1232(6)
Author: Frossati G.

LISA - An ESA cornerstone mission for the detection and observation of gravitational waves
pp. 1233-1242(10)
Authors: Danzmann K.; LISA Science Team

Gravitational wave sources containing massive black holes
pp. 1243-1246(4)
Authors: Bender P.L.; Hils D.

LISA - The interferometer
pp. 1247-1250(4)
Authors: Hough J.; Robertson D.; Ward H.; McNamara P.; LISA Science Team

The LISA accelerometer
pp. 1251-1254(4)
Authors: Rodrigues M.; Touboul P.

Laser light sources for space-based gravitational wave detectors
pp. 1255-1258(4)
Authors: Freitag I.; Rottengatter P.; Tunnermann A.; Welling H.

LISA data reduction
pp. 1259-1262(4)
Authors: Stebbins R.T.; Bender P.L.; Folkner W.M.

Position determination of gravitational wave sources with LISA
pp. 1263-1266(4)
Authors: Peterseim M.; Jennrich O.; Schutz B.F.; Danzmann K.

Measuring a binary's orientation with LISA
pp. 1267-1270(4)
Authors: Jennrich O.; Peterseim M.; Danzmann K.; Schutz B.F.

Spurious forces on the LISA proof masses due to electrostatic charging
pp. 1271-1275(5)
Author: Jafry Y.R.

Mission analysis for the Laser Interferometer Space Antenna (LISA) mission
pp. 1277-1282(6)
Authors: Hechler F.; Folkner W.M.

Progress in laboratory research for fundamental physics space missions using optical devices
pp. 1283-1287(5)
Authors: Ni W.-T.; Shy J.-T.; Tseng S.-M.; Yeh H.-C.

Theoretical motivations for Equivalence Principle tests
pp. 1289-1296(8)
Author: Fayet P.

Historical perspective on testing the Equivalence Principle
pp. 1297-1300(4)
Authors: Everitt C.W.F.; Damour T.; Nordtvedt K.; Reinhard R.

Drop tower tests of the Weak Principle of Equivalence - One step to space missions for gravitational physics
pp. 1301-1305(5)
Authors: Dittus H.; Vodel W.; Greger R.; Lochmann S.; Mehls C.; Koch H.; Nietzsche S.; Zameck-Glyscinski J.v.

Testing the Weak Equivalence Principle with a free-fall experiment from a balloon
pp. 1307-1310(4)
Authors: Lorenzini E.C.; Iafolla V.; Nozzoli S.; Orlando P.; Cosmo M.L.; Grossi M.D.

Testing the Equivalence Principle with laser ranging to the Moon
pp. 1311-1320(10)
Author: Nordtvedt K.

ESA's STEP assessment and phase a studies for M2 and M3
pp. 1321-1324(4)
Author: Reinhard R.

Principle of the STEP accelerometer design
pp. 1325-1333(9)
Authors: Paik H.J.; Blaser J.-P.; Vitale S.

Selection of test mass materials for Equivalence Principle experiments
pp. 1335-1338(4)
Authors: Blaser J.P.; Damour T.

Test mass design for the EP experiment on M3 STEP
pp. 1339-1344(6)
Authors: Lockerbie N.A.; Veryaskin A.V.; Xu X.

Force and force gradients due to trapped-flux in superconducting accelerometers
pp. 1345-1350(6)
Authors: Speake C.C.; Trenkel C.; Colclough M.S.

Electrostatic charging of test masses in Equivalence Principle experiments in low-Earth, near-polar orbits
pp. 1351-1356(6)
Authors: Jafry Y.R.; Reinhard R.

Electrostatic accelerometers for the Equivalence Principle test in space
pp. 1357-1360(4)
Authors: Touboul P.; Bernard A.

Liquid helium motion and confinement for a cryogenic gravimetric mission
pp. 1361-1366(6)
Authors: Vitale S.; Taffarello L.

GEOSTEP: A gravitation experiment in Earth-orbiting satellite to test the Equivalence Principle
pp. 1367-1372(6)
Author: Bonneville R.

The NASA/ESA MiniSTEP project
pp. 1373-1377(5)
Authors: Swanson P.N.; Everitt C.W.F.; Lee M.C.

The NASA-ESA MiniSTEP payload
pp. 1379-1382(4)
Authors: Worden P.W.; Torii R.; Everitt C.W.F.

The MiniSTEP drag-free control system
pp. 1383-1386(4)
Author: Jafry Y.R.

Development of the Gravity Probe B flight mission
pp. 1387-1396(10)
Authors: Turneaure J.P.; Everitt C.W.F.; Parkinson B.W.; Bardas D.; Buchman S.; DeBra D.B.; Dougherty H.; Gill D.; Grammer J.; Green G.B.; Gutt G.M.; Gwo D.-H.; Heifetz M.; Kasdin N.J.; Keiser G.M.; Lipa J.A.; Lockhart J.M.; Mester J.C.; Muhlfelder B.; Parmley R.; Silbergleit A.S.; Sullivan M.T.; Taber M.A.; Van Patten R.A.; Vassar R.; Wang S.; Xiao Y.M.; Zhou P.

The Gravity Probe B gyroscope readout system
pp. 1397-1400(4)
Authors: Muhlfelder B.; Lockhart J.M.; Gutt G.M.

The Gravity Probe-B star-tracking telescope
pp. 1401-1405(5)
Authors: Gwo D.-H.; Wang S.; Bower K.A.; Davidson D.E.; Ehrensberger P.; Huff L.; Romero E.; Sullivan M.T.; Triebes K.; Lipa J.A.

Performance of the relativity mission superfluid helium flight dewar
pp. 1407-1416(10)
Authors: Parmley R.T.; Bell G.A.; Frank D.J.; Murray D.O.; Whelan R.A.

Gravity Probe B payload verification and test program
pp. 1417-1420(4)
Authors: Taber M.A.; Bardas D.; Buchman S.; DeBra D.B.; Everitt C.W.F.; Gutt G.M.; Keiser G.M.; Lockhart J.M.; Mester J.C.; Muhlfelder B.; Murray D.O.; Parkinson B.W.; Van Patten R.A.; Turneaure J.P.; Xiao Y.M.

The cronos hydrogen maser clock redshift experiment on Radioastron
pp. 1421-1428(8)
Authors: Busca G.; Bernier L.G.; Schweda H.; Kardashev N.; Andreianov V.; Roxburgh I.W.; Polnarev S.

Covariance study of radar ranging data for measuring the Sun's gravitational to inertial mass ratio
pp. 1429-1432(4)
Author: Nordtvedt K.

EOTVOS, an inertial instrument for testing the Equivalence Principle
pp. 1433-1436(4)
Authors: Blaser J.P.; Lockerbie N.A.; Paik H.J.; Speake C.C.; Vitale S.

Astrodynamical Space Test of Relativity using Optical Devices
pp. 1437-1441(5)
Authors: Ni W.-T.; Sandford M.C.W.; Veillet C.; Wu A.-M.; Fridelance P.; Samain E.; Spalding G.; Xu X.

Gravitational modelling of the proof mass for ASTROD mission
pp. 1443-1446(4)
Authors: Xu X.; Ni W.-T.

Author index
pp. 1447-1448(2)