the instrument drift and uses every repeated reading at any station during the whole survey. Linear drift, non- linear drift, and the reading accuracy are taken into account. The results are given in Table 4 for LCR G 445 in 1992. The instrument was recalibrated shortly before the survey by the manufacturer. A comparison with the Sodin gravity meter, and in 1993 with anoth- er LaCoste-Romberg gravimeter D 187, showed no systematic scale differences. Note that the gravity dif- ferences and absolute values pertain to the locations and heights of measurement, not reduced to bench- mark heights because the true free air gravity gradient is unknown and the assumption of a standard value may lead to errors. For example, a local -10% devia- tion of the free air gradient could, in the worst case (Pt 1000), lead to a 30 - 40 uGal error. In one case a temporal gravity change has already been detected, between point No. 5273 (Djúpivogur Hotel, -50 km from the ice edge) and point No. 5219 (Homafjörður Airport, old, near Höfn, -20 km from the ice edge). In 1968, 24 years earlier, the gravity dif- ference (in the Icelandic base gravity network) was - 13.94 (±.024) mGal ('5219' - '5273') (Pálmason etal., 1973; Thorbergsson et al., 1993). In 1992 it was - 13.969 (+.010) mGal; i.e. a change of -29 (±26) uGal in the gravity difference is discemible. If Djúpivogur is assumed to be fixed, this is a gravity decrease near Höfn. It would, at face value, imply a land rise of about 0.17 (±0.14) m in 24 years or nearly 7 (±6) mm/year near Höfn, if interpreted as a change in the Bouguer anomaly with mantle mass inflow below the rising surface (£ = 3.3 g/cm3). If interpreted as a "Free Air effect", i.e., purely elastic plate expansion with no lateral mass movement, the implied land rise would be only 0.1 (±0.08) m or 5 (±4) mm/year. The two in- terpretations probably represent upper and lower bounds. OTHER MEASUREMENTS Other methods capable of detecting the expected changes in elevation include long-term sea-level mea- surements, VLBI (Very Long Baseline Interferome- try), and repeated levelling. A sea-level gauge was in- stalled at the Skinneyjarhöfði promontory in June 1994 (Fig. 1). A drill hole was drilled into the rock near the cliff's edge, with its bottom well below the low tide level. A small explosion was set off at the bottom of the hole to provide connection to the sea. The sea-level gauge consists of a pressure transducer at the bottom of the hole, 3 independent water level detectors for automatic calibration of the pressure transducer, and a digital data logger installed at the top of the hole. Pressure values are read every 5-10 minutes, and every time the water level passes a water level detector. The VLBI technology is based on simultaneous recording of radio signals from distant astronomical objects at a set of radio telescopes. The relative posi- tions of the observation points can be determined to within several millimeters. A VLBI experiment was carried out in the town of Höfn in the summer of 1992 Table 3. GPS lo- cations, geocen- tric coordinates (WGS84), and repeatability # Station n network solution and weighted rms around them (cm) X rx y ry Z rz m re ru 1 DJUP 3 265395952.38 0.23 -675676656.12 1.05 574102029.31 0.24 0.08 1.10 0.24 2 FLAT 11 267915860.36 2.33 -74264417.26 1.81 572113993.91 2.00 0.38 0.15 0.65 3 GILD 7 266889653.62 1.30 -73248203.31 0.39 572721422.07 2.01 0.80 0.27 2.36 4 HEIN 6 267027688.62 3.69 -74834583.68 2.52 572462019.39 1.33 0.53 0.10 1.67 5 HOFF 9 266257723.70 1.50 -73311888.96 1.44 573009899.70 3.77 1.83 1.40 2.95 6 HOFN 20 267971550.23 0.00 -72797065.40 0.00 572276434.63 0.00 0.00 0.00 0.00 7 HROL 2 268258664.64 0.24 -77305278.87 0.49 571556354.02 0.32 0.24 0.39 0.46 8 HVAL 5 267460130.43 0.76 -69378033.92 0.21 572935863.96 2.49 0.92 0.39 2.71 9 STAP 5 267317514.50 0.49 -72882277.35 0.21 572572524.31 0.73 0.21 0.24 0.83 10 UPPS 4 267861207.98 0.42 -75407892.39 0.37 571994582.67 1.17 0.58 0.28 1.49 3. tafla. Staðsetn- ing GPS-punkta í jarðmiðjuhnitum (WGS84), ásamt endurtekningar- nákvœmni. JOKULL, No. 44 35

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