Ice-thickness measurements on Sólheimajöhull and receiver. At least 10 minutes of pseudorange data were collected at each point, and positions were computed using Magellan post processing software (Magellan, 1991). Accuracy for the positions is ±2 to 5 m RMS for X, Y and ±6 to 15 m for Z co-ordinates depending on satellite geometry and duration of data logging at each location. Computed positions often varied by over 100 m from uncorrected fixes, justify- ing the use of differential GPS. Altitude checks were made against the GPS results using a digital aneroid barometer. 0 * 5.G0mV > l.OOusEBt 5.00mV > l.OOns Figure 2. Downloaded oscilloscope screen for a typical basal return signal (Point 2). The cursors are located at the air and return pulses, and the two way travel time is 3.16 microseconds. - Skjámynd af sveiflusjá. Hver rúða jafngildir einni míkrósekúndu. Lóðrétt lína liggur við endurkastið frá botni jökuls- ins sem kemur 3,16 míkrósekúndum eftir að merkið er sent afstað. Ice depth was determined using a portable mono- pulse ice radar constructed following the principles of Watts and England (1975). Antennae systems for both transmitter and receiver were resistively dam- pened dipoles, and were adjusted to change frequency depending on ice thickness (2.5 MHz for most rea- dings and 5 MHz for ice thinner than ~150 m). The antennae were oriented either parallel or perpendicul- ar to the direction of flow depending on surface geometry, degree of crevassing and signal strength. The transmitter and receiver were separated by 50 m for each sounding. The basal return signals were in- terpreted in the field on a Fluke Scopemeter 96, but were also downloaded onto a PC so that spurious traces could be re-examined (Figure 2). The accuracy depends largely on the time resolution of the digital storage oscilloscope, where the corresponding points on the transmitted pulse and the ice/bedrock echo can usually be determined to the nearest time-step. In practice these limitations resulted in an accuracy for the thickness determinations of ~5%, and usually less than ± 10 m. Ice thickness was calculated from the two-way travel time allowing for the spacing between transmitter and receiver, and time for the air pulse to reach the receiver (Bogorodskii et al., 1985). RESULTS The long profile of the bed is notable for its lack of large undulations (Figure 3). The most complex topography occurs near the snout, where there is evi- dence of a sub-glacial hill and an overdeepening. The glacier bed remains close to sea level for 3.5 km in- land from the snout, and would become a fjord if ice free under higher sea levels (for example, during the early Holocene). The greatest ice thickness of 433 m was located at points 22 and 23, where the relief of the valley sides is highest (Table 1). The ice is thinner at the top of the survey line at the southern rim of the Katla caldera. The results of two cross sections are shown in Figure 3. Cross section 1 was taken at point 23, 4.5 km from the snout where the glacier reached its maximum thickness (Figure 1). The trough approx- imates a parabolic profile with steep sides and a gently undulating floor. Cross section 2 was taken at point 34,1.25 km from the snout (Figure 1). Here the trough was found to be asymmetrical, associated with diver- gence of the snout around Jökulhaus, with the deepest point occurring below the main (NW) ice stream. The surface of Sólheimajökull has a gentle long profile with few undulations. An exception occurs JÖKULL No. 48 11

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