| Title: |
Geophysical Survey at Land East of Stowmarket |
| Series: |
Magnitude Surveys Ltd unpublished report series
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| Downloads: |
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magnitud1-513503_211547.pdf (5 MB)
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| Biblio Note |
This report was uploaded to the OASIS system by the named Publisher. The report has been transferred into the ADS Library for public access and to facilitate future research.
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| Licence Type: |
ADS Terms of Use and Access
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| DOI |
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| Publication Type: |
Report (in Series)
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| Abstract: |
6. Methodology 6.1. Data Collection 6.1.1. Magnetometer surveys are generally the most cost effective and suitable geophysical technique for the detection of archaeology in England. Therefore, a magnetometer survey should be the preferred geophysical technique unless its use is precluded by any specific survey objectives or the site environment. For this site, no factors precluded the recommendation of a standard magnetometer survey. Geophysical survey therefore comprised the magnetic method as described in the following section. 6.1.2. Geophysical prospection comprised the magnetic method as described in the following table. 6.1.3. Table of survey strategies: Method Instrument Traverse Interval Sample Interval Magnetic Bartington Instruments Grad-13 Digital Three-Axis Gradiometer 1m 200Hz reprojected to 0.125m 6.1.4. The magnetic data were collected using MS’ bespoke hand-carried GNSS-positioned system]. 6.1.4.1. MS’ hand -carried system was comprised of Bartington Instruments Grad 13 Digital Three-Axis Gradiometers. Positional referencing was through a multi-channel, multi-constellation GNSS Smart Antenna RTK GPS outputting in NMEA mode to ensure high positional accuracy of collected measurements. The RTK GPS is accurate to 0.008m + 1ppm in the horizontal and 0.015m + 1ppm in the vertical. 6.1.4.2. Magnetic and GPS data were stored on an SD card within MS’ bespoke datalogger. The datalogger was continuously synced, via an in-field Wi-Fi unit, to servers within MS’ offices. This allowed for data collection, processing and visualisation to be monitored in real-time as fieldwork was ongoing. 6.1.4.3. A navigation system was integrated with the RTK GPS, which was used to guide the surveyor. Data were collected by traversing the survey area along the longest possible lines, ensuring efficient collection and processing. 6.2. Data Processing 6.2.1. Magnetic data were processed in bespoke in-house software produced by MS. Processing steps conform to the EAC and Historic England guidelines for ‘minimally enhanced data’ (see Section 3.8 in Schmidt et al., 2015: 33 and Section IV.2 in David et al., 2008: 11). Sensor Calibration – The sensors were calibrated using a bespoke in-house algorithm, which conforms to Olsen et al. (2003). Zero Median Traverse – The median of each sensor traverse is calculated within a specified range and subtracted from the collected data. This removes striping effects caused by small variations in sensor electronics. Projection to a Regular Grid – Data collected using RTK GPS positioning requires a uniform grid projection to visualise data. Data are rotated to best fit an orthogonal grid projection and are resampled onto the grid using an inverse distance-weighting algorithm. Interpolation to Square Pixels – Data are interpolated using a bicubic algorithm to increase the pixel density between sensor traverses. This produces images with square pixels for ease of visualisation. 6.3. Data Visualisation and Interpretation 6.3.1. This report presents the gradient of the sensors’ total field data as greyscale images (Figures 7, 10, 13, 16 & 19), as well as the total field data from the lower sensors (Figures 3 & 5). The gradient of the sensors minimises external interferences and reduces the blown-out responses from ferrous and other high contrast material. However, the contrast of weak or ephemeral anomalies can be reduced through the process of calculating the gradient. Consequently, some features can be clearer in the respective gradient or total field datasets. Multiple greyscale images of the gradient and total field at different plotting ranges have been used for data interpretation. Greyscale images should be viewed alongside the XY trace plot (Figures 9, 12, 15, 18 & 21). XY trace plots visualise the magnitude and form of the geophysical response, aiding anomaly interpretation. 6.3.2. |
| Author: |
David Taylor
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| Publisher: |
Magnitude Surveys Ltd
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| Other Person/Org: |
Suffolk HER (OASIS Reviewer)
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| Year of Publication: |
2023
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| Locations: |
| District: |
Mid Suffolk |
| Parish: |
Stonham Earl |
| County: |
Suffolk |
| Country: |
England |
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Grid Reference: 609219, 260635 (Easting, Northing)
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| Subjects / Periods: |
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| Identifiers: |
| OASIS Id: |
magnitud1-513503 |
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| Source: |
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| Relations: |
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| Created Date: |
19 Jan 2024 |
