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Wiki source code of Field Deployment Guides

Last modified by Jack Dent on 2025/10/30 11:52
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robert 1.1 1 (% class="row" %)
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robert 25.3 5 = Site selection and preparation =
robert 1.1 6
robert 25.2 7 (((
robert 32.1 8 * If possible, choose a location with minimal noise interference far away from traffic and people. Try to keep your station out of sight to avoid theft or tampering. The site should not be installed in a place where "the public" would ever stumble upon it (e.g. a walking trail or park area).
9 * Nearby trees, bushes, power poles etc can induce low frequency noise in your data when they sway in the wind. A rule of thumb is to have your sensor at least as far away from these as their height.
robert 31.5 10 * Cattle and stock can and will destroy your site and our instrumentation. NEVER **EVER** install a station where cows can get to it because they //will// get to it and they **WILL** destroy it.
robert 25.2 11 * If the area looks like a place that has flooded, or may flood again, absolutely assume that it will. This very much includes dry riverbeds or ponds. Always prefer locally elevated terranes.
12 * The harder the soil, the better the signal. Sand and mud are your enemy.
KB 34.1 13 * Grass can often grow high enough to block your solar panel from sun. If possible, clear an area in front of the panel to minimize power loss.
Sima Mousavi 3.1 14 )))
robert 1.1 15
robert 25.3 16 = Installing Sensors =
robert 1.1 17
robert 32.1 18 * Bury seismometers for noise reduction and stable ground coupling, typically 0.5-0.8 metre depth but deeper the better.
robert 25.2 19 * Ensure the sensor is leveled correctly, typically the sensor can be placed on a well leveled paver to make this easier.
robert 32.1 20 * Orient the sensor correctly using a compass, paying special attention to the north direction and **accounting for declination**.
Jack Dent 24.1 21 ** When using a compass to orient the sensors, ensure it is kept away from metal objects or structures that could interfere with its magnetic field.
robert 32.1 22 ** It is recommended to take a picture of the sensor's orientation next to the compass in case there are questions or issues later.
Jack Dent 24.1 23 * Hold the sensor or sensor covering securely while infilling and compacting the hole to ensure the setup is kept in the correct position (level and oriented).
robert 27.1 24 * Burial styles can vary depending on sensor type, soil, wetness/humidity and the duration of the experiment. See the **Sensor Protection** section below for more detail.
robert 1.1 25
robert 27.1 26 == Importance of locking sensor feet ==
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robert 31.2 28 The Trillium Compact 120s and 20s sensors have three adjustable feet for leveling. It is **critical** to "lock" these feet in place by spinning the locking disk upwards towards the sensor, as tight as possible. This reduces "wobble" which shows up in both low and high frequency signal. It is also a good idea to keep the length of the three feet as small as possible to maximize stability.
robert 27.1 29
robert 28.1 30 [[image:TC20_feetlocked_vs_unlocked.png||alt="Figured showing how unlocked feet can amplify fake noise and rattle" data-xwiki-image-style-alignment="center"]]
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robert 25.3 32 = Setting up Data Logger =
robert 1.1 33
Sima Mousavi 3.1 34 * Install data loggers or recorders compatible with the sensors.
Jack Dent 19.1 35 * Establish a reliable power source, such as solar panels, batteries, or local grid connection. Use a compass to align solar panels facing north in the southern hemisphere for optimal sunlight exposure.
Jack Dent 15.1 36 * Set up a GPS antenna to provide accurate time synchronization for the seismic data.
Sima Mousavi 6.1 37 * Ensure the GPS antenna has a clear view of the sky for optimal signal reception.
Sima Mousavi 4.1 38 * Calibrate sensors and data acquisition systems for accuracy.
39 * Test for sensitivity, noise levels, and overall performance.
santi 31.1 40 * More information for logger setup can be found on the [[ANU Seismic Data Loggers>>doc:Instrumentation.ANU LPR-200.WebHome]] page.
robert 1.1 41
robert 25.3 42 = Setting up Fencing =
robert 1.1 43
robert 25.3 44 * You'll have to know a priori where north is as that is where you want to point the solar panel towards //(in the Southern Hemisphere, anyway)//
45 * Pound in the star picket fence post well away from the sensor hole, and slightly north of it. You will want to then put the fence through the star picket so that it is on the NORTH side. This lets techs "flip up" the fence from behind for easy access.
46 * Use wire to secure the fence to the post and also the solar panel to the fence.
santi 30.1 47 * Place the solar panel as high on the fence as possible to reduce any interference from grass and weeds. When securing the solar panel to the fence with wire, make the wire as tight as possible to reduce "rattle" in the wind. Test yourself. It's usually a great idea to use a pair of pliers to make the final twist in the wire so that it is **really tight**.
Sima Mousavi 4.1 48
KB 33.1 49 = Fire Protection & Security =
robert 25.3 50
KB 34.1 51 * In fire-prone areas, clear a perimeter around the installation to reduce fuel sources. Assume the area will catch on fire~-~- will your site survive?
KB 33.1 52 * Consider using fireproof covers for the logger. This will have the added benefit of reducing soil contact, especially dirt getting into SD card slots. A permeable cover will avoid trapping rainwater ~-~- a problem associated with plastic tarps, which damages the logger and attracts insects/animals (ants, centipedes, snakes, etc.). We are still testing materials for suitability in the field (e.g., safe and tolerable degradation in the environment).
53 * We recommend adding a soil layer for insulation. This seems to keep loggers cooler, reduce fire damage, and discourage interference by people passing by.
robert 25.3 54
55 = Metadata & Site Logs =
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KB 34.1 57 * Documenting site installs and service information is a mandatory requirement of your ANSIR agreement. You are expected to keep proper site logs... trust us, it's for your own good. Failure to do so may result in ban for future loans.
santi 31.1 58 * Document the installation process, including sensor types, **serial numbers**, orientations, high quality latitude/longitude coordinates, elevation, and system configurations, along with fire safety measures implemented.
KB 34.1 59 * Draw a map, or at least take a google/open maps screenshot with some drawn annotations so others can find the site.
Sima Mousavi 4.1 60 * Record essential metadata for seismic data interpretation.
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robert 25.3 62 = Sensor protection =
Jack Dent 16.1 63
Jack Dent 16.2 64 Sensors can be covered with a PVC pipe to help prevent degradation of the components (i.e. sensor casing and cable connections), however, some sensors are made for direct burial (no protection). When installing a sensor, only use these two options. Do not try to protect the sensor via any other means such as a plastic bag or moisture absorbers & desiccants.
Jack Dent 16.1 65
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robert 31.3 68 DO NOT: bury the sensors with anything other than a PVC housing or direct burial. Other methods (especially using a plastic bag!!) may damage the equipment more than protect it.
Jack Dent 16.1 69 )))
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robert 26.1 71 = Step-by-step field installation guide (with images) =
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Jack Dent 9.1 73
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76 [[image:1715740852278-219.jpg||height="185" width="185"]]
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Jack Dent 14.1 78 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)1. Dig a hole roughly 80cm deep and wide enough to place a paver in.
Jack Dent 9.1 79 )))|(% style="width:191px" %)[[image:1715740856792-247.jpg||height="181" width="181"]](((
Jack Dent 10.1 80 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)2. Level the bottom of the hole. A paver or brick can be used to create a flat base for the device. Draw a line on the paver, orient it towards North and level it.
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82 [[image:1715740874992-904.jpg||height="179" width="179"]]
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Jack Dent 10.1 84 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)3. Place the seismometer on the paver and ensure it is levelled and oriented (remember to account for the declination in your area).
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Jack Dent 15.1 87 [[image:1715740934594-394.jpg||height="203" width="203"]]
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Jack Dent 10.1 89 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)4. Depending on the model of the seismometer, place a protective PVC tub over it.
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Jack Dent 25.1 91 [[image:1715741200573-382.jpg||height="203" width="102"]][[image:1715741200573-909.jpg||height="203" width="102"]]
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robert 10.2 93 (% style="color:#000000; font-family:Arial,sans-serif; font-size:14.6667px; white-space-collapse:preserve" %)5. Fill in the hole whilst stabilising the sensor and packing the dirt firmly.
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95 [[image:1715741278653-711.jpg||height="189" width="189"]]
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Jack Dent 10.1 97 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)6. Once the hole is filled and levelled, drive a stake (star pickets work well) into the ground next to the seismometer, and fit the wire panels over it, driving pegs into the north-facing side.
Jack Dent 9.1 98 )))
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Jack Dent 15.1 100 [[image:1715742260851-696.jpg||height="220" width="220"]]
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Jack Dent 10.1 102 (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)7. Attach the solar panel to this side, and the GPS to the stake (wrap the wire around the stake once or twice so it stays in position if it is detached).
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Jack Dent 15.1 104 [[image:1715741876857-916.jpg||height="218" width="218"]]
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Jack Dent 15.1 106 8. (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)Connect the seismometer, solar panel, and GPS to the logger and turn the logger on. See "setting up data logger" and "ANU seismic data loggers" page for more details. Set the logger to record and ensure it starts recording.
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Jack Dent 15.1 108 [[image:IMG_0667.jpg||height="218" width="218"]]
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Jack Dent 10.1 110 9. (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)Cover the logger with a fire blanket, starting by placing it on the top, so the opening is underneath the logger.
Jack Dent 9.1 111 )))
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113 [[image:1715742037353-873.jpg||height="189" width="189"]]
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Jack Dent 10.1 115 10. (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)Once all the sides of the blanket are tucked under the logger, cover the logger with rocks or dirt.
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Jack Dent 15.1 117 [[image:1715742099260-834.jpg||height="187" width="187"]]
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Jack Dent 12.1 119 11. (% style="color:#000000; font-family:Arial,sans-serif; font-size:11pt; font-style:normal; font-variant:normal; font-weight:400; text-decoration:none; white-space:pre-wrap" %)Fold the other metal grating panel over and peg it into the ground. If the ground is too hard, a wire can be used to fix the metal grates to each other. This will also help reduce noise from the rattle of the cage prevent animals from getting to the logger.
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121 [[image:1715742149920-412.jpg||height="186" width="186"]]
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Jack Dent 10.1 123 12. A completed site. Rocks and sticks can also be piled on the ends of the cage if there is a risk of animals tampering in the area.
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Jack Dent 24.1 126
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128 = Experimental Sand Burial: =
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robert 31.4 130 Direct burials are used for Trillium Compact Postholes as they are specifically designed to be corrosion resistant. Other sensors such as the Trillium Compact 120, Trillium Compact 20, and 3D Lites are not built with this degree of corrosion resistance. Currently, the best prevention for moisture trapping and corrosion is burying them with a PVC covering. However, in particularly wet environments, some moisture can still collect within these coverings. One experimental method that is being trialled in hopes of providing better drainage is the sand burial. Steps 1, 2, and 3 remain the same, though once the sensor is set with the correct leveling and orientation, the subsequent infill steps differ. Once the open PVC tube is placed around the sensor, infill the hole around the tubing, holding it in place (image A). Once the hole is back-filled level with the tubing, securing it in place, begin filling the interior of the PVC tube with sand. Hold the sensor in place and ensure the sand is packed tightly around it (image B). Once the sand fills the PVC tube, gently remove the PVC tube while holding the sensor in place (pliers may be required to grip the tube). The last deviation for a sand burial from the standard burial is continuing to place some sand above the sensor, and dirt (or other local substrate around that sand pocket) until level with the surface (image C).
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134 |(% style="width:263px" %)A) [[image:original_c8aaadae-30a0-45b3-9069-bfe03459e06f_IMG_20250525_123128828.jpg||height="208" width="222"]]|(% style="width:268px" %)B) [[image:original_3168dca2-ab8b-4062-9847-b0ee1d0fcf80_IMG_20250525_123247255.jpg||height="208" width="223"]]|(% style="width:273px" %)C) [[image:IMG_20250525_123327086.jpg||height="205" width="211"]]
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Jack Dent 35.1 136
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138 Comparison of installation methods on Black Mountain (Canberra):
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140 The seismic equipment was left in the field for approximately 6 months (April – October) through winter. There was much rain throughout the experiment period, with the last rain occurring one day prior to excavation, and heavy rain occurring the week before. Note that more temperature fluctuations may occur throughout summer, and thus more chances for condensation and corrosion to occur, therefore this experiment should be conducted again over a summer period.
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142 Upon excavating all setups, there appeared to be little difference in the moisture levels.
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144 The first method (PVC) had collected a small amount of moisture. The seismometer was a little bit wet, while the interior of the PVC housing had condensation lining the walls. The paver beneath was also quite damp, however, no water had pooled at the bottom of the seismometer.
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146 The other two setups (both using the sand method) were also quite moist. Upon excavation, the coarse river sand was damp (though not soaked). There had been no infiltration of mud from the surrounding area into the coarse river sand, suggesting that all the moisture had come straight down the column of sand, and not flowed in from the sides. Underneath the feet of the seismometer (SN3660) from the full setup, much condensation had been collected. There were no feet on the seismometer of the second sand setup and thus no space for condensation underneath. The tops of both seismometers were covered in damp sand, though there appeared slightly less moisture than the top of the sensor in the PVC housing. An accurate assessment of moisture content was difficult as one seismometer was covered in sand, and the other showed a clear view of how much surface condensation there was. 
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148 Additionally, when unwrapping the cloth adhesive from the PVC burial, there appeared to be a glob of hydrated glue from the adhesive. This was not present on the connections of the two sand burial seismometers, despite using the same cloth adhesive. This may suggest that moisture lingers for a longer period in the PVC housing (as suspected), having time to be absorbed into the adhesive more. 
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150 Upon inspection of the connectors of each seismometer, there was little condensation within each, and no sand had appeared to infiltrate the connections in the sand buried equipment.
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153 [[PVC burial>>image:20251027_111019.jpg||height="216" width="200"]]
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155 [[PVC burial>>image:PVC glue.jpg||height="219" width="268"]]
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157 [[Sand burial>>image:20251027_112642.jpg||height="218" width="192"]]
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159 [[Sand burial>>image:20251027_112721.jpg||height="221" width="218"]]
Sima Mousavi 6.3 160 )))
robert 1.1 161
Jack Dent 35.1 162 Key findings:
Sima Mousavi 6.2 163
Jack Dent 35.1 164 The PVC burial method resulted in a small amount of moisture collecting on the top of the seismometer and within the PVC casing, and the development of a hydrated glob around the connector. 
Jack Dent 24.1 165
Jack Dent 35.1 166 The sand burial method resulted in slightly less moisture collecting around the top of the seismometer (subject to error of perception), though no glob of hydrated adhesive, suggesting quicker drainage did occur. The sand burial did however allow for more moisture to collect on the underside of the seismometer compared to the PVC burial, though as the connector is atop the seismometer, this result may be irrelevant.
Jack Dent 25.1 167
Jack Dent 35.1 168 It should be noted that there was no mud present in the column of sand, suggesting little to no lateral seepage of moisture.
robert 25.2 169
Jack Dent 35.1 170 Lastly, all connectors contained a small amount of condensation, were free of sand or dirt (thanks to the cloth tape), and no corrosion was noticeable.
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santi 30.1 175
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robert 1.1 186 (% class="col-xs-12 col-sm-4" %)
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188 {{box title="**Contents**"}}
189 {{toc/}}
190 {{/box}}
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robert 1.4 192 [[image:station_example.png||alt="example long term station setup" data-xwiki-image-style-alignment="center"]]//Figure 1: Typical station setup (LPR-200 & 10w solar panel)//
robert 1.1 193
robert 1.4 194 [[image:20230925_122808.jpg||alt="working on a site" data-xwiki-image-style-alignment="center" height="467" width="350"]]
195 //Figure 2: Flipping up the back of the fence onto the support picket to work comfortably//
Sima Mousavi 4.1 196
Sima Mousavi 7.2 197
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