Last modified by robert on 2026/06/29 16:42

From version 112.1
edited by robert
on 2026/06/17 16:54
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To version 96.1
edited by KB
on 2026/01/19 13:43
Change comment: There is no comment for this version

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1 -XWiki.robert
1 +XWiki.KB
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6 6  
7 7  ANSIR supply two types of three-channel nodes, and one type of one-channel node:
8 8  
9 -* **SmartSolo IGU-16HR 3C (5 Hz, 'very' short period)**
9 +* **SmartSolo IGU 16HR 3C (5 Hz, 'very' short period)**
10 10  * **SmartSolo BD3C-5 (5 second, short period)**
11 -* **SmartSolo IGU-16 1C (5 Hz, 'very' short period, single channel. Not 'HR')**
11 +* **SmartSolo IGU 16 1C (5 Hz, 'very' short period, single channel)**
12 12  
13 -Visit the [[SmartSolo page>>https://smartsolo.com/igu.html]] for more detail.
14 -
15 15  The three-channel nodes have a theoretical battery capacity of ~~30 days, whereas the single-channel type has a capacity of ~~50 days. The programming, operation and downloading procedures for all types of SmartSolo nodes are also similar.
16 16  
17 17  (% class="box infomessage" %)
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25 25  
26 26  The nodes must be programmed in the SoloLite software prior to use. The screenshots below show our recommended parameters for the 5 Hz (16HR-3C) and 5 second (BDC3-5) nodes.
27 27  
28 -[[IGU16HR-3C programming screen set at 250 Hz. Ensure circled areas are set!>>image:5Hz_node_programming.labels.png||alt="IGU-16 3C programming screen"]]
26 +[[IGU-16 3C programming screen set at 250 Hz. Ensure that the circled areas are set!>>image:5Hz_node_programming.labels.png||alt="IGU-16 3C programming screen"]][[image:5S_node_programming.labels.png||alt="BD3C-5 programming screen"]][[image:5S_node_programming.labels.png]]
29 29  
30 -[[BD3C-5 programming screen set at 250 Hz. Ensure circled areas are set!>>image:5S_node_programming.labels.png||alt="BD3C-5 programming screen set at 250 hz. Ensure that the circled areas are set!"]]
28 +BD3C-5 programming screen set at 250 hz. Ensure that the circled areas are set!
31 31  
32 -
33 33  FIFO (first in, first out) data mode is safest as this will overwrite old data in case you forgot to clear the storage. At <= 250 hz you can fit 4++ months of data on these, shouldn't be an issue.
34 34  
35 35  Note that the samplerate is instead given in sample spacing, in milliseconds. 4 ms = 250 Hz, 1 ms = 1000 Hz, 10 ms = 100 Hz, ad nauseam.
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71 71  
72 72  We have experienced interference from animals (foxes, dogs, goats) digging up and carrying nodes off for tens or hundreds of metres. It is helpful to minimise human and food smells (particularly on the rope handles) when working in areas where this is a risk. Or, wipe down affected nodes with 50-80% methylated spirits if extensive handling can not be avoided.
73 73  
74 -If you come to collect your node and it is missing~-~- LOOK FOR IT! It may not have gotten far. We have found dozens of nodes by spending 15 minutes looking for them.
75 -
76 -= External Power =
77 -
78 -Both the 5Hz IGU-16HR and 5s BD3C-5 can be optionally powered via external battery via either a replacement bottom half (the 5Hz nodes) or a battery cable accessory (BD3C-5) using standard lead acid batteries from 9-36v. We have done preliminary testing at 250 Hz with a 12v battery:
79 -
80 -- BD3C-5: ~~2 days of recording per 1 Ah
81 -
82 -- IGU16-HR 3C:  ~~3.5 days of recording per 1 Ah
83 -
84 -- IGU16-HR 1C: ~~7 days of recording per 1 Ah
85 -
86 86  = **Installation** =
87 87  
88 88  (% class="box infomessage" %)
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109 109  
110 110  **Site Analysis**:
111 111  
112 -* **Take compass measurements away from the sensor as it will affect your measurement. Use a stick or shovel to help align.**
113 -* Take photographs from various angles to document the site setup thoroughly. Have a colleague stand next to it pointing at it.
114 -* Include a detailed site description in your notes.
97 +* **Take compass measurements away from the sensor as it will affect your measurement.**
98 +* Take photographs from various angles to document the site setup thoroughly.
99 +* Include a detailed site description in your notes
115 115  
116 116  == 3. GPS Considerations ==
117 117  
118 118  (% class="wikigeneratedid" %)
119 -The GPS antenna is at the top and center of the unit, and will (usually) only receive signal with a clear sky view directly above. The signal is able to penetrate plastic and terracotta planters and a thin (2 cm?) layer of soil, but may struggle if the soil layer is too thick. **These nodes will not start recording without attaining a GPS lock** and repeated attempts will excessively drain the battery.
104 +The GPS antenna is at the top and center of the unit, and will (usually) only receive signal with a clear sky view directly above. The signal is able to penetrate plastic and terracotta planters and a thin layer of soil, but may struggle if the soil layer is too thick. **These nodes will not start recording without attaining a GPS lock** and repeated attempts will excessively drain the battery.
120 120  
121 121  == 4. Visibility and Location Marking ==
122 122  
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124 124  
125 125  **GPS Marking**:
126 126  
127 -* Use a GPS device to mark the instrument's exact location. Most modern cell phones can get to about a 3m error with their internal GPS also; you can probably also get away with investing a few dollars in a good app that shows error and lets you log markers.
128 -* Also write the GPS down on paper (ie your [[LOG SHEET>>http://auspass.edu.au/field/NODES_blank_fieldlog.pdf]]).
112 +* Use a GPS device to mark the instrument's exact location.
113 +* Record this location in both your paper notes and the GPS device.
129 129  
130 130  == (% style="color:inherit; font-family:inherit; font-size:max(18px, min(20px, 14.4444px + 0.462963vw))" %)5. Charge Time, Pre-Deployment & Post-Deployment(%%) ==
131 131  
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322 322  
323 323  * Once a new project is created, the Data Transfer View panel will display connected nodes with details like series number and data size.
324 324  * If “Prospect not matched” appears, it simply means the new project doesn’t match the original programming project. This is not a concern.
325 -* Select all nodes and right-click to “force download”. This starts the download process.[[image:Smartsolo harvesting #4 copy.png]]
310 +* Select all nodes and right-click to “force download”. This starts the download process.
326 326  * Completed downloads will appear as new folders in the Downloaded Data panel.
327 327  )))
328 328  1. (((
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329 329  **Exporting Data in Readable Format**:
330 330  
331 331  * Go to the “Tool” menu and select “export seismic data”.
332 -* Tailor other parameters to project preference and ensure "Sample Interval" matches the setting used during node reset (note: the standard used by ANU is 4ms, or 250hz)
317 +* Tailor other parameters to personal preference and ensure "Sample Interval" matches the setting used during node reset.
318 +* Click “prepare” followed by “run” to start reformatting. Monitor this process in the small panel at the bottom left.
333 333  * (% class="box warningmessage" %)
334 334  (((
335 -**Ensure export data is set to "COUNTS" (int32), not "mV" (float). This is critical!**
321 +* **Ensure to export data as "COUNTS" (int32), not "mV" (float). This is critical!**
322 +
323 +* **Set "Remove Gain" to the same decibel gain as during programming. By default ANU sets this to 24db for short period nodes (a scaling factor of 15.848932), and 6db (a factor of 2.0) for broadband nodes.**
336 336  )))
337 -* Set "Remove Gain" to the same decibel gain as during programming. By default ANU sets this to 24db for short period nodes (a scaling factor of 15.848932), and 6db (a factor of 2.0) for broadband nodes.
338 -* Set "Remove DC" to "Yes" to centre the data around the zero value
339 -* Set the correct Start Time (UTC) and End Time (UTC) of the project to prevent the unnecessary export of older data
340 -* [[image:Smartsolo harvesting #9 copy.png]]
341 -* Click “prepare” followed by “run” to start reformatting. Monitor this process in the small panel at the bottom left.
342 -* The data will be exported to the SOLODATA folder. For a windows system, the following file explorer page is where you must navigate to to locate your project folder[[image:Smartsolo harvesting #8 copy.png]]
343 343  )))
344 344  
345 345  == Smart Solo IGU-16HR Polarity Notice ==
346 346  
347 -See [[5Hz Node Polarity Issues>>https://auspass.edu.au/xwiki/bin/view/Data/AusPass%20Data/#HSmartSoloNodePolarityIssues]] for discussion. If data is headed to AusPass, we prefer to invert the IGU-16HR channel data manually rather than in the SoloLite software or inverting the response metadata.
329 +See [[https:~~/~~/auspass.edu.au/xwiki/bin/view/Data/AusPass%20Data/#HSmartSoloNodeZPolaritybug>>https://auspass.edu.au/xwiki/bin/view/Data/AusPass%20Data/#HSmartSoloNodeZPolaritybug]] for discussion. If data is headed to AusPass, we prefer to invert the IGU-16HR channel data manually rather than in the SoloLite software or inverting the response metadata.
348 348  
349 -**The BD3C-5 data does not require any sort of polarity inversion.**
331 +**The BD3C-5 data does not require a polarity inversion.**
350 350  
351 351  == 18 Leap Second bug ==
352 352  
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406 406  **Finalizing the Download**:
407 407  
408 408  * After downloading, mark the //"D"// box on your temporary labels to indicate completion.
391 +
392 +
409 409  )))
410 410  
395 +[[image:1706153266647-145.png||data-xwiki-image-style-alignment="center" height="340" width="603"]]
411 411  
412 412  
413 413  
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428 428  
429 429  ----
430 430  
431 -= Instrument Response =
432 -
433 -We are aware that there are various different published responses for these instruments and trust very few of them. One has to be careful with how polarity is handled between groups as well, and if one is working in integer counts (the ANSIR default) or mV (unclear why anyone would use this as it makes file sizes enormous). The response information published below is in **counts** and seems to fit well in huddle tests. Note that the response is the same for all channels and all units (e.g. there are no bespoke calibrations!), all appear to be sample rate insensitive, and the IGU data has been inverted (multiplied by -1) as described here: [[5Hz Node Polarity Issues>>https://auspass.edu.au/xwiki/bin/view/Data/AusPass%20Data/#HSmartSoloNodePolarityIssues]]
434 -
435 -== IGU 16HR-3C ==
436 -
437 - '16HR3C': {'poles':[(-22.211059+22.217768j), (-22.211059-22.217768j)],
438 - 'zeros':[0j, 0j],
439 - 'gain':1,
440 - 'sensitivity': 257019225.55108312}
441 -
442 -[[X axis is samples (.01 s), Y axis is velocity (m/s), 0.5-5 Hz filter>>image:IGU16_Z_huddle.png]]
443 -
444 -[[X axis is samples (.01 s), Y axis is velocity (m/s), 0.5-5 Hz bandpass filter>>image:IGU16_N_huddle.png]]
445 -
446 -== IGU 16-1C ==
447 -
448 -The 1C nodes seem to have the same response as the 3-channel IGU-16HR-3C (above), however the response posted at IRIS-NRL seems to imply that there is no poles and zeros information (e.g. a flat/linear response). This is 100% not so.
449 -
450 -[[IGU-16 1C, X axis is samples (.01 s), Y axis is velocity (m/s), 0.5-5 Hz bandpass filter. Seems to be same response as IGU-16HR-3C.>>image:IGU16_1C_Z_huddle.png]]
451 -
452 -== BD3C-5 ==
453 -
454 - 'BD3C': {'poles':[(-1720.4+0j), (-1.2+0.9j), (-1.2-0.9j)],
455 - 'zeros':[(14164+0j), (-7162+0j), 0j, 0j],
456 - 'gain':1.69726e-05,
457 - 'sensitivity': 702651512.6046528}
458 -
459 -Above 0.5 Hz, the BD3C-5 response fits well:
460 -
461 -[[X axis is samples (.01 s), Y axis is velocity (m/s), 0.5-5 Hz filter>>image:BD3C_Z_huddle.0.5.png]]
462 -
463 -[[X axis is samples (.01 s), Y axis is velocity (m/s), 0.5-5 Hz bandpass filter>>image:BD3C_N_huddle.0.5.png]]
464 -
465 -(% class="wikigeneratedid" %)
466 -Below the corner frequency (0.2 Hz) the phase response still fares well, but amplitude response may need to be dialed in a bit (it seems a bit high). In the next two figures the filter is **0.1** to 5 Hz:
467 -
468 -
469 -[[BD3C **0.1 **to 5 Hz bandpass filter>>image:BD3C_Z_huddle.0.1.png]]
470 -
471 -[[BD3C **0.1** to 5 Hz bandpass filter>>image:BD3C_N_huddle.0.1.png]]
472 -
473 -== IGU-16 Horizontal noise & how to avoid ==
474 -
475 -The** 5 Hz nodes** are susceptible to horizontal noise due to the placement of geophones in the units, **but this can be mitigated by completely burying the units flush with the ground.** In the below example, the node was set on the floor of our basement set on its plastic carrying case support. As such the amount of horizontal noise noticeably increases above ~~ 10Hz.
476 -
477 -[[IGU-16HR-3C Power spectrum huddle test vs a CMG-6TD (S1) and TC120/Centaur combo. The N and E channels have excess noise above 10Hz due to "sticking up" out of the ground.>>image:IGU16_spectrum.png]]
478 -
479 -(% class="wikigeneratedid" %)
480 -The BD3C-5 nodes do not have this issue:
481 -
482 -[[BD3C-5 test, as above. There is no additional noise on the horizontal channels.>>image:BD3C_psd.png]]
483 -
484 484  = **Cleaning** =
485 485  
486 -When assembled, the nodes are water resistant but not submersible. They can handle a good spray and wipe-down. A stiff plastic brush is helpful to reach areas between the metal spikes on the bottom.
418 +When assembled, the nodes are water resistant but not submersible. They can handle a good spray and wipe-down. A strong, non-wire brush is helpful to reach areas between the metal spikes on the bottom.
487 487  
488 488  = **Weights (for shipping)** =
489 489  
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583 583  |**Dimensions (LxHxW)**|558 x 357 x 300mm
584 584  |**Input rating**|100-210V - 50/60Hz
585 585  |**Power**|1000W
586 -|**Weight**|14.5 kg
587 -|**Weight with cables**|21 kg
518 +|**Weight**|14.5kg
519 +|**Weight with cables**|21kg
588 588  )))
589 589  
590 590  (% class="box" id="HSmartSoloBD3C-16PortableBatteryCharger" %)
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596 596  |**Dimensions (LxHxW)**|625 x 500 x 366mm
597 597  |**Input rating**|100-210V - 50/60Hz
598 598  |**Power**|100W
599 -|**Weight**|21.5 - 24 kg
600 -|**Capacity**|16 nodes
531 +|**Weight**|21.5 - 24kg
532 +|**Slots no.**|16
601 601  |**Download Speed**|20MB/sec/slot
602 602  )))
603 603  
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607 607  
608 608  [[image:20250729_124644.jpg]]
609 609  
610 -|**Dimensions (LxHxW)**|625 x 500 x 366 mm
611 -|**Input rating**|100-210V - 50/60 Hz
612 -|**Power**|640 W
613 -|**Weight**|26.3 kg
614 -|**Capacity**|16 nodes
542 +|**Dimensions (LxHxW)**|625 x 500 x 366mm
543 +|**Input rating**|100-210V - 50/60Hz
544 +|**Power**|640W
545 +|**Weight**|26.3kg
546 +|**Slots no.**|16
615 615  )))
616 616  
617 617  (% class="box" %)
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621 621  [[image:20250729_124957.jpg]]
622 622  
623 623  
624 -|**Dimensions (LxHxW)**|590 x 225 x 405 mm
625 -|**Weight**|8.2 kg
626 -|**Capacity**|6 nodes
556 +|**Dimensions (LxHxW)**|590 x 225 x 405mm
557 +|**Weight**|8.2kg
558 +|**Slots no.**|6
627 627  )))
628 628  
629 629  (% class="box" %)
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633 633  [[image:20250729_124502.jpg]]
634 634  
635 635  |**Dimensions (LxHxW)**|230 x 340 x 310mm
636 -|**Weight**|(((
637 -3.6kg (empty)
638 -
639 -18.0kg (full)
568 +|**Weight**|3.6kg
569 +|**Slots no.**|6
640 640  )))
641 -|**Capacity**|6 nodes
642 -)))
643 643  
644 644  (% class="box" %)
645 645  (((
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649 649  
650 650  |**Dimensions (LxHxW)**|225 x 200 x 550mm
651 651  |**Weight**|
652 -|**Capacity**|8 nodes
580 +|**Slots no.**|6
653 653  )))
654 654  )))
655 655  )))
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