Changes for page ANU Seismic Data Loggers

Summary

• Page properties (2 modified, 0 added, 0 removed)
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  • TC120_ANU_vs_CENTAUR.png
  • full_vs_fast.png

Details

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1		-XWiki.JackD
	1	+XWiki.robert

Content

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10	10	)))
11	11	)))
12	12
13		-= Power Considerations =
14		-
15		-Both the LPR-200 (or "Low Power Recorder" 200) and TerraSAWR are designed to use as little power as possible, and more or less use the same amount of power.
16		-
17		-At 100 Hz and with a GPS cable connected these loggers draw about 220 mW of power once the screen is off (higher sample rates draw more power but only marginally, < 5mW). Adding a sensor (e.g. a Trillium Compact 120) increases this to approximately 400 mW, or 0.4 volt-amps. So, in theory 7 Ah battery should last about 10 days without a solar panel, but in practice it seems to be a bit closer to 8 which may be due to variability in power drain while in getting GPS locks.
18		-
19		-For very sunny environments (latitudes < 30) a 20V 10 Watt solar panel should have no issue keeping these loggers alive over the summer months, and assuming unobstructed skies should also be fine over winter. However there is no harm in using 20 or even a 40 Watt panel, especially for high latitudes, coastal regions, or areas without a full sky view. In theory up to a 60 Watt solar panel is fine, but we don't recommend anything over 40 Watts and that amount of power is already overkill.
20		-
21		-(% class="box infomessage" %)
22		-(((
23		-Power issues are easy and cheap to solve relative to the cost of your experiment, don't skimp!
24		-)))
25		-
26		-(% class="wikigeneratedid" %)
27		-In the case of an LPR, there is a large compartment for housing an internal battery, able to accommodate anything from a 10-30Ah battery. To use a standard lead acid battery with a positive and negative terminal, a 6 pin adaptor must be used. This ensures the voltage from the external power port (pins
28		-
29	29	= Data Card Formatting and Information =
30	30
31	31	Both the TerraSAWR and LPR-200 require SD Cards to be formatted in FAT32 filesystem. For 64Gb cards it can be difficult to format in FAT32, but [[software >>http://auspass.edu.au/field/fat32cardformatter.exe]]is available. ANU recommend SanDisk Extreme 150 mb/s cards in either 32 or 64Gb size. We strongly discourage using cards larger than 64Gb, and in general smaller cards are less likely to fail. We have also found that "adapter" cards (e.g. SD to microSD) are prone to having write issues and **strongly** advise against them.
...	...	@@ -32,27 +32,25 @@
32	32
33	33	The loggers can be "pre-programmed" with information (e.g. site name, sampling rate, etc) or they can be programmed in the field using the buttons on the logger. To pre-program the cards you simply edit a text file (named "[[ANUSRSetup.txt>>http://auspass.edu.au/field/ANUSRSetup.txt]]" for the LPRs, or "[[tSAWRSetup.txt>>http://auspass.edu.au/field/tSAWRSetup.txt]]" for the TerraSAWRs) and place it in the root directory on the SDCard. When the logger boots up, it will parse and load this information.
34	34
35		-== The format for ANUSRSetup.txt / LPR200s will be a single line of text that looks like this: ==
	19	+=== The format for ANUSRSetup.txt / LPR200s will be a single line of text that looks like this: ===
36	36
37	37	{{{XXX195G0100010034864 2 }}}
38	38
39		-//corresponding to//
	23	+corresponding to site XXX19,
	24	+ network 5G,
	25	+ sample rate 0100, (i.e. 100 Hz)
	26	+ "gps interval" 01 (once per hour~-~- don't change),
	27	+ start mode (always 0),
	28	+ stop mode (always 0),
	29	+ seismometer type (3 = broadband (+/- 20V), 2 = Guralp (+/- 10V), 1 = shortperiod (+/- 5V),
	30	+ and seismometer serial number (4864).
40	40
41		- site **XXX19**,
42		- network **5G**,
43		- sample rate **0100**, (i.e. 100 Hz)
44		- "gps interval" **01** (once per hour~-~- don't change),
45		- start mode (always **0**),
46		- stop mode (always **0**),
47		- seismometer type (**3** = broadband (+/- 20V), 2 = Guralp (+/- 10V), 1 = shortperiod (+/- 5V),
48		- and seismometer serial number (**4864**).
49		-
50	50	(% class="box warningmessage" %)
51	51	(((
52	52	NOTE: the 2 at the very end is for "RECORD ON RESTART". The record on restart option ensures that if the logger dies and is powered back up whilst in the field (due to battery charging cycles or other causes) that the recording will resume. (# of blank spaces before this doesn't matter)
53	53	)))
54	54
55		-== The format for TSAWR loggers is shorter: ==
	37	+=== The format for TSAWR loggers is shorter: ===
56	56
57	57	(% class="box errormessage" %)
58	58	(((
...	...	@@ -71,7 +71,7 @@
71	71	and seismometer serial number (9999).
72	72
73	73
74		-== The formatting process using the logger: ==
	56	+=== The formatting process using the logger: ===
75	75
76	76	The process for formatting an SD card within the logger is straightforward. Navigate to the "SD INFORMATION" screen and press ERASE SD CARD. This process may take up to a minute. This will result in erasing all files from the card. Upon starting recording, a new 'seed' will be written containing all the information that the logger has been set with FINISH THIS SECTION
77	77
...	...	@@ -83,17 +83,7 @@
83	83	32Gb card: 122 days @ 250hz or 305 days @ 100hz
84	84	}}}
85	85
86		-== Default Settings ==
87	87
88		-As of 2025, the default settings for both LPR (v. 2.7) and TSWAR (v 3.6a) loggers are below. If you're using a broadband instrument, you are essentially good to go without having to program the cards.
89		-
90		-* XX.ANUSR network and station name
91		-* 100 Hz Sample Rate
92		-* 40V pp (or +/- 20 V) gain / Trillium Compact seismometer version
93		-* Record on Restart enabled
94		-
95		-Note that if a user sets the gain incorrectly, this can be fixed later (assuming nothing clipped) by multiplying or dividing by factors of 2. The gain setting can be looked up from the logfile, else you may have to guess from a PSD or other method.
96		-
97	97	= Logger Menus Overview (and setup) =
98	98
99	99	The same menus are used in both the TSAWR and LPR-200 loggers.
...	...	@@ -104,27 +104,40 @@
104	104
105	105	This menu also displays the firmware version, battery, external, and solar voltages, and the temperature of the system.
106	106
107		-* Check all Initialisation Parameters are marked as successful.
108		-* Check that solar voltage is above 10 V, otherwise the station will not last long.
	79	+==== Upon setup ====
109	109
	81	+- Check all Initialisation Parameters are marked as successful.
	82	+
	83	+- Check that solar voltage is above 10 V, otherwise the station will not last long.
	84	+
	85	+
110	110	== Live Seismometer Data ==
111	111
112	112	This screen displays real time seismometer data for all 3 axes of the seismometer. Initially, a plot of raw data from all 3 channels is shown. By pressing enter, a high pass filter can be applied showing a more useful plot of all channels. The up and down arrows can be used to change between a view of all channels, individual channels, and all channels on different X axes.
113	113
114		-* Check that all 3 channels are present and are producing a signal.
115		-* Stomp on the ground near where the sensor is installed to check that a signal is being picked up by all 3 channels.
116		-* Common representations of poor signals include channels sloping smoothly from high values to zero, or sharp corners in the plots.
	90	+==== Upon setup ====
117	117
	92	+- Check that all 3 channels are present and are producing a signal.
	93	+
	94	+- Stomp on the ground near where the sensor is installed to check that a signal is being picked up by all 3 channels.
	95	+
	96	+- Common representations of poor signals include channels sloping smoothly from high values to zero, or sharp corners in the plots.
	97	+
	98	+
118	118	== GPS Data ==
119	119
120	120	This menu displays the status of the stations' GPS connection. The screen lists; UTC time, UTC date, latitude, longitude, altitude, number of satellite connections, and SNR.
121	121
122		-* Check that the station is connected to satellites
	103	+==== Upon setup ====
123	123
	105	+- Check that the station is connected to satellites
	106	+
	107	+
124	124	== SD Information ==
125	125
126	126	The menu lists if the SD card has been initialised, as well as the capacity and space free on the memory card. See "Data card formatting" (above) to see how to format and initialise the inserted SD card.
127	127
	112	+
128	128	== System Configuration ==
129	129
130	130	This menu is used to set the stations identifiers and parameters.
...	...	@@ -137,19 +137,26 @@
137	137
138	138	The seismometer model and serial number (up to 10 characters) can be set. Seismometer model options include:
139	139
140		-* Trillium Compact (same for 20 and 120)
141		-* CMG - 3ESP
142		-* Guralp 40T
143		-* LE-3D Lite
144		-* Mark L4C
145		-* Mark L4
	125	+- Trillium Compact
146	146
	127	+- CMG - 3ESP
	128	+
	129	+- Guralp 40T
	130	+
	131	+- LE-3D Lite
	132	+
	133	+- Mark L4C
	134	+
	135	+- Mark L4
	136	+
147	147	Additionally, the following settings can be used in place of the seismometer model types: +/- 20V, +/- 10V, +/- 5V
148	148
149	149	The record on restart option ensures that if the logger dies and is powered back up whilst in the field (due to battery charging cycles or other causes) that the recording will resume.
150	150
151		-* Set the sampling rate, station identifier, and network code. Set the appropriate seismometer type. Most importantly, ensure the record on restart setting is checked.
	141	+==== Upon setup ====
152	152
	143	+- Set the sampling rate, station identifier, and network code. Set the appropriate seismometer type. Most importantly, ensure the record on restart setting is checked.
	144	+
153	153	(% class="box errormessage" %)
154	154	(((
155	155	NOTE: Ensure the 'RECORD ON RESTART' option is marked with a cross.
...	...	@@ -160,42 +160,59 @@
160	160
161	161	== STA/LTA Configuration ==
162	162
163		-The Short Term Average and Long Term Average Configuration screen.. this is a relic for when people weren't recording continuously. Not advised!
	155	+The Short Term Average and Long Term Average Configuration screen is no longer used.
164	164
	157	+
165	165	= LogFile Conversion Script =
166	166
167	167	Both the TSAWR and LPR-200 write logging information as a binary "dat" file which includes GPS time syncs, temperatures, battery power, and position. To convert them into ASCII you can read, use [[THIS PYTHON SCRIPT>>http://auspass.edu.au/field/anusr_log.py]].
168	168
	162	+
169	169	= Instrument Response =
170	170
171		-Both the TerraSAWR and LPR-200 use the same ADS1281 analog-to-digital converter chip and are designed to have identical instrument response. The ADC (analog to digital) chip in both loggers originally samples at 1024000 Hz and downsamples towards the output data rate via a 5th order SINC filter, then another four FIR filters. If the output is below 250 Hz, a final "pure" /5 decimation is done without any sort of FIR filter.
	165	+Both the TerraSAWR and LPR-200 use the same ADS1281 analog-to-digital converter chip and are designed to have identical instrument response. Depending on the output sample rate (e.g. 100 Hz, 250 Hz, 500 Hz, 1000 Hz) amplitude response is consistently flat up to ~~100 Hz but phase response can vary above 1 Hz at 100 Hz (or 10 Hz at 250 Hz).
172	172
173		-{{info}}
174		-The Stage 3 SINC coefficients (600+) during the initial 1024k > 16k decimation were left off as they slowed down the process x10 and contribute very little (< 0.3 db, < 0.31 ms) to the end result
175		-{{/info}}
	167	+The user can choose to apply a 2nd stage "sensor gain" by selecting an instrument type in the setup menu. This effectively selects a 10 Vpp (e.g. short period sensors), 20 Vpp, 40 Vpp (most broadband sensors) regime to match the sensor's sensitivity. This has the effect of doubling amplitude from 10v to 20v, or quadrupling from 10v to 40v. If you have set your sensor correctly (and the signal isn't clipped!) you can "correct" this by simply multiplying your data by 0.5 etc.
176	176
177		-The user can choose to apply a 2nd stage "sensor gain" by selecting an instrument type in the setup menu. This effectively selects a 10 Vpp (e.g. short period sensors), 20 Vpp, 40 Vpp (most broadband sensors) regime to match the sensor's sensitivity. This has the effect of doubling amplitude from 10v to 20v, or quadrupling from 10v to 40v. If you have set your sensor correctly (and the signal isn't clipped!) you can "correct" this by simply multiplying your data by 0.5 etc. This gain manifests itself in stage 2 in the response information.
	169	+Another important thing to note is that the group delay associated with late stage FIR filters is **automatically applied in the logger**, hence there is no need to apply this in the response. These tend to max out at 0.124 seconds for most output sampling rates (0.062 s for 100 Hz).
178	178
179		-Instrument response can be downloaded from IRIS [[Nominal Response Library>>https://ds.iris.edu/ds/nrl/]] if need be, or [[directly from us>>http://auspass.edu.au/data/logger_response]] , or by downloading the response of an equivalent sensor at AusPass (e.g. get_stations(level='response') ).
	171	+Instrument response can be downloaded from IRIS-NRL (v2) if need be, or by downloading the response of an equivalent sensor at AusPass (e.g. get_stations(level='response') )
180	180
181		-[[Huddle test comparing a Trillium Compact 120 + TerraSAWR vs a Trillium Compact 120 + Nanometrics Centaur (M8.AUANU)>>image:TC120_ANU_vs_CENTAUR.png||data-xwiki-image-style-alignment="center"]]
182	182
183		-= ANU TerraSAWR (Gen 3, FW 3.5a, 2017- current) =
	174	+= ANU TerraSAWR (Gen 3, FW 3.5a, 2017?- current) =
184	184
185		-Not sure there's much left to say
	176	+Text here
186	186
	178	+== Sub-paragraph ==
187	187
	180	+XXXX
188	188
	182	+== Sub-paragraph ==
	183	+
	184	+xx
	185	+
	186	+=== Sub-sub paragraph ===
	187	+
	188	+x
	189	+
	190	+
189	189	= ANU LPR-200 (Gen 2, FW 2.6a/2.7a, 2013 - current) =
190	190
191		-Ditto the mighty LPR!
	193	+Text here
192	192
	195	+== Sub-paragraph ==
193	193
194		-= ANU "ANUSR" (Gen 1, 2003? - 2012) =
	197	+x
195	195
196		-This logger has been retired for a long time and has a different instrument response. It used modular component boards and was powered via an acrylic case of 6 x 6V lantern batteries. There is a somewhat complete one above the CAT lab door if anyone is so inclined to have a look.
	199	+== Sub-paragraph ==
197	197
	201	+x
198	198
	203	+
	204	+= ANU "ANUSR" (Gen 1, 2003? - 2013?) =
	205	+
	206	+x
	207	+
199	199	= References =
200	200
201	201	* [[PDF Manual>>http://auspass.edu.au/field/LPR-200_Instruction_Manual.pdf]]
...	...	@@ -211,14 +211,6 @@
211	211	)))
212	212
213	213
214		-
215		-
216		-
217		-
218		-
219		-
220		-
221		-
222	222	(% class="box" %)
223	223	(((
224	224	= TerraSAWR Specs =
...	...	@@ -231,13 +231,12 @@
231	231	[[image:1704864886951-793.jpg]]
232	232
233	233	|=Size (L x W x H)|30 x 25 x12cm
234		-|=Weight (with battery)| 1.9kg (2.5kg)
	235	+|=Weight (with battery)| ~*~*1.9kg (2.5kg)
235	235	|=Battery|(((
236		-Lead-acid 12v, ~~7-9Ah
	237	+Lead-acid 12v, ~~7Ah
237	237
238	238	Rechargeable
239	239	)))
240		-|=Current Firmware|3.5a (Jan 2025)
241	241
242	242	[[image:terrasawr battery.jpg]]
243	243	)))
...	...	@@ -254,18 +254,13 @@
254	254	[[image:LPR 3.jpg]]
255	255
256	256	|=Size (L x W x H)|42 x 34 x17 cm
257		-|=Weight (no battery)|5.5 kg
	257	+|=Weight (with battery)|4.9 kg (7.3 kg)
258	258	|=Battery|(((
259		-NOW: Any 12v battery with tab connections that will fit (ex. the same TSAWR battery)
	259	+LiFePo4 140Ah
260	260
261		-DISCONTINUED: LiFePo4 140Ah Rechargeable (shown below).
	261	+Rechargeable
262	262	)))
263		-|=Current Firmware|(((
264		-2.6a (old GPS modules) / 2.7a
265	265
266		-Jan 2025
267		-)))
268		-
269	269	[[image:LPR battery.jpg]]
270	270	)))
271	271	)))

TC120_ANU_vs_CENTAUR.png

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full_vs_fast.png

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