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As someone who used to work for a university's geosciences department as a Unix sysadmin/programmer and who worked on two different seismic monitoring networks (one spread across the state for earthquake monitoring and one parked on top of a coal mine), allow me to explain why earthquake monitoring in the United States is largely stuck in the stone age: There's no f---ing money. Back in the '80s, there were a lot of regional seismic networks around the country, especially east of the Mississippi. But as time marched on and budgets got slashed, regional seismic networks disappeared one by one. Today, only the largest regional networks survive — generally the ones that are mostly funded by the states they're in and/or have increased their share of USGS/ANSS funding by taking over monitoring for areas of the country that used to be covered by the now-defunct networks. The regional seismic networks that are left spend pretty much all of their dollars on equipment and operations. Installing/upgrading/running permanent seismograph stations is expensive — a basic solar-powered one with a shallow fiberglass vault, a three component short period sensor, and a three channel digitizer will run you ~$12,000 just in equipment and materials. The sky's the limit if you go fancier than that (broadband sensors, strong motion sensors, atmospheric sensors, borehole sensors, six channel digitizer, elaborate vaults, VSAT, etc.). Then there's the recurring communications cost, the cost of regular site visits, the cost of regular battery replacements, replacing solar panels/equipment boxes that morons shoot at for laughs, etc. What I'm getting at is that in the monetary battles of "keep seismograph stations working" vs. "hire programmer to write useful software", the stations will win every time. Even this LA Times article about Berkeley's early warning system notes, "A lack of funds, however, has slowed the system's progress." If the epicenter of tech wants to do something wonderful for earthquake seismology, figure out how to make dirt cheap 1- or 3-channel seismic digitizers (low-pass filter + low noise amp + 20-bit ADC @ 100–200 accurately timestamped samples/s, ≤1 watt average power draw @ 12 VDC, speaks TCP/IP over 802.11g/n) and dirt cheap 1- or 3-component short period sensors (1 or 2 Hz corner frequency, decent sensitivity). Then figure out how to get thousands of these dirt cheap digitizers and sensors in backyards all over the country and contributing data in real-time to IRIS and/or the closest regional seismic network. If the cost of acquiring quality seismic data goes down, that frees up money to actually do something with the data. When I was still at the university job, my job-related pipe dream was to blanket the state with these non-existent dirt cheap stations. Even one or two per county in my state would've increased our station count by a factor of >15, greatly improved the quality of our earthquake locations, and allowed us to determine focal mechanisms (the orientation of the fault and direction of the slip) even for small earthquakes. |
From the 50's to the 80's there was a significant amount of defense funding (mostly DARPA) for seismic monitoring to detect, locate, and analyze nuclear detonations in addition to civilian research purposes. After the cold war ended, the majority of the military funding went away.
Also, on a side note, for those of you looking at the hardware description and thinking "all that exists", notice the sample rate and power requirements. (Don't forget data transmission and/or storage, either.) It's already possible to get dirt cheap sensors. (For some purposes (e.g. surface waves), off-the-shelf accelerometers are good enough, and even traditional oil industry geophones are fairly cheap.) (Obviously broadband stations are a completely different story...) The problem is sample rate and power draw.