GeoSIG GMC Measuring Centre
Key Features
- Internet Enabled, Multifunctional and Multichannel Measuring System
- > 130 dB, up to 72 channels, up to 500 SPS
- Linux Operating System with On Board Processing and Evaluation
- Timing via NTP (Network Time Protocol), Optional GPS or 433 MHz Wi-Synch
- Enhanced Connectivity Options for GSM, GPRS, Satellite, Radio Telemetry or Landline Modem, Wired/Wireless Network
- Ring Buffer Continuous Recording
- Data Stream Output, Network Triggering
The GMC Measuring Centre, now a legacy product, was an instrument based on the GMS / NetQuake technology, and it had 100% software compatibility with the GMS instruments. It was the new generation of the GeoSIG Measuring Systems with extended connectivity capability and flexibility.
It included an Ethernet connection and optionally a 2.4 GHz Wi-Fi module to ensure fast and reliable data transfer.
Its design and efficiency made it the first choice for any application requiring seismic instruments. With its optimised installation, operation and maintenance philosophy, the GMC offered the real possibility to implement such as high density arrays with total operating costs at a small fraction of conventional strong-motion seismograph networks.
The instrument’s software processed data in real time. If triggered by a seismic event, GMS calculated Peak Ground Acceleration (PGA), Peak Ground Velocity (PGV), Peak Ground Displacement (PGD) and Response Spectrum (RSA) at various frequencies of the event. GMC could report these parameters, which are related to the strength of shaking, to a data centre where a synopsis (such as a shake map) for disaster management facilities could be generated in almost real time over the Internet. An event file was also recorded in the memory, which was sent out from the instrument and also securely accessible over the Internet.
The GMC was self-contained and was equipped with an uninterruptible power-supply, which provided, excluding options, more than 3 hours emergency operation without external power with internal battery and more than 24 hours with additional external battery. Since the battery and power management are critical components in applications, excessive care had been taken in the charger design, and the GMC was released as the first unit that could warn of a faulty battery before it was detected by a lack of communication during an AC power loss.
The GMC used an intelligent “Real Time Clock” (RTC) with self-learning temperature compensation at a fraction of power and thus cost of a TCXO. The RTC was able to synchronise with GPS or NTP (Network Time Protocol based on Internet UTC timing) to provide high timing accuracy.
The instrument could be locally connected to a laptop through its ports for configuration, testing or data retrieval. The internal memory cards could also be simply exchanged to retrieve the data. Several advanced communication options existed, such as for connection over the Internet; it could utilise a list of servers where the communication was based on a simple but highly secure file exchange.
Wired or Wireless Interconnected Network option enabled the use of several units together in a time and trigger synchronised manner; wireless using the Wi-Fi and Wi-Synch options.
It included an Ethernet connection and optionally a 2.4 GHz Wi-Fi module to ensure fast and reliable data transfer.
Its design and efficiency made it the first choice for any application requiring seismic instruments. With its optimised installation, operation and maintenance philosophy, the GMC offered the real possibility to implement such as high density arrays with total operating costs at a small fraction of conventional strong-motion seismograph networks.
The instrument’s software processed data in real time. If triggered by a seismic event, GMS calculated Peak Ground Acceleration (PGA), Peak Ground Velocity (PGV), Peak Ground Displacement (PGD) and Response Spectrum (RSA) at various frequencies of the event. GMC could report these parameters, which are related to the strength of shaking, to a data centre where a synopsis (such as a shake map) for disaster management facilities could be generated in almost real time over the Internet. An event file was also recorded in the memory, which was sent out from the instrument and also securely accessible over the Internet.
The GMC was self-contained and was equipped with an uninterruptible power-supply, which provided, excluding options, more than 3 hours emergency operation without external power with internal battery and more than 24 hours with additional external battery. Since the battery and power management are critical components in applications, excessive care had been taken in the charger design, and the GMC was released as the first unit that could warn of a faulty battery before it was detected by a lack of communication during an AC power loss.
The GMC used an intelligent “Real Time Clock” (RTC) with self-learning temperature compensation at a fraction of power and thus cost of a TCXO. The RTC was able to synchronise with GPS or NTP (Network Time Protocol based on Internet UTC timing) to provide high timing accuracy.
The instrument could be locally connected to a laptop through its ports for configuration, testing or data retrieval. The internal memory cards could also be simply exchanged to retrieve the data. Several advanced communication options existed, such as for connection over the Internet; it could utilise a list of servers where the communication was based on a simple but highly secure file exchange.
Wired or Wireless Interconnected Network option enabled the use of several units together in a time and trigger synchronised manner; wireless using the Wi-Fi and Wi-Synch options.