A vibration monitoring system at a work site is provided. The vibration monitoring system includes a vibration detection sensor associated with a structure provided at the work site. The vibration detection sensor is configured to generate a signal indicative of vibrations in an area proximate to the structure. The system includes a stationary alert assembly provided at the work site. The stationary alert assembly is proximate to the structure and the stationary alert assembly is positioned such that an alert provided by the stationary alert assembly is perceivable by users operating at the work site. The system also includes a controller coupled to the vibration detection sensor and the stationary alert assembly. The controller is configured to receive the signal indicative of the vibrations and compare the signal with a predetermined threshold. The controller is configured to provide the alert to the users through the stationary alert assembly based on the comparison.

A method for forecasting an environmental event/a type of environmental event includes acquiring at least one test data set of at least one behavioral and/or physiological parameter of a population of animals; generating a test profile based on said at least one test data set, representing behavior and/or physiological status of the population of animals; calculating a ratio between the test profile and a first reference profile; and setting an alert, if said ratio reaches a predefined threshold value. A system for forecasting an environmental event/a type of environmental event employs at least one data acquisition unit configured to acquire at least one data set of at least one behavioral and/or physiological parameter of a population of animals; at least one profile generation unit configured to generate at least one first reference profile and/or at least one test profile wherein each profile is based on at least one data set; at least one ratio calculation unit configured to calculate at least one ratio between the at least one test profile and one of the at least one first reference profile; at least one alert unit configured to raise an alert if at least one of the at least one calculated ratio reaches a predefined threshold value.

A method, system and surface covering for enabling wireless detection of damage to a structure is disclosed. At least one array having a plurality of nodes are coupled to a surface covering, such as at least one of a wall, ceiling and floor covering for a least a portion of the structure. An electronic reader is operable to wirelessly interrogate the array and read return signals from nodes in the array. The return signals contain data representing an ID for corresponding responsive nodes in the array, and the returned IDs are extracted and compared to a plurality of IDs stored in a data store for nodes in any given array. A mismatch between the returned and stored IDs for the nodes in the array indicates a structural defect in a respective portion of the structure overlaid by the floor/wall covering.

This is an early identification method for a shallow soil landslide, belonging to the technical field of landslide prevention and control engineering. The present invention accurately determines and identifies a shallow soil landslide in a quantitative manner, improving the early identification efficiency of a landslide and helping to improve the disaster prevention effect.

This is an early identification method for a shallow soil landslide, belonging to the technical field of landslide prevention and control engineering. The present invention accurately determines and identifies a shallow soil landslide in a quantitative manner, improving the early identification efficiency of a landslide and helping to improve the disaster prevention effect.

In certain embodiments, an assembly has intermediate pods magnetically, but not galvanically, coupled along an electrically conductive cable. Each pod has a magnetic core surrounding and inductively coupled to the cable and one or more coils inductively coupled to the magnetic core. The pod transmits, for example, outgoing current pulses on the cable by inducing electrical signals in the cable using a transmitter coil and the magnetic core. In addition, the pod repeats, for example, incoming current pulses on the cable by inducing electrical signals in the cable using the transmitter coil and the magnetic core, based on electrical signals induced in a receiver coil via the magnetic core by the incoming current pulses. Such an assembly can function as a data collection system for scientific research and/or as an early-warning system for events, such as earthquakes and tsunamis, without having to modify the cable itself.

A moment tensor is determined using an inversion algorithm for each of a plurality of microseismic events passively detected by receivers. Each of the moment tensors includes two nodal planes. A subset of the microseismic events is grouped into a family of microseismic events. If the microseismic events in the family have a common nodal plane, the common plane is a solution fault plane for the family of microseismic events. Information related to the fault plane is used to optimize fracking operation.

A method, system and surface covering for enabling wireless detection of damage to a structure is disclosed. At least one array having a plurality of nodes are coupled to a surface covering, such as at least one of a wall, ceiling and floor covering for a least a portion of the structure. An electronic reader is operable to wirelessly interrogate the array and read return signals from nodes in the array. The return signals contain data representing an ID for corresponding responsive nodes in the array, and the returned IDs are extracted and compared to a plurality of IDs stored in a data store for nodes in any given array. A mismatch between the returned and stored IDs for the nodes in the array indicates a structural defect in a respective portion of the structure overlaid by the floor/wall covering.

The techniques described herein relate to methods, apparatus, and computer readable media for real-time induced seismicity management. A distribution value, such as a b value, and an uncertainty of the distribution value is calculated based on the received magnitude data, wherein the distribution represents the proportion of each magnitude earthquake observed in the distribution. A seismogenic index is calculated based on a set of fluid injection rates and the distribution value, wherein the seismogenic index represents the proportion of earthquakes per volume of fluid injected into the earth at a particular location. A distribution of a number of earthquakes that will be induced of each magnitude from future injection is forecasted based on the seismogenic index. A ground motion prediction model is calculated, representing shaking intensity and distance based on the forecasted distribution of earthquakes. Seismicity can then be managed to not exceed a tolerated chance of induced shaking consequences.

According to an example aspect of the present invention, there is provided an apparatus comprising a memory configured to store seismic data, at least one processing core configured to perform a geographic determination, based on the seismic data and reference data, the geographic determination relating to a geographical location of a device that produced the seismic data. In some embodiments, the device that produced the seismic data is comprised in a cloud computing server. In other embodiments, the device that produced the seismic data is integrated in a secure computing element on a motherboard of a computer. In further embodiments, the reference data originates in a trusted seismographic source.