Systems and methods are disclosed to detect cloud-to-ground (CG) strokes that include or are followed by continuing current. As an example, earth-based lightning data may be generated for one or more lightning pulses detected in an environmental space using multiple earth-based lightning detection sensors. Space-based lightning data may be received for one or more optical signals detected in the environmental space using one or more space-based lightning detection sensors. It may be determined whether one or more lightning pulses is a CG stroke based on the earth-based lightning data. In response to determining that a given one of the one or more lightning pulses is a CG stroke, it may be determined whether the CG stroke includes or is followed by continuing current based on the space-based lightning data.

Systems and methods are disclosed to detect cloud-to-ground (CG) strokes that include or are followed by continuing current. As an example, earth-based lightning data may be generated for one or more lightning pulses detected in an environmental space using multiple earth-based lightning detection sensors. Space-based lightning data may be received for one or more optical signals detected in the environmental space using one or more space-based lightning detection sensors. It may be determined whether one or more lightning pulses is a CG stroke based on the earth-based lightning data. In response to determining that a given one of the one or more lightning pulses is a CG stroke, it may be determined whether the CG stroke includes or is followed by continuing current based on the space-based lightning data.

A method for protecting an electronic system against a voltage surge, which electronic system is connected to a telecommunication network and includes a control integrated circuit, the method including successively connecting the electronic system to a remote server containing meteorological data; recovering meteorological data originating from the remote server; analyzing by the control circuit the recovered meteorological data to assign thereto a danger level of the current or imminent meteorological event; and, when the assigned danger level exceeds a main warning threshold: sending by the control circuit a warning signal to a display terminal connected to the electronic system; displaying a first warning message on the display terminal from information contained in the warning signal, the first warning message warning a user of the display terminal of a risk of voltage surge due to the current or imminent meteorological event; and electrical isolating a port of the electronic system.

A MEMS-based atmospheric electric field sensor on the ground includes an arc-roof detection structure and a MEMS electric field measuring module. The arc-roof detection structure includes an electric conducting arc-roof rainproof housing, an electric conducting connecting column, a fixing-supporting chamber body upper part, and a fixing-supporting chamber body lower part. The top part of the electric conducting arc-roof rainproof housing is arc-shaped, and the bottom part of the same is provided with a groove facing towards the top part. The electric conducting connecting column is arranged on a top part of the groove and electrically connected to the arc-roof rainproof housing. The fixing-supporting chamber body upper part is a barrel in the groove. The fixing-supporting chamber body closes the bottom opening of the fixing-supporting chamber body upper part to form a fixing-supporting chamber body. The MEMS electric field measuring module is provided inside the fixing-supporting chamber body.

A MEMS-based atmospheric electric field sensor on the ground includes an arc-roof detection structure and a MEMS electric field measuring module. The arc-roof detection structure includes an electric conducting arc-roof rainproof housing, an electric conducting connecting column, a fixing-supporting chamber body upper part, and a fixing-supporting chamber body lower part. The top part of the electric conducting arc-roof rainproof housing is arc-shaped, and the bottom part of the same is provided with a groove facing towards the top part. The electric conducting connecting column is arranged on a top part of the groove and electrically connected to the arc-roof rainproof housing. The fixing-supporting chamber body upper part is a barrel in the groove. The fixing-supporting chamber body closes the bottom opening of the fixing-supporting chamber body upper part to form a fixing-supporting chamber body. The MEMS electric field measuring module is provided inside the fixing-supporting chamber body.

A lightning strike alarm system using a Bipolar Conventional Air Terminal (BCAT) is provided. The lightning strike alarm system using BCAT including a rod element to which a ground charge is electrified and an electrification plate-cone or an electrification plate-tube electrified by a thunderstorm cloud, includes a luminescence unit to be electrically connected to the rod element and the electrification plate-cone or the electrification plate-tube and emits light by electric energy electrified to the electrification plate-cone or the electrification plate-tube by the thunderstorm cloud. The lightning strike alarm system enables a user to find that an impulse current of the thunderstorm is normally and safely flown to the ground, and thus, the user may have psychological security.

A lightning strike alarm system using a Bipolar Conventional Air Terminal (BCAT) is provided. The lightning strike alarm system using BCAT including a rod element to which a ground charge is electrified and an electrification plate-cone or an electrification plate-tube electrified by a thunderstorm cloud, includes a luminescence unit to be electrically connected to the rod element and the electrification plate-cone or the electrification plate-tube and emits light by electric energy electrified to the electrification plate-cone or the electrification plate-tube by the thunderstorm cloud. The lightning strike alarm system enables a user to find that an impulse current of the thunderstorm is normally and safely flown to the ground, and thus, the user may have psychological security.

A method includes detecting, by a pair sensors located at two locations, a radio wave generated from a lightning discharge occurring; for the pair of sensors, determining propagation paths between the discharge and sensors; repeating the same with a second pair of sensors and another lightning discharge; for each path, determine path vectors defined by an attenuation coefficient vector; constructing a matrix with each row comprising the difference between path vectors from sensor pair measurements from the lightning discharge and including a selection entry based on the identification of the sensors to enable the logarithm of sensor calibration factors to be solved for; constructing another vector, where each entry comprises the difference between the logarithms of the sensor amplitudes from a sensor pair measurement adjusted by a logarithm of an offset; inverting a system of linear equations defined by the matrix to solve for attenuation and sensor calibration factors.

A method includes detecting, by a pair sensors located at two locations, a radio wave generated from a lightning discharge occurring; for the pair of sensors, determining propagation paths between the discharge and sensors; repeating the same with a second pair of sensors and another lightning discharge; for each path, determine path vectors defined by an attenuation coefficient vector; constructing a matrix with each row comprising the difference between path vectors from sensor pair measurements from the lightning discharge and including a selection entry based on the identification of the sensors to enable the logarithm of sensor calibration factors to be solved for; constructing another vector, where each entry comprises the difference between the logarithms of the sensor amplitudes from a sensor pair measurement adjusted by a logarithm of an offset; inverting a system of linear equations defined by the matrix to solve for attenuation and sensor calibration factors.

A method to generate data to geolocate lightning pulses may include detecting in an environment EMF generated from the lightning pulses. The method may include producing lightning-EMF from the detected EMF where the lightning-EMF may represent the EMF generated from the lightning pulses. The method may include extracting a lightning-waveform-feature set from the lightning-EMF data, including extracting one or more waveform features for each of the lightning pulses from the lightning-EMF data. The method may also include transmitting the extracted lightning-waveform-feature set to a server to perform time alignment on multiple extracted lightning-waveform-feature sets received from multiple lightning-detection sensors and to geolocate the lightning pulses based on the time-aligned extracted lightning-waveform-feature sets.