Abstract: A method and a system for classifying at least one individual gas compound from a plurality of leaked gases in a specified field of view are provided herein. The method may include the following steps: generating, by a cryogenically cooled detector and using a first of at least n filters, multiple spectral band images of the specified view in spectral bands coinciding with said leaking gases spectral bands in which said leaking gases emit and absorb electromagnetic radiation; calculating from the images, the relative absorption response of said gases in each of said filters, respectively; calculating a set of predetermined coefficients; normalizing said relative absorption responses to the sum of relative responses of said filters; and calculating the weighted average molecular mass of said gas compound of said leaking gases.

Abstract: A method and a system for classifying at least one individual gas compound from a plurality of leaked gases in a specified field of view are provided herein. The method may include the following steps: generating, by a cryogenically cooled detector and using a first of at least n filters, multiple spectral band images of the specified view in spectral bands coinciding with said leaking gases spectral bands in which said leaking gases emit and absorb electromagnetic radiation; calculating from the images, the relative absorption response of said gases in each of said filters, respectively; calculating a set of predetermined coefficients; normalizing said relative absorption responses to the sum of relative responses of said filters; and calculating the weighted average molecular mass of said gas compound of said leaking gases.

Abstract: Gas leakage monitoring systems and methods are provided, which use infrared camera(s) configured to capture images and to detect gas leakage at specified detection locations (SDLs) captured thereby, sniffer(s) configured to quantify the gas leakage at specified measurement points, and processing unit(s) in communication with the sniffer(s) and the camera(s), which are configured to associate and display sniffer point measurements within captured image(s) or video of the corresponding SDLs. The systems and methods generate a documentation of gas leakage measurements in association with images of the sniffers' positions during the measurements, e.g., measurement data being displayed on the image(s) of the sniffer(s) and provide additional combined analysis of images and measurements.

Abstract: System and method of quantifying a gas leak in a specified field of view are disclosed. The system may comprise a cooled detector and two interchangeable band-pass non-cooled filters. A first non-cooled band-pass filter transmits electromagnetic radiation in a first spectral band that coincides with a non-transparent leaking gas spectral band. A second non-cooled band-pass filter transmits only electromagnetic radiation in a second spectral band which coincides with a transparent leaking gas spectral band. The system may comprise a quantification unit arranged to process the images generated by the cooled detector to thereby determine, based on the images thereof, a flowrate of the leaking gas in the specified field of view. The system may comprise a detection unit arranged to determine, based on alternately generated multiple first spectral band images and multiple second spectral band images, a gas leak in the specified field of view.

Abstract: Client and cloud synchronization may be provided. First, a request may be received. Then the request may be labeled with a package metadata tag yielding a labeled request. The package metadata tag may identify a package assigned to a client device corresponding to the request. Next, the labeled request may be routed to a version of a first cloud service component based on the package metadata tag. The labeled request may then be routed from the version of the first cloud service component to a version of a second cloud service component based on the package metadata tag.

Abstract: System and method of quantifying a gas leak in a specified field of view are disclosed. The system may comprise a cooled detector and two interchangeable band-pass non-cooled filters. A first non-cooled band-pass filter transmits electromagnetic radiation in a first spectral band that coincides with a non-transparent leaking gas spectral band. A second non-cooled band-pass filter transmits only electromagnetic radiation in a second spectral band which coincides with a transparent leaking gas spectral band. The system may comprise a quantification unit arranged to process the images generated by the cooled detector to thereby determine, based on the images thereof, a flowrate of the leaking gas in the specified field of view. The system may comprise a detection unit arranged to determine, based on alternately generated multiple first spectral band images and multiple second spectral band images, a gas leak in the specified field of view.

Abstract: Gas leakage monitoring systems and methods are provided, which use infrared camera(s) configured to capture images and to detect gas leakage at specified detection locations (SDLs) captured thereby, sniffer(s) configured to quantify the gas leakage at specified measurement points, and processing unit(s) in communication with the sniffer(s) and the camera(s), which are configured to associate and display sniffer point measurements within captured image(s) or video of the corresponding SDLs. The systems and methods generate a documentation of gas leakage measurements in association with images of the sniffers' positions during the measurements, e.g., measurement data being displayed on the image(s) of the sniffer(s) and provide additional combined analysis of images and measurements.

Abstract: Client and cloud synchronization may be provided. First, a request may be received. Then the request may be labeled with a package metadata tag yielding a labeled request. The package metadata tag may identify a package assigned to a client device corresponding to the request. Next, the labeled request may be routed to a version of a first cloud service component based on the package metadata tag. The labeled request may then be routed from the version of the first cloud service component to a version of a second cloud service component based on the package metadata tag.

Abstract: A system kit and a method for creating a thermal imaging camera by connecting an infrared radiation capturing device to an external platform are provided herein. The kit may include a front end module which may include an image capturing device comprising a micro bolometer detector; and a universal serial bus (USB) interface connected to the image capturing device. The kit may further include a backend module, comprising data sets which are specific to said micro bolometer detector and computer readable code which is executable by a computer processor located at a physical location other than the front end module, wherein said front end module is configured to obtain raw data from the micro bolometer detector and deliver it over the USB interface to said backend module, wherein said backend module code turns the raw data into thermal imagery and temperature readings.

Abstract: A system kit and a method for creating a thermal imaging camera by connecting an infrared radiation capturing device to an external platform are provided herein. The kit may include a front end module which may include an image capturing device comprising a micro bolometer detector; and a universal serial bus (USB) interface connected to the image capturing device. The kit may further include a backend module, comprising data sets which are specific to said micro bolometer detector and computer readable code which is executable by a computer processor located at a physical location other than the front end module, wherein said front end module is configured to obtain raw data from the micro bolometer detector and deliver it over the USB interface to said backend module, wherein said backend module code turns the raw data into thermal imagery and temperature readings.