Abstract: A self-contained disaster condition monitoring system to alert a user of one or more disaster conditions at a location via a personal electronic device includes a self-contained housing assembly having a housing unit, wherein the self-contained housing assembly is equipped with a self-contained monitoring assembly comprising at least a disaster condition sensor or a disaster condition detector. A user interface assembly is provided and is operable by a user to configure at least the sensor or the detector of the self-contained monitoring assembly. A communication assembly includes an SMS communication module configured to transmit a direct SMS alarm message to the personal electronic device upon detection of at least one disaster condition by the self-contained monitoring assembly. The system also includes a power supply assembly to provide power to at least the self-contained monitoring assembly and the communication assembly, wherein the power supply assembly includes a backup power supply.

Abstract: A method for identifying and characterizing a condensate entrained in a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents and condensates within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents and condensates flowing through the pipe on a real time basis.

Abstract: Apparatus and methods relate to applying a condition decay function to a property's initial investment value to generate numerical baseline condition scores for multiple predetermined time increments, and adjusting the baseline condition scores by investment value of property structure improvements occurring during each time increment and scaled according to a statistical distribution of values of property structure improvements to peer structures. Investment values may be calculated per square foot of structure. Investment values of an investment activity may be imputed according to a statistical distribution of investment values of peer structure investment activities. Adjusted condition score values may be scaled to standardized condition score values according to a predetermined quantile shift function for a property's jurisdiction(s). Effective age of a structure may be determined from condition score values.

Abstract: A method for detecting an operational condition of a multi-conductor cable is described, and which includes generating a first, single ended, time domain reflectometer signal which is introduced into a multi-conductor cable; processing the first, single ended, time domain reflectometer signal so as to generate a first, differential time domain reflectometer signal; supplying the first, differential time domain reflectometer signal to the multi-conductor cable; converting a reflected, differential time domain reflectometer signal into a second, single ended, time domain reflectometer signal; numerically and/or graphically analyzing the second, single ended, time domain reflectometer signal; and identifying, by the numerical and/or graphical analysis, an operational condition of the multi-conductor cable undergoing the testing.

Abstract: A method for detecting an operational condition of a multi-conductor cable is described, and which includes generating a first, single ended, time domain reflectometer signal which is introduced into a multi-conductor cable; processing the first, single ended, time domain reflectometer signal so as to generate a first, differential time domain reflectometer signal; supplying the first, differential time domain reflectometer signal to the multi-conductor cable; converting a reflected, differential time domain reflectometer signal into a second, single ended, time domain reflectometer signal; numerically and/or graphically analyzing the second, single ended, time domain reflectometer signal; and identifying, by the numerical and/or graphical analysis, an operational condition of the multi-conductor cable undergoing the testing.

Abstract: Computer-implemented methods and computer systems for identifying whether there exists building permit information associated with a structure, or for estimating underinsurance of condition of a structure are provided. The computer implemented methods include acquiring construction information on a plurality of structures in computer-readable form and converting the construction information into a standardized database. The construction information may include building permit data including one or more of the number of building permits within a particular time frame, building permit age, building permit category, and job cost. Further, the computer implemented methods may include estimating underinsurance or condition of a target structure based on the construction information.

Abstract: A method for identifying and characterizing a condensate entrained in a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents and condensates within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents and condensates flowing through the pipe on a real time basis.

Abstract: A method for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: An apparatus for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: A probe for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: A probe for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: A method for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: An apparatus for identifying and measuring volume fraction constituents of a fluid using time domain analysis and frequency domain analysis to identify individual volume fraction constituents within a pipe on a real time basis and to measure the volume of the individual volume fraction constituents flowing through the pipe on a real time basis.

Abstract: The system described here is a bolt-type seal lock which includes a bolt, having a shaft with proximal and distal portions and a head that is wider than the distal portion of the shaft and located at the proximal portion of the shaft; a locking body having a passageway with an open end for receiving and retaining the distal portion of the shaft of the bolt in locking engagement after the shaft has been inserted a predetermined extent into the open end of the passageway, at which point the shaft cannot be withdrawn from the open end of the passageway; and a housing connected to, and rotatable relative to, the locking body, configured to be removably mounted to a door of a shipping container, thereby preventing swinging motion of the locking body. The housing contains electronics, including memory, a wireless communication component, and a power source.

Abstract: The system described here is a bolt-type seal lock which includes a bolt, having a shaft with proximal and distal portions, a head that is wider than the distal portion of the shaft and located at the proximal portion of the shaft, and a microchip that electronically contains a unique serial number of the bolt; and a locking body having a passageway with an open end for receiving and retaining the distal portion of the shaft of the bolt in locking engagement after the shaft has been inserted a predetermined extent into the open end of the passageway, at which point the shaft cannot be withdrawn from the open end of the passageway. The locking body contains electronics, including memory for storing data, wireless communications equipment, and a power source, configured to read and store the serial number form the microchip after the locking engagement.

Abstract: The system described here is a system for monitoring security of shipping containers, which includes: a plurality of shipping containers, each having a bolt-type seal lock module, and a sensor module mounted to an interior surface of the shipping container, configured to wirelessly communicate data over an external network; and a centralized computer database configured to receive data over the network that is external to the shipping containers from the plurality of shipping containers, by which data the security of the shipping containers is monitored.

Abstract: The system described here is a shipping container security system including a bolt-type seal lock module located on an exterior surface of a door of a shipping container; and a sensor module mounted to an interior surface of the shipping container. The bolt-type seal lock module and the sensor module are configured to wirelessly communicate data therebetween.

Abstract: The system described here is a bolt-type seal lock which includes a bolt, having a shaft with proximal and distal portions and a head that is wider than the distal portion of the shaft and located at the proximal portion of the shaft; a locking body configured to receive and retain the shaft in locking engagement after the shaft has been inserted a predetermined extent into an open end of a passageway of the locking body; and a component connected to the locking body such that the component and locking body are rotatable relative to each other, the component configured to be removably mounted to a door of a shipping container, whereby the locking body does not freely swing on the distal portion of the shaft of the bold during movement of the shipping container.

Abstract: The system described here is a shipping container security system which includes an RF data communications device; and an RF device mounted on an interior surface of a door of the shipping container and configured to form a short-range communications link with the radio communication component inside the shipping container via the antenna mounted on the exterior of the shipping container when the RF device and the radio communication component are within radio communications range. The RF device is mounted on the interior surface of the door such that, the RF device and the radio communication component are within radio communications range when the door is closed, and the RF device and the radio communication component are outside of radio communications range when the door is opened, whereby the opening and closing of the door of the shipping container is determinable.

Abstract: The system described here is a bolt-type seal lock which includes a bolt, having a shaft with proximal and distal portions, a head that is wider than the distal portion of the shaft and located at the proximal portion of the shaft, and a microchip containing a unique serial number of the bolt; a locking body having a passageway with an open end for receiving and retaining the distal portion of the shaft of the bolt in locking engagement after the shaft has been inserted a predetermined extent into the open end of the passageway, at which point the shaft cannot be withdrawn from the open end of the passageway; and a housing connected to, and movable relative to, the locking body, having electronics and a power source therein. The electronics and the housing are configured to read the unique serial number of the bolt from the microchip.