Embodiments relate generally to systems and methods for controlling the display of a gas detector. A method may comprise receiving sensed data from a plurality of sensors of the gas detector; displaying the received sensed data on a user interface of the gas detector, wherein the user interface comprises a display, and wherein the display includes information for more than one of the plurality of sensors; and changing the display to an alarm screen that includes only the alarm information, when the gas detector is in an alarm or alert mode. A gas detector configured to detect multiple gases may comprise a plurality of sensors configured to detect a plurality of gases and conditions, and a user interface comprising a display configured to display information received from the plurality of sensors.

Systems, apparatuses, and methods for monitoring an environment are provided. These systems, apparatus, and methods may include a monitoring unit positioned within the environment that includes an air quality sensor configured to generate particle data, a communications unit configured to directly or indirectly transmit data between the monitoring unit and a remote computing unit, and a controller with instructions to cause the air quality sensor to generate particle data about particles in the environment, and transmit the particle data to the remote computing unit. The remote computing unit may be positioned outside the environment, and include a second processor, another communications unit, and another non-transitory memory device with instructions to receive and store the particle data, and determine, based on the received particle data generated by the air quality sensor, whether a first exposure threshold has been exceeded for the monitoring unit.

Various devices, systems, and methods may be presented. A sensor unit may be presented that includes a housing and a chamber arranged within the housing and configured to receive air from outside of the housing of the sensor unit. Also present may be a sensor arranged within the housing and configured to measure a characteristic within the chamber. The sensor unit may include a fan arranged within the housing in relation to the chamber, the fan configured to clear air from the chamber of the sensor unit. Further, the sensor unit may include a controller in communication with the fan and the sensor, the controller configured to operate the fan.

Provided is a method and apparatus for calculating a safety grade of a working environment that may receive harmful gas information from a gas sensor configured to detect a harmful gas to calculate a safety grade, receive biometric information of a user from a biometric sensor configured to measure the biometric information of the user, calculate a safety grade for the user based on the harmful gas information and the biometric information, and output the calculated safety grade.

A system that includes a gas sensor, a fresh air flow controller, a sample flow controller, and a system controller. The fresh air flow controller is configured to deliver fresh air to the gas sensor. The sample flow controller is configured to deliver a sample to the gas sensor. The system controller has a processor connected to memory storing instructions that are executable by the processor. When executed, the instructions cause the processor to determine an intermix ratio of the sample to the fresh air, instruct the fresh air flow controller and the sample flow controller to deliver the fresh air and the sample, respectively, to the gas sensor in accordance with the intermix ratio, and receive a sensor reading from the gas sensor after the fresh air flow controller and the sample flow controller have adjusted the fresh air and the sample, respectively.

A distributed security system includes a detection unit disposed at a first location. The detection unit includes a particle sensor that is configured to detect a particle count in first location. The detection unit also includes a housing enclosing a portion of the particle sensor. The security system also includes a camera disposed at a second location and having a field of vision encompassing the first location. The camera is configured to capture a video of the first location. The system also includes a server communicatively connected to the detection unit and the camera and configured to associate the particle count with the video.

A method and apparatus for testing and monitoring of personal, hyper-local chemical composition or environmental conditions is accomplished when a user or group of users gather data utilizing the combination of a sensor-extensible apparatus attached to one or more mobile communications devices, employing the associated mobile computing operating systems and network, in order to capture and transmit the relevant data to a cloud computing complex for storage, analysis and reporting. The cloud computing complex is configured to validate data by gathering corroborating evidence of location and reading accuracy, and provide a recommendation to a user or group of users within a threshold confidence level.

A system for smoke/fire discrimination and identification of the fire source is provided. The system comprises a control unit that is configured to receive data pertaining to gases present in the smoke generated by a burning material and receive data pertaining to temporal characteristics of fire caused by the burning material. The control unit identifies the burning material based on the data pertaining to the one or more gas and the data pertaining to temporal characteristics of fire; and trigger a fire event based on the identified burning material. The control unit identifies and classifies the burning material as one of the known burning materials based on matching of the detected gas and the captured temporal characteristics with the database.

Techniques for alerting for instruments that transfer physical samples are disclosed. An alarm module, placed within a communication pathway of a first chemical processor and a second chemical processor, includes a timer configured to count time elapsed since receiving, from the first chemical processor, a transfer-ready signal indicating that 1) the first chemical processor received a receive-ready signal from the second chemical processor; ii) the first chemical processor has completed processing a chemical analyte; and iii) the first chemical processor is ready to physically transfer the chemical analyte to the second chemical processor. Upon receiving the transfer-ready signal from the first chemical processor, the timer is restarted. An alarm triggers when the elapsed time counted by the timer exceeds a specified threshold. The alarm is audible or visual. Upon the triggering of an alarm, an alert notification (e.g., an email, a text message, etc.) is transmitted.

Embodiments relate generally to systems and methods for gas detection. A method may comprise operating a gas detector (102) with a first alarm setting comprising a first predefined threshold; receiving sensed data of oxygen content in the ambient air; when the sensed data is below the first predefined threshold, activating an alarm (110); generating an acknowledgement request asking if the gas detector has entered an inert work zone (122); receiving a response from the user acknowledging that the gas detector has entered an inert work zone; deactivating the alarm; changing the alarm settings of the gas detector to a second alarm setting comprising a second predefined threshold; continuing to receive sensed data of oxygen content in the ambient air; when the sensed data is above the second predefined threshold, activating an alarm; and generating an acknowledgement request for the user asking if the gas detector has entered a normal operation work zone (120).