The system and method provide for the monitoring and trending the rate at which fire detection devices get dirty. This information is used to determine which devices are clogged or getting clogged and to establish that the chambers are open to air flow because they are accumulating dirt over time. Air flow through the detection chamber is proven using this analysis. Further self-testing is also employed for the fire detection devices by including modules that simulate the smoke interference with the light. This can be accomplished in two ways. In one example, light from the chamber light source can be reflected toward the scattered light photodetector to simulate alarm conditions. In another example, an additional chamber light source can be added to the detection chamber that can generate light to simulate alarm conditions.

A system and method for testing fire detection and fire annunciation/notification devices of a fire alarm system includes a central operations system, which provides a link between a control panel of the fire alarm system and a mobile computing device operated by a technician. One or more wireless nodes create a mesh network between the control panel and a testing computer. Then, during a walkthrough test, the on-site technician activates fire detection or fire annunciation devices of the fire alarm system and the activated devices signal the control panel and event data are generated. Event data from the control panel are sent to the central operations system via the mesh network. The central operations system sends the event data to a mobile computing device operated by the technician. The on-site technician is then able verify that the devices are physically sound, unaltered, working properly, and located in their assigned locations.

Systems and methods of increasing the efficiency and accuracy of a walk test in a fire alarm system are provided. Some methods can include receiving one or more walk test result signals from a system in a region, the signals indicative of one or more triggered input devices in the system and one or more activated output devices in the system, identifying one or more output devices in the system configured to be activated responsive to the one or more triggered input devices, comparing the activated output devices to the output devices configured to be activated, and transmitting a signal indicative of results of the comparing. Additionally or alternatively, some methods can include visually displaying or audibly emitting an indication of the results of the comparing.

Methods, systems, and apparatus, including computer programs encoded on a storage device, for using a drone to test a sensor. In one aspect, the method includes actions of detecting a message (i) broadcast by the drone and (ii) indicating that the drone is going to administer a test of a sensor, determining, by the monitoring system and based on the message and (i) sensor data generated by the sensor in response to the administration of the test, by the drone, within a predetermined period of time of the message or (ii) a lack of sensor data generated by the sensor in response to the administration of the test, by the drone, within a predetermined period of time of the message, whether the sensor is functioning properly, and in response to a determination that the sensor is not functioning properly, storing data indicating that the sensor is not functioning properly.

Various methods, systems, and devices for identifying a condition of a battery-powered device are presented. For example, a device may include a smoke detection sensor that detect smokes and, in response to detecting smoke, generate a smoke detection signal. The device may include test circuitry that tests an aspect of the battery-powered device. The device may include an audio output device that outputs a sound in response to the test circuitry determining a particular condition is present. The device may include a proximity detector that monitors for a wave movement of an object within a distance of the battery-powered device and generates a proximity detection signal when the proximity detector detects the wave movement performed by the object within the distance of the smoke detector device.

A smoke detector and method for testing a smoke detector are provided. The smoke detector includes a housing defining a chamber, an emitter, and a receiver. The housing includes an inlet port and an outlet port configured to allow an airflow to pass through the chamber. The emitter is configured to emit light into the chamber. The receiver is configured to receive light reflected by ambient materials in the airflow passing through the chamber. The smoke detector includes an entry point and an exit point, defining a channel therebetween. At least a portion of the airflow passes through the channel. The channel is in fluid communication with a sensor. The sensor is configured to detect at least one of a pressure differential and a mass flow of the airflow. The smoke detector and method for testing the smoke detector enable in situ testing of the smoke detector.

According to systems and methods for testing alarm initiating devices of a fire alarm system, a control panel of the fire alarm system is placed into test mode. Then, during a walkthrough test, an inspector activates an inspector-activated mechanism of a device. This sends a test mode signal to the control panel, which places the device into a test mode. The inspector or inspector then manually activates the device. The control panel initiates a fire alarm condition in response to a received device signals while the control panel not initiating a fire alarm condition when the device signals are indicative of a fire if the device signals were from alarm initiating devices in the test mode. Alternatively, the control panel places a group of alarm initiating devices into test mode on a rolling basis. As the inspector tests the devices, additional devices are added to the group and previously tested devices are returned to normal operation mode.

A method of validating a set of location sensors deployed in a facility includes: receiving sensor data from at least a subset of the location sensors; generating a current location of a mobile reference target within the facility based on (i) the sensor data and (ii) expected positions corresponding to the location sensors; based at least on the current location: (i) selecting at least one of the location sensors, and (ii) setting an inspection indicator for the selected location sensor; presenting sensor status data including the inspection indicator via an output device associated with the mobile reference target; and repeating the generating, the selecting, the setting, and the presenting until inspection indicators have been set for each of the location sensors.

A method of validating a set of location sensors deployed in a facility includes: receiving sensor data from at least a subset of the location sensors; generating a current location of a mobile reference target within the facility based on (i) the sensor data and (ii) expected positions corresponding to the location sensors; based at least on the current location: (i) selecting at least one of the location sensors, and (ii) setting an inspection indicator for the selected location sensor; presenting sensor status data including the inspection indicator via an output device associated with the mobile reference target; and repeating the generating, the selecting, the setting, and the presenting until inspection indicators have been set for each of the location sensors.

A heat alarm unit includes a housing and a button assembly. The housing has a central axis and defines an opening disposed substantially normal to like housing. The button assembly is exposed through the opening and is constructed and arranged to move with respect to the housing. The button assembly has a support structure and a heat sensor supported by the support structure.