Abstract: A wireless bollard that is adapted to house electrical and electronic devices and includes an anchor base, equipment stand and an exterior shell. The anchor base is adapted to be attached to a ground level surface. The equipment stand is mounted within the wireless bollard, where the equipment stand is adapted to receive and support at least one device. The exterior shell fits over the equipment stand and is adapted to protect the device and allow transmission of wireless signals, where the exterior shell is mounted to the anchor base and has a shape that is taller than is wide.

Abstract: An environmental monitor device with a database comprises a data bus, a multitude of sensors, at least one processing unit, input/output device(s); communications interface(s), and memory. Communications interface(s) communicate with at least one environmental sensor device comprising with a multitude of sensors. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one environmental sensor device; store at least some of the sensor data in at least one database; and generate a report of sensor data that exceeds at least one threshold.

Abstract: An environmental monitoring device comprises a data bus, a multitude of sensors, at least one processing unit, input/output device(s); communications interface(s), and memory. Communications interface(s) communicate with at least one environmental sensor device comprising with a multitude of sensors. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one environmental sensor device; and generate a report of sensor data that exceeds at least one threshold.

Abstract: An environmental sensor device with alarms comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, and set alarm(s) based, at least in part on processed sensor data. The communications interface is configured to communicate the report to at least one external device.

Abstract: An environmental sensor device with thresholding comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, determine at least one threshold, and generate report(s) that comprises processed sensor data that exceeds at least one threshold. The communications interface is configured to communicate the report to at least one external device.

Abstract: An environmental monitor device with a database comprises a data bus, a multitude of sensors, at least one processing unit, input/output device(s); communications interface(s), and memory. Communications interface(s) communicate with at least one environmental sensor device comprising with a multitude of sensors. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one environmental sensor device; store at least some of the sensor data in at least one database; and generate a report of sensor data that exceeds at least one threshold.

Abstract: An environmental monitoring device comprises a data bus, a multitude of sensors, at least one processing unit, input/output device(s); communications interface(s), and memory. Communications interface(s) communicate with at least one environmental sensor device comprising with a multitude of sensors. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one environmental sensor device; and generate a report of sensor data that exceeds at least one threshold.

Abstract: A patient satisfaction sensor device comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include light sensor(s), sound sensor(s), humidity sensor(s), temperature sensor(s), air quality sensor(s), and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, and generate a report that comprises processed sensor data that exceeds at least one threshold. The communications interface is configured to communicate the report to at least one external device.

Abstract: An air quality sensing and/or monitoring device comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, and generate a report of processed sensor data that exceeds at least one threshold. The communications interface is configured to communicate the report to at least one external device.

Abstract: An environmental sensor device with alarms comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, and set alarm(s) based, at least in part on processed sensor data. The communications interface is configured to communicate the report to at least one external device.

Abstract: An environmental sensing system comprises environmental sensing device(s) and monitoring device(s). Environmental sensing device(s) and monitoring device(s) may comprise a data bus, at least one processing unit, a communications interface, and memory. Environmental sensing device(s) may comprise a multitude of sensors comprising particle counter(s), pressure sensor(s), and/or the like. Environmental sensing device(s) may be configured to collect sensor data from sensor(s), and generate processed sensor data from the sensor data. Monitoring device(s) may be configured to collect processed sensor data from environmental sensing device(s), and report if processed sensor data exceeds at least one predetermined threshold.

Abstract: An environmental sensor device with calibration comprises a data bus, a multitude of sensors, at least one processing unit, a communications interface, and memory. The multitude of sensors may include particle counter(s), pressure sensor(s) and/or the like. The memory is configured to hold data and machine executable instructions. The machine executable instructions are configured to cause at least one processing unit to: calibrate at least one of the multitude of sensors; collect sensor data from at least one of the multitude of sensors, generate processed sensor data from the sensor data, and generate a report of processed sensor data that exceeds at least one threshold. The communications interface is configured to communicate the report to at least one external device.

Abstract: A telecommunications enclosure for telecommunications equipment that includes an equipment housing with sealed openings to receive wiring. Each sealed opening having a removable blank so that the sealed opening can be utilized. There being at least two brackets mounted to the inside surface of the top of the equipment housing to receive and secure the telecommunications equipment. There being an enclosure door attached to the equipment housing to close off the open end of the equipment housing. The enclosure door being removable to allow access to the equipment housing. The enclosure door having perforations covering at least 30 percent of the enclosure door to allow airflow to flow in and out of the enclosure door when in a closed position on the equipment housing. The enclosure door having a depth such that a portion of the enclosure door with all of the perforations extends in the room.

Abstract: A ceiling device system for securing a device in a ceiling. The ceiling device system includes a cover plate to simulate a ceiling and has a device opening to receive the device. The ceiling device system includes a sliding mechanism mounted on an inside surface of the cover plate. The sliding mechanism includes a sliding component which moves within an area about the device opening. The ceiling device system includes a lock mechanism connected to the sliding component. The lock mechanism connected such that movement of the lock mechanism moves the sliding component. The ceiling device system includes a device mounting plate with slide tabs to engage the device and mounted to the sliding component of the sliding mechanism. The slide tabs are shaped to slide within the device to lock the device in the device opening of the cover plate due to movement of the sliding component.

Abstract: A POE tapping device for extracting power from a data cable. The POE tapping device includes an input connector, an output connector, a flow through connection, a bridge circuit, and a remote accessory connector. The flow through connection is between the input connector and the output connector, such that there is a direct feed from the first data cable to the second data cable. The bridge circuit is connected to the flow through connection to tap electrical current from the flow through connection, where the bridge circuit has a positive output and negative output to provide electrical current. The remote accessory connector is to be connected to a remote accessory, where the remote accessory connector is connected to the positive output and the negative output of the bridge circuit to receive electrical current from the bridge circuit that was tapped from the flow through connection.