A lidar system for detection of a gas comprises an optical transceiver for transmitting and receiving optical radiation. A method of operating the system comprises performing spatially scanned sensing measurements of the gas across a system field of view, and analyzing the sensing measurements to determine the presence and location of excess of the gas in the system field of view. Based on the determined location, an adjusted system field of view is determined and spatially scanned sensing measurements of the gas are performed across the adjusted system field of view to obtain sensing measurements at higher spatial resolution.

The present disclosure provides a Scheimpflug LIDAR apparatus for detecting a property of a gas comprising: a light source configured to emit a light along at least a first axis, a light detection arrangement, and an optical configuration fulfilling the Scheimpflug condition and Hinge rule. The light source comprises an expander aperture, and wherein the expander aperture and light detection arrangement are configured such that: a spot size of the emitted light along the first axis is matched to a pixel footprint of pixels configured to receive light from corresponding distances along the first axis, and an effective range resolution of at least one column of pixels or probe volume deteriorates linearly with respect to the range.

A monitoring system is presented for monitoring quality of fluid in a fluid chamber. The system includes: a sensing system which comprises sensing units of different types configured to measure multiple parameters of the fluid and generate corresponding measured fluid quality data and to perform self-diagnostic of an operational condition of the sensing system and generate sensing data indicative of sensing quality, and a control system comprising a local controller configured to be responsive to data indicative of a relation between the measured fluid quality data and the sensing quality and selectively generate operational data to initiate one or more of the following: generation of alarm signal indicative of an abnormal condition of the quality of the fluid, correction of the measured fluid quality data in accordance with the sensing quality; and replacement of one or more elements of the sensing units.

A settlement analyser and a method of analysing settlement which employs an array of emitters and at least one array of detectors, wherein the settlement analyser is configured to analyse a sample placed or otherwise located between the array of emitters and the at least one array of detectors by sequentially emitting light from the array of emitters, and detecting light which arrives at the at least one array of detectors via the sample volume. Repeating this sequence allows an optical profile of the sample to be determined as a function of time. The sequence may be a linear sequence, or it may be a non-linear sequence, and light from a particular emitter may be detected by several different detectors in order to increase the resolution of the analyser and the method. The analyser and the method may thereby identify the location of boundaries or interfaces between different layers in a sample once settled and during settlement. Furthermore, measurements obtained by the settlement analyser and method may be used to determine one or more properties of the sample, including MLSS concentration, SV30 number and SVI value. In one embodiment one or more settlement analysers may be comprised in an apparatus which may be located in a process or flow and thereby obtain and analyse samples directly from the process or flow, and in another embodiment a stand-alone analyser is able to receive and analyse samples within sample holders.

The present invention relates to a photoelectric smoke detector having a double-bulkhead darkroom structure and, more particularly, to a photoelectric smoke detector having a double-bulkhead darkroom structure, comprising: a base having, on one side thereof, a light emitting element receiving part in which a light emitting element for irradiating light to the inside thereof is mounted and, on the other side thereof, a light receiving element part in which a light element for receiving scattered light generated by smoke particles from the light irradiated by the light emitting element is mounted; an outer bulkhead which protrudes toward a lower side of the base to form an outer wall of the smoke detector and in which a smoke inlet having a specific height is formed in a circumferential direction; a lower end surface coupled to a lower end of the outer bulkhead; and an inner bulkhead which protrudes from the lower end surface to an upper side, is disposed to be spaced apart from the outer bulkhead at a specific interval, and is formed to have a height smaller than the height of the outer bulkhead so as to form a gas flow area in an upper portion thereof, wherein smoke flows in through the smoke inlet and passes through a space between the outer bulkhead and the inner bulkhead, and the gas flow area.

A water quality and flow monitoring and control apparatus, method and system installed at an end user location and being capable of monitoring one or more of the following water quality parameters: microorganisms (including E. coli), mineral or other ion concentration, pH, temperature, and turbidity. The system also has a water meter that detects the flow of water and has a valve to shut the flow of water off upon detecting a fault condition such as a leak.

To provide a fire sensing system, fire sensing method, and program with which it is possible to identify the position of a fire using a low number of sensors A fire sensing system 1 provided with: gas sensors 11a, 11b, 11c for sensing a change in gas concentration at three locations P.sub.1, P.sub.2, P.sub.3; a gas propagation speed calculation unit 12 for sensing gas concentration increase times T.sub.1, T.sub.2, T.sub.3 at the three locations P.sub.1, P.sub.2, P.sub.3 and calculating the gas propagation speeds v.sub.1, v.sub.2, v.sub.3 at the three locations P.sub.1, P.sub.2, P.sub.3; and a fire information estimation unit 13 for estimating the position of the fire on the basis of the gas concentration increase times T.sub.1, T.sub.2, T.sub.3 and the gas propagation speeds v.sub.1, v.sub.2, v.sub.3.

A sensor analysis computer device for analyzing particulate matter is provided. The computer device includes at least one memory and at least one processor in communication with the at least one memory. The computer device is in communication with a sensor configured to measure particulate matter. The at least one processor is programmed to store a plurality of parameter data for the sensor including a calibration factor, receive a plurality of sensor data from the sensor, determine a present calibration factor based on the plurality of parameter data and the plurality of sensor data, determine an updated calibration factor for the sensor based on the present calibration factor and the plurality of parameter data, and transmit the updated calibration factor to the sensor, wherein the sensor is configured to adjust subsequent sensor data based on the updated calibration factor.

A method of operating a detection system includes switching the system from a normal mode for sensing smoke to a high sensitivity mode for sensing airborne particles, such that in the high sensitivity mode the detection system is configured to discriminate between particles of diameters less than 2.5 micrometers and 10 micrometers. Transmitting light from one or more light sources of the detection system into a monitored space, and detecting scattered light at one or more light sensing devices of the detection system. The detection of scattered light is indicative of one or more indoor air quality conditions in the monitored space.

A method is provided for detecting a property of a gas comprising: emitting a light, comprising a plurality of wavelengths covering a plurality of absorption lines of the gas, along a first axis, the light being scattered by particles of the gas resulting in a scattered light, generating a sensor image using a detection arrangement configured to receive the scattered light and comprising: an optical arrangement having an optical plane and being configured to direct the scattered light on to a light sensor, the light sensor having at least one pixel columns, wherein the pixel columns are aligned to an image plane and configured to output a sensor image, wherein the first axis, the optical plane, and the image plane intersect such that a Scheimpflug condition is achieved, determining, from the sensor image, properties of the gas at a plurality of positions along the first axis.