PMH-2006 Precision Meteorological Hygrometer
The Model PMH-2006 Precision Meteorological Hygrometer is a precision ambient dew/frost point measuring system with chilled mirror dew point sensor for outdoor or indoor test chamber applications. It provides the highest accuracy available on the market. Dew point temperatures above 0°C are determined to an accuracy of ±0.2°C, while frost point temperatures down to -70°C have an accuracy of ±0.5°C, using an intelligent, CPU-managed chilled mirror dew/frost point hygrometer sensor. Above 0°C, the hygrometer tracks the dew point temperature; below 0°C, it tracks the frost point temperature. Sensitivity ±0.01°C. Slew rate typically 1.5°C/second. Zero hysteresis. CPU utilizing DSP technology performs continuous, automatic, and unattended ambient dew point measurements, and performs a daily heat cycle. 0-5VDC analog and digital RS-232 interfaces. NIST traceable.
PMH-2006 PRECISION METEOROLOGICAL HYGROMETER | ||||||||||||||||||||||
DescriptionThe Model PMH-2006 is a precision ambient dew/frost point measuring system designed for the meteorologist, climatologist, or atmospheric scientist. It provides the highest accuracy available on the market. Dew point temperatures above 0°C are determined to an accuracy of ±0.2 C, while frost point temperatures down to -70°C have an accuracy of ±0.5°C, suing an aspirated intelligent, CPU-managed chilled mirror dew/frost point hygrometer sensor. Above 0°C, the hygrometer tracks the dew point temperature; below 0°C, it tracks the frost point temperature. Historically, techniques other than direct measurement of ambient temperature have provided support for the global warming issue, but precise knowledge of atmospheric water vapor is also a fundamental component to understanding the Earth's climatic mechanisms and hydrological cycles. Observational errors in climatic water vapor measurements can be reduced using the PMH-2006. Features
ApplicationsThe PMH-2006 offers more precision than existing ambient humidity measuring systems, making it ideally suited for:
Mechanical ConfigurationThe PMH-2006 electronics are packaged in a weatherproof NEMA-type PVC enclosure. Electrical
PMH-2006 systemand mechanical components are designed to operate over a temperature span of ±50°C; reduced aspirator motor life can be expected when system installation temperatures are below -50°C due to bearing lubricant degradation. The system typically mounts two meters above the ground to a customer tower or support. Digital Output Data FormatThe RS-232 serial digital output is used to fully cover the resolution and precision of measurements. The output stream is similar to other automated surface observation system thermohygrometers (e.g. the TSL Model 1800). The PMH-2006 responds to a "T" string at the serial port with a constant length record. This includes a T echo; then a five-digit-long right-justified dew/frost point temperature value (selectable as °C or °F via an on-board jumper); followed by a mirror status and blower status; terminating with CR and LF characters. An example of a PMH-2006 fixed length output record follows: T 22.54 DIRTY=0 FANFAIL=0 PMH-2006 functional block diagram Internal CPU OperationThe PMH-2006 is controlled by an embedded microprocessor CPU that serves several functions:
Electrical ConnectionsTwo foil-shielded 10' (3m) long cables are supplied with pig tails for interface to the user's junction box:
Cable runs are possible up to 50' via a user cable splice or junction box. Both DCE and DTE RS-232 serial interfaces can be interfaced.
Available Options
Development HistoryThe PMH-2006 is a subset of the Model MET-2010, itself the result of an intensive five-year R&D effort, sponsored in part by the United States Department of Agriculture, to develop and field test an improved means of measuring ambient temperature at climatological monitoring sites. The MET-2010 represents the first major improvement in air temperature measurement since the introduction in the 1970s of the Gill radiation shield.
The measurement of ambient air temperature is fundamental to the study of global climate and climate change mechanisms. Assessing the degree of global warming occurring from the increase of so-called "greenhouse gases" has been frustrated by variations in long-term temperature records due to earlier ambient temperature sensors that had calibration drifts. These variations stemmed from a variety of factors, including changes in the technology of measurement, methods of exposing the instrument, frequency of data collection, methods of calibration, and the training and dedication of the person collecting the data.
Specifications
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