======== Lufft R2S (Radar Rain Sensor) =========
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* Dimensions: (diameter x length) 90mm x 220mm
* Weight: approximately 4.5 kilograms
* Black aluminum sensor housing
* Heated plastic dome
* Easy installation
==== Features ====
* Maintenance free precipitation sensor
* Differentiation between rain / snow
* Determination of quantity (1mm, 0.1mm, 0.01mm)
* Interface: RS485 and 2 digital outputs
* Can be configured for replacing tipping bucket systems
==== Storage and Operating Conditions ====
* Storage temperature: -40°C to +70°C
* Relative humidity: 0 to 100% RH
* Operating temperature: -40°C to +60°C
* Relative humidity: 0 to 100% RH
==== Installation Procedures ====
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* Sensor can be provided with shield if required distances not met.
==== Connections ====
* There is an 8-pole screw-in connector on the underside of the device.
* This serves to connect the power supply and the interfaces using the associated connection cable.
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* 1 negative power supply
* 2 positive power supply
* 3 RS485_A
* 4 RS485_B
* 5 not assigned
* 6 Uout1
* 7 GND reference potential for the digital outputs
* 8 Uout2
==== Interface ====
* Data bits: 8
* Stop bit: 1
* Parity: none
* Settable baud rates: 1200, 2400, 4800, 9600, 14400, 19200, 28800, 57600
* 19200 is factory setting and baud rate for firmware update
==== Electrical Data ====
* Power supply: 20 to 30 VDC; typically 24 VDC
* Power consumption: < 100 mA (heating off)
* Heating duty 30VA
* Protection class: III (SELV)
==== Digital Outputs ====
* The Uout1 and Uout2 digital outputs are short-circuit proof high side switches (12V) with integrated pull-down resistors.
* Possible configurations for Uout1 are:
* Tipping bucket simulation with 1mm, 0.1mm, or .01mm resolution
* Length of the output pulse for this simulation is typically 50 milliseconds
* Type of precipitation is transmitted on output Uout2 in the form of different frequencies.
^ Precipitation Type ^ Frequency/Hz ^
| Dry | 0 |
| Rain | 10 |
| Snow | 20 |
| Sleet | 30 |
| Freezing Rain | 40 |
| Hail | 50 |
* If accumulated precipitation quantity is greater than 0.01mm, the frequency signal is transmitted for 2 minutes.
* The output of the frequency signal is maintained if a precipitation quantity greater than or equal to 0.01mm is measured within 2 minutes.
==== Configuration ====
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* Factory setting
* Device ID: 1
* Baud rate: 19200
* RS485 protocol: binary
* ID must be changed if several R2S devices are operated in a UMB network.
* **Drizzle detection**:
* When activated, measurement takes place with greater sensitivity.
* Identifies water droplets with a diameter of 0.3mm.
* The only disadvantage is that the high sensitivity may cause a slightly higher water quantity to be measured.
* **Hail detection**:
* If hail detection is activated, the side shield must be installed in all cases.
* The measurement signal reacts to movements (e.g. trucks) of up to 72 km/h
* Movements are interpreted as precipitation.
* Since the fall speed is identical, very large water droplets may be interpreted as small hail
* **Evaporation per day**:
* Simulate the natural evaporation of a tipping bucket
* A defined value is deducted from the rainfall quantity every minute.
* This is set at 0.24mm per day in the delivered condition.
* **Rainfall, Snowfall, and Hail correction factor**:
* The water quantity is assessed with this factor.
* The three particle types (rain, snow and hail) are added together and the precipitation type is assessed every minute.
* Requests 1-4 are carried out.
* They only take place if previous conditions are unfulfilled.
* __The factors cannot be changed__.
1) Number of hail particles per minute > 40% (Hail factor)
* Precipitation type = Hail
2) Number of rain particles > 90% (Freezing Rain factor) and ambient temperature <= 0°C
* Precipitation type = Freezing rain
3) Number of rain particles >20 % (Sleet factor) and ambient temperature in the range from –5°C to 4°C:
* Precipitation type = Sleet
4) Number of rain particles > 50% (Rain factor) :
* Precipitation type = Rain
**If none of the 4 conditions is met but particles were measured, the precipitation type is snow.**
* Adjustment values:
* The range of the rain sensor measurement spectrum is from 130Hz (drizzle) to 1600 Hz (heavy rain).
* This range is divided into 23 zones, which can be individually corrected with factors from 0.1 to 10.
==== Theory ====
* Doppler radars measure velocity by estimating the frequency-shift produced by an ensemble of moving targets.
* Doppler radars also provide information about the total power returned and about the spectrum width of the precipitation particles within the pulse volume.
* The reflected signal is the result of the energy from the transmitted pulse interacting with precipitation (snow, ice pellets, hail, and rain) particles.
* A small portion of the power is then returned to the radar and analyzed to determine an estimate of the rain or snow rate.
* The relationship between the size and power return is highly non-linear.
* An example is a very small, spherical drop.
* If you double the size of a the drop, you increase the reflected power return by a factor of 64.
* If you triple the size of the drop, you increase the reflected power return by a factor of 729.
* Polarimetric radars are designed to eliminate this problem.
**Precipitation Rates**
* Example of two scenarios with identical rain rates:
* Rain water concentrated in a very small number of large drops.
* Rain water concentrated in a very large number of small drops.
* Reflected power returned to the radar is heavily weighted towards the largest drops.
* If only using the returned power to estimate rain rate, you might end up with either a significant overestimation or a significant underestimation of the rain rate.
* Radar power returned from irregular shaped mixtures of precipitation types can get quite complicated.
* The rainfall rate (R) is a product of the mass content and the fall velocity in a radar volume.
* Precipitation rate depends on particle size distributions.
* The natural variability in drop-size distributions is an important source of uncertainty in radar measurements of precipitation.
* Precipitation is usually measured by using the Z-R relation:
* Z = ARb
* A and b are constants.
* This relationship is not unique.
* Many empirical relations have been developed.
* Typical values for the index and exponent are A = 200, b = 1.60
**Radar Equation**
* Pr = (C |K|2 Z)/r2
*|K|2 is the refractive index factor of the target
* r is the slant range from the radar to the target (meters)
* Z is the radar reflectivity factor (usually taken as the equivalent reflectivity factor Ze when the target characteristics are not well known), in mm6 m-3.
* C is the radar constant.
**Attenuation**
* Attenuation by hydrometeors can result from both absorption and scattering.
* It is dependent on the shape, size, number and composition of the particles.
* Attenuation is dependent on wavelength.
* At 10 cm wavelengths, the attenuation is rather small while at 3 cm it is quite significant.
* Wavelengths below 5 cm are not recommended for good precipitation measurement except for short-range applications.
* The attenuation is dependent on water mass of the target.
* Ice particles attenuate much less than liquid particles.
* Snow or ice particles (or a hailstone) can grow to a size much larger than a raindrop.
**Radar Wavelength**
^ Band ^ Frequency ^ Wavelength ^
| UHF |300-1000 MHz | 1-0.3 m |
| L | 1-2 GHz | 30-15 cm |
| S | 2-4 GHz | 15-8 cm |
| C | 4-8 GHz | 8-4 cm |
| X | 8-12 GHz | 4-2.5 cm |
| K | 18-27 GHz | 1.2 – 0.75 cm |
* The larger the wavelength, the greater the cost of the radar system.
* This is due both to an increase in the amount of material and to the difficulty in meeting tolerances over a greater size.
* Bands of weather radar interest include S, C, X and K.
* The sensitivity or ability of the radar to detect a target is strongly dependent on the wavelength.
* For the same antenna, the target detectability increases with decreasing wavelength.
* The shorter wavelengths provide better sensitivity.
* The disadvantage is that the smaller wavelengths have much larger attenuation.
==== Field Work ====
* The Surface Transportation Weather Research Center (STWRC), along with the North Dakota Department of Transportation, established the STWRC Road Weather Field Research Facility (RWFRF) in late 2006.
* The purpose of this site is to understand better the physics associated with the interactions between the atmosphere and the roadway.
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* All observations are presented in 1-minute intervals.
* Evaluates the performance of the precipitation sensor.
* Provides monitoring of precipitation events.
* **Road Weather Field Research Topics Online:**
* Overview of the facility
* Field Site Data
* 24 hour Observations
* http://stwrc.und.edu/timeplot/rwfrf.html
* Pavement Condition Model Validation
* Lufft R2S Observed Precipitation
* RWFRF Camera Images
==== Maintenance/Cost ====
* Service and maintenance is carried out by a trained specialist.
* The recommended service interval is 12 months.
* The device must be disconnected from the power supply.
* Estimated cost for Lufft R2S system:
* $3000-4000
==== Calibration ====
* The device is calibrated in the factory.
* The recommended calibration interval is 24 months.
* An onsite calibration service is available on enquiry.
* Testing of the signal processor with known artificially generated signals.
* Doppler calibration includes verification and adjustment of phase stability using fixed targets or artificial signals.
* The presence or absence of echoes from fixed ground targets may also serve as a crude check of transmitter or receiver performance.
==== References ====
* Lufft R2S Precipitation Sensor Manual. 2006.
* __RADAR for Meteorologists.__ Rhinehart. 2004.
* Surface Transportation Weather Research Center. http://stwrc.und.edu/. 2008.