![](pixel.gif)
![Home page button](Assets/BtnHomePageGray.gif)
![](pixel.gif)
![Sponsors button](Assets/BtnSponsorsGray.gif)
![](pixel.gif)
![Site map button](Assets/BtnSiteMapGray.gif)
![](pixel.gif)
![Search button](Assets/BtnSearchGray.gif)
![](pixel.gif)
![Contact us button](Assets/BtnContactUsGray.gif)
![](pixel.gif)
![Solar data button](Assets/BtnSolarDataGray.gif)
![](pixel.gif)
![About our data button](Assets/BtnAboutOurDataGray.gif)
![](pixel.gif)
![Monitoring stations button](Assets/BtnMonitoringStationsGray.gif)
![](pixel.gif)
![Instruments button](Assets/BtnInstrumentsGray.gif)
![](pixel.gif)
![Software tools button](Assets/BtnSoftwareToolsGray.gif)
![](pixel.gif)
![Educational material button](Assets/BtnEducationalMaterialGray.gif)
![](pixel.gif)
![Publications button](Assets/BtnPublicationsGray.gif) |
![](pixel.gif) |
![](pixel.gif)
YES Multifilter Rotating Shadowband
Radiometer (MFR-7)
![](pixel.gif)
The Multifilter Rotating Shadowband Radiometer
(MFR-7) measures total, diffuse, and direct irradiance with a broad-band silicon
pyranometer and at six wavelengths using sensors with narrow band filters at 415, 500,
615, 673, 870, and 940 nanometers. The full width half maximum width is ten nanometers.
The head, where the sensors are located, is thermally stabilized to significantly reduce
uncertainties associated with temperature variation. The MFR-7 makes measurements
simultaneously across all seven channels. The shadowband enables the instrument to
measure the global and diffuse components of solar irradiance and then calculate the
beam component. The MFR-7 system includes the YESDAS-2 datalogger.
The shadow band is controlled by a microprocessor.
Measurements can be made as frequently as one every 15 seconds and averaged or stored
individually. In Eugene, we make one measurement every minute. First the shadowband is
positioned to the east side of the entrance aperture, then it completely shades the
aperture, and then it moves to the west side of the aperture. The measurements made
when the shadowband is to the east or west of the aperture are used to correct for the
shading of the sky by the shadowband itself.
Global values are determined when the shadowband
is at rest, and diffuse measurements take place when the aperture is shaded. The diffuse
values are adjusted by adding back the amount of the sky shaded by the shadowband not
blocking the sun. The corrected diffuse is then subtracted from the global and the
horizontal beam is projected back onto the direct normal.
The broadband diffuse measurement has the same
problem experienced by the sensor in an RSP. Responsivity of the sensor to
diffuse radiation is different on cloudy days: it is about 30 percent higher than the
responsivity of the sensor to diffuse radiation on clear days. Both sensors are solar
cell based and they experience the same problem. The narrowband sensors are spectrally
selective and don't experience this problem.
The MFR-7 wavelengths are chosen to allow the
reconstruction of the incident solar spectral irradiance and the determination of
optical depths of water vapor, aerosols, and ozone (using the Chappuis ozone
absorption bands).
![](pixel.gif)
MFR-7 Radiometer Assembly
![](pixel.gif)
The MFR-7 Radiometer Assembly consists of the
MFR-7 sensor head along with a rotating shadowband that is driven by a stepper motor: both
are mounted
on a common base. An electronics enclosure, mounted below the Detector Assembly,
contains a YESDAS microprocessor-driven data acquisition and control system. The
system electronics has 13-bit A/D conversion accuracy and has the capability of
collecting data from an additional 24 analog and six pulse/counting-type
meteorological sensors.
![](pixel.gif)
Specifications
![](pixel.gif)
|
![](pixel.gif)
Spectral Response: 415, 500, 615, 673,
870, and 940, each 10 nanometers FWHM, plus a Si-based broadband
channel |
|
![](pixel.gif)
Cosine Response: Better than 5% for
0-80° zenith angle; better than 1% with corrections |
|
![](pixel.gif)
Operating Range: -30° C to +50°
C |
|
![](pixel.gif)
Power Requirement: 115/230 VA, 50/60 Hz,
50 Watts (maximum) or 12 Vdc at 1A (typical), 3A (maximum) |
|
![](pixel.gif)
Sampling Rate: Up to 4
samples/minute |
|
![](pixel.gif)
Communication: RS-232 port, or
user-supplied modem |
|
![](pixel.gif)
System Memory: 32 Kbytes; expandable
to 2 Mbytes |
![](pixel.gif)
![](pixel.gif)
(Above: interior optical detector assembly)
![](pixel.gif)
Control and Data Logging System
![](pixel.gif)
The MFR-7 instrument operation and data logging
are controlled by a microprocessor. This on-board CPU: 1) performs the required
ephemeris calculations, 2) controls the stepper motor which positions the shadowband,
3) controls the acquisition, processing and storage of sensor data for the MFR-7 and
up to 24 additional analog meteorological sensors, and 4) permits simultaneous data
telemetry. The very stable system time keeping (with an accuracy of 1 second per
month) ensures that the positioning of the shadowband will be precise over extended
time periods, with no need for operator intervention or adjustment.
The system data logger includes a state-of-the-art
13-bit self-calibrating analog-to-digital converter and on-board data storage
capability of up to two Mbytes with the PCMCIA-2 memory option. Most MFR-7 users
will need the two Mbyte card to permit high time resolution sampling. You can
communicate directly from a PC, Macintosh, or UNIX workstation through a serial port
(3m cable provided) or over a phone line using a user-supplied modem. The user may
download the stored data and has full control over the data acquisition process.
Below is a schematic diagram of the control and data logging system.
![](pixel.gif)
![](pixel.gif)
Calibration Facilities
![](pixel.gif)
The usefulness of any instrument depends critically
on the quality and long-term stability of its calibration. Yankee Environmental Systems,
Inc. has fully equipped optical laboratories to completely characterize the performance
and calibrate each MFR-7 instrument. The cosine, spectral, and absolute responses of
each wavelength channel of the instrument are measured with NIST-traceable optical and
electronic equipment and test results are supplied with each system. Interference filters
deteriorate over time and yearly recalibrations of the MFR-7 are recommended.
![](pixel.gif)
Spectral Response
![](pixel.gif)
The spectral response of each wavelength channel
of the MFR-7 instrument is measured in YES's laboratory. Below is a graph showing
the typical filter passbands of an MFR instrument.
![](pixel.gif)
![](pixel.gif)
Absolute Response
![](pixel.gif)
![](pixel.gif)
The absolute response of each wavelength channel
of the MFR-7 instrument is measured using a 1,000 watt FEL NIST-traceable spectral
irradiance standard light source. The spectral response of the channel and the output
of the instrument in response to the irradiation by the FEL lamp are used to obtain
the channel calibration constant.
![](pixel.gif)
Cosine Response
![](pixel.gif)
The MFR-7 belongs to a class of instruments that
measure flux incident on a horizontal surface. The response of such instruments to
radiation incident at an angle, q, with respect to the surface normal is called the
cosine response. The ideal cosine response is proportional to the cosine of the angle q,
and any deviation from this response introduces measurement errors.
The MFR-7 has a novel
input optic with superb cosine response and long-term stability. The radiation receiver
element is a specially shaped Spectralon diffuser disk that is directly coupled to
a Spectralon integrating cavity. Spectralon is a halocarbon with excellent
resistance to chemical and ultraviolet degradation, thus ensuring calibration stability
in the field. Below is a graph of the ratio of a typical instrument's
angular response to the ideal cosine response:
![](pixel.gif)
![](pixel.gif)
The cosine response of each MFR-7 is fully
characterized in YES's angular test facility. Each instrument is tested by placing it
on a computer-controlled rotary actuator and measuring the instrument response as a
function of its angle with respect to a feedback-stabilized, parallel, uniform light
beam. The individual MFR-7 cosine response, supplied with each instrument, is used by
YESDAS system software to correct, in real time, for deviations from the ideal cosine
response.
![](pixel.gif)
![Image map links to top of page and home page](Assets/ImgMapFooter.gif)
![](pixel.gif)
© 2022, UO Solar Radiation Monitoring
Laboratory.
Last
revised: April 7, 2022.
![](pixel.gif)
![](pixel.gif)
Home page URL: solardata.uoregon.edu |