PDS_VERSION_ID        = PDS3
RECORD_TYPE           = STREAM

OBJECT                = TEXT
   PUBLICATION_DATE    = 2011-07-15
   NOTE                = "Description of contents of DATA directory"
END_OBJECT            = TEXT
END

The data products in the DATA directory correspond to NASA Level 2, or PDS 
Level 5 Derived Data. According to the PDS Standards Reference, these are 
"derived results, as maps, reports, graphics, etc." Each image has an 
accompanying detached PDS label. 

The data set consists of 5 image files for each region mapped during a 
typical 29-minute radar integration period. The images are named as follows: 
XXXXXX_SCP.IMG (same-sense circular polarization map), XXXXXX_OCP.IMG 
(opposite-sense circular polarization map), XXXXXX_ANG.IMG (map of beam 
angle in radians), XXXXXX_INC.IMG (map of incidence angle in radians), and 
XXXXXX_CPR.IMG (circular polarization ratio image), where XXXXXX is the 
center latitude and longitude of the radar pointing target over the 
observation period. This is expressed as XX deg N (for north latitude) or S 
(for south latitude) followed by the east longitude in degrees (for example, 
20N310 corresponds to 20 degrees north latitude, 310 degrees east 
longitude). North is at the top of the frame in all of these images.

For the polarized ("OCP") and depolarized ("SCP") maps, the floating point 
values represent the estimated dimensionless backscatter coefficient (often 
called sigma-zero) of the lunar surface at a radar wavelength of 12.6 cm 
(2380 MHz frequency). 'Polarized' refers to energy scattered from the lunar 
surface in the opposite circular polarization sense to that transmitted (the 
behavior expected of a flat, mirror-like reflecting surface). 'Depolarized' 
refers to reflected energy with the same sense of circular polarization (the 
behavior expected from a surface with abundant wavelength-scale objects that 
randomize the reflected polarization).

The data were collected by transmitting a continuous-wave, circular 
polarized signal from the Arecibo Observatory, and receiving the lunar 
echoes at the Robert C. Byrd Green Bank Telescope (GBT) in West Virginia. 
The transmitted signal was a 65535-sample pseudo-random code with baud 
length of 0.2 microseconds. The resulting 13.17-millisecond period between 
pulses allows for the full possible range of echo time delays over the 
Moon's surface. The reflected signals were recorded at the GBT using 4-bit 
analog-to-digital conversion, 5-MHz sampling rate, and a 4.4-MHz Gaussian 
lowpass filter. Pulse compression was carried out to recover the intrinsic 
2-microsecond delay resolution. A patch focusing method was used to correct 
for time-varying Doppler changes at lunar surface points distant from the 
radar pointing target. Multiple independent integration periods (looks) were 
added together to reduce radar speckle.

Image power values were normalized to the effective scattering area that 
contributes to each pixel (based on a reference spherical shape) and to the 
thermal background noise measured at the Green Bank Telescope. Subtraction 
of this background noise level can lead to small negative values of the 
backscatter coefficient where the signal-to-noise ratio (SNR) of the echoes 
is close to unity. The effect of the two antenna beam patterns on the gain 
across the lunar surface is also compensated to first order, and pointing 
errors at Arecibo are estimated and accounted for in this calibration step. 
Final calibration to values of the dimensionless backscatter coefficient is 
performed by comparing the GBT thermal noise to that of a quasar of known 
flux at 2380 MHz. To date, these calibrated values are consistent over 
numerous radar observing periods, but are systematically lower (by a factor 
of 6-10 in power) than values measured by previous investigators. Ratios 
between the two circular polarization channels are well calibrated, since 
they depend only upon determination of the relative noise power in the two 
received channels. The "OCP" and "SCP" images are further normalized to the 
cosine of the radar incidence angle for a reference sphere (given in the 
"INC" files) at each location. The stated location of the sub-radar point at 
2380 MHz is an approximate value at the start of the multi-look observing 
period.

In addition to the "OCP" and "SCP" images, the archive also includes "CPR", 
"ANG", and "INC" images. The "CPR" image files are circular polarization 
ratio images formed by averaging pixels over a 5x5 moving window, and 
dividing the averaged "SCP" data by the averaged "OCP" data. No other 
normalization is performed, so the polarization ratio images have a strong 
decrease toward the center of the Moon (lower incidence angle). Note that in 
areas of low SNR, occasional negative values of the CPR could occur due to 
the subtraction of the background thermal noise. Values of unity and greater 
are typical of rough surfaces, particularly at high incidence angles where 
the diffuse scattering component dominates the echo. 

The other image files ("ANG" and "INC") display the beam angle and incidence 
angle, respectively, in radians for each pixel. These co-registered maps, in 
floating point format, will allow a user to reverse the applied calibration 
steps if desired. The beam angle value for each pixel represents the angle 
(in radians) between a vector from the observer to the surface location and 
the vector from the observer to the radar pointing target given for each 
map. The incidence angle value for each pixel represents the angle (in 
radians) between a vector from the Moon's center of mass (COM) to the 
surface location and the vector from the COM that passes through the 
sub-radar point. Values near the radar-visible limb of the Moon thus 
approach 90 degrees.
    
Please see slrm_ds.cat for information about known problems with the data.

Please see CAMPBELLETAL2010 for more details on the 12.6-cm wavelength radar 
mapping and calibration.