IAPRS & SIS, Vol.34, Part 7, "Resource and Environmental Monitoring", Hyderabad, India,2002 
  
  
Johannesen et al., 2000). These results and their consequences 
have thrown open interesting and intriguing questions about 
modeling climate change in the face of envisaged greenhouse 
warming. 
In view of the great importance attached to the role of 
secularly (slowly) changing sea ice cover over the polar 
regions in relation to future of global climate, it is extremely 
important that each of the pace-based PMRs providing sea 
ice information be calibrated absolutely and inter-calibrated 
relative to each other. Due to well known difficulties 
associated with collection of sea truth at the desired spatial 
scales in the harsh polar environment, most of the efforts have 
concentrated on relative calibration between sensors. Space- 
based Landsat and NOAA  Visible/IR band high resolution 
images of polar sea ice region obtained during sunlit and 
cloud free seasons/situations have been employed to obtain 
and compare sea ice extent estimates derived from passive 
microwave measurements. Short overlap between different 
microwave sensors e.g. between SMMR and SSM/I during 
1987 and between successive SSM/I sensors later on has 
played a key role in the inter-calibration of sea ice estimates 
from SMMR and SSM/. As a result we now have a highly 
reliable 25 year long time series of sea ice measurements over 
the Arctic and Antarctic regions (Comiso, 2000, Hanna and 
Bamber, 2001, Gloersen et al., 1992). It may be mentioned 
that this period has seen many important natural and human- 
induced changes in the planetary atmosphere and the ocean 
e.g. the occurrence of ‘ozone hole’ and several strong El-Nino 
events which impact significantly on the global climate. 
In this paper, ve present an inter-comparison of simultaneous 
and coincident MSMR and 5SSM/ based brightness 
temperature measurements as well as the estimated sea ice 
characteristics from the two sensors. 
2.0 MSMR AND SSM/I 
MSMR onboard OCEANSAT-1 is a four frequency, eight 
channel dual polarised Dicke switched PMR system operating 
at 6.6, 10.65, 18 and 21 GHz. MSMR carries a black body 
maintained at ambient system temperature and it has cold 
space viewing horns for calibration of all the radiometers. The 
extensive initial pre-launch calibration is carried out on 
ground. The calibration performance and stability of the 
radiometers have been analysed by Misra et al. (2002). All the 
radiometers are shown to have a temperature sensitivity of 
better than 1 K. Ali et al. (2000) have attempted the validation 
of various geophysical parameters derived from MSMR over 
the tropical region. 
SSM/I is a similar dual polarisation total power radiometer 
system operating at 19.35, 22.235, 37 and 85.5 GHz, with 
22.235 GHz channel providing only vertical polarization 
information. It also incorporates cold (sky horn) and hot 
(reference absorber) calibration targets. After extensive 
calibration and validation studies, SSM/I data products have 
been made available on an operational basis. 
For relative calibration of the MSMR observed brightness 
temperatures as well as derived geophysical (sea ice) 
parameters over the polar regions, we make use of the 
simultaneous SSM/I measurements over the Antarctic region. 
Characteristics of MSMR and SSM/I sensors along with the 
orbital platforms from which they operate are summarized in 
Table-1. Both MSMR and SSM/I are conically scanning 
410 
multi-frequency passive microwave radiometers. However, 
there are several differences e.g. available frequency 
channels and their center frequencies, the incidence angle, 
the coverage swath, maximum north and south latitude 
attainable and the local time of observations etc. While most 
of these are minor differences as far observing Antarctic sea 
ice is concerned, these must however be kept in mind during 
the inter-comparison exercise. Since, 18/19 GHz channel is 
the most suitable common ‘channel between MSMR and 
SSM/L in providing surface characteristics with reasonably 
good atmospheric transparency and with acceptably high 
spatial resolution, we have restricted our analysis to data 
from this channel. This channel is also common between the 
three most used sensors for sea ice research viz. SMMR, 
SSM/I and MSMR. Moreover, for developing the 
algorithms for estimation of sea ice concentration, we have 
used brightness temperatures of 10 and 18 GHz channels of 
MSMR to derive the polarization and spectral gradient 
ratios (Gloersen et al, 1992) to be used as in-dependent 
variables. 
Table —1: Characteristics of MSMR and SSM/I 
  
  
  
  
  
  
  
  
  
Satellite OCEANSAT-1 DMSP -5D 
Launch May 26, 1999 1987... 
Orbit Polar Polar 
Sun-Synchronous Sun-Synchronous 
Orbital Height | 720 830-860 
(Km) 
Orbital 98.28 98.8 
Inclination 
(Deg) 
Equatorial 12 noon 06:15 
Crossing Time 
Sensor MSMR_ SSM/I | 
Frequency 6.6, 10.65,18, 21 19.35 22.235 1.31, 
(GHz) 85.5 
Polarisation H & V all H&V 
channels (22.235 V-only) 
Scanning Off-nadir Conical | Off-nadir Conical 
Incidence 49.7 53.1 
Angle (Deg.) 
Swath (Km) 1360 1390 
Repetivity Two days Two days 
  
  
  
  
  
3.0 ANALYSIS OF BRIGHTNESS TEMPERATURES 
FROM MSMR AND SSM/I 
Fig. 1 provides a guide -map of the Antarctic region showing 
various features of the continental ice as well as various 
sectors of the Southern Ocean. It also shows small regions 
over which MSMR — SSM/I comparison analysis is made. 
In order to inter-calibrate MSMR observed brightness 
temperatures with those from SSM/I, sample SSM/I data 
sets covering the summer and winter seasons over the 
Antarctic region were obtained from NASA/GSFC. The 
SSM/I 19.35 GHz Tb values available at 25 km resolution 
were first averaged using a 2x2 pixel window and then 
resampled at 0.5 deg. x 0.5 deg. resolution to make these 
observations compatible with MSMR. The SSM/I observed