by Ajey Lele
Monday, August 5, 2013
On July 26, 2013, India’s dedicated meteorological satellite INSAT-3D was successfully launched into a geosynchronous transfer orbit (GTO) by an Ariane 5 from Kourou, French Guiana. India already has two operational meteorological satellites in space: the KALPANA and INSAT-3A satellites of India have been in service in geostationary orbit for the past decade. The article puts in context India’s overall investments in the field of metrological satellites at the backdrop of successful launch of INSAT-3D.
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| INSAT-3D prior to its launch last month. The satellite is the latest series of spacecraft developed by India to augment its weather forecasting and climate science capabilities. (credit: ISRO) |
| One of the major reasons India chose to invest in space technologies was to offer assistance to its agriculture sector. |
One of the major reasons India chose to invest in space technologies was to offer assistance to its agriculture sector. India started its space program in 1963 in a very modest fashion by launching sounding rockets to study upper atmosphere. India established its Indian National Satellite System (INSAT) program in 1983. During its initial phase, INSAT series satellites were developed as multipurpose satellites with multiple payloads. Invariably, all these satellites had a meteorological payload on board. This was mainly done because India was not in a position to financially afford a dedicated satellite only for meteorological purposes. Also, India had become a spacefaring nation only during 1980 and thus was in a period of learning and experimentation. Now, after three decades, the launch of a very sophisticated satellite like INSAT-3D indicates that India has come a long way in this field.
INSAT-3D is an advanced weather satellite configured with an improved imaging system and atmospheric sounder. The other Indian weather satellites, KALPANA and INSAT-3A, provides imagery in visible, near-infrared, shortwave infrared, water vapor, and thermal infrared bands. INSAT-3D, though, offers significant improvements over its predecessors. It offers the imaging in the mid-infrared band to provide nighttime pictures of low clouds and fog. Significant improvements in the quality of sensors have taken place during the last decade and, along with cloud pictures, INSAT-3D also can measure the sea surface temperature with much better accuracy.
In addition, INSAT-3D adds a new dimension to weather monitoring through its atmospheric sounding system, which provides vertical profiles of temperature (40 levels from the surface to about 70 kilometers), humidity (21 levels from the surface to about 15 kilometers), and integrated ozone from the surface to the top of the atmosphere. The satellite also has a data relay transponder onboard to collect weather observations from automatic weather stations located at inaccessible areas in deserts, mountains, and bodies of water. IMD and ISRO have already established over 1,800 data collection platforms at various remote places in India. Another key payload of this system is the search and rescue unit, which will pick up distress beacons from users on land, sea, and in air during emergencies. India’s neighbors and islands in the Indian Ocean region will also benefit from this system.
It is important to visualize the launch INSAT-3D in a larger framework. For last few years, India has been making investments in various satellite systems that could enhance the country’s observational capabilities in respect to various atmospheric parameters, and to assist in improving various forecasting models.
Two missions launched by ISRO in the recent past should be viewed in this framework. On February 25, 2013, India successfully launched its PSLV-C20/SARAL mission. The main payload of this mission was the 409-kilogram SARAL (Satellite for Argos-3 and Altika). SARAL is studying the circulation of ocean currents and also measures sea surface heights, for which it has an altimeter onboard. This information is important to predict the development of weather systems. SARAL has two independent payloads (developed by the French space agency CNES): Argos-3 for data collection, and the Altika altimeter for measuring sea surface height. These payloads were integrated into a satellite bus from India and the entire satellite was built in India. The data received from SARAL supports the French program of operational oceanography development. The data collected also contributes to the Global Ocean Data Assimilation Experiment (GODAE), the first international operational oceanography experiment. SARAL is one of the very few such ocean-centric satellites specifically developed for studying sea surface heights. It is somewhat similar to ISRO’s Oceansat-2, a satellite launched in September 2009 to study surface winds and ocean surface strata. The inputs provided by Oceansat-2 assisted NASA in monitoring Hurricane Sandy in October 2012.
| These satellite launches undertaken by India in recent years indicate that a major focus of India’s space program is the study of weather, climate, and associated issues. |
These satellite launches undertaken by India in recent years indicate that a major focus of India’s space program is the study of weather, climate, and associated issues. For this purpose, India has created a system by positioning satellites in geostationary and polar orbits and also using relevant (direct or indirect inputs) from satellites launched for other purposes.
India’s geography puts it at a disadvantage in regards to adverse weather and climate. The country has faced the worst form of natural disasters in the recent past. Peninsular India shares its northern and eastern borders with the Himalayan mountain ranges, a tectonically active region. Glaciers in these ranges are found melting at a rapid speed in recent times. Due to its geography, India is affected by both tropical and subtropical weather systems, making weather prediction more challenging.
A little over a month ago, the Uttarakhand region in the northern part of India suffered a major natural disaster. The flash floods following heavy rains on June 16–18 had forced the Indian government to launch one of the biggest relief and rescue operations in recent times. This disaster killed thousands, and the India’s security forces, civil rescue workers, and the disaster management agency rescued an estimated 100,000 people. The mammoth physical effort by these agencies was supported by appropriate weather “nowcasting” and short range forecasting. This became possible due to variety of factors, including the inputs received from the disaster area about weather and topographic conductions, inputs received from radars and satellites, and usage of Geographical Information Systems (GIS) tools.
| India requires a vastly improved meteorological satellites regime to arm itself for addressing various challenges and there are high expectations from ISRO in this regard. |
In regards to issues related to global warming and climate change, there is a criticism of India’s position from certain quarters. Now, having a group of weather satellites at its disposal, India could be in a position to present to the world the correct facts about the weather and climate in their region. This could bring in more transparency towards making climate assessments and drawing conclusions.
India requires a vastly improved meteorological satellites regime to arm itself for addressing various challenges and there are high expectations from ISRO in this regard. India needs to continuously make investments to create state-of-art space assets for meteorological purposes. The launch of INSAT-3D is expected to add a new dimension to weather monitoring over the country but much more still needs to be done.
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