India has made rapid strides in space technology. It recent launch of ‘Jugnu’ a little big satellite is the latest feat of high tech engineering. The loaf-sized nano satellite designed by IIT-Kanpur is an impressive feat in miniaturization.
The satellite was placed into orbit by the Polar Satellite Launch Vehicle C18 (PSLV-C18) of the ISRO. It contains all the basic functions of a satellite in its modest frame.
The satellite is just a foot long and four inches in height, and weighs a mere 3 kgs.
IIT-Kanpur designed Jugnu’s ejection system, a complex piece of technology that makes space missions possible by separating the satellite from the launch vehicle and placing it in a precise orbit. The mechanism went through dozens of rigorous tests before certification by the Vikram Sarabhai Space Centre as spaceworthy.
IIT-Kanpur will be filing a patent through ISRO before dedicating it to the nation.
Ejection systems – or separation mechanism – available with ISRO are meant only for much larger satellites weighing between 100 kg and 1,000 kg, but not for a nanosat like Jugnu, said Nalinaksh Vyas, Jugnu’s project leader and professor of mechanical engineering at IIT-Kanpur.
They are usually imported at a cost of Rs.50 lakh ($100,350) apiece, he added.
Vyas told IANS that “there were several challenges in terms of both design development and administrative ones”, which were successfully overcome by the enthusiastic band of 50 boys and girls from various engineering and science disciplines of IIT-Kanpur.
Jugnu cast such a spell on students that some of them even shunned tempting job offers at the peak of the IT boom, just to stay with the project, recalls Prof Vyas. Some even quit lucrative jobs to join the team. “Others like Shantanu Agarwal opted for M.Tech after completing B.Tech to be able to continue with the project,” added Vyas.
Vyas mentioned Shashank Chintalagiri, a young physicist, as the mainstay of the project who inspired others with his innovativeness and bold approach, fixing problems as and when they arose, besides Preneet from the physics stream, Kshitij Deo (mechanical) and Anant Goyal.
Chintalagiri, elaborating on his experiences as a project member, said:
“A nanosatellite is smaller but has the same kind of functionality as a larger satellite does. We were initially torn between ISRO’s ‘right way’ of doing things and a more practical approach that we could fit in our small size and weight.
“Eventually, we decided to go ahead and design our system, taking cues from other nanosatellites built around the world. When we gave our system a rough shape, only then did we compare it with what ISRO would do on its own satellites and made modifications accordingly.
“We would never have been able to achieve the size reduction we did by blindly following ISRO specifics, and ISRO themselves knew that as well. We were able to combine technology used in daily life . . . with the design principles of space technology,” Chintalagiri concluded.
Initially, only three students had volunteered for the project begun in 2008 as part of the IIT-Kanpur Golden Jubliee celebrations, in a bid to foster space research capability among IITians and to develop technology for nanosats. The current lot included first year undergraduates to final year post-graduates and 14 faculty heads from as many disciplines to complete this challenging assignment.
Jugnu has started transmitting a beacon (blinking signal) round the clock all over the earth. Amateur frequency bands will be used for communication so that the ‘beacon’ can be tracked by amateur HAM (radio operators) around the world.
In fact HAM operators in Japan and the US have already received signals from Jugnu, according to sources in IIT-Kanpur. Messages sent to the satellite from a ground station are “uplinked,” while those transmitted from the satellite to Earth are “downlinked.” Jugnu operates on 3.5 watts of power and is expected to have a year-long life.
Jugnu will conduct remote sensing to map land use and cover, agriculture, soils, forestry, city planning, archaeological investigations, etc. Jugnu is powered by rechargeable batteries relying on solar panels, provided by ISRO, but the charging circuitry was fabricated by IIT-Kanpur, Vyas said. Normally it takes two hours to fully charge such a battery, lasting from a few hours to a few days, depending on the number of operations attempted for the payloads.