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In defence of Mangalyaan: Why even developing countries like India need space research programmes

When ISRO ( Indian Space Research Organization) launched its Mars orbiter mission, this week, it caught the imagination of the whole world. Though India says its Mars mission is the cheapest inter-planetary mission ever to have been undertaken in half a century of space exploration, some are questioning its scientific purpose. There are a few critics too who say when so many poor are starving in a developing country like India, spending Rupees 450 crores on it is not correct. India's space programme spends $1.1bn annually, while the Mars mission alone would take up $74m. Critics say there are about 350 million people in the country who live on less than $2 a day. These skeptics say the space research is taking away the money from the development programmes. I feel this is a short sighted view. I have written on this earlier too (ref 1, 2). Again I want to write on this to remove these misconceptions and why India needs these space research programmes.

Indian Prime Minister Manmohan Singh himself dismissed criticism saying: "Questions are sometimes asked about whether a poor country like India can afford a space programme and whether the funds spent, albeit modest, could be better utilised elsewhere," he said in a speech last year. "This misses the point that a nation's state of development is finally a product of its technological powers." So India's space programme is ultimately intended as a capability demonstration. It is designed to put India 'out there' with other space-faring nations, and this is reflective of Indian ambitions to increase its international profile more generally. If we can't dare to dream big it would leave us as hewers of wood and drawers of water! India is today too big to be just living on the fringes of high technology.

My art work based on this very theme " Spaceman Vs Boxmen"

(In this space age, where new thoughts & actions of some people are taking the human kind towards development & progress, others are refusing to come out of the boxes they live in even though the environment they are in is hindering the free, forward movement.

http://www.kkartfromscience.com  )

“If India were to feed its masses before doing anything else, not one bit of science will be done in the country. When the rest of the world is moving forward, we will end up having a society which is not only hungry but also scientifically lagging.”

And there is international support too: "To think that India is going to the moon and Mars because of some cynical ploy to engage in one-upmanship with the Chinese is wrong," said John Sheldon, a US national security analyst and founder of strategy firm The Torridon Group. "For every rupee invested, there is a return for regular Indian people in terms of what that programme provides," he told the Washington Post. Then read what an article of BBC says here:

http://www.bbc.co.uk/news/magazine-24867914

The same sentiment is echoed by ISRO Chairman Dr. Radhakrishnan."Space is one area right from the beginning that has been contributing to the development process of the country," he said, referring to the beneficial contribution of weather forecasting on farmers of the country. Isro's main objective is not to find aliens but to get “weather report to farmers, natural disaster warnings and free online education to remote locations.”

However, India does appear to be conscious of its neighbours and the strategic implications of being ahead in space technology. "India doesn't live in a benign neighbourhood," said Rajeshwari Rajagopalan, a space security expert at the Observer Research Foundation, New Delhi, according to the Wall Street Journal. According to her, India is focused on peaceful use of outer space, but since China successfully tested an anti-satellite missile in 2007, there has been a "sort of arms race". We need space programme and satellites to defend our country too! In August this year, India successfully launched its first dedicated military satellite for naval intelligence gathering in the backdrop of concerns about Chinese naval presence in the Indian Ocean. "India's achievements in space technology are contributing to its missile technology, including the Agni-V."

ISRO has very humble origins. In fact both Brazil and India started their space research at the same time. Both had very little money. While Brazil spent all its money on constructing big buildings, Indian scientists  worked from old make shift buildings and spent the little money they had on building rockets. In 1963 ISRO launched its first rocket from Thumba Equatorial Launching Station.  The station had a single launch pad in the midst of coconut plantations. A local Catholic Church the St Mary Magadelene's Church served as the main office for the scientists. The bishop's house was converted into a workshop. A Cattle shed became the laboratory in which young Indian scientists like Abdul Kalam Azad worked and the rocket was transported to lift-off pad ON A BICYCLE. The second rocket, which was launched sometime later, was a little bigger and heavier and it was transported in a bullock cart for the lift off.   Over the next 12 years, India built and launched more than 350 sound rockets. India's first rocket was transported on a bicycle and satellite APPLE in a bullock cart (4)! Now look where Brazil is and where India is! ISRO knows the value of money and how to spend it!

According to ISRO the aim of the mission is 85% tech demonstration and 15% scientific quest ( studying the whole planet, unlike the US mission, and finding methane and water on Mars). India's 1,350kg (2,976lb) robotic satellite which is undertaking the 10-month-long, over 200-million-kilometre journey to Mars is equipped with five instruments.

They include a sensor to track methane or marsh gas - a possible sign of life - on Mars, a colour camera for taking pictures, and a thermal imaging spectrometer to map the surface and mineral wealth of the planet. The mission will also analyse the thin Martian atmosphere.

This is to demonstrate India's interplanetary mission capabilities to retain its place in the spacefarer's club.

 Spending 450 crore rupees on Mangalyaan is a small sum for national pride. According to ISRO: You never know if we may find something that is worth much more than Rs. 450 crore figure. People who ask what ISRO is going to find would understand that not finding something is also a finding, a discovery that something is not there. So in science even a failure will become a source of valuable knowledge! Remember the words of Edison of light blub fame? When Edison was asked what he had achieved by failing 999 times and only succeeding the 1000th time, he replied: I realized how you cannot make a bulb in 999ways. That is the spirit of science. But aren't we spending more on sports and movies? Aren't politians and beaurocrats wasting more public money on their personal quests? Aren't the rich wasting so much money on celebrations and parties? Each and every project the Indian government under takes is wasting large sums of money because of corruption and mismanagement. I can give  several other examples which waste lots of money like useless Diwali crackers which just go up in smoke. I think this money spent on space research is  an useful expenditure on a scientific project. Moreover, ISRO earns money on its own by launching satellites from other countries while saving money by sending our own satellites through our own launch vehicles. If we think about only feeding the poor - which of course is important - we will never progress in the scientific field which is also important to develop and feed the poor through Agricultural development, good storage and nutritional feeding of the poor! Satellite communications that can save lives can never be realized! This is spending peanuts to gain scientific knowledge and not a waste! If the Mars mission succeeds, it will be a big morale booster for India.

Earlier missions and previous ground based calculations have found methane in Martian atmosphere, but none have been able to conclude if they definitely indicated any life. This is because methane could be of geological as well as biological origin. Methane is interesting because most of it in our atmosphere is produced by methanogenic Archaea (or microbes); in other words, it is a signal of life. So if we find out the source, we might have detected life on Mars if it is biological in origin. Whatever the source, finding the methane - which one of the five scientific instruments on board the Mars orbiter would try - would add considerably to research on the red planet. The Lyman alpha photometer would be looking for abundance of deuterium and hydrogen in the Martian upper atmosphere, which are indicators of early existence of water. This will allow the amount of water loss to outer space to be estimated, thus revealing an important aspect of the history of water on the planet. Given that all life as we know it requires liquid water this will be another datapoint in the search for life, as well as revealing more about the climate history of the planet.

 Mangalyaan launch proves the creative blend of Indian scientific community and its scientific and technological capabilities. This has been proved when it is noted that this mission was made possible within 15 months of government approval and on a meager budget of just Rs. 450 crore. It is important to note that the Mars probe had to be launched using modified PSLV launch vehicle instead of GSLV rocket which demonstrates ISRO's ability to make do with available technology. Only when you technologically demonstrate your capabilities, you will get respect and noticed and grab a good space market. This aspect can be commercially exploited on a large scale. It can secure satellite launch contracts from several countries including the most developed ones which makes ISRO self-funding as well as bringing lots of money to India. It will help create a market for Indian space products. This in turn would lead to create lots of jobs in the tech front. The excellent record of ISRO is a great morale booster for scientists and other skilled people of India. A successful or even attempted project will improve the brand image of not only ISRO but also that of India.

 Critics had put forth a similar argument that the project was a waste of public money when India was preparing for Chandrayaan-1 too. But India's moon mission alone found moisture in moon's polar region which even men who walked on moon couldn't!

 This mission to Mars is a historical necessity. After having helped find water on the moon through Chandrayaan-1, looking for a sign of life on Mars is s natural progression. Not only would a successful mission be a towering achievement, it will also provide vital technological know-how that should aid India's next planned mission: a robotic voyage to the moon. ISRO argues that the goals for its Mars mission are mostly technological, showing that they have the know-how to design and navigate a deep-space probe. No matter how the probe fares from here, what India learns from its Mars mission should add to the capabilities of their next attempt to reach the moon, Chandrayaan-2. The nation's next lunar project is slated to be the first fully robotic mission to bundle an orbiter, a lander and a rover into a single launch, all developed by India. ISRO has said that the craft will test out novel technologies and science instruments.

How will this project help with the future moon mission? One of the trickiest phases in any interplanetary trek is launching and then perfecting orbital trajectories between Earth and your destination. India's Mars  mission offers a chance to refine their techniques for climbing out of Earth orbit and heading deeper into space. Mars Orbitor is going to be orbiting the Earth for some extended period of time, checking the spacecraft out before they commit to injecting it on a Mars trajectory. One of the issues there is the accuracy of their navigation and their ability to get it on the right trajectory. With lessons learned from this project, plus another attempt in December at flying the heavy-lift rocket that will eventually launch the moon probe, India should be better placed for success when Chandrayaan-2 is ready for take-off. Any time you fly a planetary mission you are going to learn something, like how to improvise when things don't go as planned.This Mars mission will certainly help with that.

  Taking Mangalyaan to the Martian orbit overcoming several difficulties, gives lots of confidence to the scientists. The success of this project would place ISRO and India in a higher orbit with regard to International space programmes.

 The spin-off of this project would be useful in the future for Indian communication satellites.

 Learning to do things with minimum resources, fuel ( by using a method called Hohmann Transfer Orbit which uses least amount of fuel possible. In this method, the spacecraft leaves Earth in a direction tangential to its orbit, and will encounter Mars at a tangent in Sep, 2014 ) and money is important for a developing country like India. ISRO had employed a complex design to take the Orbitor from Earth to Mars without spending too much energy and money ( according to one calculation just Rs. 12/km and another one says just Rs. 7/km all the way to Mars!). Only 21 out of 51 missions by other countries have been successful so far. This shows how complex and difficult the mission is. Getting the orbiter to go around Mars itself would be a mark of success!

Mars mission is a major technological challenge - but like Chandrayaan -1, it has excited the younger generation,catching their imagination which is being fed day in and day out with only news from sports, movies and music, and ignite the young minds and give them an electric alternative to think about and choose another exciting career. It will also give a boost to scientific research in India.

 There are women scientists working at ISRO executing key manoeuvres at the mission control center. Just knowing this is enough to inspire women to get into key scientific areas of research and engineering.

 The benefits of space research are being enjoyed in every sphere of life today. Examples: Saving lives during cyclones . In October, when cyclone Phailin headed for the south-eastern and eastern states, India could track it precisely, and one million people were evacuated at the right time. The investment made in satellite programmes over the years made the difference. India's space programme has brought mobile phone access even to the interiors of country, which revolutionised the channels available for farmers to sell their produce and for fishermen in isolated villages to get the best price.

Satellite Communication (Satcom) technology of ISRO offers the unique capability of simultaneously reaching out to very large numbers spread over large distances even in the most remote corners of the country. The hallmark of Indian Space Programme has been the application oriented efforts and the benefits that have accrued to the country. In the past two and a half decades Indian National Satellite (INSAT) system have revolutionized the country’s telecommunications, TV broadcasting, DTH services, business communications, rural area connectivity, Tele-education, Tele-medicine, Village Resource Centres, Search and Rescue operations and Emergency Communications (ref 3).

Remote sensing has enabled mapping, studying, monitoring and management of various resources like agriculture, forestry, geology, water, ocean etc. It has further enabled monitoring of environment and thereby helping in conservation. In the last four decades it has grown as a major tool for collecting information on almost every aspect on the earth. With the availability of very high spatial resolution satellites in the recent years, the applications have multiplied. In India remote sensing has been used for various applications during the last four decades and has contributed significantly towards development (3).

The Disaster Management Support (DMS) Programme of ISRO, provides timely support and services from aero-space systems, both imaging and communications, towards efficient management of disasters in the country. The DMS programme addresses disasters such as flood, cyclone, drought, forest fire, landslide and Earthquake. These include creation of digital data base for facilitating hazard zonation, damage assessment, etc., monitoring of major natural disasters using satellite and aerial data; development of appropriate techniques and tools for decision support, establishing satellite based reliable communication network, deployment of emergency communication equipments and R&D towards early warning of disasters (3).

Other services of ISRO are Telemedicine Programme (an innovative process of synergising benefits of Satellite communication technology and information technology with Biomedical Engineering and Medical Sciences to deliver the health care services to the remote, distant and under served regions of the country), village resource centers ( to provide the space technology enabled services directly to the rural population), and tele-education.

Technology designed for outer space can help detect disease on planet Earth (8). For instance, Sepsis, a life-threatening condition in which the body is fighting a severe infection that has spread via the bloodstream leading to poor circulation and lack of blood perfusion of vital tissues and organs, is one of the most significant causes of premature death in the world. These deaths are thought to be preventable through improved diagnosis and reduced treatment delays. Researchers are now trialling the use of a simple breath test  developed by RAL Space to study gases in the Martian atmosphere. The device known as a Laser Isotope Ratiometer (LIR) can provide instant results helping doctors start treatment earlier which could reduce the number of sepsis linked deaths. Patients just breathe into a bag where the LIR uses laser beams to examine the gas samples. Now this is where gets a bit technical: the LIR then measures the concentration of two isotopes (or atoms) of carbon found in the sample. Carbon-13 and carbon-12 are exhaled as molecules or so called isotopologues 13CO2 and 12CO2. The onset of sepsis can change the ratio of 13CO2 and 12CO2 in the breath when the body's immune system responds to infection and thus changing it from its healthy levels. If the laser beam is adjusted to a certain frequency, the carbon dioxide molecules will absorb energy from it and become excited. This stops the light from transmitting through fully. The more 13CO2 or 12CO2 molecules are in the line of the laser beam, the less light will be transmitted through. The breath test  is non-invasive making it safe for frequent use by at risk patients and faster than regular blood tests which require an extended waiting period due to laboratory analysis.

What is the importance of space exploration?  GPS. Satellites gave us GPS. Weather predictions. WD-40. Space exploration gave us WD-40. MRI machines, CAT scan machines, artificial limbs, water-purification technology, efficient solar energy.. From Wikipedia: freeze-dried food, firefighting equipment, emergency "space blankets", DustBusterscochlear implantsLZR Racerswimsuits, and CMOS image sensors. As of 2016, NASA has published over 2,000 other spinoffs in the fields of computer technology, environment and agriculture, health and medicine, public safety, transportation, recreation, and industrial productivity and much, much, MUCH more.. There is a very long list of technological innovations and benefits that are “spin-offs” of space exploration.

The future of Mankind’s survival lies beyond this insignificant ball of dust. Yes, we need to study other planets to both improve the conditions here on Earth, protect ourselves from what made Mars and other planets inhospitable if we don't find life on them and to make them hospitable so that in future if we have to travel to other planets for various reasons we can do it with ease.

The more sober of us see Mars as the most likely site in our solar system for a second origin of life. Discovering even microbes there could revolutionize biology, challenge some religious beliefs and point to an answer to that great question “Are we alone?” (5)

In science, nothing is a waste. People -laymen would be an appropriate word here - say space science is waste.  It is just ignorance to think so. The technology used in space science is being used now in medical field too to save money and lives! And this is a fact. It is also being used to improve infrastructure and technologies used in industries. Are we not using satellites for communications and educational purposes?  Radio-technology used in radio telescopes is now being used in mobile phones improving the communication systems around the world! So according to scientists space science is not a waste. (ref 2)

Science is knowledge. It can be used one way or the other and nothing in science is ever going to be a waste. Advancements in one field often lead to developments in very different areas. 

If we are to play a meaningful  role nationally and in the community of nations, we must be second to none in the application of advanced technologies to the real problems mankind is facing today and solve them effectively. That is what exactly ISRO is doing today.

 "What will you do by going to a moon? What is the use of finding that moon is a barren land?" Somebody asked me this Q. And my reply is:  try to understand this ... Apart from gaining knowledge about the moon ... how the technology used in space science is being used now in medical field...  

In fact, our former president, who is a scientist at Defence Research and Development Organization, Mr. APJ Abdul Kalam , collaborated with Care foundation doctors and developed a cost-effective stent using space technology. He also helped Nizam Institute of Medical Sciences doctors in developing low-weight ortho calipers  - prosthetic legs for polio-effected patients and amputees - using space age materials. Space science is not at all a waste!

Scientists at the Vikram Sarabhai Space Centre, Thiruvananthapuram, India's premier rocket lab recently manufactured the world's lightest material called silica aerogel or 'blue air.' Silica Aerogel is the lightest synthetic material ever made by man.This material, scientists say, has excellent thermal resistance and if used as a filler in soldiers' uniforms it can possibly help save many lives at the Siachen glacier. The material has uses both in space and on Earth. So light weight that it can be delicately placed on a flower head, ISRO has made the world's lightest known material, sometimes also called 'frozen smoke.' Scientists hope it can be used to insulate rocket engines (7). But, the uses extended beyond rocket insulations. It has applications for thermal jacket, foot insoles, as well as for window glazing. It is extremely useful for people working in very cold environments, in a very strategic way . 

Like one science enthusiast says: "We bear witness to the astonishing capacities for scientific knowledge to aid us in transcending our seeming boundaries, to realise they're not really boundaries. It's a great thing. Let's celebrate that." So instead of  criticizing it, let us support science - especially space science, the scientific community and celebrate their achievements and spirit.

Some Good News:  2nd Dcember, 2013: Mangalyaan finally left the Earth's orbit and started its long journey towards the Mars. India’s spacecraft to Mars has bid adieu to its Earth-bound orbit and is cruising in its sun-centric orbit. In a remarkably successful execution of a complex manoeuvre, ISRO fired the propulsion system on board the spacecraft for a prolonged duration of 23 minutes from 0049 hours on Sunday. In space parlance, the manoeuvre is called Trans-Mars Injection (TMI). ISRO called it “the mother of all slingshots.” Well done ISRO!

Sci-Art Lab Wishes the spacecraft of MOM a Bon Voyage through space....

Updates:

24th Sept., 2014 ... and ISRO and India have created history by  becoming the first space research organization and country to successfully get a spacecraft into the Martian orbit on their maiden attempt! Indian Space Research Organisation's Mars Orbiter Mission (MOM) spacecraft started orbiting the red planet at 7.47am, but it was only 12 minutes later —because of a time delay in radio signals travelling the 680 million km -- that scientists at Isro Telemetry, Tracking and Command Network in Bangalore, could erupt in joy as Prime Minister Narendra Modi stood a happy witness. We have done it!

Very proud of you scientists at ISRO!

 

I completely trusted you all the while and wrote this article when MOM was first launched supporting you and following you. Now see what happened! I have been proved right till now and will be proved right in the future too. Scientists at ISRO will never let us down because they are made of  stuff others can only dream of! They are in great demand now and NASA and Chinese space scientists want to work in collaboration with ISRO now. ISRO and NASA set up a joint Mars working group too to enhance cooperation between India and the US in explorations of the red planet. This success must now silence the critics of MOM.

The low cost of this mission also can be attributed to technologies like that used on the cryogenic engine and communication systems were produced by indigenous companies working with ISRO, but developed at a fraction of the cost charged by Western companies and other scientists also attribute lower costs to the dedication of Indian scientists who worked overtime at comparatively low salaries to get Mangalayaan going.

The biggest achievement of  the odyssey is India's demonstration of mastery over making the spacecraft 'think and act' on its own! (6) The 'electronic brain' that helped the MOM to journey for more than 689 km - correcting altitudes and positioning its antenna constantly toward  the  Earth for  communication and its solar panels toward the Sun to generate power - is very vital for the success of the spaceship. It is this brain that stored  commands from ISRO in Bangalore  10 days in advance and carried them out to fire its engine to enter Martian orbit.  All through its journey MOM has controlled its temperature and cruised in the direction of Mars with very little prodding from Earth. Some 150 automated thermo-controllers kept the temperature  steady. While speeding at more than 82,000 kmph. it never lost direction, thanks to the star-gazing equipment on board which looked at constellations of 6-10 stars every microsecond and compare them with preloaded patterns. MOM continuously matched the patterns and in relation to the constallations, determined its position and direction.  Scientists call it autonomy.  Autonomy can deliver things stranger than we think. And it can be used here on Earth to benefit humanity! Need I say more?

References:

1. http://kkartlab.in/group/some-science/forum/topics/criticism-of-sci...

2. http://kkartlab.in/group/Criticisms/forum/topics/the-yard-sticks-fo...

3. http://www.isro.org/

4. http://www.isro.org/Imagegallery/otherimages.aspx

5. http://www.asianscientist.com/features/indian-mars-mission-beats-ne...

6. TOI, 25th Sept, 2014.

7. http://www.ndtv.com/india-news/isros-new-light-as-air-gel-can-keep-...

8. https://phys.org/news/2020-01-technology-outer-space-disease-planet...

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Time Magazine picks Mangalyaan for best inventions of 2014 : http://indianexpress.com/article/india/india-others/mangalyaan-amon...
ISRO wins Indira Gandhi peace Prize (2014) : http://www.thehindu.com/news/national/isro-chosen-for-indira-gandhi...
ISRO's Radhakrishnan in Nature journal's top ten list: http://www.thehindu.com/sci-tech/science/isros-radhakrishnan-in-nat...

India's Mars Orbiter team wins 2015 Space Pioneer Award

The award was won in the science and engineering category from the US based National Space Society (NSS)
http://www.business-standard.com/article/news-ians/india-s-mars-orb...
http://economictimes.indiatimes.com/delhi-poll-express/isro-mars-or...
U.S. Space Society to honour Mars Orbiter team
http://www.thehindu.com/news/national/us-space-society-to-honour-ma...

21st Sept., 2015

As it prepares to celebrate the first anniversary of its spacecraft's tryst with Mars, ISRO today said the mission to the Red Planet will last for "many years" as there is not much of a "problem" and they have not had any failures so far.

"Mars (mission) is expected to last for many years now, because it has gone through solar conjunction also; so we don't see much of a problem," ISRO Chairman AS Kiran Kumar told reporters today.

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https://kkartlab.in/group/some-science/forum/topics/developing-canc...

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Replies to This Discussion

Most of Earth’s methane comes from anaerobic bacteria living in low-oxygen environments, such as stagnant water and the guts of animals, though abiotic processes such as hot water flowing through mineral-rich rock can also produce the gas.

Mars’s minuscule methane background is broadly consistent with what should be produced by ultraviolet light striking the carbon-rich debris of meteorites, comets, and interplanetary dust that periodically fall to the Red Planet. But this mechanism cannot easily explain the methane spikes on Mars. Alternatively, the methane spikes may come from unseen, buried deposits of clathrates, lattices of ice that can trap gases such as methane in their crystalline structure. Another possibility is that the methane spikes aren’t small, transient events produced near Curiosity, but that they are instead whiffs of larger methane releases occurring much farther away on the planet. The results show that methane has a source on the planet.

India developing atomic clocks for use on satellites

The Indian Space Research Organisation (ISRO) is developing rubidium-based, high-precision atomic clocks for use in its next series of navigation satellites, ISRO Chairman A.S. Kiran Kumar said on Wednesday.

The ISRO is building the seven-satellite regional navigation constellation. The four that are up use European atomic clocks. These satellites, meant for civil and military uses, need to show the exact position and time of persons and objects on earth. So, they should keep extremely accurate time as they send signals.

The ISRO’s Space Applications Centre in Ahmedabad is developing prototypes of atomic clocks, along with the CSIR’s National Physical Laboratory in New Delhi, Dr. Kiran Kumar said on the sidelines of an event organised by the Metrology Society here.

“We still have to make qualified and flight-worthy versions. Our next generation navigation satellites will carry our own clocks” when they start replacing the IRNSS-1 series after their life of 10 years, he said. The IRNSS has commonly been called India’s own local ‘GPS.’

A senior scientist says the atomic clock figures among the top critical technologies to be developed indigenously.

Each navigation spacecraft carries an active and two stand-by clocks. The home-made ones need to be compact and fuel-efficient in space.
http://www.thehindu.com/news/national/tamil-nadu/india-developing-a...

Megapixel camera like 1600 space invention have revolutionized common man’s life, ISRO chief
More than 1600 technological innovations that were created for space applications have played revolutionary role in daily life of a common man, said ISRO chief A S Kiran Kumar at a convocation ceremony of a private university in New Delhi. While addressing the crowd he said that technologies including megapixel camera, MRI, advanced cardiac pacemakers, all were developed for space applications which later became essential part human life on Earth.

“The megapixel cameras using which you take selfies was originally designed of space photography. The MRI that acts as guide to life-saving (medical process) was made for moon observation for Apollo Mission. Velcro used in bags, shoes and purses were popularised to bind equipment in zero gravity solutions. In fact, over 1,600 technologies ended up revolutionising our lives,” he said.

He also accepted the fact that India needs to innovate in order to compete with other countries. Also, the innovation must come in a cost effective manner. For this to accomplish researchers can use existing technology, knowledge and expertise to innovate and develop new technology in a cost-effective manner, according to the ISRO chief. While being proud, he said that ISRO has always been on the same path and has successfully adopted its innovative concepts and technologies since early days of its inception.

He further pointed out that India’s space missions including GAGAN, IRNSS, Astrosat, Aditya have seen several technological advances. Now, ISRO scientists are working on making reusable space shuttles which will significantly bring down the cost of satellite launches.

Apart from megapixel camera, memory foam mattresses, home blood pressure kits, digital signal processing for MRI and Cat scans, dental braces, cardiac pacemakers, scratch resistant lenses, implantable insulin pumps, etc are some out of 1600 technological advancement that were developed for space missions, eventually ended up revolutionizing common man’s life.

http://www.tecake.com/1600-space-applications-revolutionized-common...

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http://www.microfinancemonitor.com/2015/06/01/more-than-1600-space-...

How more than 1600 space applications revolutionised our lives?


From home-based BP machines to camera pixels to hi-fi MRI and CAT scans, more than 1,600 applications originally developed for space applications have made their way into our daily lives revolutionising our life-style, said ISRO chief A.S. Kiran Kumar.

He said most of these innovations do not come from a single new technology but come from an existing technology that undergoes constant updates and refining with the latest technology offering cost benefit and better performance, said Dr. Kumar.

“The megapixel cameras using which you take selfies was originally designed of space photography. The MRI that acts as guide to life-saving was made for moon observation for Apollo Mission… In fact, over 1,600 technologies ended up revolutiionsing our lives,” he said.

“We indeed have space technology to thank for memory foam mattresses, home blood pressure kits, CMOS sensors for mobile phone cameras of today, digital signal processing technology for MRI and CAT scans, scratch-resistant lenses, implantable insulin pumps, advanced cardiac pacemakers, modern dental braces and so much more,” he noted.

Kumar has pointed out India’s GAGAN, IRNSS, Astrosat, Aditya and other space missions which have offered or will offer similar advances made in technology and the next major phase in its exploration of deep space with re-usable shuttle will test some more technologies in the future, which could bring down the price of satellite launches.

Speaking at a convocatipon ceremony of a private university in New Delhi, according to a PTI report, the ISRO chief pondered on Velcro of Swiss-based technology that was in vogue since the 1940s but made its way into the Apollo mission for moon study in the late 1960s.

Even the megapixel cameras used in mobile phones of today to take selfies were used originally for space photography, he reminded. No wonder, we have several space applications which require application to make lives of people better.

Essentially, A.S. Kumar is reiterating the fact which was highlighted by then DRDO chief and former President Abul Kalam who made the light-weight material used in rocket science applicable to make Jaipur leg for patients who had lost their parts.

Space research in anti-cancer fight

Experiments in the weightless environment of space have led to "crazy progress" in the fight against cancer, NASA officials say.

Not only do cells in space age more rapidly, speeding up research, their structures are also described as "purer."

They all don't clump together (as they do) on Earth because of gravity. They are suspended in space enabling better analysis of their molecular structures.

Research conducted in space can help make cancer drugs more effective.

Pharmaceutical giant Merck has conducted research on the ISS with Keytruda, an anti-cancer drug that patients now receive intravenously.

Its key ingredient is difficult to transform into a liquid. One solution is crystallization, a process often used in drug manufacturing.

In 2017, Merck conducted experiments to see if the crystals would form more rapidly in space than on Earth.

Two pictures taken  demonstrate the difference. The first showed a blurry, transparent spot. But on the second, a large number of clear gray spots had emerged.

That photo showed that smaller, more uniform crystals were forming in space—and "forming better".

Thanks to such research, researchers will be able to make a drug that can be administered by injection in a doctor's office instead of through long and painful chemotherapy treatments.

Merck identified techniques that can help it imitate the effects of these crystals on Earth as it works to develop a drug that can be stored at room temperature.

Still, it can take years between research in space and the wide availability of a drug developed there.

Cancer research in space began more than 40 years ago but has become "revolutionary" in recent years.

Biden launched a "Cancer Moonshot" initiative in 2016, when he was then vice president, echoing a speech by John F. Kennedy some 60 years earlier outlining the bold goal of sending an American to the moon.

The goal of the "Moonshot" is to halve the death rate from cancer over the next quarter century, saving four million lives, according to the White House.

Political realities may hinder that ambitious goal, though. Congress has earmarked just over $25 billion to NASA for 2024, two percent less than the previous year and well below what the White House had sought.

"The ability of space to capture the imagination is huge. And space cancer research has a firm goal: "It can save lives." and should be pursued, according to the scientific community.

Source: AFP

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