President’s Address at the Technology Day Awards Function 2007, New Delhi
Technology
and Innovation power Competitiveness
"Technology
is a non-linear tool which can effect
fundamental changes in economic competitiveness"
I am very happy to
participate in the National Technology Day Award Function 2007 organized by
Ministry of Science and Technology. This day reminds us of our resolve to achieve
self reliance in indigenous technologies needed for societal transformation. My
greetings to the organizers, scientists, technologists and entrepreneurs and
congratulations to the award winners. While I am with you, I would like to talk
to you on the topic "technology and innovation power
competitiveness".
Economic development and
prosperity
Since the audience consists
of scientists and technologists, entrepreneurs, members from academia and
policy makers, let me share with you the linkages among economic development,
competitiveness, technology and marketing and evolution of a creative leaders.
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Nation’s Economic development
is powered by competitiveness.
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The competitiveness is
powered by knowledge power.
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The knowledge power is
powered by Technology and innovation.
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The Technology and innovation
are powered by resource investment.
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The Resource investment is
powered by revenue and return on Investment.
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The Revenue is powered by
Volume and repeat sales through customer loyalty.
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The customer loyalty is
powered by Quality and value of products.
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Quality and value of products
is powered by Employee Productivity and innovation.
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The Employee Productivity is
powered by Employee Loyalty, employee satisfaction and working environment.
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The Working Environment is
powered by management stewardship.
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Management stewardship is
powered by Creative leadership.
For success in all missions,
we need creative leaders. Creative leadership means exercising the vision to
change the traditional role from the commander to the coach, manager to mentor,
from director to delegator and from one who demands respect to one who
facilitates self-respect. For a prosperous and developed India, the important
thrust will be on the growth in the number of creative leaders in every laboratory,
institution, every industry, every department and finally every organization in
the ministry. Let me now discuss two recent missions of Indian Polar Satellite
Launch Vehicle programme for technology development and commercial
applications.
PSLV-C7 Mission orbiting
four satellites, including Space capsule Recovery Experiment (SRE)
On January 10, 2007, the
country witnessed in real time, the flight of PSLV-C7 from Satish Dhawan Space
Centre (SDSC) SHAR, Sriharikota, successfully orbiting four satellites --
India’s CARTOSAT-2 and Space Capsule Recovery Experiment (SRE-1), Indonesia’s
LAPAN-TUBSAT and Argentina’s PEHUENSAT-1 into a 635 km polar orbit.
Recovery of Space Capsule
Recovery Experiment (SRE), a major technological feat
SRE-1 was successfully recovered
on January 22, 2007, after being maneuvered to reenter the earth’s atmosphere
and descend over Bay of Bengal about 140 km East of Sriharikota. The critical
maneuvers were executed from the Spacecraft Control Centre (SCC) of ISRO at
Bangalore supported by a network of ground stations in India and abroad.
On January 22, 2007, the
re-orientation of SRE-1 capsule for de-boost operations commenced at 08:42 am
(IST). The capsule made its re-entry at 09:37 am at an altitude of 100 km with
a velocity of 8 km/sec (29,000 km per hour). During its reentry, the capsule
was protected from the intense heat by carbon phenolic ablative material and
silica tiles on its outer surface. SRE-1 splashed down in the Bay of Bengal
with a velocity of 12 m/sec (about 43 km per hour) at 09:46 am. The flotation
system, which immediately got triggered, kept the capsule floating. Recovery
operations were supported and carried out by the Indian Coast Guard and Indian
Navy using ships, aircraft and helicopters. During its stay in orbit for 12
days, two experiments on board SRE-1 were conducted under micro gravity
conditions.
The successful launch,
in-orbit operation of the on board experiments and reentry and recovery of
SRE-1 have demonstrated India’s capability in important technologies like
aero-thermo structures, deceleration and flotation systems, navigation,
guidance and control. Now, I would like to talk about another important PSLV
mission which shows our ability to provide state-of-the-art commercial launch
services to an international customer. I had mentioned about this to the
European Union of Parliament within two days of the launch.
PSLV C8 Commercial launch
for international customer
On 23rd April 2007, at 15.30
hrs IST, the Indian PSLV-C8 lifted off majestically from SDSC, SHAR and in
about twenty minutes, placed the 352 Kg Italian Satellite AGILE into a circular
orbit of 550 km with an inclination of 2.47 degrees with a precise orbital
accuracy of 1 km in altitude and 0.03 degrees in inclination. AGILE is an X-ray
and Gamma ray astronomical satellite of the Italian Space Agency (ASI), Rome.
This scientific satellite is an excitement not only for Italian and European
scientists but also to the Indian and the entire space scientific community.
PSLV-C8 is the first major commercial launch for a primary satellite.
What is the message? Starting
with the design and development in the late eighties, with its first successful
flight in 1994, PSLV through ten consecutive successful flights has orbited
eight Indian remote sensing satellites, an amateur radio satellite, HAMSAT, a
recoverable space capsule, SRE-1, and six small satellites for foreign
customers in addition to AGILE. Besides, it has launched India’s exclusive
meteorological satellite, Kalpana-1, into Geosynchronous Transfer Orbit (GTO).
PSLV will also be used to launch India’s first spacecraft mission to moon,
Chandrayaan-1, during 2008. Such a development in indigenous high technology
from concept to meeting the stringent performance and time specifications of commercial
customer was possible due to a mission mode partnership of ISRO’s centres of
excellence, with industries and academic institutions. Likewise, I would
suggest that the industries to take up concept to completion programme based on
their core competence for producing goods and services which will have large
impact both nationally and internationally. That is how, science and technology
can lead to higher level of competitiveness in the industry. Let me now discuss
an important technological milestone achieved by our defence scientists.
Missile intercepts another
missile
A few months back, I was in a
place called Chandipur at Sea off the coast of Orissa, where the preparations
for a major missile test were being carried out. What was this test? This test
was to intercept an incoming missile presumably from an adversary by our
missile. Imagine, an incoming missile is traveling at a speed of 1200 meters
per second, very high above the ground. You cannot judge it with your eyes.
There are telemetry systems continuously radiating performance information
about the missile. We make use of radars, which work by bouncing off radio
waves and sensing the echo to find out the position and speed of the target.
These radars are very powerful so that they can detect precisely a small object
hundreds of kilometers away. Having detected a fast moving target what do we do
next? We must then decide, “is this a missile aimed at us?” To do this we must
make use of extremely powerful fast computers on the ground running millions of
calculations per second. Based on these calculations, if we conclude that the
object is indeed a missile coming towards us, then steps must be taken to
intercept the target missile. What are these steps? These steps are to find out
where is the missile launched from? Where is it going to impact and then to see
which of our own missile can intercept this incoming missile. You can very well
imagine the minimum time available for the required operations. Having done
this, the next step is to launch our own indigenously designed missile at the
correct time from the designated launch pad. Are our jobs over? No. Having
launched our own missile we must guide towards the enemy missile. This is done
by guiding our own missile through a radio link to track where is the enemy
missile right now. As our missile approaches the target, the missile opens its
own small radar called a seeker to accurately locate the target and then to
home on to it, intercept and destroy.
All these were done
successfully by our defence scientists during November 2006 in the Wheeler
Island and they had a direct interception of the incoming missile which they
destroyed. This is a major achievement for our country as the test involved the
development and integration of many technologies, based on the work of a large
number of teams. This has been made possible because of the continuous
development by DRDO in various missile systems in close collaboration with
industry, other national research laboratories and academic institutions.
Similarly, I would suggest industries to consolidate the cumulative development
of technologies taking place in various S & T institutions in the country
and develop products using state-of-the-art technology for ensuring
availability of competitive products for both national and international
market. Now, let me present a few thoughts on convergence of technologies.
Convergence of Technologies
Information technology and
communication technology have already converged leading to Information and
Communication Technology (ICT). Information Technology combined with
bio-technology has led to bio-informatics. Now, Nano-technology is knocking at
our doors. It is the field of the future that will replace microelectronics and
many fields with tremendous application potential in the areas of medicine,
electronics and material science. When Nano technology and ICT meet, integrated
silicon electronics, photonics are born and it can be said that material
convergence will happen. With material convergence and biotechnology linked, a
new science called Intelligent Bioscience will be born which would lead to a
disease free, happy and more intelligent human habitat with longevity and high
human capabilities. Convergence of bio-nano-info technologies can lead to the
development of nano robots. Nano robots when they are injected into a patient,
my expert friends say, will diagnose and deliver the treatment exclusively in
the affected area and then the nano-robot gets digested as it is a DNA based
product.
Convergence of ICT, aerospace
and Nano technologies will emerge and revolutionize the aerospace industry and
electronics leading to nano computing systems. This technological convergence
will enable building of cost effective low weight, high payload, and highly
reliable aerospace systems, which can be used for inter-planetary
transportation.
Potential collaboration with
Greece
Recently, I was in Greece and
interacted with the scientists of National Centre for Scientific Research.
There I discussed with them the application of nano-science and technology in a
number of societal programmes. I would like to mention some of the important
areas.
Agriculture and food
processing: We are in the mission of
generating 400 million tonnes of food grains with reduced land, with reduced
water and with reduced workforce. It is essential to take up agro food
processing in a big way which will bring employment potential in rural areas.
Some of the possible areas of
research in agriculture and food processing are: Nano-porous zeo-lites for
slow-release and efficient doses of water and fertilizers for plants, and of
nutrients and drugs for livestock, nano-capsules for herbicide delivery, nano
sensors for soil quality and for plant health monitoring. Nano-composites for
plastic film coatings used in food packaging, antimicrobial nano-emulsions for
applications in decontamination of food equipment, packaging or food processing
are other important areas of research.
Infrastructure: India is aspiring to build hundred million houses within
next ten years. The infrastructure development in metropolitan and tier-2
cities needs to be enhanced in the form of new bridges, airports, marketing
complexes and industrial units. 40% of the rural areas need to be covered with
all weather roads; we need to double the present national highways ratio per
100 square kilometer area.
Nano-science material and
technology research can definitely provide a solution. Our research focus in
the nano-material should be towards cheaper rural housing, surfaces, coatings,
use of concrete with heat and light exclusion. Can we develop heat resistance
nano-material to block ultraviolet and infra red radiation? We should also
develop a nano-molecular structure to make concrete more robust to water
seepage, with self cleaning surfaces and bio active coating.
Energy: Energy Independence is India’s first and highest priority. We
are determined to achieve this by the year 2030 through three different sources
namely renewable energy (solar, wind and hydro power), electrical power from
nuclear energy and bio-fuel for the transportation sector. Energy independence
throws very important technological challenges to the world: The solar cell
efficiency has to increase from the present 15% to 20% to 45 to 50% through
intensified research on CNT based solar cells. For thorium reactors, as it is
known, thorium is a non-fissile material. It has to be converted into a fissile
material using Fast Breeder Technology. In the Bio-fuel area, the challenge is
bio-fuel plantation for higher yield, esterification technologies for the
higher output and the modification to automobile power plants. These three
research areas definitely need intensive cooperation between Greece and India.
Safe Drinking Water: We have embarked on a mission for water purification, water
de-toxification, water desalination through nano membranes and nano sensor for
detecting contaminants and pathogens? How the nano-porous zeo-lites,
nano-porous polymers can be used to design and develop products for water
purification.
Healthcare: India has already patented the development of drug delivery
system using nano-technology. Stem cell research in India is advancing in the
field of cardiology, ophthalmology, diabetic research, endocrinology, oncology
and immunology. It is essential to develop drug delivery system for stem cell
implantation into the specific organs of the body related to the ailment using
nano technology. During my discussions, the scientists in Greece were keen to
work with Indian laboratories and industries in such frontier areas. I would
suggest the Ministry of Science and Technology to take the lead and create a
linkage between R & D laboratories, educational institutions and industries
of India and Greece for working in frontier areas of research leading to rapid
commercialization of state-of-the-art products needed in the international
market.
Conclusion
Dear friends, as you all
know, our small scale industries have spread throughout the country and total
number exceeds three million with a tremendous impact on Indian economy. These
industries need continuous technological updation and infusion of new
technologies. I would suggest that the Hon’ble Minister of Science and
Technology may facilitate laboratory, small scale industry partnership in
coordination with the Ministry of Small Scale Industries. Such collaboration
will enable world class products emanating from our small scale industries.
Once again let me
congratulate the award winners and my best wishes to all of you in your mission
of promoting scientific discoveries, technological inventions and innovations
for societal transformation.
May God bless you.
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DS/LV/MK
(Release ID :27907)