SECOND-GENERATION NAVIC SATELLITE

1. Context 

2. Key points

• Each of the seven satellites currently in the Indian Regional Navigation Satellite System (IRNSS) Constellation, operationally named NavIC, weighed much less around 1, 425 kg at liftoff.
• They all rode the lighter Polar Satellite Launch Vehicle (PSLV), ISRO's workhorse launch rocket.
• The last IRNSS Satellite, IRNSS-1I, was launched in April 2018 to replace an older, partially defunct satellite in the constellation.
• IRNSS-1I was ISRO's ninth satellite for the NavIC constellation but is considered to be the eighth because the IRNSS-1H launched eight months earlier in August 2017 and originally intended to replace the older satellite was lost after the heat shield of the payload failed to open on time.

Image source: ISRO

3. About the second generation NavIC satellite

• The second-generation satellite christened NVS-01, the first of ISRO's NVS series of payloads is heavier. Other than that:
  Atomic Clock: The satellite will have a Rubidium atomic clock onboard, a significant technology developed by India.
• The Space-qualified Rubidium Atomic clock indigenously developed by Space Application Centre-Ahmedabad is an important technology which only a handful of countries possess.
• L1 signals for better use in wearable devices: The Second-generation satellites will send signals in a third frequency, L1, besides the L5 and S frequency signals that the existing satellites provide, increasing interoperability with other satellite-based navigation systems.
• The L1 frequency is among the most commonly used in the Global Positioning System (GPS) and will increase the use of the regional navigation system in wearable devices and personal trackers that use low-power, single-frequency chips.
• Longer mission life:  The second-generation satellites will also have a longer mission life of more than 12 years. The existing satellites have a mission life of 10 years.

4. Significance of the atomic clock on board the NVS-01 payload

• Several of the existing satellites stopped providing location data after their onboard atomic clocks failed this was the main reason for the launch of the replacement satellite in 2018.
• Since a satellite-based positioning system determines the location of objects by accurately measuring the time it takes for a signal to travel to and back from it using the atomic clocks on board, the failure of clocks means the satellites are no longer able to provide accurate locations.
• Currently, only four IRNSS satellites can provide location services, according to ISRO officials.
• The other satellites can only be used for messaging services such as providing disaster warnings or potential fishing zone messages for fishermen.

5. The age of the satellites

• This is the second major concern, besides the failing atomic clocks.
• IRNSS-1A was launched into orbit on July 1, 2013, and the 1B and 1C satellites were launched the following year.
• 1A is almost defunct- the failed 1H mission of 2018 was intended to replace this satellite and all the three oldest satellites in the constellation are close to the end of their 10-year mission lives.
• At least three new satellites must be put into orbit to keep the seven-satellite constellation fully functional.

6. NAvIC constellation 

• ISRO has been criticised by experts for not focussing on the development of the user segment until very late in the life of some of the satellites in the constellation.
• No receivers were developed for the NavIC system, even though the satellites were sending signals.
  A 2018 report by the Comptroller and Auditor General (CAG) of India said that even though the Cabinet cleared funding of Rs 200 crores to develop user receivers in 2006, work on the project started only in March 2017, by which time seven launches had already taken place.
• The receivers have now been developed and NavIC is in use for projects like public vehicle safety, power grid synchronisation, real-time train information systems and fishermen's safety.
• Other upcoming initiatives such as common alert protocol-based emergency warning, time dissemination, geodetic network, and unmanned aerial vehicles are in the process of adopting the NavIC system.
• Some cell phone chipsets such as the ones built by Qualcomm and Media Tek integrated NavIC receivers in 2019.
• The Ministry of Electronics and IT is in talks with smartphone companies to urge them to make their handsets NavIC compatible.

7. Advantage of having a regional navigation system

• India is the only country that has a regional satellite-based navigation system.
• There are four global satellite-based navigation systems the American GPS, the Russian GLONASS (GLObalnaya NAvigatsionnnaya Sputnikovaya Sistema), the European Galileo and the Chinese Beidou.
• Japan has a four-satellite system that can augment GPS signals over the country, similar to India's GAGAN (GPS Aided GEO Augmented Navigation).
• Once fully operational with ground stations outside India for better triangulation of signals NavIC open signals will be accurate up to 5 meters and restricted signals will be even more accurate.
• GPS signals by contrast are accurate up to around 20 meters. Work is underway to set up ground stations in Japan, France and Russia.
• NavIC provides coverage over the Indian landmass and up to a radius of 1, 500 km around it.
• In this region, NavIC signals will likely be available in even hard-to-reach areas.
• Unlike GPS, NavIC uses satellites in high geo-stationery orbit the satellites move at a constant speed relative to Earth, so they are always looking over the same region on Earth.
• NavIC signals come to India at a 90-degree angle, making it easier for them to reach devices located even in congested areas, dense forests or mountains.
• GPS Signals are received over India at an angle.
• With the use of NavIC picking up, the government has been looking at the possibility of increasing the coverage area of the system.