Indian Space Research Organisation

Set up as the marketing arm of ISRO, Antrix's job is to promote products, services and technology developed by ISRO.[52][53]

Set up for marketing spin-off technologies, tech transfers through industry interface and scale up industry participation in the space programmes.[54]

• Aerospace Command of India (ACI)
• Balasore Rocket Launching Station (BRLS) – Odisha
• Human Space Flight Centre (HSFC), Bengaluru.
• Indian National Committee for Space Research (INCOSPAR)
• Indian Regional Navigational Satellite System (IRNSS)
• Indian Space Science Data Centre (ISSDC)
• Integrated Space Cell
• Inter University Centre for Astronomy and Astrophysics (IUCAA)
• ISRO Inertial Systems Unit (IISU) – Thiruvananthapuram
• National Deep Space Observation Centre (NDSPO)
• Regional Remote Sensing Service Centres (RRSSC)
• Master Control Facility

Status: Decommissioned

The Satellite Launch Vehicle (SLV or SLV-3) was a 4-stage solid-propellant light launcher. It was intended to reach a height of 500 kilometres (310 miles) and carry a payload of 40 kilograms (88 pounds).[56] Its first launch took place in 1979 with two more in each subsequent year, and the final launch in 1983. Only two of its four test flights were successful.[57]

Status: Decommissioned

The Augmented Satellite Launch Vehicle (ASLV) was a five-stage solid propellant rocket with the capability of placing a 150-kilogram (330-pound) satellite into Low Earth Orbit. This project was started during the early 1980s to develop technologies needed for a payload to be placed into a geostationary orbit. Its design was based on Satellite Launch Vehicle.[58] The first launch test was held in 1987, and after that three others followed in 1988, 1992 and 1994, out of which only two were successful, before it was decommissioned.[57]

Status: Active

PSLV C42 on the First Launch Pad

The Polar Satellite Launch Vehicle (PSLV) is an expendable launch system developed by ISRO to allow India to launch its Indian Remote Sensing (IRS) satellites into Sun synchronous orbits. PSLV can also launch small satellites into geostationary transfer orbit (GTO). The reliability and versatility of the PSLV is proven by the fact that it has launched, as of 2014, seventy-one satellites/spacecraft (thirty-one Indian and forty foreign) into a variety of orbits.[59][60] The maximum number of satellites launched by the PSLV in a single launch is 104, in the PSLV-C37 launch on 15 February 2017.[61][62][63]

Decade-wise summary of PSLV launches:

Status: Active

GSLV F11 at Second Launch Pad

The Geosynchronous Satellite Launch Vehicle (GSLV) is an expendable launch system developed to enable India to launch its INSAT-type satellites into geostationary orbit and to make India less dependent on foreign rockets. At present, it is ISRO's second-heaviest launch vehicle and is capable of putting a total payload of up to 5 tons to low Earth orbit.[64] The vehicle is built by India, originally with a cryogenic engine purchased from Russia, while the ISRO developed its own cryogenic engine.

The first version of the GSLV (GSLV Mk.I), using the Russian cryogenic stage, became operational in 2004, after an unsuccessful first launch in 2001 and a second, successful development launch in 2003. The first attempt to launch the GSLV Mk.II with an Indian built cryogenic engine, GSLV-F06 carrying GSAT-5P, failed on 25 December 2010. The initial evaluation indicated that loss of control of the strap-on boosters caused the rocket to veer from its intended flight path, forcing a programmed detonation. Sixty-four seconds into the first stage of flight, the rocket began to break up due to aerodynamic forces from the high angle of attack. The body housing the 3rd stage, the cryogenic stage, incurred structural damage, forcing the range safety team to initiate a programmed detonation of the rocket.[65]

On 5 January 2014, GSLV-D5 launched GSAT-14 into its intended orbit. This marked the first successful flight using the indigenous cryogenic engine CE-7.5, making India the sixth country in the world to have this technology.[19][20]

Again on 27 August 2015, GSLV-D6 launched GSAT-6 into a transfer orbit. ISRO used the indigenously developed Cryogenic Upper Stage (CUS) for third time in this GSLV flight.[66]

On 8 September 2016, GSLV-F05 launched INSAT-3DR, a weather satellite weighing 2,211 kg (4,874 lb) into a geostationary transfer orbit (GTO). GSLV is designed to inject 2–5 tonnes (2.2–5.5 tons) -class of satellites into GTO. The launch took place from the Second Launch Pad at Satish Dhawan Space Centre SHAR (SDSC SHAR), Sriharikota. The GSLV-F05 flight was the first operational flight of GSLV carrying the Cryogenic Upper Stage (CUS). The indigenously developed CUS was carried on board for the fourth time during a GSLV-F05 flight. The GSLV-F05 vehicle is configured with three stages, including the CUS similar to the ones flown during the previous GSLV-D5 and D6 missions in January 2014 and August 2015.[67]

Decade-wise summary of GSLV Launches:

Status: Active

GSLV Mk III M1

GSLV-Mk III is a launch vehicle capable to launch four-tonne satellites into geosynchronous transfer orbit (GTO). GSLV-Mk III is a three-stage vehicle with a 110-tonne (120-ton) core liquid propellant stage (L-110) flanked by two 200-tonne (220-ton) solid propellant strap-on booster motors (S-200). The upper stage is cryogenic with a propellant loading of 25 tonnes (C-25). The vehicle has a lift-off mass of about 640 tonnes and is 43.43 metres tall. The payload fairing has a diameter of 5 metres and a payload volume of 100 cubic metres.[68] It allows India to become less dependent on foreign rockets for heavy lifting.[69]

On 18 December 2014, ISRO conducted an experimental test-flight of GSLV MK III carrying a crew module, to be used in future human space missions.[70] This suborbital test flight demonstrated the performance of GSLV Mk III in the atmosphere.[71]

A GSLV Mk III-D1 carrying the communication satellite GSAT-19 lifted off from the second launch pad at Satish Dhawan Space Centre in Sriharikota on 5 June 2017, and placed the communication satellite into a geosynchronous transfer orbit sixteen minutes after takeoff. GSAT-19 satellite has a mass of 3,136 kg (6,914 lb), and is configured around ISRO's standard I-3K bus.[72] On 14 July GSLV-Mk III was supposed to launch Chandrayaan 2 but due to some technical issues regarding the helium tank it was postponed to 22 July 2019. On 22 July 2019 the GSLV-Mk III launched India's second Moon mission, Chandrayaan-2.

Decade-wise summary of GSLV III launches:

INSAT-1B satellite: The broadcasting sector in India is highly dependent on INSAT system.

The Indian National Satellite System (INSAT) is a series of multipurpose geostationary satellites built and launched by ISRO to satisfy the telecommunications, broadcasting, meteorology and search-and-rescue needs of India. Commissioned in 1983, INSAT is the largest domestic communication system in the Asia-Pacific Region. It is a joint venture of the Department of Space, Department of Telecommunications, India Meteorological Department, All India Radio and Doordarshan. The overall coordination and management of INSAT system rests with the Secretary-level INSAT Coordination Committee.

The Indian Remote Sensing satellites (IRS) are a series of Earth observation satellites, built, launched and maintained by ISRO. The IRS series provides remote sensing services to the country and is the largest collection of remote sensing satellites for civilian use in operation today in the world. All the satellites are placed in polar Sun-synchronous orbit and provide data in a variety of spatial, spectral and temporal resolutions to enable several programmes to be undertaken relevant to national development. The initial versions are composed of the 1 (A, B, C, D) nomenclature. The later versions are named based on their area of application including OceanSat, CartoSat, ResourceSat.

ISRO currently operates three Radar Imaging Satellites (RISAT). RISAT-1 was launched from Sriharikota Spaceport on 26 April 2012 on board a PSLV. RISAT-1 carries a C band synthetic-aperture radar (SAR) payload, operating in a multi-polarisation and multi-resolution mode and can provide images with coarse, fine and high spatial resolutions.[74] RISAT-2 which was launched in 2009 due to delay with the indigenously developed C band SAR for RISAT-1. The X-band SAR used by RISAT-2 was obtained from IAI in return for launch services for TecSAR satellite.[75] PSLV-C46 launched the third satellite RISAT-2B intended to replace RISAT-2, on 22 May 2019 at 0000 (UTC) from Satish Dhawan Space Centre with an indigenously developed Synthetic Aperture Radar (SAR) operating in X Band.[76] This will be followed by a new series of high-resolution optical surveillance satellites called Cartosat-3 series.[77]

ISRO has also launched a set of experimental geostationary satellites known as the GSAT series. Kalpana-1, ISRO's first dedicated meteorological satellite,[78] was launched on a Polar Satellite Launch Vehicle on 12 September 2002.[79] The satellite was originally known as MetSat-1.[80] In February 2003 it was renamed to Kalpana-1 by the Indian prime minister Atal Bihari Vajpayee in memory of Kalpana Chawla – a NASA astronaut of Indian origin who perished in the Space Shuttle Columbia disaster.

ISRO also launched the Indo-French satellite SARAL on 25 February 2013. SARAL (or "Satellite with ARgos and AltiKa") is a cooperative altimetry technology mission. It is being used for monitoring the oceans' surface and sea levels. AltiKa measures ocean surface topography with an accuracy of 8 mm, against 2.5 cm on average using altimeters, and with a spatial resolution of 2 km.[81][82]

In June 2014, ISRO launched French Earth Observation Satellite SPOT-7 (mass 714 kg) along with Singapore's first nano satellite VELOX-I, Canada's satellite CAN-X5, Germany's satellite AISAT, via the PSLV-C23 launch vehicle. It was ISRO's 4th commercial launch.[83][84]

The South Asia Satellite (GSAT-9) is a geosynchronous communications satellite by ISRO for the South Asian Association for Regional Cooperation (SAARC) region. The satellite was launched on 5 May 2017. During the 18th SAARC summit held in Nepal in 2014, Indian prime minister Narendra Modi mooted the idea of a satellite serving the needs of SAARC member nations, part of his 'neighbourhood first' policy. One month after sworn in as the prime minister of India, in June 2014 Modi asked ISRO to develop a SAARC satellite, which can be dedicated as a 'gift' to the neighbors.

It is a satellite for the SAARC region with 12 Ku-band transponders (36 MHz each) and launch using the Indian Geosynchronous Satellite Launch Vehicle GSLV Mk-II. The total cost of launching the satellite is estimated to be about ₹2,350,000,000 (₹2.35 billion). The cost associated with the launch was met by the Government of India. The satellite enables full range of applications and services in the areas of telecommunication and broadcasting applications such as television (TV), direct-to-home (DTH), very small aperture terminals (VSATs), tele-education, telemedicine and disaster management support.

The Ministry of Civil Aviation has decided to implement an indigenous Satellite-Based Regional GPS Augmentation System also known as Space-Based Augmentation System (SBAS) as part of the Satellite-Based Communications, Navigation, Surveillance and Air Traffic Management plan for civil aviation. The Indian SBAS system has been given an acronym GAGAN – GPS Aided GEO Augmented Navigation. A national plan for satellite navigation including implementation of Technology Demonstration System over the Indian air space as a proof of concept has been prepared jointly by Airports Authority of India and ISRO. Technology Demonstration System was completed during 2007 by installing eight Indian Reference Stations at eight Indian airports and linked to the Master Control Centre located near Bangalore.

The first GAGAN navigation payload was fabricated and it was proposed to be flown on GSAT-4 in April 2010. However, GSAT-4 was not placed in orbit as GSLV Mk II-D3 could not complete the mission. Two more GAGAN payloads were to be subsequently flown, one each on two geostationary satellites, GSAT-8 and GSAT-10.

The third GAGAN payload satellite GSAT-15 with an estimated lifespan of 12 years similar to GSAT-10 was successfully launched on 10 November 2015 at 21:34:07 UTC aboard an Ariane 5 rocket.

Coverage of the IRNSS in blue, as of 2020

IRNSS with an operational name NAVIC is an independent regional navigation satellite system developed by India. It is designed to provide accurate position information service to users in India as well as the region extending up to 1500 km from its borders, which is its primary service area. IRNSS provides two types of services, namely, Standard Positioning Service (SPS) and Restricted Service (RS) and provides a position accuracy of better than 20 m in the primary service area.[85] It is an autonomous regional satellite navigation system being developed by Indian Space Research Organisation, which is under total control of Indian government. The requirement of such a navigation system is driven by the fact that access to global navigation systems like GPS is not guaranteed in hostile situations. ISRO initially planned to launch the constellation of satellites between 2012 and 2014 but the project got delayed by nearly two years.

On 1 July 2013, ISRO launched from Sriharikota the first Indian navigation satellite, the IRNSS-1A aboard a PSLV-C22. The constellation would comprise seven satellites built on the I-1K bus, each weighing around 1,450 kilograms, with three satellites in the Geostationary Earth Orbit (GEO) and four in Geosynchronous Earth orbit(GSO).[86]

On 4 April 2014, ISRO launched IRNSS-1B from Sriharikota, its second of seven IRNSS series. 19 minutes after launch, the PSLV-C24 was injected into its orbit. IRNSS-1C was launched on 16 October 2014, and IRNSS-1D on 28 March 2015.[87]

On 20 January 2016, IRNSS-1E was launched aboard PSLV-C31. On 10 March 2016, IRNSS-1F was launched aboard PSLV-C32. On 28 April 2016, IRNSS-1G was launched aboard PSLV-XL-C33; this satellite is the seventh and the last in the IRNSS system and completes India's own navigation system.

ISRO was in the process of developing four back-up satellites to the constellation of existing IRNSS satellites.[88]

On 31 August 2017, ISRO failed in its attempt to launch its eighth regional navigation satellite (IRNSS-1H). The satellite got stuck in the fourth stage of the Polar Satellite Launch Vehicle–PSLV-C39. A replacement satellite, IRNSS-1I, was successfully placed into orbit on 12 April 2018.[89]

To boost the accuracy of NAVIC system, ISRO is likely to extend the Indian Regional Navigation Satellite System programme with new IRNSS series which will be entirely a new project as per chairman K Sivan. The new IRNSS series is not meant to extend its coverage beyond the regional boundaries extending up to 1500 kilometers.[90]

The Space Capsule Recovery Experiment (SCRE or more commonly SRE or SRE-1)[99] is an experimental spacecraft that was launched on 10 January 2007 using the PSLV C7 rocket, along with three other satellites. It remained in orbit for 12 days before re-entering the Earth's atmosphere and splashing down into the Bay of Bengal.[100]

The SRE-1 was designed to demonstrate the capability to recover an orbiting space capsule and the technology for performing experiments in the microgravity conditions of an orbiting platform. It was also intended to test thermal protection, navigation, guidance, control, deceleration, and flotation systems, as well as study hypersonic aerothermodynamics, management of communication blackouts, and recovery operations. A follow-up project named SRE-2 was canceled mid-way after years of delay.[101]

on 18 December 2014, ISRO launched the Crew Module Atmospheric Re-entry Experiment aboard the GSLV Mk3 for a sub-orbital flight.[102][103] The crew module separated from the rocket at an altitude of 126 km and underwent free fall. The module heat shield experienced temperature in excess of 1600 °C. Parachutes were deployed at an altitude of 15 km to slow down the module which performed a splashdown in the Bay of Bengal. This flight was used to test orbital injection, separation and re-entry procedures and systems of the Crew Capsule. Also tested were the capsule separation, heat shields and aerobraking systems, deployment of parachute, retro-firing, splashdown, flotation systems and procedures to recover the Crew Capsule from the Bay of Bengal.[104][105]

On 5 July 2018, ISRO conducted a pad abort test of their launch abort system (LAS) at Satish Dhawan Space Centre, Sriharikota. This is the first in a series of tests to qualify the critical crew escape system technology for future crewed missions. The LAS is designed to quickly pull out the crew to safety in case of emergency.[106]

The newly established Human Space Flight Centre (HSFC) will coordinate the IHSF campaign.[107][108] ISRO will set up an astronaut training centre in Bengaluru to prepare personnel for flights on board the crewed vehicle. The centre will use simulation facilities to train the selected astronauts in rescue and recovery operations and survival in zero gravity, and will undertake studies of the radiation environment of space. ISRO will build centrifuges to prepare astronauts for the acceleration phase of the launch. Existing launch facilities in Satish Dhawan Space Centre will be upgraded for the Indian Human Spaceflight campaign.[109] Human Space Flight Centre and Glavcosmos signed an agreement on 1 July 2019 for the selection, support, medical examination and space training of Indian astronauts.[110] An ISRO Technical Liaison Unit (ITLU) will be setup in Moscow to facilitate the development of some key technologies and establishment of special facilities which are essential to support life in space.[111]

ISRO is working towards an orbital crewed spacecraft that can operate for seven days in a low Earth orbit. The spacecraft, called Gaganyaan (गगनयान), will be the basis of the Indian Human Spaceflight Programme. The spacecraft is being developed to carry up to three people, and a planned upgraded version will be equipped with a rendezvous and docking capability. In its maiden crewed mission, ISRO's largely autonomous 3-ton spacecraft will orbit the Earth at 400  km in altitude for up to seven days with a two-person crew on board. The crewed mission is planned to be launched on ISRO's GSLV Mk III in 2022.[112]

India plans to build a space station as a follow-up programme of the Gaganyaan mission. ISRO chairman K. Sivan has said that India will not join the International Space Station program and will instead build a 20 tonne space station on its own.[113][114] It is expected to be placed in a low earth orbit of 400 kilometres (250 mi) altitude and be capable of harbouring three humans for 15–20 days. Rough time-frame is five to seven years after completion of Gaganyaan project.[115][116]

Astrosat-1 in deployed configuration

Astrosat is India's first multi wavelength space observatory and full-fledged astronomy satellite. Its observation study includes active galactic nuclei, hot white dwarfs, pulsations of pulsars, binary star systems, supermassive black holes located at the centre of the galaxies, etc.[121]

The X-ray Polarimeter Satellite (XPoSat) is a planned mission to study polarisation. It is planned to have a mission life of five years and is planned to be launched in 2021.[122] The spacecraft is planned to carry the Polarimeter Instrument in X-rays (POLIX) payload which will study the degree and angle of polarisation of bright astronomical X-ray sources in the energy range 5–30 keV.[123]

Exoworlds is a joint proposal by ISRO, IIST and the University of Cambridge for a space telescope dedicated for atmospheric studies of exoplanets. The proposal is aiming for readiness by 2025.[124][125]

Rendering of Chandrayaan-1 spacecraft

Chandrayaan-1 was India's first mission to the Moon. The robotic lunar exploration mission included a lunar orbiter and an impactor called the Moon Impact Probe. ISRO launched the spacecraft using a modified version of the PSLV on 22 October 2008 from Satish Dhawan Space Centre, Sriharikota. The vehicle was inserted into lunar orbit on 8 November 2008. It carried high-resolution remote sensing equipment for visible, near infrared, and soft and hard X-ray frequencies. During its 312 days operational period (2 years planned), it surveyed the lunar surface to produce a complete map of its chemical characteristics and 3-dimensional topography. The polar regions were of special interest, as they possibly had ice deposits. The spacecraft carried 11 instruments: 5 Indian and 6 from foreign institutes and space agencies (including NASA, ESA, Bulgarian Academy of Sciences, Brown University and other European and North American institutes/companies), which were carried free of cost. Chandrayaan-1 became the first lunar mission to discover existence of water on the Moon.[126] The Chandrayaan-166 team was awarded the American Institute of Aeronautics and Astronautics SPACE 2009 award,[127] the International Lunar Exploration Working Group's International Co-operation award in 2008,[128] and the National Space Society's 2009 Space Pioneer Award in the science and engineering category.[129][130]

Main article: Mars Orbiter Mission

Artist's rendering of the Mars Orbiter Mission spacecraft, with Mars in the background.

The Mars Orbiter Mission (MOM), informally known as Mangalayaan, was launched into Earth orbit on 5 November 2013 by the Indian Space Research Organisation (ISRO) and has entered Mars orbit on 24 September 2014.[131] India thus became the first country to enter Mars orbit on its first attempt. It was completed at a record low cost of $74 million.[132]

MOM was placed into Mars orbit on 24 September 2014 at 8:23 am IST. The spacecraft had a launch mass of 1,337 kg (2,948 lb), with 15 kg (33 lb) of five scientific instruments as payload.

The National Space Society awarded the Mars Orbiter Mission team the 2015 Space Pioneer Award in the science and engineering category.[133][134]

Vikram lander mounted on top of the Chandrayaan-2 orbiter.

Chandrayaan-2 is second mission to the Moon, which included an orbiter, a lander and a rover. Chandrayaan-2 was launched on a Geosynchronous Satellite Launch Vehicle Mark III (GSLV-MkIII) on 22 July 2019, consisted of a lunar orbiter, the Vikram lander, and the Pragyan lunar rover, all of which were developed in India.[135][136] It is the first mission meant to explore the little-explored lunar south pole region.[137] The main objective of the Chandrayaan-2 mission is to demonstrate ISRO's ability to soft-land on the lunar surface and operate a robotic rover on the surface. Some of its scientific aims are to conduct studies of lunar topography, mineralogy, elemental abundance, the lunar exosphere, and signatures of hydroxyl and water ice.[138]

The Vikram lander, carrying the Pragyan rover, was scheduled to land on the near side of the Moon, in a south polar region at a latitude of about 70° south at approximately 1:50 am(IST) on 7 September 2019. However, the lander deviated from its intended trajectory starting from an altitude of 2.1 kilometres (1.3 mi), and telemetry was lost seconds before touchdown was expected.[139] A review board concluded that the crash-landing was caused by a software glitch.[140] The lunar orbiter was efficiently positioned in an optimal lunar orbit, extending its expected service time from one year to seven years.[141] There will be another attempt for soft landing on moon at the end of 2020 or early 2021, but without an orbiter.[142]

ISRO plans to follow up with Mars Orbiter Mission 2, and is assessing missions to Venus, the Sun, and near-Earth objects such as asteroids and comets.[148]

Geosynchronous Satellite Launch Vehicle Mark III is intended as a launch vehicle for crewed missions under the Indian Human Spaceflight Programme announced in Prime Minister Modi's 2018 Independence Day speech.[149]

ISRO plans to carry out a mission to the Sun by the year 2020.[150][151] The probe is named Aditya-L1 (Sanskrit: आदित्य L१) and will have a mass of about 400 kg (880 lb).[152] It is the first Indian space-based solar coronagraph to study the corona in visible and near-IR bands. Launch of the Aditya mission was planned during the heightened solar activity period in 2012, but was postponed to 2021 due to the extensive work involved in the fabrication, and other technical aspects. The main objective of the mission is to study coronal mass ejections (CMEs), their properties (the structure and evolution of their magnetic fields for example), and consequently constrain parameters that affect space weather.

ISRO is in the process of conducting conceptual studies to send a spacecraft to Jupiter or Venus.

ISRO is assessing an orbiter mission to Venus called Shukrayaan-1, that could launch as early as 2023 to study its atmosphere.[153] Some budget has been allocated to perform preliminary studies as part of 2017–18 Indian budget under Space Sciences,[154][155][156] and solicitations for potential instruments were requested in 2017[157] and in 2018.

The ideal launch window to send a spacecraft to Jupiter occurs every 33 months. If the mission to Jupiter is launched, a flyby of Venus would be required.[158]

The next Mars mission, Mars Orbiter Mission 2, also called Mangalyaan 2 (Sanskrit: मंगलयान-२), will be launched in 2024.[146] It will have a less elliptical orbit around Mars and could weigh seven times more than the first mission.[159] This orbiter mission will facilitate the community to address several open science problems. The science payload of the planned satellite is estimated at no more than 100 kg (220 lb).

ISRO signed an Implementation Arrangement (IA) on December 2017 for pre-phase A, phase A study and completed the feasibility report on March 2018 with Japan Aerospace Exploration Agency (JAXA)[160] to explore the polar regions of Moon for water[161] with a Joint Lunar Polar Exploration mission that would be launched by 2024.[162][163]

Small Satellite Launch Vehicle or SSLV is in development for the commercial launch of small satellites with a payload of 500 kg to low Earth orbit. SSLV would be a four-staged vehicle with three solid propellant-based stages and a Velocity Trimming Module. The maiden flight is expected in July 2019 from Satish Dhawan Space Centre.[164][165]

As a first step towards realizing a two-stage-to-orbit (TSTO) fully re-usable launch vehicle, a series of technology demonstration missions have been conceived. For this purpose, the winged Reusable Launch Vehicle Technology Demonstrator (RLV-TD) has been configured. The RLV-TD is acting as a flying testbed to evaluate various technologies such as hypersonic flight, autonomous landing, powered cruise flight, and hypersonic flight using air-breathing propulsion.

First in the series of demonstration trials was the Hypersonic Flight Experiment (HEX). ISRO launched the prototype's test flight from the Sriharikota spaceport in February 2016. The prototype, called RLV-TD, weighs around 1.5 tonnes and flew up to a height of 70 km.[166] The test flight, known as HEX, was completed on 23 May 2016. A scaled up version of could serve as fly-back booster stage for their winged TSTO concept.[167]

The Unified Launch Vehicle (ULV) is a launch vehicle in development by ISRO. The project's core objective is to design a modular architecture that will enable the replacement of the PSLV, GSLV Mk II and GSLV Mk III with a single family of launchers. The SCE-200 engine can even be clustered for heavy launch configuration. The ULV will be able to launch 6000 kg to 10,000 kg of payload into GTO. This will mark the renunciation of the liquid stage with Vikas engine, which uses toxic UDMH and N₂O₄.

ISRO is conducting preliminary research for the development of a Super heavy-lift launch vehicle which is planned to have a lifting capacity of over 50–60 tonnes into an unspecified orbit.[168]

India uses its satellite communication network – one of the largest in the world – for applications such as land management, water resources management, natural disaster forecasting, radio networking, weather forecasting, meteorological imaging and computer communication.[169] Business, administrative services, and schemes such as the National Informatics Centre (NIC) are direct beneficiaries of applied satellite technology.[170] Dinshaw Mistry, on the subject of practical applications of the Indian space program, writes:

"The INSAT-2 satellites also provide telephone links to remote areas; data transmission for organisations such as the National Stock Exchange; mobile satellite service communications for private operators, railways, and road transport; and broadcast satellite services, used by India's state-owned television agency as well as commercial television channels. India's EDUSAT (Educational Satellite), launched aboard the GSLV in 2004, was intended for adult literacy and distance learning applications in rural areas. It augmented and would eventually replace such capabilities already provided by INSAT-3B."

The IRS satellites have found applications with the Indian Natural Resource Management program, with Regional Remote Sensing Service Centres in five Indian cities, and with Remote Sensing Application Centres in twenty Indian states that use IRS images for economic development applications. These include environmental monitoring, analysing soil erosion and the impact of soil conservation measures, forestry management, determining land cover for wildlife sanctuaries, delineating groundwater potential zones, flood inundation mapping, drought monitoring, estimating crop acreage and deriving agricultural production estimates, fisheries monitoring, mining and geological applications such as surveying metal and mineral deposits, and urban planning.

Integrated Space Cell, under the Integrated Defence Staff headquarters of the Indian Ministry of Defence,[171] has been set up to utilize more effectively the country's space-based assets for military purposes and to look into threats to these assets.[172][173] This command will leverage space technology including satellites. Unlike an aerospace command, where the air force controls most of its activities, the Integrated Space Cell envisages cooperation and coordination between the three services as well as civilian agencies dealing with space.[171] With 14 satellites, including GSAT-7A for the exclusive military use and the rest as dual use satellites, India has the fourth largest number of satellites active in the sky which includes satellites for the exclusive use of Indian Air Force and Indian Navy respectively.[174] GSAT-7A, an advanced military communications satellite exclusively for the Indian Air Force,[175] is similar to Indian Navy's GSAT-7, and GSAT-7A will enhance Network-centric warfare capabilities of the Indian Air Force by interlinking different ground radar stations, ground airbase and Airborne early warning and control (AWACS) aircraft such as Beriev A-50 Phalcon and DRDO AEW&CS.[175][176] GSAT-7A will also be used by Indian Army's Aviation Corps for its helicopters and UAV's operations.[175][176] In 2013, ISRO launched GSAT-7 for the exclusive use of the Indian Navy to monitor the Indian Ocean Region (IOR) with the satellite's 2,000 nautical mile 'footprint' and real-time input capabilities to Indian warships, submarines and maritime aircraft.[174] To boost the network-centric operations of the IAF, ISRO launched GSAT-7A on 19 December 2018.[177][174] The RISAT series of radar-imaging earth observation satellites is also meant for Military use.[178] ISRO launched EMISAT on 1 April 2019. EMISAT is an electronic intelligence (ELINT) satellite which has a weight of 436-kg. It will help improve the situational awareness of the Indian Armed Forces by providing information and location of hostile radars.[179]

India's satellites and satellite launch vehicles have had military spin-offs. While India's 93–124-mile (150–200-kilometre) range Prithvi missile is not derived from the Indian space programme, the intermediate range Agni missile is drawn from the Indian space programme's SLV-3. In its early years, when headed by Vikram Sarabhai and Satish Dhawan, ISRO opposed military applications for its dual-use projects such as the SLV-3. Eventually, the Defence Research and Development Organisation (DRDO) based missile programme borrowed human resources and technology from ISRO. Missile scientist A.P.J. Abdul Kalam (elected president of India in 2002), who had headed the SLV-3 project at ISRO, moved to DRDO to direct India's missile programme. About a dozen scientists accompanied Kalam from ISRO to DRDO, where he designed the Agni missile using the SLV-3's solid fuel first stage and a liquid-fuel (Prithvi-missile-derived) second stage. The IRS and INSAT satellites were primarily intended and used for civilian-economic applications, but they also offered military spin-offs. In 1996 New Delhi's Ministry of Defence temporarily blocked the use of IRS-1C by India's environmental and agricultural ministries to monitor ballistic missiles near India's borders. In 1997 the Indian Air Force's "Airpower Doctrine" aspired to use space assets for surveillance and battle management.[180]

Institutions like the Indira Gandhi National Open University and the Indian Institutes of Technology use satellites for scholarly applications.[181] Between 1975 and 1976, India conducted its largest sociological programme using space technology, reaching 2400 villages through video programming in local languages aimed at educational development via ATS-6 technology developed by NASA.[182] This experiment—named Satellite Instructional Television Experiment (SITE)—conducted large scale video broadcasts resulting in significant improvement in rural education.[182] Education could reach far remote rural places with the help of above programs.

ISRO has applied its technology for telemedicine, directly connecting patients in rural areas to medical professionals in urban locations via satellites.[181] Since high-quality healthcare is not universally available in some of the remote areas of India, the patients in remote areas are diagnosed and analysed by doctors in urban centers in real time via video conferencing.[181] The patient is then advised medicine and treatment.[181] The patient is then treated by the staff at one of the 'super-specialty hospitals' under instructions from the doctor.[181] Mobile telemedicine vans are also deployed to visit locations in far-flung areas and provide diagnosis and support to patients.[181]

ISRO has also helped implement India's Biodiversity Information System, completed in October 2002.[183] Nirupa Sen details the program: "Based on intensive field sampling and mapping using satellite remote sensing and geospatial modeling tools, maps have been made of vegetation cover on a 1: 250,000 scale. This has been put together in a web-enabled database that links gene-level information of plant species with spatial information in a BIOSPEC database of the ecological hot spot regions, namely northeastern India, Western Ghats, Western Himalayas and Andaman and Nicobar Islands. This has been made possible with collaboration between the Department of Biotechnology and ISRO."[183]

The Indian IRS-P5 (CARTOSAT-1) was equipped with high-resolution panchromatic equipment to enable it for cartographic purposes.[33] IRS-P5 (CARTOSAT-1) was followed by a more advanced model named IRS-P6 developed also for agricultural applications.[33] The CARTOSAT-2 project, equipped with single panchromatic camera that supported scene-specific on-spot images, succeeded the CARTOSAT-1 project.[184]

Several ISRO satellites have been launched by foreign space agencies (of Europe, USSR / Russia, and United States). The details (as of December 2016) are given in the tables below.[193]

ISRO satellites that were launched by foreign agencies, are listed in the table below.

In India, electromagnetic spectrum, being a scarce resource for wireless communication, is auctioned by the Government of India to telecom companies for use. As an example of its value, in 2010, 20 MHz of 3G spectrum was auctioned for ₹677 billion (US$9.5 billion). This part of the spectrum is allocated for terrestrial communication (cell phones). However, in January 2005, Antrix Corporation (commercial arm of ISRO) signed an agreement with Devas Multimedia (a private company formed by former ISRO employees and venture capitalists from the US) for lease of S band transponders (amounting to 70 MHz of spectrum) on two ISRO satellites (GSAT 6 and GSAT 6A) for a price of ₹14 billion (US$200 million), to be paid over a period of 12 years. The spectrum used in these satellites (2500 MHz and above) is allocated by the International Telecommunication Union specifically for satellite-based communication in India. Hypothetically, if the spectrum allocation is changed for utilisation for terrestrial transmission and if this 70 MHz of spectrum were sold at the 2010 auction price of the 3G spectrum, its value would have been over ₹2,000 billion (US$28 billion). This was a hypothetical situation. However, the Comptroller and Auditor General of India considered this hypothetical situation and estimated the difference between the prices as a loss to the Indian Government.[232][233]

There were lapses on implementing Government of India procedures. Antrix/ISRO had allocated the capacity of the above two satellites to Devas Multimedia on an exclusive basis, while rules said it should always be non-exclusive. The Cabinet was misinformed in November 2005 that several service providers were interested in using satellite capacity, while the Devas deal was already signed. Also, the Space Commission was kept in the dark while taking approval for the second satellite (its cost was diluted so that Cabinet approval was not needed). ISRO committed to spending ₹7.66 billion (US$110 million) of public money on building, launching, and operating two satellites that were leased out for Devas.

In late 2009, some ISRO insiders exposed information about the Devas-Antrix deal,[233][234] and the ensuing investigations resulted in the deal being annulled. G. Madhavan Nair (ISRO Chairperson when the agreement was signed) was barred from holding any post under the Department of Space. Some former scientists were found guilty of "acts of commission" or "acts of omission". Devas and Deutsche Telekom demanded US$2 billion and US$1 billion, respectively, in damages.[235] Government of India's Department of Revenue and Ministry of Corporate Affairs initiated an inquiry into Devas shareholding.

The Central Bureau of Investigation concluded investigations into the Antrix-Devas scam and registered a case against the accused in the Antrix-Devas deal under Section 120-B, besides Section 420 of IPC and Section 13(2) read with 13(1)(d) of PC Act, 1988 on 18 March 2015 against the then Executive Director of Antrix Corporation, two officials of USA-based company, Bangalore based private multimedia company, and other unknown officials of Antrix Corporation or Department of Space.[236][237]

Devas Multimedia started arbitration proceedings against Antrix in June 2011. In September 2015, the International Court of Arbitration of the International Chamber of Commerce ruled in favour of Devas, and directed Antrix to pay US$672 million (Rs 44.35 billion) in damages to Devas.[238] Antrix opposed the Devas plea for tribunal award in the Delhi High Court.[239]