| Rudram-1 (NGARM) | |
|---|---|
 DRDO Rudram-1 on a Su-30MKI | |
| Type | Air-to-surfaceanti-radiation missile[1] |
| Place of origin | India |
| Service history | |
| In service | Rudram-1: 2022 to present |
| Used by | Indian Air Force |
| Production history | |
| Designer | Defence Research and Development Organisation |
| Designed | 2012–present |
| Manufacturer | Adani Defence & Aerospace |
| Produced | Under Development |
| Variants |
|
| Specifications | |
| Mass | Rudram-1 : 600 kg (1,300 lb)[2] |
| Length | 5.5 m (18 ft) |
| Warhead |
|
| Warhead weight | |
Detonation mechanism | Optical proximity fuze |
| Engine | Dual-pulsed rocket motor |
| Propellant | Solid fuel |
Operational range | |
| Flight altitude | |
| Maximum speed | |
Guidance system |
Mid-course :INS +Passive radar homing Terminal :MMWActive radar homing[15][16]
Terminal :IIR homing
Mid-course :INS +SatNav +Passive radar homing Terminal :IIR homing[17] |
| Accuracy | 5 mCEP |
Launch platform |
|
TheRudram (lit. 'Roaring')[18] is a series ofsupersonic andhypersonic[19] air-to-surfaceground attack andanti-radiation missiles in development by theDefence Research and Development Organisation of India.[20] It can be launched from a range of altitudes with largestandoff distance[21][22] for destroying enemy surveillance radars, communication stations and bunkers.[23][24]
It will be manufactured jointly byBharat Dynamics Limited andBharat Electronics Limited after trials and introduction.[25] DRDO also involvedAdani Defence & Aerospace under Development cum Production Partner programme formass production.[26] The hypersonic variant Rudram-2 will also be manufactured by Adani Defence and Aerospace in theirHyderabad facility.[27]
Defence Research and Development Laboratory is the primary agency which carried out the design and development of the missile system along withArmament Research and Development Establishment,Defence Electronics Research Laboratory,High Energy Materials Research Laboratory,Research Centre Imarat andTerminal Ballistics Research Laboratory.[28] Many subsystem level developmental works were outsourced to private sector players.[29] Software Development Institute of the Indian Air Force (IAF)[30] helped in the integration of DRDO ARM withSukhoi Su-30MKI while theHindustan Aeronautics Limited (HAL), Nasik Division did the AKU-58 launcher modification which undertook extensive wind-tunnel tests at National Trisonic Aerodynamic Facilities division ofNational Aerospace Laboratories,Bengaluru.[31][32][33]
DRDO ARM has a range of 100–250 km[34][35] which is made to be integrated withSukhoi Su-30MKI as its primary test platform, although can be used withDassault Mirage 2000,SEPECAT Jaguar,HAL Tejas andHAL Tejas Mark 2/MWF in future.[1] According to the then Director ofResearch Centre Imarat,G. Satheesh Reddy, the missile will feature amillimetre wave seeker (mmW) transmitting on frequencies of 30gigahertz and above while capable of lock-on before launch andlock-on after launch modes.[36][37] Mid-course guidance is accomplished throughinertial navigation system and two-waydatalink combined withGlobal Positioning System/NavICsatellite guidance through digital filtering as fall back to correct accumulated errors and a passive homing head (PHH) seeker which is developed by Defence Electronics Research Laboratory that can detect radio frequency emissions from 100 km away. PHH is a wide-band receiver system operating withinD band toJ band frequency of theelectromagnetic spectrum.[38] Its compact front-end structure is due to the use ofmonolithic microwave integrated circuit (MMIC) technology for identification of radiation emitting sources.[39][40][41]
The missile is a single-stage, approximately 5.5-metre in length and 600 kg[42] of weight withcruciform wing surface to increase high maneuverability and to give constant aerodynamic characteristics similar toAstrabeyond-visual-range missile.[39] It uses pre-fragmented warhead with opticalproximity fuze and is powered by a dual-pulsed solid rocket motor made by Premier Explosives Limited undertechnology transfer from DRDO.[43][44] The dual-pulsed solid rocket motor produces variable thrust within a range of 0.6 to 2 Mach that reduces the overall reaction time while widening the targeting envelope as well as the engagement capability. DRDO ARM can target mobile integratedair-defence system as well asradar station that shutdown to avoid detection.[34][45]
Development had begun by April 2012 at Defence Research and Development Laboratory.[46] The project was officially approved in December 2012 with a budget of₹317.2crore (equivalent to₹598 crore or US$71 million in 2023) with project completion by 2017.[47][48] The feasibility studies were done in 2012–2013 with the aim is to develop a fully indigenous tactical, anti-radiation capable missile for theIndian Air force (IAF) which is comparable toAGM-88E AARGM,MAR-1,Kh-31P and better thanMartel orKh-25MP.[36]
From 2014, the development of missile picked up interest of the IAF.[32] As of 2014, missile design and hardware development are in progress with first successful flight trial to happen before year 2017.[49] IAF was initially very concerned with the higher weight and shorter range of new missile compare to the western ones due to the use of bulky Russian maderadio frequency (RF) seekers.[50] IAF at the same time was also negotiating with USA for 1,500 AGM-88E which IAF was planning to induct in the next five years.[25][51] The technologies that were developed by DRDO for NGARM are wide-band passive seeker, milli-metric wave active seeker,radome for the seekers and dual-pulsedpropulsion system which are mostly lessons learnt during the development ofAstra andBarak 8.[51]
The Captive Flight Trial–1 of DRDO ARM was completed in April/May 2016 byNo. 20 Squadron of IAF which checked the performance of seeker,navigation andcontrol system, structural capability andaerodynamic vibrations while the Drop Flight Trial was completed by December 2016 with the missile released bySukhoi Su-30MKI at a speed of 0.8Mach, from 6.5 km altitude.[52][53] Further carriage flight test was carried out to check mechanical/electrical integration as well as software interfacing of the missile before the maiden flight on 18 January 2018, where the missile was successfully flight tested for the first time on parametres such as auto-launch sequence, store separation, control guidance, aerodynamics, thermal batteries, airframe and propulsion without a seeker which were all proven successful.[54] On 25 January 2019, NGARM was fired from a Sukhoi Su-30MKI overBay of Bengal off the coast ofOdisha that hit the designated target with a high degree of accuracy.[55][56] The missile achieved an accuracy within 10 mCEP covering a range of 100 km.[33] The developmental test proved the performance of seeker, structural integrity of the missile, correct functioning of navigation and control system while validation of aerodynamic capability.[39] The missile can strike at distances double the intended range depending upon the altitude. NGARM will further undergo series of carriage and release flight trials to check the performance of seekers against a different range of targets.
Next trials during the period of July to August 2019 will be conducted initially to check the performance of indigenous passive seeker developed by Defence Electronics Research Laboratory with further test for an active seeker at later stage.[32] While the crucial sensor technology is yet to be fully mastered by DRDO, the IAF wants fast track development of NGARM due to urgent requirement of newer anti-radiation missile.[57] NGARM developmental trials will resume from 2020 after a gap of two years.[58]
The DRDO Anti-Radiation Missile or NGARM now officially named Rudram-1 was successfully test-fired from Integrated Test Range, Balasore on 9 October 2020.[59][60][61] DRDO is planning final test flight between 28 and 29 December 2021 before moving Rudram-1 for serial production from 2022.[62]
In 2023, report suggested that the missile is ready for user trials.[63] In July 2024, reports emerged about another flight test of Rudram-1 missile.[64][65]
The release flight trial was conducted in 2022 fromSukhoi Su-30MKI.[66] The first test of the anti radiation of the Rudram-II was reported in July 2023. It has a range of 300 km and has an additional Imaging Infrared (IIR) seeker. The missile can be fired from Sukhoi Su-30MKI andMirage 2000.[67]
The Rudram-II air-to-ground missile was successfully flight-tested from a Sukhoi-30MKI fighter off the coast of Odisha on 29 May 2024. The propulsion system and control & guiding algorithm were validated by the test.[68][69] It will replaceKh-31s in IAF inventory.[70] The missile can be launched from a range of altitudes and can identify signals from radars and enemy radio frequencies at ranges more than 100 km. It has Lock-On-Before/After-Launch systems installed, which allow for flexible targeting. The missile also has an internal guidance system that allows it to find its way to the target on its own after launch.[71]
According to report, the plan is to make the missile a part of the Air Force by 2022 after conducting six to seven more tests. The missile's passive homing head can detect, classify and engage targets over a wide band of frequencies as programmed.[72]
In 2022, Indian Air Force has proposed to theMinistry of Defence to purchase Rudram-1 missile through a contract worth₹14,000crore (equivalent to₹150 billion or US$1.8 billion in 2023).[73][74]
DRDO is planning to bring further software improvements to handle a larger variety of targets under various operational conditions while developing a separate ground-based variant to be launched from mobile launcher.[25][32] DRDO is developing Rudram-2 with a range of 300 km and air to ground version Rudram-3 with 550 km range.[75]
