ELECTRONIC WARFARE – EW is a Crucial Op Requirement

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Military operations are executed in an information environment increasingly complicated by the electromagnetic spectrum. Electronic warfare (EW) is going to play a crucial role in any future conflict. With war clouds hovering over Ladakh, it is time to refresh all issues related to the electromagnetic spectrum (EM spectrum). The purpose of electronic warfare is to deny the opponent the advantage of, and ensure friendly unimpeded access to, the EM spectrum. EW can be applied from air, sea, land, and/or space by manned and unmanned systems, and can target humans, communications, radar, or other assets (military and civilian).

Electronic attack (EA), electronic defence (ED) and electronic surveillance (ES), electronic countermeasures (ECM), electronic protective measures (EPM) and electronic support measures (ESM) are some of terms that are indicative of the total environmental action. Besides EW, other EM operations include intelligence, surveillance, target acquisition, and reconnaissance (ISTAR) and signals intelligence (SIGINT). Each country has an EW policy and doctrine.Primary EW activities are in electro-optical; infrared and radio frequency countermeasures; and involves EM compatibility and deception; radio jamming; radar jamming and deception and electronic counter-countermeasures (or anti-jamming); electronic masking, probing, reconnaissance, and intelligence; electronic security; EW reprogramming; emission control; spectrum management; and wartime reserve modes.

EW Operations

EA and ECM involve the offensive use of EM energy, directed energy, or anti-radiation weapons to attack personnel, facilities, or equipment with the intent of degrading, neutralizing, or destroying enemy combat capability including human life. In the case of anti-radiation weapons, many times this includes missiles or bombs that can home in on a specific signal (radio or radar) and follow that path directly to impact, thus destroying the system broadcasting.ED or electronic counter-countermeasures (ECCM) involves protecting friendly forces from enemy use of ECM. Flares and chaff are often used to distract IR and radar guide missiles to miss their target. Other examples are spread spectrum technologies, use of restricted frequency lists, emissions control, low observability (stealth) technology and DRFM decoy systems.

Electronic Warfare Support

Electronic warfare support (ES) to detect, intercept, identify, locate, and/or localize sources of intended and unintended radiated electromagnetic (EM) energy. Intelligence, surveillance and reconnaissance (ISR) or intelligence, surveillance, target acquisition, and reconnaissance (ISTAR) are the terms used. The purpose is to provide immediate recognition, prioritization, and targeting of threats to battlefield commanders. Signal Intelligence (SIGINT), is related process of analysing and identifying intercepted transmissions from sources such as radio communication, mobile phones, radar, or microwave communications. SIGINT covers electronic intelligence (ELINT), and communications intelligence (COMINT). Analysis parameters measured include frequency, bandwidth, modulation, and polarization.

Optical Fibre Cable (OFC) Hacking

Many people do not realize that unguarded fibre optic cables are often easily accessible, making them a potential targets for hackers looking to tap into the huge amounts of data that travel across these fibre networks. Systemic malignant penetration perpetrated by compromising data quality of the stream on the broadband cable through either OFC or copper medium could be an exponentially augmented hazard There are serious security vulnerabilities that impact operations.

Important EW Operations

During World War II, there was extensive use of EW, also referred to as the “Battle of the Beams”. The first application of EW in WWII was to defeat those navigational radars. Chaff was also introduced during WWII. Electronic warfare played a major role in many military operations during the Vietnam War. Operation Mole Cricket 19 was a suppression of enemy air defences (SEAD) campaign launched by the Israeli Air Force against Syrian targets on 9 June 1982, at the outset of the 1982 Lebanon War. The operation was the first time in history that a Western-equipped air force successfully destroyed a Soviet built SAM network. The result was a decisive Israeli victory, leading to the colloquial name the “Bekaa Valley Turkey Shoot”. The battle lasted about two hours, and involved innovative tactics and technology. By the end of the day, Israeli forces had destroyed 29 of 30 SAM batteries deployed in the Bekaa Valley, and shot down 82-86 enemy aircraft, with minimal losses of its own. In 2007, an Israeli attack on a suspected Syrian nuclear site (Operation Orchard) used electronic warfare systems to disrupt Syrian air defences while Israeli jets crossed much of Syria, bombed their targets, and returned to Israel undeterred.

Defence Avionics Research Establishment (DARE)

DARE is a laboratory of the Indian Defence Research and Development Organisation (DRDO), located in Bangalore. It is one of the two DRDO laboratories involved in the research and development of airborne electronic warfare and mission avionics systems. It was established in 1986 as a Project Laboratory, then named “Advanced Systems Integration and Evaluation Organisation” (ASIEO). On 1 June 2001, ASIEO became a full-fledged DRDO laboratory and was renamed as Defence Avionics Research Establishment (DARE). DARE works on development of electronic warfare systems and mission avionics for aircraft. ASIEO developed the first mission computer for Light Combat Aircraft in 1991. It also developed a self-protection suite for the aircraft that included radar warning receiver, laser warning receiver, jammer, missile approach warning system and countermeasure dispensers under a program named Mayawi in collaboration with Israel’s Elisra.

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Sukhoi Su-30MKI uses Tarang Mk 2 radar warning receiver developed by DARE and manufactured by Bharat Electronics Limited (BEL). Its mission computer, radar processor and indication management computer were also developed by DARE and manufactured by Hindustan Aeronautics Limited’s (HAL) Hyderabad division. In 2006, DARE partnered with EADS’s defence electronics division to develop a missile approach warning system for the Indian Air Force (IAF) based on the latter’s AN/AAR-60 system. The jointly developed system was put into trials in 2008 and was planned to be co-produced with Alpha Technologies. DARE has also partnered with Elisra to jointly develop electronic warfare systems for Indian and Israeli aircraft. DARE has utilized this partnership to develop an electronic warfare suite for Mikoyan MiG-29 named D-29.

DARE has worked with HAL to develop avionics for upgrade programs for several IAF aircraft. It participated in the development of a mission computer for Jaguar and in the development of navigation and electronic warfare systems for Mikoyan MiG-27M. DARE, in collaboration with Centre for Airborne Systems and Defence Electronics Research Laboratory, developed antennas for electronic warfare support measures and communication systems of DRDO AEW&CS. DARE also developed a unified electronic warfare suite with an integrated radar jammer and a radar warning receiver for HAL Tejas.

Defence Electronics Research Laboratory (DLRL)

DLRL is a laboratory of the DRDO, located in Hyderabad, to design and development of integrated Electronic Warfare systems for the Indian Armed Forces. For testing and evaluation of EW systems ELSEC, an extension of DLRL, was established in 1998. EW system simulation and modelling facilities are located inside ELSEC to carry out simulation of complex systems. DLRL works on COMINT/ ELINT/ ESM/ ECM systems covering radar and communication frequency bands. It also conducts systems integration and evaluation of these technologies on various platforms, like aircraft, ships, helicopters, vehicles, etc. DLRL also conducts specialized training courses in Electronic Warfare and technology management for DRDO Scientists and officers of the Indian Armed Forces. DLRL is involved in the Integrated Guided Missile Development Program (IGMDP), providing ground electronic support for IGMDP, and expertise in the design and development of various components, antennas and sub-systems for HF to microwave and millimetric wave frequencies. DLRL has designed, developed and produced a large number of ruggedised EW Systems. These systems have been inducted into the Services after rigorous field evaluation and user testing.

SPECTRA – Rafale’s internal “Electronic Warfare” (EW) System

SPECTRA (Self-Protection Equipment Countering Threats to Rafale Aircraft) was jointly developed by Thales Group and MBDA for the Dassault Rafale fighter aircraft. The full SPECTRA integrated electronic warfare suite provides long-range detection, identification and accurate localisation of infrared homing, radio frequency and laser threats. The system incorporates radar warning receiver, laser warning and Missile Approach Warning for threat detection plus a phased array radar jammer and a decoy dispenser for threat countering. The SPECTRA system consists of two new-generation infrared missile warning sensors. The new infrared array detector enhances performance with regard to the range at which a missile firing will be detected. With two sensors, each equipped with a fish-eye lens, it provides a spherical field of view around the aircraft. It also offers improved rejection of false alarms and gives an angular localisation capability which will be compatible with the future use of Directional Infrared Counter Measures (DIRCM). Dassault claims that stealthy jamming modes of SPECTRA actually reduce the aircraft’s apparent radar signature, perhaps using active cancellation technology. SPECTRA ensures Rafale’s outstanding survivability against the latest airborne and ground threats. The system carries out reliable long-range detection, identification and localisation of threats, allowing the pilot to instantly select the most effective defensive measures based on combinations of radar jamming, infrared or radar decoying and evasive manoeuvres. The angular localisation performance of the SPECTRA sensors makes it possible to accurately locate ground threats in order to avoid them, or to target them for destruction with precision guided munitions. The SPECTRA’s airborne threat localisation, gives Rafale superior situational awareness.

French AREOS – Recce Pod

For both strategic and tactical reconnaissance missions, the French Armed Forces have been using the new generation Thales AREOS reconnaissance system on the Rafale. The equipment has been operationally used in Libya, Mali, the Central African Republic, Iraq and Syria. To shorten the intelligence gathering cycle and accelerate the tempo of operations, the AREOS pod is fitted with a data link which allows high resolution images to be transmitted back to military decision makers in real time.

Modern warfare has made impressive strides in the areas of communications, radar and surveillance. Military SIGINT platforms are trying to cover the spectrum from HF to Ka band, sometimes over an enormous dynamic range. All efforts are on for improving EW technologies through means such as machine learning. While cognitive EW is a work in progress, the miniaturization and density of electronics components continue to increase, and if cooling technology keeps up, this will drive radio frequency (RF) system functional consolidation and enhance sensor performance.

The future will see multispectral, multimode and multifunction capability, said Chris Rappa, product line director for RF, EW and advanced electronics with BAE Systems’ FAST Labs research and development organization. Active electronically scanned arrays (AESA) are already multimode but over a narrow band, he said. The aim is to build large or small totally digital arrays, where the electronics behind every element in the array are digital and the array can be controlled in every aspect at the element level. Ten years from now Rappa expects to see very large, all-digital, precisely controlled arrays that are multifunction, multimode and capable of learning on the fly to be cooperative or disruptive, whenever they need to be. He expects they will be highly flexible – able to do signals intelligence, ESM, EA, radar, positioning, navigation and timing (PNT), and communications, all from one array and one box, and all cognitively and adaptively controlled.

Major Driving Factors – Global EW Market

As per Global Newswire report of December 10, 2019, the global Electronic Warfare market was US$ 25.813 Billion in 2018 and is projected to grow at a CAGR of 4.58% from 2019 to 2026. A major factor for the growth of the market will be the increasing focus on cognitive electronic warfare technology. The increasing rate of change in electronic, cyber, and optical domains will involve a perceptible shift in war-fighting techniques. Since the avenues of technological advancement in these fields are limitless, new generations of equipment will emerge at a rapid rate. The challenge would be to integrate them into the physical domain of war-fighting and achieve the desired effect on the adversary. The relatively new field of Quantum Computing has the potential of creating a new generation of satellites. Trends like these will help drive the market further over the forecast period.

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Equipment like the Russian Krasukha-4 or the Turkish KORAL ground-based jammer can generate very high power output over a broadband of frequencies that can be effective at distances up to 300km, which is a big jump from the previous generation of jammers. Truly multi-role aircraft operating in high threat AD environment will be more effective than single mission electronic attack legacy aircraft. There is a greater emphasis on information superiority and situational awareness, and this is expected to be a major factor driving spending in this sector.Aerial Platform is predicted to be the second-largest segment in the market, with a global market share of over 30% in 2026.

Jon Harper wrote in National Defense in July 2019, that Gen. Joseph Dunford, chairman of the Joint Chiefs of Staff, has said that EW is the No. 1 functional area where investments need to be made in the coming years. “Being in a position to achieve superiority in the electromagnetic spectrum is absolutely critical,” he said. “If you take a look at what China and Russia are doing in terms of their war-fighting strategy, they emphasize being able to operate effectively in the electromagnetic spectrum,” said Mark Gunzinger, a non-resident senior fellow at the Center for Strategic and Budgetary Assessments. That includes being able to deny an enemy’s ability to control the spectrum. It is a domain where wars can be won or lost, he said. New offensive and defensive capabilities that could be useful include directed energy weapons such as high power microwaves that are capable of destroying electronic components, and new unmanned systems with EW weapons, he said.

Way Ahead for India

South Asia is becoming a place of EW action, including its coupling with cyber warfare (CW). Chinese armed forces have been going through major reforms since 2015. Armed forces technical functions have been consolidated under the People’s Liberation Army Strategic Support Forces (PLASSF). Clearly indicating greater focus on intelligence and information warfare. The Chinese recognise the complementarities between the electronic and cyber warfare. The theatre commands are tailored to exploit the unified information warfare service in the form of the PLASSF.

The Pakistan Air Force (PAF) has acquired advanced electronic warfare capabilities and airborne warning and control system aircraft to conduct electronic warfare and to support the command and control. Another area that Pakistan has been pushing is the Software Defined Radio (SDR). These ensure clear or encrypted voice and data communication in VHF and UHF frequency band as well as fully automatic integration with tactical and strategic networks to provide “cellular phone” services to tactical users. A Chinese made JY-27A counter-very-low-observable radar has been seen at Mianwali airbase in Pakistan as per a Jane’s report.

India’s Land Warfare Doctrine 2018, clearly speaks of enhancing the capabilities in network centric and electronic warfare. India now has a Defence Cyber Agency (DCA) that is already active. IAF’s Integrated Air Command and Control System (IACCS) greatly enhances the network warfare capability. The Rafale brings a state of the art EW suite. All other combat aircraft of IAF already have electronic self-protection suites, and many have offensive ECM pods. Indian Naval ships have a powerful EW complement. Indian armed forces are pushing to improve network centric and electronic warfare capabilities. Notwithstanding, India is still highly import dependent on high end EW systems. Joint Venture route may be the best option initially. Israel and DRDO have been working closely on many radar and EW projects, including for the LCA ‘Tejas’. There is thus a need to push for indigenous technologies.