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E bombs emits electromagnetic shock waves that destroys electronic circuits and communication networks of enemy forces .
The Indian Defence Research and Development Organisation (DRDO) is developing an E-bomb which will emit electromagnetic shock waves that destroy electronic circuits and communication networks of enemy forces, said Avinash Chander, DRDO chief and scientific advisor to the defence minister.
The E-bomb, he said, would give an option to the military as the bomb can target the enemy’s mobile targets, air defence systems, mobile or static radars, naval vessels with communication systems and even ill-shielded communication or electronic systems at a military base. “So next time there is a Kargil or a LoC violation, you may not hear gunshots or mortar shells, because the electromagnetic bomb will throw life out of gear”, said Chander to newspapers.
The Indian Defence Research and Development Organisation (DRDO) is developing an E-bomb which will emit electromagnetic shock waves that destroy electronic circuits and communication networks of enemy forces, said Avinash Chander, DRDO chief and scientific advisor to the defence minister.
The E-bomb, he said, would give an option to the military as the bomb can target the enemy’s mobile targets, air defence systems, mobile or static radars, naval vessels with communication systems and even ill-shielded communication or electronic systems at a military base.
Understand here what is EMP !!
The ElectroMagnetic Pulse (EMP) effect was first observed during the early testing of high altitude airburst nuclear weapons . The effect is characterised by the production of a very short (hundreds of nanoseconds) but intense electromagnetic pulse, which propagates away from its source with ever diminishing intensity, governed by the theory of electromagnetism. The ElectroMagnetic Pulse is in effect an electromagnetic shock wave.
This pulse of energy produces a powerful electromagnetic field, particularly within the vicinity of the weapon burst. The field can be sufficiently strong to produce short lived transient voltages of thousands of Volts (ie kiloVolts) on exposed electrical conductors, such as wires, or conductive tracks on printed circuit boards, where exposed.
It is this aspect of the EMP effect which is of military significance, as it can result in irreversible damage to a wide range of electrical and electronic equipment, particularly computers and radio or radar receivers. Subject to the electromagnetic hardness of the electronics, a measure of the equipment’s resilience to this effect, and the intensity of the field produced by the weapon, the equipment can be irreversibly damaged or in effect electrically destroyed. The damage inflicted is not unlike that experienced through exposure to close proximity lightning strikes, and may require complete replacement of the equipment, or at least substantial portions thereof.
Commercial computer equipment is particularly vulnerable to EMP effects, as it is largely built up of high density Metal Oxide Semiconductor (MOS) devices, which are very sensitive to exposure to high voltage transients. What is significant about MOS devices is that very little energy is required to permanently wound or destroy them, any voltage in typically in excess of tens of Volts can produce an effect termed gate breakdown which effectively destroys the device. Even if the pulse is not powerful enough to produce thermal damage, the power supply in the equipment will readily supply enough energy to complete the destructive process. Wounded devices may still function, but their reliability will be seriously impaired. Shielding electronics by equipment chassis provides only limited protection, as any cables running in and out of the equipment will behave very much like antennae, in effect guiding the high voltage transients into the equipment.
Computers used in data processing systems, communications systems, displays, industrial control applications, including road and rail signalling, and those embedded in military equipment, such as signal processors, electronic flight controls and digital engine control systems, are all potentially vulnerable to the EMP effect.
Other electronic devices and electrical equipment may also be destroyed by the EMP effect. Telecommunications equipment can be highly vulnerable, due to the presence of lengthy copper cables between devices. Receivers of all varieties are particularly sensitive to EMP, as the highly sensitive miniature high frequency transistors and diodes in such equipment are easily destroyed by exposure to high voltage electrical transients. Therefore radar and electronic warfare equipment, satellite, microwave, UHF, VHF, HF and low band communications equipment and television equipment are all potentially vulnerable to the EMP effect.
It is significant that modern military platforms are densely packed with electronic equipment, and unless these platforms are well hardened, an EMP device can substantially reduce their function or render them unusable.
Classified as Directed Energy Weapons,NNEMP weapons generate a less powerful EMP and have radii of effectiveness ranging from a few hundred meters to a few kilometres.6 Military NNEMP weapons are probably in existence in the form of either aircraft or missile delivered e-bombs7or mounted systems on aircraft, drones or missiles. Boeing claims to have successfully tested an EMP missile — Counter-electronics High-powered Microwave Advanced Missile Project (CHAMP) —at the Utah Test and Training Range in 2012.8 Small suitcase-sized ground-based NNEMP weapons with short ranges are also feasible.9The adverse impact of a NNEMP attack is envisaged to be more on systems and devices with electronic components, as the voltages required to damage semi-conductors are small.
Experts consider that NNEMP are easy to develop and relatively inexpensive and that these could also be put together using Commercial-Off-The-Shelf (COTS) materials.Avi Schnurr, CEO and President of the Electric Infrastructure Security (EIS) Council of the United Kingdom (UK), has stated that ‘the biggest issue with non-nuclear EMP weapons is that the complexity and threshold required to produce them is minimal, to say the most.’Given the relative ease of development, not only major powers but even smaller countries could develop them.
On March 25, 2003, CBS NEWS reported the first possible use of an e-bomb by noting that ‘The U.S. Air Force has hit Iraqi TV with an experimental electro-magnetic pulse device called the “E-Bomb” in an attempt to knock it off the air and shut down Saddam Hussein’s propaganda machine.
https://defenceupdate.in/what-is-e-bomb-does-india-have-an-e-bombelectro-magnetic-bomb/
The Indian Defence Research and Development Organisation (DRDO) is developing an E-bomb which will emit electromagnetic shock waves that destroy electronic circuits and communication networks of enemy forces, said Avinash Chander, DRDO chief and scientific advisor to the defence minister.
The E-bomb, he said, would give an option to the military as the bomb can target the enemy’s mobile targets, air defence systems, mobile or static radars, naval vessels with communication systems and even ill-shielded communication or electronic systems at a military base. “So next time there is a Kargil or a LoC violation, you may not hear gunshots or mortar shells, because the electromagnetic bomb will throw life out of gear”, said Chander to newspapers.
The Indian Defence Research and Development Organisation (DRDO) is developing an E-bomb which will emit electromagnetic shock waves that destroy electronic circuits and communication networks of enemy forces, said Avinash Chander, DRDO chief and scientific advisor to the defence minister.
The E-bomb, he said, would give an option to the military as the bomb can target the enemy’s mobile targets, air defence systems, mobile or static radars, naval vessels with communication systems and even ill-shielded communication or electronic systems at a military base.
Understand here what is EMP !!
The ElectroMagnetic Pulse (EMP) effect was first observed during the early testing of high altitude airburst nuclear weapons . The effect is characterised by the production of a very short (hundreds of nanoseconds) but intense electromagnetic pulse, which propagates away from its source with ever diminishing intensity, governed by the theory of electromagnetism. The ElectroMagnetic Pulse is in effect an electromagnetic shock wave.
This pulse of energy produces a powerful electromagnetic field, particularly within the vicinity of the weapon burst. The field can be sufficiently strong to produce short lived transient voltages of thousands of Volts (ie kiloVolts) on exposed electrical conductors, such as wires, or conductive tracks on printed circuit boards, where exposed.
It is this aspect of the EMP effect which is of military significance, as it can result in irreversible damage to a wide range of electrical and electronic equipment, particularly computers and radio or radar receivers. Subject to the electromagnetic hardness of the electronics, a measure of the equipment’s resilience to this effect, and the intensity of the field produced by the weapon, the equipment can be irreversibly damaged or in effect electrically destroyed. The damage inflicted is not unlike that experienced through exposure to close proximity lightning strikes, and may require complete replacement of the equipment, or at least substantial portions thereof.
Commercial computer equipment is particularly vulnerable to EMP effects, as it is largely built up of high density Metal Oxide Semiconductor (MOS) devices, which are very sensitive to exposure to high voltage transients. What is significant about MOS devices is that very little energy is required to permanently wound or destroy them, any voltage in typically in excess of tens of Volts can produce an effect termed gate breakdown which effectively destroys the device. Even if the pulse is not powerful enough to produce thermal damage, the power supply in the equipment will readily supply enough energy to complete the destructive process. Wounded devices may still function, but their reliability will be seriously impaired. Shielding electronics by equipment chassis provides only limited protection, as any cables running in and out of the equipment will behave very much like antennae, in effect guiding the high voltage transients into the equipment.
Computers used in data processing systems, communications systems, displays, industrial control applications, including road and rail signalling, and those embedded in military equipment, such as signal processors, electronic flight controls and digital engine control systems, are all potentially vulnerable to the EMP effect.
Other electronic devices and electrical equipment may also be destroyed by the EMP effect. Telecommunications equipment can be highly vulnerable, due to the presence of lengthy copper cables between devices. Receivers of all varieties are particularly sensitive to EMP, as the highly sensitive miniature high frequency transistors and diodes in such equipment are easily destroyed by exposure to high voltage electrical transients. Therefore radar and electronic warfare equipment, satellite, microwave, UHF, VHF, HF and low band communications equipment and television equipment are all potentially vulnerable to the EMP effect.
It is significant that modern military platforms are densely packed with electronic equipment, and unless these platforms are well hardened, an EMP device can substantially reduce their function or render them unusable.
Classified as Directed Energy Weapons,NNEMP weapons generate a less powerful EMP and have radii of effectiveness ranging from a few hundred meters to a few kilometres.6 Military NNEMP weapons are probably in existence in the form of either aircraft or missile delivered e-bombs7or mounted systems on aircraft, drones or missiles. Boeing claims to have successfully tested an EMP missile — Counter-electronics High-powered Microwave Advanced Missile Project (CHAMP) —at the Utah Test and Training Range in 2012.8 Small suitcase-sized ground-based NNEMP weapons with short ranges are also feasible.9The adverse impact of a NNEMP attack is envisaged to be more on systems and devices with electronic components, as the voltages required to damage semi-conductors are small.
Experts consider that NNEMP are easy to develop and relatively inexpensive and that these could also be put together using Commercial-Off-The-Shelf (COTS) materials.Avi Schnurr, CEO and President of the Electric Infrastructure Security (EIS) Council of the United Kingdom (UK), has stated that ‘the biggest issue with non-nuclear EMP weapons is that the complexity and threshold required to produce them is minimal, to say the most.’Given the relative ease of development, not only major powers but even smaller countries could develop them.
On March 25, 2003, CBS NEWS reported the first possible use of an e-bomb by noting that ‘The U.S. Air Force has hit Iraqi TV with an experimental electro-magnetic pulse device called the “E-Bomb” in an attempt to knock it off the air and shut down Saddam Hussein’s propaganda machine.
https://defenceupdate.in/what-is-e-bomb-does-india-have-an-e-bombelectro-magnetic-bomb/
