Iff ppt
- 1. PROJECT ON IFFSYSTEMFORDEFENCE Guided by: Submitted by: Mr. Satyendra Sharma Kunal Dua H.O.D.(ECE Dept.) Himanshi Sharma Parnika Singh Himanshu Sharma
- 2. CONTENTS : Objective Problem Statement Radar Basic Principle Of Radar Working Of Radar Open Source Software/Hardware Used Application Of Radar Advantages Conclusion Future & Research Work
- 3. OBJECTIVE: To prevent friendly-fire by soldiers in battle. To maintain command and control in telecommunication . To enable military and national interrogation systems to identify aircraft, vehicles or forces and prevent fratricide. To determine their bearing and range from the interrogator.
- 4. PROBLEM STATEMENT: Incidents of friendly fire have been responsible for numerous casualties amongst soldiers. For controlling human cost of war caused by miscommunication and aggressive tactics. Each soldier’s rifle is fitted with a laser that sends out an IFF query. If a friendly soldier is in line of sight, the IFF system produces a feedback signal. This signal can be used to generate an audio/visual warning, or momentarily jam the rifle.
- 5. RADAR : It is an electromagnetic system used for the detection and location of reflecting objects like aircrafts , ships , vehicles etc. It radiates energy into space and detecting the reflected echo signal from an object or target. Radar can perform its function at long or short distances and under conditions impervious to optical and infrared sensors.
- 6. BASIC PRINCIPLE OF RADAR :
- 7. WORKING OF RADAR : Transmitter transmits a high power pulse to a switch, which then directs the pulse to be transmitted out an antenna and the switch switches control to receiver, which allows the antenna to receive echoed signals. The switch may toggle control between the transmitter and the receiver as much as 1000 times per second. A radar transponder, that replies to each signal by transmitting a response containing encoded data.
- 8. The transponder is a radio receiver and transmitter which receives on one frequency (1030 MHz) and transmits on another (1090 MHz).
- 9. METHOD PROPOSED: A soldier equipped with the IFF system has a responder unit on their body armor, and an initiator unit mounted on their rifle. An MCU in the responder unit will decrypt the laser message using a pre-set private key. If decryption is successful, the MCU identifies which friendly soldier is currently aiming at the target soldier.
- 10. IMPLEMENTATION STRATEGY & WORKING OF THE PROJECT: The system facilitates in recognition of friendly soldier. Our initial design concept used a directed RF signal on the rifle instead of a laser to transmit the IFF query. If the RF signal transmitted from the rifle will sufficiently directional, the IFF query will be send only to RF receiver’s fire. If potential fratricide is detected, a buzzer mounted on the rifle goes off, signaling that the current rifle position might result in friendly fire.
- 11. BLOCK DIAGRAM: System Architecture
- 12. OPEN SOURCE SOFTWARE/HARDWARE USED: Hardware used: Laser RF Transmitter RF Receiver Buzzer Software used: C Programing Keil µVision
- 13. APPLICATIONS OF RADAR : Air Traffic Control. Ship Safety. Space. Remote Sensing. Defence or Military purposes.
- 14. ADVANTAGES : Radar can perform functions at short and long distances. Measure distance with high accuracy and in all weather conditions. Radar units operates on different frequencies. It can operate in darkness ,haze,fog rain as well as snow.
- 15. CONCLUSION: This allows an accurate target signature to be obtained. It provides a advanced tactic to segregate between friend and enemy. The major military benefits of IFF include preventing "friendly fire" and being able to positively identify friendly forces. IFF can positively identify friendly targets but not hostile ones.
- 16. FUTURE & RESEARCH WORK: 1. Each transmitter will transmit a first coded signal which will be detected by the receivers in other vehicles. 2. The receivers provide an unblocking signal after the first coded signal is correctly identified. 3. The unblocking signal clears a radiation transmission path in the vehicle. 4. This path containing a reflector which reflects the received signal back to the source of the transmission. 5. The reflector adds a further predetermined code to the signal reflected from the reflector with each vehicle having another detector for detecting a reflected signal and a device to identify the further predetermined code.