Turkey Military News, Reports, Data, etc.
- Thread starter Jeff Head
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Future radar projects of Turkiye
Network-based radar operation is also becoming an important issue today. A concept different from the structure in which all radars currently made in RADNET transfer data to a single center is aimed. In this context, radars need to work together. In other words, a structure that can benefit from the advantages of target and radar geometry should be provided, not trace fusion. This also provides protection against mixing. Because even if a radar in the system is confused, other radars can continue to detect. It is aimed to evaluate signals coming from different angles by using the echoes of radars at different angles against stealth aircraft. Significant technologies are required to synchronize each other's frequency, waveforms and time, and a network-based structure capable of communication in very wide bands is considered.
Network-Based Distributed Radar Applications
*Resource Optimization via Joint Management
*Plot and/or Data Fusion
*Hypersonic Target and Ballistic Missile Handover
*Time, Frequency, and Waveform Synchronization.
*Coverage Optimization
*High Performance
-Resistance to jamming
-Variety in the geometry of detection
*Endurance
Multistatic radars, on the other hand, provide superiority to radars in terms of invisible vision. The fact that the location of the Almaçar is not known provides this situation. However, the radars in question must be synchronized in time and frequency slots. The need for PCB and processor structures that can process and transfer data at hundreds of gigabits per second is also increasing due to compact filters that can fit into small antenna gaps, stronger and more efficient power amplifier structures and their packaging and increased digitization.
Multistatik Radar ( Radar system which has transmitters and receivers in separate locations)
More resistant to Radar EW Systems ( Radar Jammers)
Geometry advantage against stealth technology
*Coverage area
*Scan time
-Transmitter can be omni (omni-directional)
-Multistatic MIMO (Multiple input multiple output)
*Communication
*Synchronization
-Time, frequency
-Phase, beam
*Noise elimination/filtering
*Separation (noise separation)
Göndermeç=Transmitter
Almaç=Receiver
Network-based radar operation is also becoming an important issue today. A concept different from the structure in which all radars currently made in RADNET transfer data to a single center is aimed. In this context, radars need to work together. In other words, a structure that can benefit from the advantages of target and radar geometry should be provided, not trace fusion. This also provides protection against mixing. Because even if a radar in the system is confused, other radars can continue to detect. It is aimed to evaluate signals coming from different angles by using the echoes of radars at different angles against stealth aircraft. Significant technologies are required to synchronize each other's frequency, waveforms and time, and a network-based structure capable of communication in very wide bands is considered.
Network-Based Distributed Radar Applications
*Resource Optimization via Joint Management
*Plot and/or Data Fusion
*Hypersonic Target and Ballistic Missile Handover
*Time, Frequency, and Waveform Synchronization.
*Coverage Optimization
*High Performance
-Resistance to jamming
-Variety in the geometry of detection
*Endurance
Multistatic radars, on the other hand, provide superiority to radars in terms of invisible vision. The fact that the location of the Almaçar is not known provides this situation. However, the radars in question must be synchronized in time and frequency slots. The need for PCB and processor structures that can process and transfer data at hundreds of gigabits per second is also increasing due to compact filters that can fit into small antenna gaps, stronger and more efficient power amplifier structures and their packaging and increased digitization.
Multistatik Radar ( Radar system which has transmitters and receivers in separate locations)
More resistant to Radar EW Systems ( Radar Jammers)
Geometry advantage against stealth technology
*Coverage area
*Scan time
-Transmitter can be omni (omni-directional)
-Multistatic MIMO (Multiple input multiple output)
*Communication
*Synchronization
-Time, frequency
-Phase, beam
*Noise elimination/filtering
*Separation (noise separation)
Göndermeç=Transmitter
Almaç=Receiver
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One more uncertainty is fabrication method and topology of the component.
Example 1, wing spar and fuselage in one piece like J-35 reduces weight by 38%, eliminating usage of steel or titanium joint. The illustration below is aluminium.
Example 2, 3D printing in large one piece, material composition in gradient, freedom in topology can drastically reduce weight.
Yes. A while back it was confirmed to be electron beam 3D printing.
Future radar projects of Turkiye
Network-based radar operation is also becoming an important issue today. A concept different from the structure in which all radars currently made in RADNET transfer data to a single center is aimed. In this context, radars need to work together. In other words, a structure that can benefit from the advantages of target and radar geometry should be provided, not trace fusion. This also provides protection against mixing. Because even if a radar in the system is confused, other radars can continue to detect. It is aimed to evaluate signals coming from different angles by using the echoes of radars at different angles against stealth aircraft. Significant technologies are required to synchronize each other's frequency, waveforms and time, and a network-based structure capable of communication in very wide bands is considered.
Network-Based Distributed Radar Applications
*Resource Optimization via Joint Management
*Plot and/or Data Fusion
*Hypersonic Target and Ballistic Missile Handover
*Time, Frequency, and Waveform Synchronization.
*Coverage Optimization
*High Performance
-Resistance to jamming
-Variety in the geometry of detection
*Endurance
Multistatic radars, on the other hand, provide superiority to radars in terms of invisible vision. The fact that the location of the Almaçar is not known provides this situation. However, the radars in question must be synchronized in time and frequency slots. The need for PCB and processor structures that can process and transfer data at hundreds of gigabits per second is also increasing due to compact filters that can fit into small antenna gaps, stronger and more efficient power amplifier structures and their packaging and increased digitization.
Multistatik Radar ( Radar system which has transmitters and receivers in separate locations)
More resistant to Radar EW Systems ( Radar Jammers)
Geometry advantage against stealth technology
*Coverage area
*Scan time
-Transmitter can be omni (omni-directional)
-Multistatic MIMO (Multiple input multiple output)
*Communication
*Synchronization
-Time, frequency
-Phase, beam
*Noise elimination/filtering
*Separation (noise separation)
Göndermeç=Transmitter
Almaç=Receiver
So point 2 and 3 on the SSB radar roadmap are currently being worked on.
First test firing of Kuzgun-KY from Marlin USV:
Via @buchmaru from twitter
I wonder if @Stealthflanker can make an RCS analysis of this
Aselsan radar road map
2022
TEİRS (Mobile EİRS)
SİPER-UMAR (Same as TEİRS)
STR (Weapon locating radar)
HTKR (Hava Trafik Kontrol Radarı/Air Traffic Control Radar)
ACAR (Land surveillance radar)
AKKOR-PULAT (Active protection system)
MURAD-X (Fighter AESA radar)
İHÖR (İlk Hız Ölçüm Radarı/Velocity measurement radar)
Siper-Ürün1 AB (Siper product 1 seeker)
GÖKTUĞ (Gokdogan BVR missile)
2023
CENK (Naval AESA radar, first use on I-class FFG)
AİR (Low altitude radar)
SİPER-ÇFAKR (Siper multi-functional radar)
F-16 AKINCI (MURAD integration?)
YENER (Yere Nüfuz Eden Radar/Ground Penetrating Radar)
SERHAT DUAL? (Mortar locating radar)
AKKOR
KARACA (Land surveillance radar)
İLKER
AESA SAR PODU
KALKAN-1 TWTA (Travelling Wave Tube Array Kalkan-1 upgrade?)
2024
AURA (Compact AESA radar for CIWS and anti-drone systems)
KAMA (Radar of KAMA active protection system)
METRAD-2 (Meteorology radar)
AKBABA
HİSAR-D (Naval Hisar, VLS?)
HÜRJET AESA
SMR
DGR
2025
DRONE FOPRAD (Forest penetrating radar)
ALPER-II
ORTA MENZİL STR (Mid-range STR (artillery locating radar))
MOBİL RADAR/KULE (Mobile radar/tower)
SİPER UMRAB (Uzun Menzilli Radar Arayıcı Başlık/Long-range radar seeker head)
2026
PARS (Passive Radar System)
SEIRS (Fixed and scaled-up TEIRS rumored to have 4x modules)
FULMAR
GÖKHAN DG (Dual Guidance- Probably dual guidance seeker for Gökhan Ramjet AA missile)
YARI AKTİF AB ( Semi-active seeker probably for low-cost rocket interception)
MMU BURUN RADARI (MMU Nose Radar/BURFIS)
MİLLİ HİBRİT HSS (National Hybrid Air defense system)
METRAD C (Another Meteorology Radar)
2027
ARDA
HİBRİT (RF+IIR) AB (Hybrid RF+IIR Seeker)
DRONA ENTEGRE GPR (Drone Integrated Ground Penetrating Radar)
İHA ERKEN İHBAR (UAV Early Warning Radar)
UÇAK ERKEN İHBAR (Airborne Early Warning Radar)
YÖRÜNGE TAKİP RADARI (Orbital Tracking Radar)
2028
YİRAD ( High Altitude Radar)
SİPER BALİSTİK FÜZE ÖNLEME (Ballistic Missile İnterception)
2029
VHF ERKEN UYARI RADARI (VHF Early Warning Radar)
2030
ÇAFRAD FAZ 2 (ÇAFRAD Phase2)
UYDUDAN ERKEN İHBAR ( Satellite Early Warning Radar)
SÜRÜ İHA ÜZERİ RADARLAR ( Swarm UAV Radars)
GÖKTÜRK-3 SAR (Göktürk-3 Satellite SAR)
Thnx to @theinsider
2022
TEİRS (Mobile EİRS)
SİPER-UMAR (Same as TEİRS)
STR (Weapon locating radar)
HTKR (Hava Trafik Kontrol Radarı/Air Traffic Control Radar)
ACAR (Land surveillance radar)
AKKOR-PULAT (Active protection system)
MURAD-X (Fighter AESA radar)
İHÖR (İlk Hız Ölçüm Radarı/Velocity measurement radar)
Siper-Ürün1 AB (Siper product 1 seeker)
GÖKTUĞ (Gokdogan BVR missile)
2023
CENK (Naval AESA radar, first use on I-class FFG)
AİR (Low altitude radar)
SİPER-ÇFAKR (Siper multi-functional radar)
F-16 AKINCI (MURAD integration?)
YENER (Yere Nüfuz Eden Radar/Ground Penetrating Radar)
SERHAT DUAL? (Mortar locating radar)
AKKOR
KARACA (Land surveillance radar)
İLKER
AESA SAR PODU
KALKAN-1 TWTA (Travelling Wave Tube Array Kalkan-1 upgrade?)
2024
AURA (Compact AESA radar for CIWS and anti-drone systems)
KAMA (Radar of KAMA active protection system)
METRAD-2 (Meteorology radar)
AKBABA
HİSAR-D (Naval Hisar, VLS?)
HÜRJET AESA
SMR
DGR
2025
DRONE FOPRAD (Forest penetrating radar)
ALPER-II
ORTA MENZİL STR (Mid-range STR (artillery locating radar))
MOBİL RADAR/KULE (Mobile radar/tower)
SİPER UMRAB (Uzun Menzilli Radar Arayıcı Başlık/Long-range radar seeker head)
2026
PARS (Passive Radar System)
SEIRS (Fixed and scaled-up TEIRS rumored to have 4x modules)
FULMAR
GÖKHAN DG (Dual Guidance- Probably dual guidance seeker for Gökhan Ramjet AA missile)
YARI AKTİF AB ( Semi-active seeker probably for low-cost rocket interception)
MMU BURUN RADARI (MMU Nose Radar/BURFIS)
MİLLİ HİBRİT HSS (National Hybrid Air defense system)
METRAD C (Another Meteorology Radar)
2027
ARDA
HİBRİT (RF+IIR) AB (Hybrid RF+IIR Seeker)
DRONA ENTEGRE GPR (Drone Integrated Ground Penetrating Radar)
İHA ERKEN İHBAR (UAV Early Warning Radar)
UÇAK ERKEN İHBAR (Airborne Early Warning Radar)
YÖRÜNGE TAKİP RADARI (Orbital Tracking Radar)
2028
YİRAD ( High Altitude Radar)
SİPER BALİSTİK FÜZE ÖNLEME (Ballistic Missile İnterception)
2029
VHF ERKEN UYARI RADARI (VHF Early Warning Radar)
2030
ÇAFRAD FAZ 2 (ÇAFRAD Phase2)
UYDUDAN ERKEN İHBAR ( Satellite Early Warning Radar)
SÜRÜ İHA ÜZERİ RADARLAR ( Swarm UAV Radars)
GÖKTÜRK-3 SAR (Göktürk-3 Satellite SAR)
Thnx to @theinsider
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