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Projects

TÜBİTAK BİLGEM, which works to develop unique and high value-added technologies that will sustain our country's competitiveness by making strategic collaborations and R&D studies with the defense industry, public institutions and private sector in the fields of informatics, information security and advanced electronics, presents projects that make an impact in the national and international arena. UEKAE has accomplished many successful projects in the fields of national electronics and cryptology with its R&D studies carried out in line with the mission of BİLGEM, which it operates under its umbrella, to shape the future and direct the science and technology of the future.

The Ongoing Projects

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National Production Integrated Underwater Combat Management System – Preveze (MÜREN-PREVEZE)

The National Production Integrated Underwater Combat Management System (MÜREN-PREVEZE) Project aims to develop a unique underwater combat management system for Preveze class submarines. This system has the capability to work integrated with acoustic sensors, as well as being adaptable to non-acoustic sensors. It also offers important capabilities such as TMA-based track/target management and weapon engagement management. Noteworthy features of the project include national integrated underwater systems, precision positioning module and weapon control unit for DM2A4/AKYA torpedoes. This innovative project will strengthen our national defense capacity by increasing the effectiveness of our Preveze-class submarines in underwater operations. The technical features of the system can be listed as follows: - National Integrated Underwater CMS, - Sensor integration and track/target management, - Integrated Sonar dry-side signal processing, - Target Movement Analysis (TMA) and tactical planning, - Precision Positioning Module, - Weapon control unit for DM2A4/AKYA torpedoes, - National Acoustic Warfare Support Center.
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ADVENT-MÜREN-SYS AKS Project

ADVENT-MÜREN-SYS AKS Project is a project that aims to provide the GÜR class submarines with a national heavy torpedo AKYA firing capability. This project aims to develop the ADVENT-MÜREN Combat Management System (CMS) by combining the ADVENT and MÜREN Combat Management Systems. The project will contribute to our national defense strategy by strengthening the firing capabilities of GÜR-class submarines. ADVENT-MÜREN CMS will increase our maritime security by enabling GÜR Class submarines to effectively launch AKYA torpedoes. Considering the importance of this project in the future, ADVENT-MÜREN-SYS is planned to be used in the Half-Life Modernization of Gür Classes and national submarine development activities. In this way, our submarines will have a more effective defense capability by having the most up-to-date technologies. The ADVENT-MÜREN-SYS AKS Project stands out as a success of our national defense industry. This project will strengthen Turkey's submarine capabilities and make our presence in the seas more effective. It will also contribute to the development of indigenous defense technologies. The successful completion of this project will increase Turkey's independence and security in the field of submarine technologies. The ADVENT-MÜREN-SYS AKS Project is considered as an important milestone in our defense industry.
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Real Time Operating System (GIS) Adaptation Projects

GIS was developed for the development of the Safety Critical Solid Real-Time Operating System, which is an important step of the roadmap, with the aim of developing fully national avionic system design and integration capability, which is among the critical technologies. With this project, it is aimed to end the foreign dependency of safety-critical system projects in line with national needs, to provide a scalable and maintainable safety-critical embedded software development platform that has the flexibility to quickly meet the needs of domestic needers, and to create a system that will also be preferred for civilian embedded system applications thanks to its reducible features. In this roadmap, the completed and ongoing projects for integration with GİS are shown. The operating system, developed in accordance with DO-178C Level-A processes, can be run in multi-core or single-core ARINC-653 mode, which provides safety-critical application interfaces, or in POSIX mode at PSE-53 operating level if desired. Development environment activities such as selecting and configuring the operating system's operating modes, application development, debugging, event analysis and simulation can be performed through the Integrated Development Environment (TGO) developed on the Eclipse platform. The Real-Time Operating System, developed in accordance with DO-178C Level-A processes, is designed in a modular structure so that it can run on different microprocessor families and different single board computers. With the ASP (Architecture Support Package) and BSP (Board Support Package) layers provided, the hardware family it supports is suitable for expansion. ARINC-653 and POSIX interface compatibility has been tested with separately developed test environments and the operating system, which has successfully passed these tests, has also proved its compliance with the standards in this regard by communicating with other single card computers running on different operating systems. Other operating systems developed using these interfaces facilitate the transition to the integrated national real-time operating system. GİS, which is of critical importance in terms of preventing the export of critical data with the national operating system in classified projects, enabling full nationalization in embedded platforms, supporting an internationally competitive industrial sector thanks to reduced costs, and the formation of new SMEs, plays an important role in reducing Turkey's foreign dependence in this field.  
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National Combat Aircraft (MMU) Life Support System

The MMU Life Support System Project aims to establish a life support system within the flight control system for the 5th generation TF-x to be produced for the National Combat Aircraft (MMU). The life support system will fulfill three basic functions: - Protecting the crew from physiological disturbances caused by changes in barometric pressure and G-LoC, - Providing qualified breathing conditions for the crew, - Providing defogging and cabin ventilation.   The MMU Life Support System Project aims to establish a life support system within the flight control system of the 5th generation TF-x aircraft designed for the National Combat Aircraft (NCA). The project aims to fulfill three main functions of the life support system: 1) To protect the crew from physiological disturbances caused by changes in barometric pressure and G-LoC (Limitation Due to Strong Movements), 2) To ensure qualified breathing conditions of the crew, 3) To provide demisting and cabin ventilation. These functions are important to protect the health and safety of the crew during the flight of the MMU, to provide sufficient oxygen and to ensure proper ventilation of the interior cabin. Within the scope of the project, the life support system is being designed to effectively fulfill these basic functions.
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Multistatic Radar Capability Acquisition (MSR-YK)

The Multistatic Radar Capability Acquisition (MSR-CA) Project aims to design a simulation environment model for the analysis and optimization of multistatic radar systems. This project focuses on the following objectives: 1) Design of the Simulation Environment Model: A simulation environment model will be designed to analyze and optimize the performance of multistatic radar systems. This model will be able to simulate system parameters and operating conditions to evaluate system performance in different scenarios. 2) Verification of the Model: A test setup will be created to validate the designed simulation environment model. The test setup will provide the opportunity to test the accuracy and performance of the model by simulating conditions similar to real world scenarios. 3) Making Comparisons: Different multistatic radar systems and algorithms will be compared using the simulation environment model and validation test setup. These comparisons will provide the opportunity to evaluate the performance, sensitivity, target detection capabilities and other important features of the systems. The MSR-YK Project is seen as an important step in the development and optimization of multistatic radar systems. The successful completion of this project will contribute to the advancement of multistatic radar technology and the development of systems with more effective radar capabilities.
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Robot Mounted Mine Detection System (ROTA)

The Robot Mounted Sensor (ROTA) Project is a project for the detection of improvised explosive devices. The goal of this project is to provide an effective detection capability through the developed product. ROTA detects improvised explosive devices using integrated multi-channel EMI&GPR technology. In addition, it has a unique and lightweight mechanical design, thus providing user convenience on the robot. The GPR signal processing software platform analyzes the acquired data and provides the necessary information for the detection of explosives. ROTA's wireless or wired communication capability enables remote detection and allows operators to detect explosives from a safe distance. ROTA is capable of detecting anti-personnel (AP), anti-tank (AT) and improvised explosive devices (IED) with high accuracy. Easy to use, ROTA allows operators to simply attach the sensor to the robot and perform the detection process.
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Safir Storage

Safir Storage is a national and secure cloud object storage application developed by TÜBİTAK BİLGEM Cloud Computing and Big Data Research Laboratory (B3LAB). You can access your files stored on Safir Storage via smartphones, tablets or computers over the internet from anywhere at any time. In addition to file operations such as folderizing, moving, renaming on all kinds of files such as documents, audio, photos, videos uploaded to Safir Storage, online viewing, editing and versioning can be done in office documents, and thanks to the sharing feature, files/folders in Safir Storage can be easily shared with anyone. As can be seen in its commercial alternatives, Safir Storage can be used with the "Software as a Service (SaaS)" method, or it can be installed on the private clouds of organizations to provide service. With the private cloud option, Safir Storage continues to provide the high and easy accessibility features of cloud storage software. On the other hand, it enables users' files to be stored in-house by installing on servers kept in customers' own data centers. Developed entirely on open source software and libraries, Safir Storage does not require special hardware with high computing or storage capacity, can run on standard servers, and can flexibly adapt to capacity increases thanks to its horizontally scalable feature. In medium and large-scale installations, it can effectively use the resources assigned with its load balancing feature and offers advisory architectures to its customers from data center to software configuration in a way that does not include "Single Point of Failure". In this way, it minimizes the possibility of service interruption and meets the "high availability" feature of cloud computing.
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Safir Cloud

Safir Cloud was separated from OpenStack in 2016 and developed as an independent platform. In addition to the services provided by OpenStack, this platform also includes its own unique services. Having successfully passed the performance tests, Safir Cloud has a reliable and stable structure. Providing services in IaaS (Infrastructure as a Service) and PaaS (Platform as a Service) layers, Safir Cloud is a platform suitable for corporate use. The prominent features of Safir Cloud are as follows: Easy and fast installation, high accessibility and a design that is resistant to simple errors, a flexible architecture that provides horizontal and vertical scalability, and enriched with local and national capabilities. Thanks to these features, Safir Cloud offers its users a reliable, flexible and fast cloud service.
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Multi-Purpose Radar Display (ÇARE) System

ÇARE (Multi-Purpose Radar Display) System, which is one of the sub-products obtained as a result of the Original CWP (Controller Working Position) R&D Project sold by DHMI to Azeraeronavigation Air Traffic Department (Azans), was installed at Heydar Aliyev Ulu, Ganja and Fuzuli International Airports by making the necessary adaptations. ÇARE is an easy-to-maintain system that displays track and detection data from various surveillance sources over the airspace to provide situational awareness to air traffic controllers, with no external system dependency. Azeraeronavigation Air Traffic Department (Azans) is a project involving the adaptation and installation of the ÇARE (Multipurpose Radar Display) System, developed as a result of the Original CWP (Controller Working Position) R&D Project sold by DHMI, at Heydar Aliyev Ulu, Ganja and Fuzuli International Airports. ÇARE System is a system designed to display tracking and detection data from various surveillance sources over the airspace to provide situational awareness to air traffic controllers. In this project, the system will be adapted to the needs of Heydar Aliyev Ulu, Ganja and Fuzuli International Airports and the system will be installed. ÇARE System has an easy-to-maintain structure that is not dependent on external systems. Thanks to this feature, it provides air traffic controllers with an effective view of the airspace and supports operational processes. With the installation of the ÇARE System at Heydar Aliyev Ulu, Ganja and Fuzuli International Airports, air traffic control processes will be carried out more efficiently and safely. With the completion of this project, the air traffic control infrastructure at international airports will be modernized and the working environment of controllers will be improved through the use of ÇARE System. This will lead to more efficient air traffic management and increase the safety of the aviation sector.
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Avionics Technologies Research Laboratory (ATAL)

Within the scope of the Avionics Technologies Research Laboratory (ATAL) Project, an R&D laboratory is being established that will enable the development of advanced avionics technologies and thus significantly increase Turkey's research and development capabilities in the field of avionics technologies. Within ATAL, the infrastructure required for the research and development activities of integrated modular avionics technologies is being established. Thanks to the hardware and software development, simulation and emulation infrastructure within ATAL, products suitable for advanced technology avionics systems required by the military and civil aviation and space industry will be developed, and design consultancy and conformity tests will be carried out before safety and security certification. The areas of work of the projects for which the Avionics Technologies Research Laboratory will provide infrastructure support are as follows: - Safety Critical Software Development, - Embedded Real-Time Software Development, - Board Support Software and Driver Software Development, - Integrated Modular Avionics Prototype Development, - Integrated Communication Navigation and Recognition System Development, - Flight Control Computer Development, - Avionics System Reconfiguration Technology Development, - Laboratory Level Integration. The institutions targeted to use the ATAL infrastructure are organizations operating in the defence and aerospace industry, relevant units of the Turkish Armed Forces and universities. ATAL infrastructure is currently being used by many defense and aerospace projects, especially the National Combat Aircraft (MMU) Integrated Processor Unit Development Project. Within the scope of the National Combat Aircraft (MMU) Project, TAI personnel also benefit from the ATAL infrastructure. In order to ensure that research and development activities are widespread throughout the country, it is aimed that similar collaborations will continue to increase.
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Handheld Mine Detection System-3 (ETMTS-3)

The ETMTS-3 Project aims to develop and deliver a handheld mine detection system to the customer. The system has various technical features: It has a sensitive metal detector and ground penetrating radar sensors. It can detect metallic/metallic mines and IEDs. It is integrated-wireless. It offers the opportunity to view the subsoil with the help of the screen on it. Provides audible, visual and vibrating detection alerts. It has an optional LCD screen. The system is a lightweight system with a maximum total weight of 4 kg, providing portability and ease of use. The ETMTS-3 Project aims to play an important role in the field operations of security forces with its handheld mine detection system.
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Onboard Sonar System (BOSS)

The Integrated Sonar System (BOSS) Project aims to fully integrate BOSS, a sonar system to be developed for surface platforms, into the Combat Management System (CMS). Within the scope of the project, Monostatic, Bistatic and Multistatic BOSS will be developed. BOSS will consist of a Medium Frequency Hull Mounted Sonar subsystem and a Towable Low Frequency Sonar (ÇAFSON) simulator. The main objective of the project is to ensure the coordinated operation of multiple sonar systems with national capabilities and to develop Multistatic Sonar capability that enables target detection from long distances. The project is being carried out in cooperation with the Presidency of Defense Industries, the Scientific and Technological Research Council of Turkey (TÜBİTAK) Marmara Research Center (MAM) and Meteksan Defence. Within the scope of the project, Bistatic/Multistatic Sonar, ÇAFSON, BOSS Simulators, multistatic sonar performance modeling, console, CMS adaptation, target motion analysis, data recording, system management and classification software are being developed. In addition, the Digital Underwater Telephone within the scope of the project is also being developed under the responsibility of the organization. The BOSS Project is an important step towards increasing the effectiveness of surface platforms underwater and contributing to the acquisition of national capabilities in the field of maritime security. This project is an example of Turkey's efforts to develop indigenous and national technologies in the defense industry.
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Underwater Acoustic Modem (SAM)

The Underwater Acoustic Modem (SAM) Project aims to develop underwater acoustic modem models to be used in underwater sensor networks and underwater manned/unmanned vehicle technologies. Within the scope of the project, models for different types of use are being developed. The first type has pressure-resistant features and the transducers are located on the modem. The second type can be installed on surface or underwater platforms and the transducers are mounted on the platform. The main features of SAM models are as follows: JANUS Protocol compatibility, product types with different output powers (10W, 33W, 100W), encrypted or non-encrypted communication capabilities. JANUS Protocol compatibility enables SAM models to be integrated with other underwater systems and provides the ability to exchange data in a compatible manner. Product types with different output powers provide flexibility to meet various application requirements. Encrypted or non-encrypted communication options play an important role in ensuring communication security and data protection. The Underwater Acoustic Modem (SAM) Project is an important step in developing underwater communication infrastructure and increasing the effectiveness of underwater systems. The modem models developed in the project are designed to provide secure and fast data communication between devices used in underwater operations. This project contributes to Turkey's progress in acquiring national capabilities and developing indigenous technologies in the defense industry.
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Airport Traffic Control Software (HTKY) Development R&D Project

Airport Traffic Control Software (HTKY) is an air traffic control system project developed by the Turkish Air Force (TurAF) in line with the requirements. HTKY is designed in accordance with International Civil Aviation Organization (ICAO) and EUROCONTROL standards. HTKY is a comprehensive air traffic control software that includes a number of features and functions. These features include surveillance source processing, flight data processing, safety and network alerting functions, controller working position, electronic flight strip system, incident analysis, monitoring and control capabilities and redundant system architecture. HTKY is designed to ensure the safe and efficient operation of air traffic services. HTKY offers advanced air traffic control functions by utilizing new technologies and user-friendly graphical interfaces. The project aims to develop HTKY in accordance with the DO-278A AL4 standard. In this way, it is aimed to realize safer, more efficient and advanced air traffic control at airports. With the ongoing installation works of HTKY within the scope of the R&D project, a modern and up-to-date air traffic control software required by the Air Force Command will be obtained. This project is an important step that will contribute to raising safety and efficiency standards in the aviation sector.
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Active Electronic Scanning Radar (AESA) Project

The AESA Project aims to design and manufacture the subcomponents of Active Electronically Scanned Radars (AESA). The main objective of the project is to ensure that the building blocks required for the development of radars that can be used in different scenarios and for different purposes can be produced in different designs. The components to be designed within the scope of the project will be designed and manufactured to provide flexibility for use in various radar applications. The designs that will emerge at the end of the project will be compiled into a library that can be updated according to new needs in the field. In this way, a continuously self-renewing and updating subcomponent cycle will be established and new subcomponents will be developed. The subsystems and integrations to be produced in the project will be used by defense companies in different application scenarios. These subsystems include X Band Beam Steering Integration, X Band Power Amplifier Integration, Receiver/Transmitter Integration and ADC/DAC Integration. In addition, subsystems such as X Band Multichannel Transceiver Module, Multichannel Frequency Converter and Multichannel Digitization Board will also be produced. This project aims to contribute to the development of AESA radar technology in Turkey and supports domestic and national production in the defense industry.
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National ATC R&D Project (MİLAT)

The National ATC R&D Project (MİLAT) will develop an Air Traffic Management System (ATMS), which provides air traffic control services and includes airspace management capabilities in order to ensure the safe and efficient movement of aircraft in all phases of flight, with national capabilities, taking into account ICAO, EUROCONTROL and EUROCAE standards. The purpose of the Air Traffic Management System is to increase flight safety by providing information to controllers from surveillance and flight information systems regarding air movements in the airspace. Navigation information is transferred to different types of controller working positions such as controllers, towers and supervisors. In order to provide all these services, the system includes air traffic management support functions such as flight plan management, surveillance information processing, safety network management, etc. This project is an important step towards ensuring safe and effective air traffic control in the aviation industry. With the development and implementation of MİLAT, the movements of aircraft will be better managed and flight safety will be significantly improved.
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TurkStat Big Data Advanced Analytics Project

With the TurkStat Big Data Advanced Analytics Project, it is aimed to design a system within the Turkish Statistical Institute (TurkStat) of the Ministry of Treasury and Finance of the Republic of Turkey that enables the storage, processing and analysis of daily price information labeled with category and subcategory information and job postings collected from websites as bulk and streaming data in the big data ecosystem. Thanks to the system, it will be possible to classify positions and skills from job postings, visualize the results, provide price tracking for flight-bus-package tour prices and perform lag analysis. Lambda architecture is used to transfer the data collected from websites to the big data environment in the form of streaming data and to analyze the transferred data as bulk and streaming data. The system architecture is being developed using open source tools in the big data ecosystem and the Cloud Computing and Big Data Research Laboratory (B3LAB) Data Quality Tool (B3DataQuality). The small-scale demo installation of the system under development is being carried out at the B3LAB Prototype Data Center located at TÜBİTAK BİLGEM Gebze Campus. Within the scope of the project, job posting position and skill classification models and lag analysis models will be created with machine learning and deep learning methods using bulk data in the bulk data processing infrastructure in the big data environment. The results obtained by processing the streaming data using machine learning models will be visualized in a business intelligence tool compatible with the big data environment.
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Customs Scanning Network Cloud Storage and Image Analysis System (GÜMSİS)

With the system planned to be developed within the scope of the Customs Scanning Network Cloud Storage and Image Analysis System (GÜMSİS) Project; It is aimed to securely store the scan images taken from X-Ray scanning systems used at customs gates operating throughout Turkey for the detection of illegal substances attempted to be smuggled into the country by hiding them in vehicles and containers, regardless of the interface and image format provided by the system manufacturer, to display the images from customs administrations and the Command and Control Center of the Ministry of Trade without changing the image quality, and to design an automatic identification system capable of detecting anomalies on the image. Within the scope of the project, scanning images produced from all X-Ray devices, regardless of their brand and model, will be converted into a standard format and stored centrally, and the images obtained will be analyzed with a common analysis program developed. It is aimed to mutually share the images with Foreign Customs Administrations. Within the scope of the project, smuggling (human, weapon, cigarette, drug) detection, container count detection, difference detection between reference images and material discrimination studies are carried out with artificial intelligence-based machine learning algorithms. Within the scope of material discrimination studies, a joint study is being carried out with Boğaziçi University Technology Transfer Office. With the realization of the project, the following gains are expected to be achieved - Ability to perform analysis independent of the scanning device, - Centralized storage of images and accessibility from all units, - Preventing human errors and saving time thanks to artificial intelligence-based smuggling and anomaly detection, - Strengthening communication between the center and the provinces, - Acceleration of decision-making processes, - Increasing efficiency in the fight against smuggling, - Shortening customs control times, - Acceleration of legal trade, - Prevention of possible tax losses.

The Other Ongoing Projects

Critical Component Development Project for Phased Array Radars

Within the scope of the Critical Component Development Project for Phased Array Radars, it is planned to design and manufacture the sub-components of Active Electronic Scanning Radars in Turkey within the body of our Institution. The main purpose of the project is to design and manufacture the necessary building blocks that can be used in different designs in order to develop radars that can be used in different scenarios and for different purposes. The designs that will emerge at the end of the project will be transformed into a library and updated according to new needs from the field. Thus, a cycle of subcomponents that will enable the creation of new subcomponents and that constantly renews and updates itself will also be provided. The produced subsystems and integrateds can be used by defense companies within the scope of different application scenarios.

Explorer Productization

Within the scope of the Explorer Project, it is aimed to build a communication intelligence system that performs 3 main tasks. These 3 main tasks are defined as follows:
• Signing, direction finding and positioning,
• Estimation of the spectrum parameters of the signal,
• Determination of the communication protocol and modulation to which the signal belongs.

Terrestrial Navigation System (CSR)

Within the scope of the Terrestrial Navigation System (CSR) Project, it is aimed to establish a system that can provide positioning services to receiving platforms through ground-based transmitters, which have been developed as an alternative to satellite-based positioning methods. This system can be used as a backup system for GPS systems, especially in cases of GPS confusion and deception, or in environments where the GPS signal cannot reach, so that systems that need location and time data are not compromised. The system-specific waveform broadcast from 4 synchronous transmitters is detected and processed in the sensor, and 3D position data is produced and presented as output.
The prominent features of the system are as follows:
• Software Defined Radio Based Receiver/Transmitter Structure
• Adjustable Wide Broadcast Frequency
• Adjustable Output Power
• Direct Sequence Spread Spectrum (DSSS) Waveform
• Precise Time Synchronization (Atomic Clock, RTK)
• 3D positioning with Time Difference of Arrival (TDOA) method
• Produce filtered/raw output

THULAB Laboratory Infrastructure

Within the scope of THULAB Laboratory, which was established with the support of the Presidency of the Republic of Turkey's Strategic Budget Department, it is aimed to establish cooperations that will serve as a bridge between the university and the industry by carrying out multi-disciplinary research and development activities that are 5G compatible and will shed light on 6G standards with the equipment, test tools and simulators in the laboratory's infrastructure. The main issues in which R&D activities are carried out are as follows:
• Millimeter wavelength, terahertz band and mass MIMO Communication Systems,
• Reconfigurable Smart Surfaces (RIS),
• Artificial intelligence and machine learning for wireless communication systems,
• Drone-speaking open radio architecture (open RAN) mobile base station technologies.

National Surveillance Radar (MGR)

National Surveillance Radar (MGR) Within the scope of Gaziantep Project, the MGR system has been made redundant for RF units. In project scope; RF Pre-Receiver Module, RF Transceiver Module and spare units of microwave distribution network are integrated into the system. Thus, in case of any malfunction in the existing channel in the redundant radar system, operation can be continued by switching to the backup channel and necessary repairs and replacements can be made in the main channel. As long as there are no malfunctions in both channels at the same time, malfunctions that may occur in the radar system do not interrupt the operation of the system. The first redundant MGR System was implemented at Oğuzeli (Gaziantep) Airport.

Mobile Coastal Surveillance System (MSGS)

Within the scope of the Mobile Coastal Surveillance System (MSGS) Project, it is aimed to develop a long-range portable surveillance radar/sensor system developed by our Institute for the detection and tracking of targets on the sea surface.
The highlights are as follows:
• Portable Switch,
• Mobile positioning on high altitude hills thanks to hydraulic feet that facilitate loading/unloading processes,
• Generator that allows the system to operate independently of the infrastructure,
• Recording plot and track data for 30 days, raw video data for 7 days,
• Opportunity to work, remote control and command without the need for an operator,
• Reducing the impact of sea, land and precipitation conditions,
• Raw data display on the map,
• Display of only surface targets with automatic filtering of land/sea regions on the map,
• Generate an audible/visual alarm in case of traces in critical areas with the critical area identification feature,

Surface Wave High Frequency Radar Core System (YDYFR)

Within the scope of the Surface Wave High-Frequency Radar Core System (YDYFR) Project, a Surface Wave High-Frequency Radar (YDYFR) Core System will be developed through R&D activities utilizing national resources to perform tasks such as surveillance from beyond the horizon in our seas, detection and tracking of sea surface platforms, and partial coastal surveillance of the backside of islands.
With the YDYFR Core System Project, a radar based on high frequency (HF) technology, which is open to continuous development, will be brought to our country with national means. With the processing of the high resolution Doppler spectrum to be obtained as a result of the measurements to be made using the High Frequency Radar, the functions of surveillance from beyond-the-horizon ranges, detection and tracking of above-sea platforms and partial surveillance of the back of the island from the shore will be performed.

SEYYAH (TRAVELER)

Within the scope of the SEYYAH Project, it is aimed to produce Walking Wave Tube Microwave Power Amplifiers (TWTA), which will be developed entirely with domestic resources. For this purpose, it is planned to develop a Traveling Wave Tube Microwave Power (TWT) operating in the X-band, as well as High Power Controllers, which can be used on various platforms.

Scandium Added Dispenser Cathode Development Project (SC-KAT)

The Scandium Doped Dispenser Cathode Development (SC-KAT) Project aims to produce a scandium doped dispenser cathode product. In this direction, the following objectives are expected to be achieved with the project:
• To develope vacuum-based microwave devices such as TWT, Magnetron and BWO, gaining strategic superiority in line with the objectives of our Institution,
• To develope the dispensary cathode studies currently underway within KAMTAM,
• To contribute to scientific research by increasing the level of R&D and innovation,
• To pave the way for the development of high-frequency devices (THz) and the development of high-power microwave generators.

Non-Linear Component Detection System (NLJD)

Within the scope of the Non-Linear Component Detection System Project, it is aimed to realize the following items:
• To detect of handmade explosives,
• To detect of remote-controlled active/passive electronic devices,
• To work with the battery group for at least 8 hours,
• To ensure that the total weight of the system is maximum 15 kg.

Radar Cross-Section Hybrid Analysis Information Gain (RKA-HABİK)

Within the scope of the Radar Cross-Sectional Area Hybrid Analysis Information Acquisition service, it is aimed to provide RKA analysis, measurement and consultancy services to customers with a software that will perform Radar Cross-Sectional Area (RCSA), range profile, scattering center and Synthetic Aperture Radar (SAR) images of platforms faster and more effectively than other software currently available.

Information Acquisition and Continuity Project in Sensor and Antenna Systems (SAS BİKAS)

Knowledge Acquisition and Continuity in Sensor and Antenna Systems (SAS BİKAS) Project is designed as an internal project to ensure the continuity of the knowledge, technology, human resources and infrastructure gains obtained in the Antenna Technologies and Measurement Systems Department, to increase their efficiency, and to carry out joint studies with universities and industry.

Near Field Radar Cross Section Test Facility (TAI NFRTF)

Millî Muharip Uçak (MMU) Projesi’nde kullanılacak 5. Nesil uçağın ve alt bileşenlerinin Radar Kesit Alanı (RKA) değerlerini güvenli, kontrol edilebilir ve tekrarlanabilir bir ortamda ölçmek için Yakın Alan Radar Kesit Alanı Test Tesisi (TAI NFRTF) Projesi ile bir test ortamı kurulması amaçlanmaktadır.

The R/L devices to be developed under the 5G Digital Radiolink Device Development Project will operate in the 7/8 GHz, 13/15 GHz and 23 GHz frequencies of the conventional band regulated by the ICTA. The devices are capable of being used in military and civilian communication networks and will be able to carry data at gigabit speed. Products that will also meet the requirements of 5G Mobile Communication will be transferred to the industry through technology transfer.

Electronic Warfare Pod RF Hardware Development (EHPOD-RF)

Within the scope of the Electronic Warfare Pod RF Hardware Development Project, it will be designed as an external pod and integrated into the F-16 aircraft, which will enable the aircraft to protect itself against air defense elements during attack, defense and joint operations, with sensing (RWR) and jamming (ECM) features, CHAFF/ It is aimed to develop a system that will work in coordination with the FLARE Release System (CMDS) and that can operate on its own in all flight profiles of the F-16 platform.
Within the scope of the project, TÜBİTAK BİLGEM BTE, TÜBİTAK BİLGEM İLTAREN, TÜBİTAK UZAY and HAVELSAN EHSİM are developing this system to be used in F16 aircraft.
Enstitümüz (BTE); geliştirilecek Elektronik Harp Podu’nun RF sistemlerini, anten birimlerini, RF Güç Yükselteci Birimlerini ve sistem yönetim yazılımlarının koşacağı Gerçek Zamanlı İşletim Sistemi’ni geliştirmektedir.

Tactical Electronic Warfare Pod - RF Hardware Development (EDPOD-RF)

Taktik Elektronik Harp Podu – RF Donanım Geliştirme (EDPOD-RF) Projesi kapsamında, düşmana ait hedef tespiti, hedef takibi, füze güdüm ve hedef aydınlatma radarlarından gelen sinyalleri algılayabilen, tanımlayabilen, yerini kestirebilen ve kayıt altına alabilen bir radar sinyal algılayıcı bir Elektronik Destek ve Ölçüm Podu geliştirilmesi amaçlanmaktadır.
The project is being developed by our Institute TÜBİTAK BİLGEM BTE and TÜBİTAK BİLGEM İLTAREN. Our institute designs and develops RF Equipment in the system.

Live Speech Analysis System (CAKAS)

The Live Speech Analysis System (CAKAS) Project aims to develop a live speech analysis and agent assistant system for call centers that can instantly transcribe customer-agent conversations, perform sentiment analysis and keyword detection on voice content, easily integrate with existing switchboard software, integrate these features with the existing Artiwise Analytics product, and provide all analysis and notifications on a single platform. The benefits targeted to be achieved with the project are as follows:
• Performing speech analysis during the call and sending instant notifications to the agent and relevant departments,
• Providing call centers with the opportunity to increase their operational efficiency and service quality,
• Developing new artificial intelligence applications based on dialogue in the future.

DHMI - ATC Portal Project

ATC Portal Project is a web-based project where;
• DHMİ (Devlet Hava Meydanları İşletmesi) – HTKM (Hava Trafiği Komuta Merkezi) personelinin iş çalışma düzeni, görev pozisyonu ve izin planlamalarının oluşturulduğu ve takip edildiği,
• The status of Air Traffic Controllers and other DHMI personnel such as degrees, incidents, training, certificates, licenses, health reports, permits are managed,
• Periodic degree renewal exams of Active Air Traffic Controllers are done securely in computer environment,
• DHMI personnel can receive distance education and access the visuals and documents of the trainings.
Within the project, detailed statistics of users are stored. These statistics are evaluated by the system for effective and fair planning of future assignments, leave and training. In addition, statistical data for degree exams, weather incidents and distance education are also stored and taken into account in exam, incident and distance education processes.

Industrial Big Data Management System (EBVYS) Platform Project

The Industrial Big Data Management System (EBVYS) Platform Project, which is supported under the TÜBİTAK TEYDEB 1505-coded University-Industry Cooperation Support Program, is carried out in cooperation with TÜBİTAK BİLGEM and IQ Vizyon Dijital Dönüşüm Inc. (IQ Vision Digital Transformation Inc.)
Within the scope of the EBVYS Project, a cloud-based big data platform will be developed with the Safir Cloud infrastructure developed by our Agency, which enables the collection, processing, management and use of industrial IoT data received from industrial systems in full-time live/instantaneous data independent of geographical location and in advanced analytics supported by artificial intelligence.
EBVYS Projesi kapsamında geliştirilecek bulut tabanlı büyük veri platformu, coğrafi konumdan bağımsız olarak ülkemiz sanayi kuruluşlarından toplanacak endüstriyel IoT verilerinin anlamlı hâle getirilerek işleneceği ve yapay zekâ destekli ileri analitiklerin uygulanabileceği bir altyapıya sahip olacaktır. Endüstriyel IoT bilgi akışının yönetilebildiği bu büyük veri platformu; günlük yaşantıyı, iş hayatını ve endüstriyel üretim sistemlerini olumlu yönde etkileyebilecek değişikliklere imkân sağlamaktadır. Endüstri ve IoT’un birleştirilmesi ile üretimde kullanılan akıllı cihazlar, insan hatasını en aza indirerek, gerçek zamanlı bilginin karar destek sistemleri tarafından değerlendirilmesini sağlayıp aşağıda sıralanan kazanımlara imkân tanımaktadır:
• Increasing the quality in production,
• Creating competitive products by reducing costs,
• Minimizing the operator contribution to the lowest level by the automatic communication of smart production machines with IoT capability with each other over the network and thus controlling the production,
• Reducing downtime due to failure by predicting mechanical and electrical failures,
• Quickly detecting and eliminating the lack of raw materials for the production of the factory,
• Allowing factory managers to receive information about production and breakdowns in real time from anywhere in the world.

The opportunities that our country will gain with the EBVYS Project are as follows:
• Collecting industrial IoT data of our country's industrial establishments in the cloud, regardless of geographical location,
• Integration of Safir Cloud platform developed by TÜBİTAK BİLGEM as a national and local infrastructure service,
• Providing services to customers abroad through production integration and intelligence, which is equipped with the capability of a cloud-based big data management system, which will serve over servers located in our country.
• Ensuring performance in volume, diversity, accuracy, speed and value metrics in industrial IoT data with the integration of the big data environment,
• Contributing to the national development of Industry 4.0 technologies,
• Presenting the financial burden to SME scale companies by deducting the financial burden.

KÜVAM MUES Lab.

Within the scope of MUES Project, it is aimed to record cultural assets in digital environment, to protect them with a sustainable management model and to manage them efficiently.
With the system that will be formed with the integration of the developed module, the transactions and processes of the artifacts in the inventory of state museums, private museums and collectors will be able to be carried out and monitored in an end-to-end digital environment.
With the completion of the project, a revolutionary step will have been taken in the field of cultural heritage protection within the scope of e-Government activities.

Parliamentary TTBS Project

Within the scope of the TGNA TTBS Project, it is aimed to record the speeches made in the General Assembly and committees of the TGNA and transform them into minutes under a single platform.
When the project is completed, all processes from transcribing speeches and turning them into minutes to sending them to the printing house and printing them will be managed on a single platform.
Especially by using Artificial Intelligence techniques, work efficiency and success will be increased by automating the transcription process. In addition to this process, which is called Speech Recognition, automatic recognition of people whose voice samples have been taken will also be realized.
Within the scope of the project, improvements will also be made by analyzing the business processes of the existing report creation activities carried out by different departments. Automatic transcription of minutes will be ensured.
With speaker recognition, it will be possible to automatically tag people and record them in the minutes. The entire process of creating a provisional report and converting the ready-to-print report into a printed report will be realized under a single platform.

Safir Bio

Bioinformatics studies (e.g. rare diseases, population genetics, etc.) involve the use of variation files related to high volumes of genetic data. A system that can transfer high volumes of genome variation information, search, filter, prioritize variations on this data, and perform complex queries based on genotype and heritability will enable bioinformatics researchers to work efficiently on large amounts of data. For this reason, the Safir Bio platform with a web-based user interface was developed using scalable, distributed and in-memory computing technologies. This system is a platform that enables easy and efficient analysis and querying of high-volume genomic variation data, as well as an infrastructure for machine learning and advanced analytical studies.
The whole genome data of an individual, consisting of about 3 billion pairs of bases, reaches a size of about 200 gigabytes after wet laboratory processing, depending on the quality of the sequence. Since the genomes of two individuals are 99.9% similar, the preferred method in genome research is to align the individual's DNA sequence to a reference genome of its own species and then to determine the differences from this reference genome. The base sequence differences resulting from these processes are recorded in variation files (Variant Call File) in VCF format. VCF files can reach an average length of 125 megabytes for an individual. The VCF is a file in which variations, genes, individuals and labeling of the study are stored in a general format.
Safir Bio is a data management platform created for the management of genomic variation files within the scope of big data and the collection of analyzes to be performed on these files. Safir Bio enables the transfer of VCF files containing high-volume genome variation information, searching, filtering, prioritizing variations on this data, and performing complex queries based on genotype and hereditary characteristics.
Researchers face difficulties in analyzing the rapidly increasing genome data with Next Generation sequencing due to the lack of standard applications and formats. With the 1,000 Genomes Project, VCF files containing variation data are considered to be a widely used file format. The examination of files and data in this format will be a key component of a possible search engine for DNA data. While there are studies in the literature on the analysis of individual or limited number of VCF files, studies on the management of large amounts of VCF files together are more limited. With Safir Bio, operations such as filtering and querying on large amounts and volumes of genomic variation data can be easily performed.
The infrastructure required to conduct population studies on large-scale datasets containing genome data of large numbers of individuals is not a system that every researcher can easily set up. In recent years, especially big data technologies have been preferred to work on genome data. With the cheapening of sequencing technologies, it is important to ensure that bioinformatics researchers can easily work on population studies with large-scale genome data collected in a short time. Thanks to the flexible and simple-to-use interfaces we have developed, the Safir Bio platform, which works with distributed in-memory computing systems, can perform variation analysis (filtering, querying, etc.) of an individual, as well as population studies with variation information of many individuals. Thus, there is no need for data conversion and transfer processes caused by the use of many different software tools, and infrastructures that can perform parallel processing on the data in the distributed file system can be used.
In the literature, different software tools have been developed for the analysis of variation files and different databases have been used. However, big data software tools are well suited for genomic data in terms of scaling. It is important for advanced gene research to enable bioinformatics researchers to run operations that are difficult or impossible to perform on desktop computers using up-to-date distributed systems and computing infrastructures that run in memory instead of disk. The system we have developed is able to run on variation files of different sizes. The scalable infrastructure of our variation analysis platform and the infrastructure that includes in-memory distributed computing functions are very suitable for adding new features and machine learning studies.
Bir bireyin yaklaşık 3 milyar çift bazdan oluşan tüm genom verisi, ıslak laboratuvar işlemlerinden sonra dizilim kalitesine göre değişkenlik gösterecek biçimde yaklaşık 200 gigabyte büyüklüğüne erişir. İki bireyin genomları %99.9 oranında benzer olduğundan genom araştırmalarında tercih edilen yöntem, bireyin DNA dizisinin kendi türüne ait referans genoma göre hizalanması/dizilmesi (alignment) ve sonrasında da bu referans genomdan farklılıklarının tespit edilmesi şeklindedir. Bu işlemler sonucunda ortaya çıkan baz dizilimi farklılıkları varyasyon dosyalarına (Variant Call File) VCF formatında kaydedilmektedir. VCF dosyaları bir birey için ortalama 125 megabyte uzunluğa ulaşabilmektedir. VCF varyasyonların, genlerin, bireylerin ve yapılan çalışmaya ait etiketlemelerin genel bir formatta saklandığı bir dosyadır.
Safir Bio is a data management platform created for the management of genomic variation files within the scope of big data and the collection of analyzes to be performed on these files. Safir Bio enables the transfer of VCF files containing high-volume genome variation information, searching, filtering, prioritizing variations on this data, and performing complex queries based on genotype and heritability.
Researchers are experiencing difficulties in the analysis of genome data, which is rapidly increasing with Next Generation sequencing, due to the lack of standard applications and formats. VCF files containing variation data with the 1,000 Genomes Project are considered a widely used file format. The basic components of a possible search engine to be developed on DNA data will be the examination of files and data in this format. Although studies on the examination of individual or limited number of VCF files are available in the literature, studies on the combined management of large volumes of VCF files are more limited. With Safit Bio, it is possible to easily perform operations such as filtering and querying on high amount and volume of genomic variation data.
The infrastructure required to perform population studies on large-scale data sets containing genome data of a large number of individuals is not a system that every researcher can easily establish. In recent years, especially big data technologies are preferred to work on genome data. With the cheapening of sequencing technologies, it is important to ensure that bioinformatics researchers can easily work with population studies with high-scale genome data collected in a short time. Within the scope of Safir Bio platform, which works with distributed in-memory computing systems thanks to the flexible and simple interfaces we have developed, an individual's variation analysis (filtering, querying, etc.) can be performed, as well as population studies with the variation information of many individuals. Thus, there is no need for data conversion and transfer operations resulting from the use of many different software tools, and infrastructures that can perform parallel operations on the data in the distributed file system can be used.
In the literature, different software has been developed and different databases have been used for the analysis of variation files. But big data software tools are well suited for genomic data in terms of scaling. It is important for advanced gene research to enable bioinformatics researchers to run processes that are difficult or impossible to do on desktop computers using up-to-date distributed systems and computational engines that run in memory instead of disk. The system we have developed is in a position to work on variation files of different sizes. The infrastructure of our variation analysis platform, which is suitable for scaling and functions that can perform in-memory distributed computing, is very suitable for adding new features and machine learning studies.

Safir Big Data

Safir Big Data offers easy-to-install and easy-to-use big data storage, data transfer and data analytics solutions. Safir Big Data enables the processing of bulk and streaming data with scalable, highly available, distributed and redundant hardware infrastructure. Safir Big Data offers solutions for big data architecture, data transfer and processing, big data analytics, big data ecosystem training, and proof of concept (PoC) applications.
Within the scope of big data architecture solutions, Hadoop cluster installation, configuration, management and optimization; operating system configuration and optimization; big data file systems configuration and optimization; big data network architecture design and installation studies are carried out.

Safir Intelligence

With the Safir Intelligence solution, Cloud Computing and Big Data Research Laboratory (B3LAB) offers an environment that provides software developers, data scientists and end users with the tools, libraries, models and services they need in their work providing services in the fields of data analytics and machine learning. Safir Intelligence belongs to the family of platforms known as MLaaS (Machine Learning as a Service).

Safir Intelligence provides a development environment where existing machine learning (ML) libraries are installed, models compiled from publications with high applicability and proven success by academic studies are provided as a ready-to-use service, and 3rd party packages can also be installed. The ready-to-use models can be accessed through a software programming interface (API).

Software developers, data scientists and end users can also develop their own machine learning applications with Safir Intelligence.

In the Safir Intelligence environment, service is provided with high accessibility in a portable structure by using container-based infrastructure technologies.

Safir Intelligence also offers the following with a simplified process wizard:

  • Instant data supply from external sources,
  • Data loading from local sources,
  • Data preview and normalization,
  • Visualization of processed data,
  • Machine learning model creation,
  • An easy-to-manage interface for developers to train and test all specified models.

It is also possible to publish the models produced with the process wizard automatically.

Within the scope of the Safir Intelligence Project, R&D activities continue within B3Lab and it is aimed to maximize the user experience by adding new features to the system in line with the needs of the sector and academia.

The Safir Intelligence Project was bifurcated as Safir Intelligence Avionics to meet the machine learning requirements targeted to be used for the advanced technologies that a new generation aircraft may need within the scope of the National Combat Aircraft (MMU) Project, which was initiated to meet the needs of the Turkish Armed Forces.

Safir Intelligence Avionics is a machine learning library development project developed within the scope of the MMU Project, specialized for avionics data analysis and avionics artificial intelligence use cases.

Deep Learning Based Image Processing and Computer Vision Applications (DerinGÖRÜ-Deep Vision)

Within the scope of the Deep Learning Based Image Processing and Computer Vision Applications (DerinGÖRÜ) Project, our Institution's attainment of the "State of the Art" in the fields of "Machine Learning", "Image Processing" and "Computer Vision", where high value-added products are developed, and contributing to this field Guided applied R&D studies are carried out on “Deep Learning” based methods. In this context, the main goal of the project is to develop applications based on deep learning for the solution of problems such as "Video Analysis", "Remote Sensing" and "Object Recognition".

TAF (TSK) Cloud Computing Consultancy Service

With the TAF Cloud Computing Systems Consultancy Service Project, the targets to be realized for the Ministry of National Defense and the institutions, organizations and units affiliated to the Ministry are as follows:
• Analyzing existing infrastructure resources and applications
• Analysis of data centers and presentation of joint data center design
• Designing the TAF cloud infrastructure
• Preparation of a Technical Requirements Document (TID) for the TAF Cloud Computing Project that can provide a high level of competition among contractor candidates.

Vehicle Mounted Mine System (ÖNCÜ)

The main features of the Vehicle Mounted EMI Sensor Project are as follows:
• Sensor Type : EMI Technology (Multi-Channel)
• Lightweight, Modular and Durable Mechanical Design
• Detecting AP, AT mines and IEDs with high accuracy
• Wide area scanning capability
• Modular panel width from 80 cm to 640 cm
• Easy assembly
• Ability to work under agitator

Computer Based Simulation Model System-LPD / MİLGEM (BTBM-LPD HIZIR)

Bilgisayar Tabanlı Benzetim Modeli Sistemi-LPD / MİLGEM (BTBM-LPD HIZIR) Projesi kapsamında, “Denizaltılar için Akustik Aldatıcı Sistemi” Projesi’ne bağlı geliştirilmiş olan “Bilgisayar Tabanlı Benzetim Modeli”nin, ASELSAN HIZIR Sistemi için farklı senaryolara göre farklı taktikler geliştirmeye imkân veren ileri bir versiyonu geliştirilecektir. Bilgisayar Tabanlı Benzetim Modeli, geliştirilen bu taktiklerin LHD, MİLGEM ve BARBAROS sınıfı gemilerdeki sistemlere yüklenebilmesi için gerekli olan altyapıyı içerecek şekilde güncellenecektir.

Dilburnu D/G Station Modernization

Within the scope of the Dilburnu D/G Station Modernization Project, magnetic, acoustic and pressure trace measurements of ships are carried out and analyzed at the modernized trace measurement station. Modern mines can detect acoustic and pressure traces in addition to magnetic traces.
The system also calculates the current values to be applied to the ship's D/G windings in order to reduce the magnetic field of the ship below safe levels after the measurement.

Ship Combat Effectiveness Assessment Model (GEMED-TR)

Within the scope of the Ship Combat Effectiveness Evaluation Model (GEMED-TR) Project, a simulation will be developed that enables the measurement and evaluation of the combat effectiveness of combatants defined as different parties against air, surface and underwater threat elements under different scenarios.
In the project, our Institute models the underwater platform, acoustic sensors, countermeasure systems, underwater weapons, command and control systems of the platforms (surface, underwater and airborne), link communication system, mission designs of the platforms (navigation/guard, evasion, engagement, etc.) and mission operating procedures (EMCON, rules of engagement, etc.).

Helicopter Tracking System (HeliTR)

The Helicopter Tracking System (HeliTR) Project aims to build a helicopter tracking and communication system.

Magnetic Trace Suppression System Projects (DG Projects)

For the safety of navigation of ships, the ship's magnetic field value must be within the safety limit within the scope of precautions against magnetic mines. Within the scope of Magnetic Trace Suppression System Projects, ship-specific Degauss (D/G) Systems are being developed.
The D/G System suppresses the magnetic signature of the ship by creating a signature equal to the magnetic signature of the ship but in the opposite direction by using D/G coils placed on the ship. Depending on the ship's position and course, currents of appropriate values are applied to the coils placed on the ship to ensure that the ship's magnetic signature remains within the desired limits. Since the magnetic signature of the ship with the D/G System active shortens the detection distance of the magnetic sensors in the mines, the risk of explosion is reduced.

Foldable Metal Mine Detector (OZAN)

The National Metal Detector Project aims to develop handheld and vehicle/robot mounted systems for the detection of mines and/or improvised explosive devices for the needs of our security forces.
Existing and emerging technologies:
• Electromagnetic Induction (Metal Detector)
• Ground penetrating radar (GPR)

National Sonar Development (IPSG-TR)

Within the scope of the National Sonar Development (IPSG-TR) Project, it is aimed to design, develop, manufacture and test basic and advanced intercept sonars (IPS and IDRS) capable of detecting, analyzing and tracking active underwater acoustic signals in broadband, and to integrate them into Ay and Preveze class submarines.
Our institute designs and develops sonar signal processing software, console software and onboard units for IPS and IDRS systems.

MUREN-AKYA

MÜREN-AKYA Projesi kapsamında, Preveze sınıfı denizaltılar için üretilen MÜREN-PREVEZE Savaş Yönetim Sistemi’ne AKYA torpidosu ateşleme ve güdebilme yeteneği kazandırılması amaçlanmaktadır.
The project aims to provide the Preveze class submarines with the following capabilities through software/hardware development for torpedo firing and engagement management:
• Ability to perform AKYA Training/War torpedo shooting,
• Using AKYA torpedo in simulation mode for training purposes,
• Being able to throw the AKYA torpedo with a linked shot.

MUREN-AY-AKYA

MÜREN-AY-AKYA Projesi kapsamında, Ay sınıfı denizaltılar için üretilen MÜREN-AY Savaş Yönetim Sistemi’ne AKYA torpidosu ateşleme ve güdebilme yeteneği kazandırılması amaçlanmaktadır.
By making software/hardware development for torpedo firing and engagement management, it is aimed to provide AY class submarines with the capability to fire AKYA Training/Warfare torpedoes from 4 shells.
Within the scope of the project, the Portable Fire Control System (TACS) is being developed.

New Type Submarine Battery Monitoring System (YTDABİS)

Within the scope of the New Type Submarine Battery Monitoring System (YTDABİS) Project, it is aimed to position wireless sensors that measure the temperature, voltage and total current values of the batteries in new type submarines in real time. The sensor data will be collected by the Data Collection Units via wireless communication and sent to the Control Unit, which will be located in the control room of the New Type Submarine. Battery Monitoring Software will run on the Control Unit, where battery data will be displayed.

New Type Submarine Underwater Telephone Production (YT-SATEL)

Developed within the scope of the New Type Submarine Underwater Telephone Production (YT-SATEL) Project, the telephone is a product developed for REİS Class submarines, capable of analog communication using underwater acoustic waves.
It allows impedance matching with different transducers.
Key Features:
• Underwater voice and telegraph communication,
• Ability to communicate in 2-45 kHz broadband,
• 360° coverage with 3 transducer groups placed at 120°,
• Emergency listening/sending (Pinger)
• In-device internal test feature
• Audio recording and playback
• Distance measurement
• NATO STANAG 1074 compliant operation

DABİS-2 Spare Parts

Within the scope of the DABİS-2 Project, studies are being carried out on the battery monitoring system, which measures the temperature, voltage and total current values of the battery cells on submarines in real time, collects and evaluates them wired or wirelessly, and displays the remaining charge/discharge times of the batteries and the amount of spent/remaining load to the operator together with the measurement values. In addition, critical warnings and alarms about the status of the batteries are also presented to the operator. Battery Monitoring Systems produced by our organization are in actual use on nearly 10 submarines.

Real Time Operating System (GIS) National Combat Aircraft (MMU)

Within the scope of the National Combat Aircraft (MMU) Integrated Processor Unit (ICU) Project, it is aimed to carry out development activities for the Real-Time Operating System (ROS).

Digital Underwater Telephone (D-SATEL)

With the system being developed under the D-SATEL Project, it will be possible to transmit digital data in addition to analog telephone and telegraph communication.
Technicial Features:
• JANUS Protocol compliance,
• Ability to connect a link crypto device externally,
• OFDM based MFSK modulation,
• Digital transmission of voice and text message,
• Full-duplex communication capability,
• Use of transducer array,
• Ability to send image/data file.

Acoustic Iridium Gateway (AIAG)

Akustik Iridium Ağ Geçidi Projesi’nin başlıca özellikleri şu şekildedir:
• JANUS Protocol compliance,
• Being able to be thrown from the water cannon in the submarine,
• Full-duplex communication capability,
• Voice and data communication,
• Ability to call PSTN lines.

Acoustic Release (AS)

An Acoustic Release System (AS) is a piece of equipment that allows various payloads to be submerged underwater for data collection and communication purposes and to be brought to the surface at the end of the mission by sending an acoustic "Release Message".
Features:
• JANUS Protocol compliance,
• Burning Wire and Solenoid models.

Mini Autonomous Surface Vehicle (MOSA)

Within the scope of the Mini Autonomous Surface Vehicle (MOSA) Project, an autonomous route-following mini unmanned surface platform was realized.
Features such as GPS route tracking, various navigation algorithms, artificial intelligence-based mission execution and autonomous docking are being developed.

Turboshaft Engine Development (TMG) Project Digital Engine Control System Real Time Operating System Harmonization (GIS TS1400 AYESAŞ)

Turboşaft Motor Geliştirme (TMG) kapsamında yürütülen Sayısal Motor Kontrol Sistemi Gerçek Zamanlı İşletim Sistemi Uyumlandırılması Projesi, TEI’nin T625 GÖKBEY helikopteri için geliştirdiği TS1400 motorunun Sayısal Motor Kontrol Sistemi (SMKS) için Gerçek Zamanlı İşletim Sistemi (GİS) ile uyumlu hâle getirilmesini ve DO-178C DAL-A Sertifikasyon Paketi’nin sağlanmasını hedeflemektedir.
The resulting product will comply with the ARINC 653 APEX APplication / EXecutive Application memory and time partitioning software standard defined for real-time operating systems in safety critical avionics systems.

National Combat Aircraft (MMU) Integrated Processing Unit Project (BÜİT)

Within the scope of the MMU BÜİT Project, it is aimed to establish a high-tech national integrated operating unit that includes nationally developed technologies for the 5th generation TF-X to be produced for the National Fighter Aircraft (MMU).

National Combat Aircraft (MMU) Integrated Processing Unit Project (BÜİT) Critical Components

Within the scope of the National Combat Aircraft (MMU) IPU Phase 2 Project, it is aimed to integrate a high-tech national mission management system and vehicle management system, including nationally developed technologies, for the 5th generation TF-X to be produced for the National Combat Aircraft (MMU).

Terrestrial Magnetic Trace Measurement and Removal System

The system is used for magnetic compensation of devices and materials before placement on board in order to keep the magnetic signature of ships low and to maintain it. The magnetic values of the materials can be measured and demagnetized if necessary.
Thanks to the system, the following functions can be realized:
• Making magnetic trace measurements,
• Performing magnetic trace removal procedures,
• Checking whether the magnetic field limit values are exceeded,
• Magnetic field removal and checking the results,
• Conducting research on magnetic fields,
• Determination of magnetic properties of materials,
• Simulation or zeroing of the Earth's magnetic field.

DHMI AZANS CARE System Installation

DHMİ AZANS ÇARE Sistemi Kurulumu Projesi kapsamında, Azeraeronavigation Air Traffic Department’a (AZANS) DHMİ tarafından satışı gerçekleştirilecek olan ÇARE Durum Veri Ekranı (SDD) Yazılımı ve Donanımı’ndan oluşan Çok Amaçlı Radar Ekranı (ÇARE) Sistemi kurulumu amaçlanmaktadır.

DHMI-AtcTRsim Installation R&D

AtcTRsim Projesi kapsamında, Hava Seyrüsefer Daire Başkanlığı Ar-Ge çalışmaları kapsamında geliştirilen ve kurulumu daha önce Esenboğa Havalimanı Eğitim ve Simülatör Tesislerine yapılan atcTRsim ATC Meydan Kontrol ve Yaklaşma/Yol Kontrol Radar Simülatörü’nün (atcTRsim) SAHA’lardaki tazeleme/intibak, ileri düzey eğitim ve simülasyon ihtiyaçlarının karşılanması doğrultusunda, “ATC Meydan Kontrol Ve Yaklaşma/Yol Kontrol Radar Simülatörü Ar-Ge Projesi” neticesinde elde edilmiş olan atcTRsim yazılımının teknik şartnamede belirtilen donanımlarla sahalara kurulması amaçlanmaktadır.

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sge

(SGE) Cyber Security Institute

The Cyber Security Institute, which was established to carry out studies to increase the national cyber security capacity, carries out research and development activities in the field of cyber security; carries out solutions-oriented projects for military institutions, public institutions and organizations and the private sector.

The main fields of activity of our institute, which has made a significant contribution to the creation of cyber security knowledge and tactical infrastructure in our country with many successful projects to date, are secure software development, penetration tests and vulnerability analysis.

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6-yze card logo

(IZE) Artificial Intelligence Institute

Artificial Intelligence Institute is the first institute established within the scope of TUBITAK centers and institutes, which cuts the sectors and research fields horizontally and focuses directly on the emerging technology field. For this reason, it constitutes an innovative model in terms of both the open innovation and co-development approach of the institute and its focus on emerging technology.

Artificial Intelligence Institute aims to develop core technologies in the field of artificial intelligence and bring these innovations from the forefront of science to the use of the industry as soon as possible. Focusing on the transformative potential of artificial intelligence, it will continue to play its part in pioneering efforts to create and sustain artificial intelligence-based innovation, growth and productivity in Turkey. Working with industry and public institutions in Turkey, together with other organizations within the artificial intelligence ecosystem, spreading the use of artificial intelligence and increasing the workforce specialized in this field are among its primary goals.

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Researcher

By joining TÜBİTAK BİLGEM as a Researcher, you can contribute to developments in the fields of information technology, information security, and advanced electronics. You'll have the opportunity to make your mark on innovations, closely follow advancements, enhance your skills, and shape your future by advancing in your career.

You can apply to our currently open positions through the TÜBİTAK Job Application System .

Application Conditions

Conditions for Job Application:

  • Foreign language proficiency: Attaining appropriate scores in the exam types specified in the announcement or studying in a program that is 100% in English for undergraduate education.
  • Fulfilling specific requirements stated in the announcement (such as undergraduate department, years of experience, expertise, etc.).
  • Satisfying the formula score:

For Candidates with Less than 3 Years of Experience:

Weighted Graduation Average + (10,000 / University Placement Exam Ranking) + Additional Score* >= 3.20

 

For Candidates with 3 Years and More of Experience:

Weighted Graduation Average + (10,000 / University Placement Exam Ranking) + 5*[1 / (1 + e^(5 - years of experience) ) ] + Additional Score* >= 3.20


*Candidates who have achieved rankings and awards in national and international competitions will receive an additional score of 0.3.

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Competence Centers

Candidate Researcher

Students in the 3rd and 4th years of relevant engineering departments at universities can apply to our Part-Time Candidate Researcher positions through our Job Application System at kariyer.tubitak.gov.tr. By doing so, they can gain work experience at TÜBİTAK BİLGEM during their university years.

This program does not have an end date. Candidate Researcher personnel working part-time during their university period can seamlessly transition to full-time employment as Researcher personnel at TÜBİTAK BİLGEM without interrupting their career journey after graduating from the undergraduate program.

Application Conditions

Conditions for the Candidate Researcher Program:

  • Being a 3rd or 4th-year student in the relevant departments specified in the announcements at universities.
  • Foreign language proficiency: Achieving appropriate scores in the exam types specified in the announcement or studying in a program that is 100% in English for undergraduate education.
  • Satisfying the formula score:

Weighted Graduation Average + (10,000/University Placement Exam Ranking) + Additional Score* >= 3.20

*Candidates who have achieved rankings and awards in national and international competitions will receive an additional score of 0.3.

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Discover institutes laboratories technologies products projects of BİLGEM.

Intern

TÜBİTAK BİLGEM builds its basic strategy for the future on qualified knowledge and qualified people focused on national targets in the research, technology development and innovation ecosystem.

Starting from the understanding that "the most important resource of a country is generally people, specifically scientists," TÜBİTAK encourages and supports our youth from an early age. In this context, providing young minds with early exposure to technology production is crucial for the success of our National Technology Move. Accordingly, TÜBİTAK BİLGEM offers internship opportunities to undergraduate students from universities every year.

You can follow internship announcements and submit your applications through the Career Gateway at https://kariyerkapisi.cbiko.gov.tr.

Application Conditions
  • Students enrolled in undergraduate (2nd year and above) and associate degree programs in departments offering education in universities and conducting insurance procedures through the higher education institution to which they are affiliated can benefit from the internship opportunity.
  • For undergraduate and associate degree students, a minimum Weighted Grade Point Average (GPA) of 2.50 out of 4 is required. The GPA of candidates with a 100-point system is converted to a 4-point system based on the "Conversion Table of Grades from the 4-Point System to the 100-Point System" published by the Higher Education Council.
  • There is no requirement for a foreign language certificate during the internship application process.
  • Students enrolled in departments such as Forensic Computing Engineering, Computer Sciences, Computer Science and Engineering, Computer Engineering, Computer and Informatics, Computer and Software Engineering, Information Systems Engineering, Electrical and Electronics Engineering, Control Engineering, Control and Computer Engineering, Control and Automation Engineering, Mechanical Engineering, Mechatronics Engineering, Telecommunication Engineering, or Software Engineering in universities can apply for internships.

Internship applications are accepted between December and January, and the internship period covers June, July, and August.

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Scholar

Scholar assignments are made for research and development activities for undergraduate, master's, doctoral students, and post-doctoral researchers. In our center, scholars are appointed for practical purposes in externally funded, TARAL, or European Union projects.

You can contact us via the email address bilgem.yetenekkazanimi@tubitak.gov.tr to apply to be a scholar.
Application Conditions

(1) The conditions for undergraduate scholars in externally funded projects conducted by the institution are specified below:

  •  Being a student continuing undergraduate education at higher education institutions established in Turkey (excluding foreign language preparatory students).
  • Having a weighted cumulative GPA for previous years, excluding preparatory years, based on the university's grading system, which satisfies the formula score and foreign language requirements in the recruitment criteria.
  • Completing at least the first semester of the first year of undergraduate education.
  • Having a GPA of "+3.00" and a University Placement Exam Ranking of "10,000 ≥" for undergraduate general average.
  • For foreign students placed in Turkish universities without taking the ÖSYM exam or for those who completed undergraduate education through exams such as Vertical Transfer Exam, the lowest university placement ranking of the department from the year the candidate started the undergraduate program is considered in the ranking formula.

(2) The conditions for master's degree scholars in externally funded projects conducted by the institution are specified below:

  • Being a student continuing master's degree education at higher education institutions established in Turkey (excluding special students and foreign language preparatory students).
  • Currently pursuing a master's degree in the project's field of responsibility.

(3) The conditions for doctoral students in externally funded projects conducted by the institution are specified below:

  • Being a student continuing doctoral education at higher education institutions established in Turkey (excluding special students and foreign language preparatory students).
  • Currently pursuing a doctorate in the project's field of responsibility or conducting a doctorate in areas determined within the framework of the YÖK-TÜBİTAK Doctoral Program Project Collaboration Protocol. (Students in medical specialization and artistic proficiency are accepted as doctoral students.)
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MILSEC 4 - Secure IP Terminal

SAFE IP TERMINAL

While the MİLSEC-4 terminal offers an up-to-date solution for next-generation secure communication (voice, data and video) in IP networks, it provides an uninterrupted communication service by maintaining the compatibility of secure voice communication in PSTN networks with PSTN secure phones in use.
provides.

Configuration, surveillance and software update processes of MILSEC-4 terminals are carried out securely remotely using the Security Management Center (GYM). MİLSEC-4 terminal is capable of IP Network Key Loading (IPAAY) through secure communication with GYM without the need for an additional device.

MİLSEC-4 terminals are interoperable with MİLSEC-1A and MİLSEC-2 phones and offer the opportunity to replace MİLSEC-1A and MİLSEC-2 phones without interruption in the gradual transformation of PSTN networks to next generation IP networks.

FEATURES

  • End-to-end secure voice communication in PSTN networks
  • End-to-end secure voice, image and data transmission in IP networks
  • NATO SCIP compliance on IP networks
  • Compatibility with commercial SIP products
  • Interoperability with MILSEC1A and MILSEC2 secure phones
  • National and AES crypto algorithms
  • Remote software update
  • Easy operation with touch screen

It is subject to the sales license to be given by the Ministry of National Defense.