Yazar "Atas, Isa" seçeneğine göre listele

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    Öğe
    Chess Playing Robotic Arm
    (Ieee, 2014) Atas, Musa; Dogan, Yahya; Atas, Isa
    In this study, a chess playing robotic arm system which has 5 degree of freedoms is developed. System comprised with various modules such as; main controller, image processing, machine learning, game engine and motion engine of robotic arm. Image processing unit is triggered only whenever opponent starts to move chessman. Meanwhile, images acquired in a specific time intervals are transmitted to the machine learning unit for classification purpose. After the classification process is taken place, opponent valid move is sent to the game engine as an input in order to generate reasonable output. Generated output is forwarded to the motion engine for positioning the robotic arm. It was observed that, developed system provides an efficient, favorable and immersive experience for player.
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    Öğe
    Development of a High Gain, Dual-Band and Two-Layer Miniaturized Microstrip Antenna for 5.8 GHz ISM and 10 GHz X-Band Applications
    (Applied Computational Electromagnetics Soc, 2019) Atas, Isa; Abbasov, Teymuraz; Kurt, Muhammed B.
    In this study, it is explained how to increase the gain of a two-layer stacked miniaturized microstrip patch antenna (MPA) operating at 5.8 GHz and 10 GHz step by step by combining several different methods used in the literature for performance improvement of MPAs. A commonly used FR4 substrate material was preferred to design and produce the antenna. For electromagnetic modeling of the prototype structure, numerical analysis, and optimization, ANSYS HFSS was used. The performance of the proposed antenna was evaluated in terms of return loss (RL), surface current distribution, radiation patterns and gain/directivity. To confirm the study, the simulation results were compared with the measurements taken over the antenna prototype and good agreement has been achieved. The peak gain values of the proposed antenna at 5.8 GHz and 10 GHz are obtained as 4.11 dBi and 7.15 dBi, respectively.
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    Öğe
    High Gain Microstrip Antenna Design for 2.4GHz WLAN Application
    (Ieee, 2015) Atas, Isa; Kurt, M. Bahaddin; Abbasov, Teymuraz
    IEEE 802.11x standard widely used in wireless local area network systems is called Wi-Fi as well. In this study high gain Microstrip Antenna (MA) design is presented for 2.4 GHz WLAN application. Simulations were made on parameters such as the geometry and size of antennas, type of dielectric material, the thickness of substrate for most appropriate designing of antenna. For simulations, HFSS software which is a full wave and finite element based simulator was used. Total maximum gain of the designed antenna were obtained as 9.06 dB.
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    High Gain Rectangular Microstrip Array Antenna Design at 2.6GHz
    (Ieee, 2016) Atas, Isa; Kurt, M. Bahaddin; Abbasov, Teymuraz
    In this study, especially the ability to be used in WiMAX applications, high-gain microstrip line feed 2 x I patch array antenna design work was done. Antenna simulation of this antenna design made using HFSS 3D gain and directivity characteristics were simulated. Since antenna impedance is greater than line impedance, impedance matching has been made with inset - fed microstrip line and thequarter-wavetransformer. The results show that the proposed antenna parameters are sufficient for WiMAX applications.
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    Öğe
    JazariInteractiveFloor: A modular Java framework for real-time interactive floor applications
    (Elsevier, 2025) Atas, Musa; Atas, Isa
    JazariInteractiveFloor presents a modular Java framework built upon Processing library for developing real-time interactive floor applications. The framework implements a component-based architecture consisting of an InputManager for computer vision tasks, BlobDetector for motion tracking, and AnimationManager for interactive visualizations. Using an event-driven design pattern through custom listener interfaces, the framework enables seamless integration between motion detection and animation subsystems. The system's modular architecture allows developers to extend functionality through custom animations while maintaining real-time performance. Our implementation has been rigorously tested in a controlled laboratory environment, demonstrating its practical applicability for various potential applications.