Ufuk Guner scite author profile

Ufuk Guner

5Publications

11Citation Statements Received

37Citation Statements Given

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Affiliations

Erzurum Technical University, Ankara Yıldırım Beyazıt University, Selçuk University

Publications

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Design and PID control of two wheeled autonomous balance robot

Ünlütürk¹,

Aydoğdu²,

Guner³

2013

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In this study, a two-wheeled autonomous balance robot has been designed and implemented practically. A visual computer interface based on Qt-Creator has been created. Thanks to the computer interface, different control algorithms can be performed on the robot easily, control parameters can be set up online, filter algorithms in various structures can be tried and the reaction of these changeable values to the system can be observed. The effects of some controllers such as Proportional (P), Proportional-Integral (PI), Proportional-Integral-Derivative (PID) on developed robot have been viewed successfully. Kalman Filters have been used for a stable control of the system and it has seen that the system can balance itself for a long time with optimum PID control parameters obtained.

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Design and implementation of adaptive vibration filter for MEMS based low cost IMU

Guner

Canbolat

Ünlütürk

2015

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The Real Time Remote Motion Control of Two Wheeled Mobile Balance Robot by Using Video Streaming

Ünlütürk

Guner

Aydoğdu

2016

MATEC Web of Conferences

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Abstract. This study presents the motion control of a real time two wheeled balance robot capable of moving back and forward, turning right and left and video streaming via IP (Internet Protocol) camera on it. A C++ based visual user interface is created on PC (Personal Computer) in order to control of the designed Two Wheeled Mobile Balance Robot (TWMBR). By means of the interface, all controller parameters of the robot can be changed via wireless communication module on it. Moreover, the robot's tilt angle with respect to time, linear displacement and controller output can be observed simultaneously. Within the robot control interface, the videos from IP camera is transferred into the operator screen via TCP/IP (Transmission Control Protocol/Internet Protocol) communication protocol. So, the robot can be controlled via arrow keys and visual interface on PC remotely by an operator. Acceleration and gyro sensors are fused by means of a real-time Kalman Filter so that robot can keep its balance in both moving and stable state in the designed system. Thus, an accurate tilt angle control is realized. Classic PID (Proportional-IntegralDerivative) algorithm is used as robot controller. In conclusion, via IP camera on the robot, the real-time motion control is performed and data diagrams about motion control are obtained.

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N-version programming approach with implicit safety guarantee for complex dynamic system stabilization applications

Subasi

Guner

Üstoğlu

2020

Measurement and Control

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Safety-critical systems are widely used in many sectors to prevent fatal accidents and prevent loss of life, damage of property, or deterioration of the environment. Implementation of software safety standards as part of the development of safety-critical software is generally considered an essential element of any safety program. Therefore, it has become more critical to produce highly reliable software to meet the safety requirements established by functional safety standards, such as IEC 61508, ISO 26262, and EN 50128. IEC 61508 supports well-known safety mechanisms such as design diversity like N-version (multi-version) programming. N-version (multi-version) programming is a method where multiple functionally equivalent programs are independently developed from the same software specifications. N-version (multi-version) programming is particularly an effective approach to increase the quality of software in a safety-critical system. In this paper, one of the well-known and widely used algorithms in the field of N-version (multi-version) programming, the majority voting algorithm, has been modified with an online stability checker where the decisions of the voter are judged against the stability of the underlying system. The plant where all the theoretical results are implemented is a tilt-rotor system with the proposed N-version (multi-version) programming–based controller. The experimental results show that the modified majority voter-based N-version (multi-version) programming controller provides more reliable control of the plant.

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Design and Implementation of Fault Tolerant Inertial Measurement Unit

Guner

Daşdemir

2021

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Ufuk Guner

Design and PID control of two wheeled autonomous balance robot

Design and implementation of adaptive vibration filter for MEMS based low cost IMU

The Real Time Remote Motion Control of Two Wheeled Mobile Balance Robot by Using Video Streaming

N-version programming approach with implicit safety guarantee for complex dynamic system stabilization applications

Design and Implementation of Fault Tolerant Inertial Measurement Unit

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