Your search keyword '"Rianto Adhy Sasongko"' showing total 17 results

1. Mathematical modelling and simulation of a quadrotor unmanned aerial vehicle with automatic altitude and speed control

Author

A. Fathurrahman, Ony Arifianto, Yazdi I. Jenie, and Rianto Adhy Sasongko

Subjects

0209 industrial biotechnology, Electronic speed control, Automatic control, business.industry, Rotor (electric), Computer science, Process (computing), Control engineering, Thrust, 02 engineering and technology, law.invention, 020901 industrial engineering & automation, Software, law, Control system, MATLAB, business, computer, computer.programming_language

Abstract

The quadrotor type of UAV (QUAV), is arguably the most popular type for civilian purposes, since it does not mandate a complicated remote controlling skill to operate it. This popularity, however, has yet to be balanced with research in mathematical modelling, design, and analysis. This paper describes a mathematical modelling process of a QUAV, by exploiting the usage of MATLAB/Simulink software. The main aim is to provide a proper mathematical model to design and evaluate the control system to maintain QUAV stability. Along with the model, three basic automatic control systems were also designed, i.e., the forward-speed hold, sideward-speed hold, and altitude hold system. Several simulations were conducted afterward, to test both the model and the designed control system, which showed satisfying results in representing a QUAV system. QUAV dynamic characteristics can be observed from the simulation, including the logical commands to alter the rotors thrust, the rotor limitation in handling many commands at once, the vehicle dependency of automatic control systems, and the fact that a motion in one degree of freedom can easily affected others. The developed model evidently has a good potential as a base for QUAV analyses and control design.

Published

2020

2. Modelling and analysis of tiltrotor aircraft flight dynamics based on numerical simulation

Author

Rianto Adhy Sasongko, A. A. Arif, and Y. K. Asalani

Subjects

021103 operations research, Discretization, Computer simulation, business.industry, Computer science, 0211 other engineering and technologies, Mode (statistics), 020206 networking & telecommunications, Thrust, 02 engineering and technology, Flight dynamics, Linearization, 0202 electrical engineering, electronic engineering, information engineering, Trimming, Runway, Aerospace engineering, business

Abstract

Development of electronic technology especially on flight controller-related aspect and engine technology which can generate more thrust with relatively small size encourage development of aircraft design to reach boundary. For a long time, fixed wing aircraft needs long runway to achieve its lift-off velocity hence the take-off phase is able to be continued by climbing and other flight phases. However, the tiltrotor configuration aircraft which is equipped with reliable flight controller can reduce the length of the runway by changing the thrust direction which is commonly fixed towards the body axis. In this research, the authors attempt to analyze the flight dynamics behavior in transition mode by discretizing the transition mode to several pseudo-cruise flight configurations. The analysis is started by calculating the pseudo-cruise flight condition for several flight configurations based on analytical calculation and then, compared to trimming and linearization results in numerical simulation platform. After knowing the pseudo-cruise flight configuration by trimming the aircraft, the dynamics stability of the aircraft is obtained for several tilting angles of engine. The aircraft model is limited to 3 DoF non-linear model to represent the behavior of the aircraft. The results show that analytical and numerical calculations have similar trend and tendency in pseudo-trim condition. Afterward, the selected aircraft is concluded as unstable system in all variations.

Published

2020

3. Dynamics Simulation and Analysis of Transition Stage of Tilt-Rotor Aircraft

Author

Rianto Adhy Sasongko and Muhammad Rafi Hadytama

Subjects

0209 industrial biotechnology, Engineering, business.product_category, business.industry, Rotor (electric), Equations of motion, 02 engineering and technology, General Medicine, Stability (probability), Flight simulator, Slow flight, Airplane, law.invention, Takeoff and landing, 020901 industrial engineering & automation, Flight dynamics, law, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Aerospace engineering, business

Abstract

This paper presents the flight dynamics simulation and analysis of a tilt-rotor vertical takeoff and landing (VTOL) aircraft on transition phase, that is conversion from vertical or hover to horizontal or level flight and vice versa. The model of the aircraft is derived from simplified equations of motion comprising the forces and moments working on the aircraft in the airplane's longitudinal plane of motion. This study focuses on the problem of the airplane's dynamic response during conversion phase, which gives an understanding about the flight characteristics of the vehicle. The understanding about the flight dynamics characteristics is important for the control system design phase. Some simulation results are given to provide better visualization about the behaviour of the tilt-rotor. The simulation results show that both transition phases are quite stable, although an improved stability can give better manoeuver and attitude handling. Improvement on the simulation model is also required to provide more accurate and realistic dynamic response of the vehicle.

Published

2016

4. Development of Air Combat Effectiveness Simulation and Analysis Scheme for beyond Visual Range (BVR) Case

Author

Rianto Adhy Sasongko and Prasetyo A.P. Suseno

Subjects

Probability of kill, Scheme (programming language), Engineering, Battle, business.industry, media_common.quotation_subject, 0211 other engineering and technologies, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, Outcome (game theory), Missile, Development (topology), 021105 building & construction, 0210 nano-technology, Beyond-visual-range missile, business, computer, Simulation, media_common, Envelope (motion), computer.programming_language

Abstract

This paper focuses on the simulation of Beyond Visual Range (BVR) Air Combat using calculation of Probability of Kill (PK) and Supremacy to analyze the effectivity of the tactics and strategies. The developed simulation program is expected to be used as a means of developing tactics, weapons systems evaluation and to support other air combat system applications. The simulation system can be utilized so that strategy for using weapons and better tactics for maneuver can be determined and formulated in the face of an aerial battle. The simulation illustrates how an aerial battle in a 2D plane took place. The battle occurs between two sides and can also cover case of many against many air battle. Fighters maneuver will be generated based on logic and defined tactic by providing input in the form of initial conditions. Formulation / functions, parameters and variables influencing the fighter effectiveness will be taken into account. These elements are modelled using a dynamic and open scenario approach. The simulation used a method called 'Missile Launch Envelope Model' for computing PK of missile along its way to the target. Simulation results for one versus one and many versus many cases show that the developed system can produce good and relatively realistic prediction of the outcome. Further modification of simulation program include fly out modeling to the missile.

Published

2016

5. A study on the response of high aspect ratio composite wing structures due to gust load

Author

Rianto Adhy Sasongko, Matza Gusto Andika, and Bambang K. Hadi

Subjects

Materials science, business.industry, Composite wing, Structural engineering, business

Abstract

The purpose of this study is to acquire the correlation between composite tailoring at symmetric balanced laminate and gust response on high aspect ratio wing. As a flexible structure, the high aspect ratio wing had a susceptibility from dynamic loading. Gust or turbulence load is one of dynamic loading which can have a bad impact on the wing structure. There are many incidents caused by turbulence load, hence to obtain structural response is important. Because gust load is a stiffness problem, one way to handle these effects is to make the airframe more rigid which is not favorable due to the weight penalty in the gross weight of the aircraft. Plies orientations can be an alternative to make structure stiffer without adding structural weight. From this study, plies-orientations at symmetrically laminated composite had been varied starting from 0 to 90 degrees with 5 degrees increment at the skin of the wing. Bending and torsional natural frequencies have changed where changed in play orientation as well as the vibration response from the gust load. The discrete gust cases defined in the EASA requirements are used in this study. The structural response from the gust problem had different characteristics between angle plies laminate, cross-plies laminate, and various plies orientation. As a result of this research that symmetrically balanced laminate composite with fiber direction ±15 or ±75 degrees had a good bending characteristic, nevertheless that direction have the lowest bending stiffness. Further research needs to optimize the plies orientation to design the high aspect ratio wing which has a good aeroelastic response and minimize weight.

Published

2020

6. Nonlinear Dynamic Modeling of a Fixed-Wing Unmanned Aerial Vehicle: a Case Study of Wulung

Author

Trio Adiono, Bambang Riyanto Trilaksono, Fadjar Rahino Triputra, Rianto Adhy Sasongko, and Mohamad Dahsyat

Subjects

strict-feedback system, Engineering, Elevator, business.industry, Airspeed, fixed-wing uav, nonlinear flight dynamics, Control engineering, Rudder, Flight test, TK1-9971, System dynamics, law.invention, Computer Science::Robotics, Nonlinear system, Aileron, Flight dynamics, law, Control theory, TJ1-1570, Electrical engineering. Electronics. Nuclear engineering, Mechanical engineering and machinery, business

Abstract

Developing a nonlinear adaptive control system for a fixed-wing unmanned aerial vehicle (UAV) requires a mathematical representation of the system dynamics analytically as a set of differential equations in the form of a strict-feedback systems. This paper presents a method for modeling a nonlinear flight dynamics of the fixed-wing UAV of BPPT Wulung in any conditions of the flight altitude and airspeed for the first step into designing a nonlinear adaptive controller. The model was formed into 10-DOF differential equations in the form of strict-feedback systems which separates the terms of elevator, aileron, rudder and throttle from the model. The model simulation results show the behavior of the flight dynamics of the Wulung UAV and also prove the compliance with the actual flight test results.

Published

2015

7. Air Combat Analysis Using NADM Computation in WVR Case

Author

Rianto Adhy Sasongko and P.S. Prasetyo Ardi

Subjects

Probability of kill, business.industry, Computer science, Computation, 0211 other engineering and technologies, Air combat, 02 engineering and technology, 021001 nanoscience & nanotechnology, Visualization, Software, 021105 building & construction, Visual range, 0210 nano-technology, Beyond-visual-range missile, business, Threat assessment, Simulation

Abstract

This paper discusses the modeling, simulation, and analysis of air combat in a within visual range (WVR) condition. The battle is occurred between two opposing aircraft in a 3-dimensional space. The air combat simulation is done using software MATLAB®. The analysis only covers within visual range air combat where the maneuver is much more aggressive than the beyond visual range (BVR) air combat. Both aircraft will be evaluated to determine the supremacy level based on their relative position. The relative position is used to determine the threat condition for both aircraft, whether they are in neutral, advantage, disadvantage, or mutual disadvantage (NADM) condition. Each possible state then will be quantified to determine the dominant condition. The pilot decision for taking particular maneuver is determined based on this threat assessment. Another method to assess the effectiveness of the fighter's maneuver is based on a parameter Probability of Kill (PK). This method will be used as a comparison to the developed NADM method.

Published

2017

8. Modelling and Control of Tilt-Rotor Longitudinal Dynamics in Transition Phase

Author

Muhammad Rafi Hadytama and Rianto Adhy Sasongko

Subjects

Physics, business.product_category, Wing, Rotor (electric), 05 social sciences, Phase (waves), 02 engineering and technology, 021001 nanoscience & nanotechnology, Airplane, law.invention, Flight dynamics, Fuselage, Control theory, law, Control system, 0502 economics and business, Full state feedback, 0210 nano-technology, business, 050203 business & management

Abstract

This paper presents the result and analysis of a tilt-rotor VTOL aircraft's longitudinal flight dynamics in transition phase. This phase bridges the airplane and helicopter mode in a tilt-rotor, and is an area that is crucial to be understood in designing the control system of a tilt-rotor. The aircraft dynamics are calculated using simplified equations of motion., and considers forces and moments generated from the fuselage, wing, rotors, and both the vertical and horizontal tail. A simple control system using pole placement and PI-like controllers are used to stabilize the aircraft. The resulting simulation shows that a fully stable transition is achieved, although its dynamic behavior can be improved.

Published

2017

9. 3D obstacle avoidance system using ellipsoid geometry

Author

S. S. Rawikara and Rianto Adhy Sasongko

Subjects

Collision avoidance (spacecraft), Computer science, business.industry, Computation, Geometry, Ellipsoid, Waypoint, Obstacle, Obstacle avoidance, Computer vision, Artificial intelligence, Guidance system, business, Normal

Abstract

This paper presents the development of a 3D obstacle avoidance algorithm for Unmanned Aerial Vehicle (UAV) system. The avoidance algorithm works by generating avoiding waypoints, within the original predefined waypoints, when the vehicle faces obstacles obstructing its flightpath. The proposed approach bases its algorithm on the utilization of ellipsoid geometry for defining a restricted zone containing the obstacle. Once the restricted ellipsoid zone has already been established, the algorithm computes the locations of new waypoints on the edge of the ellipsoid. These new waypoints represent the contact points between the ellipsoid and planes the normal vector of which are determined form the vehicle velocity vector. The geometry and dimension of the ellipsoid are determined using the known information about the size of obstacle which is assumed to be available, either from mission database or predicted from UAV's ground detection system. At this stage, the algorithm computation is implemented in MATLAB environment and then evaluated for a couple of cases representing some situations when an UAV has to avoid obstacles during its flight to a predefined destination. This algorithm then can be integrated into a waypoint following system and/or guidance system of UAV.

Published

2016

10. The development of operational concept and Design Requirements and Objectives (DRO) of medical transport drone in Liukang Tangaya Archipelago

Author

Muhammad Fazlur Rahman, A. Fariz, Ony Arifianto, Rianto Adhy Sasongko, Yazdi I. Jenie, and Imam Safi’i

Subjects

History, geography, Engineering, geography.geographical_feature_category, Aeronautics, business.industry, Archipelago, business, Drone, Computer Science Applications, Education

Published

2018

11. Development of Nonlinear Flight Mechanical Model of High Aspect Ratio Light Utility Aircraft

Author

S Bahri and Rianto Adhy Sasongko

Subjects

History, Nonlinear system, Computer science, business.industry, Development (differential geometry), Aerospace engineering, business, Computer Science Applications, Education

Published

2018

12. Modelling and simulation of RKX200 rocket flight dynamics

Author

Alfi Nurhafid, Ahmad Riyadl, Rianto Adhy Sasongko, Herma Yudhi Irwanto, and Bambang Riyanto Trilaksono

Subjects

Vehicle dynamics, Engineering, Missile, business.product_category, Flight dynamics, Rocket, business.industry, Hardware-in-the-loop simulation, Aerodynamics, Aerospace engineering, business, Rigid body, United States Air Force Stability and Control Digital DATCOM

Abstract

In this paper, modelling and simulation of RKX200 rocket flight dynamics are presented. The dynamics model is constructed by first-principle method based on forces and moments acting the rocket rigid body. In the development of the model, the aerodynamics coefficients are determined by using missile DATCOM software. A six Degree of Freedom (DoF) nonlinear model, as well as linear decoupled longitudinal and lateral-directional models are constructed for representing the flight dynamics of the rocket. The resulting models are numerically modelled and simulated using Simulink™ while its motion visualization is constructed using FlightGear™. Further, the dynamics model and the visualization application then are integrated and tested in Hardware In The Loop Simulation (HILS) environment.

Published

2013

13. Guided Rocket Navigation design and implementation on Hardware in Loop Simulation

Author

Bambang Riyanto Trilaksono, Ammar Novel, and Rianto Adhy Sasongko

Subjects

Engineering, business.product_category, business.industry, Navigation system, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Kalman filter, Extended Kalman filter, Rocket, Inertial measurement unit, Control theory, Control system, Global Positioning System, business, Encoder, Simulation

Abstract

The main role of Rocket Navigation System is to deliver an attitude command to Flight Control System hence the rocket can be directed to a particular path or a specific target. This command is produced from Trajectory Planning algorithm. The Navigation System also performs attitude estimation by using the Extended Kalman Filter. The inputs of Navigation System are obtained from GPS, IMU, Pitot tube, Altitude meter and actuator encoder which have been modeled in SIMULINK. From the test results, the Trajectory Planning algorithm is successful enough to give an attitude command and the rocket can reach the target. Also, the Extended Kalman Filter has successfully estimated pitch angle, u-velocity, and w-velocity. Moreover, the Extended Kalman Filter has successfully filtered out the pitch rate noise from the simulated IMU sensor.

Published

2013

14. Three-loop autopilot for attitude control system on Hardware In Loop Simulation

Author

Angga Irawan, Rianto Adhy Sasongko, Bambang Riyanto Trilaksono, and Herma Yudhi Irwanto

Subjects

Engineering, business.product_category, business.industry, Angle of attack, Integral windup, Phase margin, law.invention, Attitude control, Rocket, Control theory, law, Control system, Autopilot, Phugoid, business, Simulation

Abstract

This paper presents the design and implementation of Three-loop autopilot that functions as an attitude control system of a guided rocket. Three-loop autopilot is designed to manage the guided rocket flight path on a longitudinal plane trajectory by controlling the rocket attitude angle. Three-loop autopilot consists of three successive closed-loop systems which manipulate short period, phugoid oscillation, and other oscillation mode to have adequate damping. Control system is designed on a certain linear condition. Classical stability margin such as gain margin and phase margin is needed to handle error between the assumed model and real system. The system is also equipped with anti-windup to overcome integral windup when the actuator gets saturated. Testing of control system is done by using hardware in the loop simulation (HILS). Control system test shows that the results are good enough. With 0° initial value of pitch and angle of attack, pitch angle can be maintained at a value of 5.5° with a 0.6 seconds rise time, 0.8 peak time, 12% overshoot and zero steady state error. In addition, roll and yaw angle values can be maintained at a value of 0°. On changed command testing, the control system shows good command tracking for small angles, but the system performance decreases when angle value large enough. This is due to the saturation in the actuators and change on system parameters.

Published

2013

15. Longitudinal dynamic system modeling of a fixed-wing UAV towards autonomous flight control system development: A case study of BPPT wulung UAV platform

Author

Bambang Riyanto Trilaksono, Mohamad Dahsyat, Fadjar Rahino Triputra, and Rianto Adhy Sasongko

Subjects

Computer Science::Robotics, Engineering, Software, Flight dynamics, business.industry, Control system, Control engineering, Mobile robot, Kalman filter, Aerodynamics, business, United States Air Force Stability and Control Digital DATCOM, System dynamics

Abstract

Developing an autonomous flight control system for a fixed-wing unmanned aerial vehicle (UAV) requires the mathematical representation of the system dynamics which can be obtained by applying analytical and/or empirical methods. This paper presents a method for modeling the flight dynamics of the fixed-wing UAV by analytically developing the model structure. The aerodynamic parameters/coefficients of the UAV, to be inserted into the dynamic model, are computed using DATCOM software, by considering various flight condition determined by the angles of attack, altitudes and velocities. In addition to that, an empirical model is also formed based on flight test data, which has been already processed using Kalman filter, to validate the analytical model. By comparing the simulation result of these two systems representations, it can be seen that the both approaches produce dynamic models that have similar characteristics.

Published

2012

16. Development of Flight Guidance System of a Small Unmanned Aerial Vehicle (UAV)

Author

Javensius Sembiring and Rianto Adhy Sasongko

Subjects

business.industry, Computer science, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Ellipsoid, Geography, Control theory, Position (vector), Obstacle, Line (geometry), Obstacle avoidance, Path (graph theory), Computer vision, Point (geometry), Artificial intelligence, business, Guidance system

Abstract

This paper presents the development of a guidance system for a small Unmanned Aerial Vehicle (UAV) system which combines a waypoints following and an obstacle avoidance systems so that the UAV has a capability to operate in an environment whose ground condition is not completely known. The waypoints following system works by adopting the VOR-Hold approach, in which a correction command will be produced to reduce the angle difference between the desired path and the line connecting the actual UAV position and the subsequent destination point. An avoidance algorithm is developed and integrated with the path following system. In case of the UAV faces an obstacle lying on its flight path, then the avoidance system will generate a set of new waypoints for correcting the flight path, so that the UAV can avoid the obstacle and then returns to the previous flight path. The proposed avoidance approach bases its algorithm on the utilization of ellipsoid geometry for defining a restricted zone containing the obstacle, which is assumed to be already identified by the detection system. When the restricted ellipsoid zone has already been established, the algorithm then computes the locations of new waypoints on the edge of the ellipsoid. The algorithm then is simulated and evaluated in some cases representing situations when an UAV has to avoid obstacles during its flight to a predefined destination.Copyright © 2011 by ASME

Published

2012

17. ANALISIS LINTAS TERBANG ROKET MULTI-STAGE RKN200

Author

Rianto Adhy Sasongko, Yazdi I. Jenie, and Ridanto Eko Poetro

Subjects

Engineering, Booster (rocketry), business.industry, Flight time, Propulsion, computer.software_genre, Separation process, law.invention, Simulation software, Ignition system, Critical phase, law, Trajectory analysis, Aerospace engineering, business, computer

Abstract

This paper deals with a trajectory analysis of RKN200 multi-stage rocket system. The implementation of a multi-stage configuration means that a separation process has to be taken within the flight phase. The separation process is basically a transition process from a phase with booster as initial/launch propulsion to that with sustainer as the propulsion for the rest of flight time. RKN200 is a multi-stage rocket developed by LAPAN Indonesia for defence applications. In a multi-stage rocket development process, stage separation becomes a critical phase which should be considered carefully, since this phase will significantly affect the entire flight performance of the rocket. In this paper, the trajectory of RKN200 is analyzed in various cases with separation process included. The separation stage is modeled as a discrete process, i.e. by applying a sudden change on the rocket parameters values at the time of separation. In addition to that, impulsive force and moment which occur as a result of the separation ignition will also introduced into the mathematical model of the rocket dynamics, such that their influence to the rocket flight variables can be counted and computed . The modeling, simulation, and analysis of the flight trajectory are conducted using a simulation software already developed for rocket dynamic and performance analysis. Some simulation results are presented and analyzed to evaluate the RKN200 flight trajectory in some flight settings and conditions, and also to observe the effect of stage separation process on the rocket flight. Keywords: Rocket, Flight trajectory, Stage separation

Published

2012