Predictive input delay compensation for motion control systems

This paper presents an analytical approach for the prediction of future motion to be used in input delay compensation of time-delayed motion control systems. The method makes use of the current and previous input values given to a nominally behaving system in order to realize the prediction of the future motion of that system. The generation of the future input is made through an integration which is realized in discrete time setting. Once the future input signal is created, it is used as the reference input of the remote system to enforce an input time delayed system, conduct a delay-free motion. Following the theoretical formulation, the proposed method is tested in experiments and the validity of the approach is verified

Disturbance observer based bilateral control systems

Bilateral teleoperation is becoming one of the far reaching application areas of robotics science. Enabling a human operator the ability to reach and manipulate a remote location will be possible with the various applications of bilateral control. In that sense, ideal bilateral control allows extension of a person's sensing to a remote environment by a master slave structure. So, the coupled goals of bilateral control is to enforce the slave system track the motion generated on the master system and to reflect the forces from the slave system. This thesis investigates the current state of the art in bilateral teleoperation. For that purpose, design and analysis of bilateral control is made based on the use of disturbance observers. First, a known control structure is investigated in the context of acceleration control. Following this, a case study is made to show a different application of bilateral control, namely grasping force control. Performance improvement in bilateral control is also studied and correspondingly, a novel functional observer is proposed for better estimation of velocity, acceleration and disturbance. In the second half of the thesis, bilateral control with time delay is realized. Design is made via separating the position and force into two different loops. For position control under time delay, a previously proposed control scheme is used in which use of communication disturbance observer with convergence terms was discussed. Observation made about the divergence from the master reference under contact motion is analyzed and a model following control structure is proposed to eliminate the remaining disturbance from the slave plant. For force control under time delay, first the response of a local controller is analyzed. In order to improve the system transparency, a new method is proposed in which environment stiffness was used for force control loop rather than the delayed slave force. In this structure, estimation of environment stiffness was made via an indirect adaptive control scheme. The analyzed structures were also tested experimentally under a master slave system consisting of 1 DOF linear motors. Experiments show the validity of the contributions made for bilateral control with and without time delay

Assistive control for non-contact machining of random shaped contours

Recent achievements in robotics and automation technology has opened the door towards different machining methodologies based on material removal. Considering the non force feedback nature of non-contact machining methods, careful attention on motion control design is a primary requirement for successful achievement of precise cutting both in machining and in surgery processes. This thesis is concerned with the design of pre-processing methods and motion control techniques to provide both automated and human-assistive non-contact machining of random and complex shaped contours. In that sense, the first part of the thesis focuses on extraction of contours and generation of reference trajectories or constraints for the machining system. Based on generated trajectories, two different control schemes are utilized for high precision automated machining. In the first scheme, preview control is adopted for enhancing the tracking performance. In the second scheme, control action is generated based on direct computation of contouring error in the operational space by introducing a new coordinate frame moving with the reference contour. Further, non-contact machining is extended for realization in a master/slave telerobotic framework to enable manual remote cutting by a human operator. With the proposed approach, the human operator (i.e. a surgeon) is limited to conduct motion within a desired virtual constraint and is equipped with the ability of adjusting the cutting depth over a that contour providing advantage for laser surgery applications. The proposed framework is experimentally tested and results of the experiments prove the applicability of proposed motion control schemes and show the validity of contributions made in the context of thesis

Functional observers for motion control systems

This paper presents a novel functional observer for motion control systems to provide higher accuracy and less noise in comparison to existing observers. The observer uses the input current and position information along with the nominal parameters of the plant and can observe the velocity, acceleration and disturbance information of the system. The novelty of the observer is based on its functional structure that can intrinsically estimate and compensate the un-measured inputs (like disturbance acting on the system) using the measured input current. The experimental results of the proposed estimator verifies its success in estimating the velocity, acceleration and disturbance with better precision than other second order observers

Gürbüz bir tutma kuvveti denetleyicisi

This paper includes modeling and simulation of a new grasping control structure using bilateral actuators. A priori knowledge of parameters for the object is assumed to be existing. The controller is designed by considering accurate tracking of the force and position according to the proposed model

Lightweight design and encoderless control of a miniature direct drive linear delta robot

This paper presents the design, integration and experimental validation of a miniature light-weight delta robot targeted to be used for a variety of applications including the pick-place operations, high speed precise positioning and haptic implementations. The improvements brought by the new design contain; the use of a novel light-weight joint type replacing the conventional and heavy bearing structures and realization of encoderless position measurement algorithm based on hall effect sensor outputs of direct drive linear motors. The description of mechanical, electrical and software based improvements are followed by the derivation of a sliding mode controller to handle tracking of planar closed curves represented by elliptic fourier descriptors (EFDs). The new robot is tested in experiments and the validity of the improvements are verified for practical implementation

Uzaktan lazer cerrahi için kısıtlı sistem tabanlı efendi köle denetleyicisi

Bu bildiri, uzaktan lazer ameliyatlarında kullanılmak üzere kısıtlı sistem tabanlı efendi-köle denetleyicisi tasarımını ve gerçek bir sisteme uyarlanışını sunmaktadır. Önerilen denetleyici şeması, sisteme beslenen bir resimden elde edilen gezinge üzerinde zamandan bağımsız bir kısıtlama yaratıp efendi robotun hareketini bu gezingeyle sınırlayan bir algoritmanın türetimini içermektedir. Efendi robot üzerine uyarlanan bu kısıtlama, cerrahın hareketini gezinge tanjantı doğrultusunda serbest bırakıp diğer doğrultularda engellemek üzere kuvvet yaratmaktadır. İlaveten ikinci bir denetleyici, gezinge doğrultusunda cerrahın yaptığı hareketi uzaktaki bir köle sistemine transfer ederek hareket senkronizasyonunu sağlamaktadır. Bu sayede, efendi sistemi kullanan cerrahın, uzakta duran köle sistemin altındaki bir dokuyu istediği derinlikte ve gezinge dışına çıkmadan lazerle kesmesini mümkün kılan bir sistem ortaya çıkarılmıştır. Önerilen yöntem, her biri üç serbestlik derecesine sahip olan efendi ve köle robotlar içeren bir deney düzeneğinde test edilmiştir. Deneylerden elde edilen başarılı sonuçlar, önerilen yöntemin robotik cerrahide kullanılabilirliğini kanıtlamakta ve lazer ameliyatlarının geleceğine dair yeni bir kapı açmaktadır

Design and control of laser micromachining workstation

The production process of miniature devices and microsystems requires the utilization of non-conventional micromachining techniques. In the past few decades laser micromachining has became micro-manufacturing technique of choice for many industrial and research applications. This paper discusses the design of motion control system for a laser micromachining workstation with particulars about automatic focusing and control of work platform used in the workstation. The automatic focusing is solved in a sliding mode optimization framework and preview controller is used to control the motion platform. Experimental results of both motion control and actual laser micromachining are presented

Model following control with discrete time SMC for time-delayed bilateral control systems

This paper proposes a new algorithm based on model following control to recover the uncompensated slave disturbance on time delayed motion control systems having contact with environment. In the previous works, a modified Communication Disturbance Observer (CDOB) was shown to be successful in ensuring position tracking in free motion under varying time delay. However, experiments show that due to the imperfections in slave plant Disturbance Observer (DOB) when there is rapid change of external force on the slave side, as in the case of environment contact, position tracking is degraded. This paper first analyzes the effect of environment contact for motion control systems with disturbance observers. Following this analysis, a model following controller scheme is proposed to restore the ideal motion on the slave system. A virtual plant is introduced which accepts the current from the master side and determines what the position output would be if there was no environment. Based on the error bet ween actual system and model system, a discrete time sliding mode controller is designed which enforces the real slave system to track the virtual slave output. In other words, convergence of slave position to the master position is achieved even though there is contact with environment. Experimental verification of the proposed control scheme also shows the improvement in slave position tracking under contact forces

Novel parameter estimation schemes in microsystems

This paper presents two novel estimation methods that are designed to enhance our ability of observing, positioning, and physically transforming the objects and/or biological structures in micromanipulation tasks. In order to effectively monitor and position the microobjects, an online calibration method with submicron precision via a recursive least square solution is presented. To provide the adequate information to manipulate the biological structures without damaging the cell or tissue during an injection, a nonlinear spring-mass-damper model is introduced and mechanical properties of a zebrafish embryo are obtained. These two methods are validated on a microassembly workstation and the results are evaluated quantitatively