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Armin Lechler
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2020 – today
- 2024
- [c64]Manuel Weiss, Florian Frick, Armin Lechler, Alexander Verl:
Modulation-Frequency-Dependent Power Dissipation Model for Servo Drives With Adaptive PWM. AMC 2024: 1-6 - [c63]Lukas Steinle, Valentin Leipe, Armin Lechler, Alexander Verl:
Learning Compensation of the State-Dependent Transmission Errors in Rack-and-Pinion Drives. ECC 2024: 2441-2447 - [c62]Valentin Leipe, Lukas Steinle, Xabier Agirre Bikuña, Armin Lechler, Alexander Verl:
Modeling and Identification of Load-Dependent Properties for Electrically Preloaded Rack-and-Pinion Drives. ECC 2024: 2460-2466 - [c61]Alexander Schulte, Armin Lechler, Alexander Verl:
Improved Control for the Impact Actuator. ECC 2024: 2467-2472 - [c60]Samed Ajdinovic, Matthias Milan Strljic, Armin Lechler, Oliver Riedel:
Interoperable Digital Product Passports: An Event-Based Approach to Aggregate Production Data to Improve Sustainability and Transparency in the Manufacturing Industry. SII 2024: 729-734 - [c59]Stefan Oechsle, Florian Frick, Moritz Walker, Armin Lechler, Alexander Verl:
Endpoint Architecture for Distributed Real-Time Applications Based on TSN. WFCS 2024: 1-8 - 2023
- [j11]Michael Neubauer, Colin Reiff, Moritz Walker, Stefan Oechsle, Armin Lechler, Alexander Verl:
Cloud-based evaluation platform for software-defined manufacturing: Cloud-basierte Evaluierungsplattform für Software-defined Manufacturing. Autom. 71(5): 351-363 (2023) - [j10]Christian Friedrich, Ralf Gulde, Armin Lechler, Alexander Verl:
Maintenance Automation: Methods for Robotics Manipulation Planning and Execution. IEEE Trans Autom. Sci. Eng. 20(2): 1081-1091 (2023) - [c58]Manuel Zürn, Annika Kienzlen, Lars Klingel, Armin Lechler, Alexander Verl, Shiyi Ren, Weiliang Xu:
Deep Learning-Based Instance Segmentation for Feature Extraction of Branched Deformable Linear Objects for Robotic Manipulation. CASE 2023: 1-6 - [c57]Shan Fur, Samed Ajdinovic, Armin Lechler, Alexander Verl:
Towards an Implementation of Simulation Based Digital Twins in Cyber-Physical Production Systems Environments. ETFA 2023: 1-4 - [c56]Moritz Walker, Lars Klingel, Stefan Oechsle, Michael Neubauer, Armin Lechler, Alexander Verl:
Safeguarded Continuous Deployment of Control Containers through Real-Time Simulation. ETFA 2023: 1-8 - [c55]Moritz Walker, Christian von Arnim, Michael Neubauer, Armin Lechler, Oliver Riedel, Alexander Verl:
Reflection-based Prototyping Framework for OPC UA Servers for Companion Specifications. ICIT 2023: 1-6 - [c54]Manuel Zürn, Markus Wnuk, Armin Lechler, Alexander Verl:
Topology Matching of Branched Deformable Linear Objects. ICRA 2023: 7097-7103 - [c53]Timo König, Alexander Verl, Armin Lechler:
Cornuspline Path Planning Algorithm for the Fabrication of Coreless Wound Fiber-Polymer Composite Structures. IECON 2023: 1-6 - [c52]Kedar Naik, Dominik Welte, Stefan Oechsle, Florian Frick, Armin Lechler, Manuel Schappacher, Axel Sikora:
Methodology and Implementation for Monitoring Precise Time Synchronisation in TSN. INDIN 2023: 1-6 - [c51]Lukas Steinle, Nico Helfesrieder, Armin Lechler, Alexander Verl, Ali Montazeri, Jinfan Wang:
Decentralized Motion Control for a Novel Planar Motor Intralogistics System. ISIE 2023: 1-8 - [c50]Moritz Walker, Marc Fischer, Armin Lechler, Alexander Verl:
Evaluation of Isolation and Communication Mechanisms for Real-Time Containers. ISIE 2023: 1-8 - [c49]Christian von Arnim, Moritz Walker, Armin Lechler, Oliver Riedel, Alexander Verl:
Isolating Shared Resources for Time-Triggered Networking of Containerized Applications. M2VIP 2023: 1-6 - [c48]Rebekka Neumann, Christian von Arnim, Michael Neubauer, Armin Lechler, Alexander Verl:
Requirements and Challenges in the Configuration of a Real-Time Node for OPC UA Publish-Subscribe Communication. M2VIP 2023: 1-6 - 2022
- [j9]Patrick Mesmer, Michael Neubauer, Armin Lechler, Alexander Verl:
Robust design of independent joint control of industrial robots with secondary encoders. Robotics Comput. Integr. Manuf. 73: 102232 (2022) - [c47]Patrick Mesmer, Christoph Hinze, Armin Lechler, Alexander Verl:
Gain-Scheduled Drive-based Damping Control for Industrial Robots. AIM 2022: 1706-1713 - [c46]Christian von Arnim, Gernot Gessner, Michael Jarwitz, Armin Lechler, Oliver Riedel:
Updating the Linux TAPRIO Scheduler in Deterministic Time. ETFA 2022: 1-7 - [c45]Philipp Neher, Armin Lechler, Alexander Verl:
Identification and Classification of the Communication Data of Automated Guided Vehicles and Autonomous Mobile Robots. ICARA 2022: 68-75 - [c44]Tonja Heinemann, Marwin Gihr, Oliver Riedel, Armin Lechler:
Towards Data-driven Production: Analysis of Data Models Describing Machinery Jobs in OPC UA. ICINCO 2022: 729-736 - [c43]Philipp Neher, Armin Lechler, Alexander Verl:
Experimental Evaluation of the Deterministic Wireless Communication System Industrial LTE. ICMRE 2022: 157-162 - [c42]Alexander Schulte, Armin Lechler, Alexander Verl:
Impact Actuator for Increased Dynamics. IECON 2022: 1-6 - [c41]Manuel Zürn, Markus Wnuk, Armin Lechler, Alexander Verl:
Software architecture for deformable linear object manipulation: a shape manipulation case study. RoSE@ICSE 2022: 9-16 - [c40]Marc Fischer, Oliver Riedel, Armin Lechler:
Comprehensive Analysis of Software-Based Fault Tolerance with Arithmetic Coding for Performant Encoding of Integer Calculations. SAFECOMP 2022: 144-157 - 2021
- [c39]Patrick Mesmer, Patrick Nagel, Armin Lechler, Alexander Verl:
Modeling and Identification of Hysteresis in Robot Joints with Cycloidal Drives. AMC 2021: 358-363 - [c38]Manuel Zürn, Markus Wnuk, Christoph Hinze, Armin Lechler, Alexander Verl, Weiliang Xu:
Kinematic Trajectory Following Control For Constrained Deformable Linear Objects. CASE 2021: 1701-1707 - [c37]Marc Fischer, Oliver Riedel, Armin Lechler, Alexander Verl:
Arithmetic Coding for Floating-Point Numbers. DSC 2021: 1-8 - [c36]Sebastian Friedl, Tonja Heinemann, Armin Lechler, Oliver Riedel:
Implicit Templates for Conformance Units in OPC UA Companion Specifications. ICIT 2021: 730-735 - [c35]Anja Elser, Armin Lechler:
Implementation of a Model Based Numerical Control for the Gravity Die Casting Process. ICIT 2021: 1094-1099 - [c34]Christian von Arnim, Armin Lechler, Oliver Riedel:
Operations for non-disruptive modification of real-time network schedules. ICIT 2021: 1131-1137 - [c33]Patrick Mesmer, Michael Neubauer, Armin Lechler, Alexander Verl:
Challenges of Linearization-based Control of Industrial Robots with Cycloidal Drives. ICM 2021: 1-8 - [c32]Marc Fischer, Oliver Riedel, Armin Lechler:
Arithmetic Coding for Floating-Points and Elementary Mathematical Functions. ICSRS 2021: 270-275 - [c31]Markus Wnuk, Christoph Hinze, Manuel Zürn, Qizhen Pan, Armin Lechler, Alexander Verl:
Tracking Branched Deformable Linear Objects With Structure Preserved Registration by Branch-wise Probability Modification. M2VIP 2021: 101-108 - 2020
- [j8]Patrick Mesmer, Michael Neubauer, Armin Lechler, Alexander Verl:
Drive-Based Vibration Damping Control for Robot Machining. IEEE Robotics Autom. Lett. 5(2): 564-571 (2020) - [c30]Christian von Arnim, Mihai Dragan, Florian Frick, Armin Lechler, Oliver Riedel, Alexander Verl:
TSN-based Converged Industrial Networks: Evolutionary Steps and Migration Paths. ETFA 2020: 294-301 - [c29]Christoph Hinze, Manuel Zürn, Markus Wnuk, Armin Lechler, Alexander Verl:
Nonlinear Trajectory Control for Deformable Linear Objects based on Physics Simulation. IECON 2020: 310-316 - [c28]Markus Wnuk, Christoph Hinze, Armin Lechler, Alexander Verl:
Kinematic Multibody Model Generation of Deformable Linear Objects from Point Clouds. IROS 2020: 9545-9552 - [c27]Konstantinos Christodoulopoulos, Wolfram Lautenschlaeger, Florian Frick, Nihel Benzaoui, Torben Henke, Ulrich Gebhard, Lars Dembeck, Armin Lechler, Yvan Pointurier, Sébastien Bigo:
Enabling the Scalability of Industrial Networks by Independent Scheduling Domains. OFC 2020: 1-3 - [c26]Sebastian Friedl, Christian von Arnim, Armin Lechler, Alexander Verl:
Generation of OPC UA Companion Specification with Eclipse Modeling Framework. WFCS 2020: 1-7
2010 – 2019
- 2019
- [c25]Frederick Prinz, Michael Schoeffler, Armin Lechler, Alexander Verl:
Virtual Network Topologies for Real-time I4.0 Components based on Time-Sensitive Networking. ETFA 2019: 1388-1391 - [c24]Christian von Arnim, Sebastian Friedl, Armin Lechler, Alexander Verl:
Automated OPC UA address space generation from existing data structures. INDIN 2019: 959-964 - [c23]Frederick Prinz, Michael Schoeffler, Andreas Eckhardt, Armin Lechler, Alexander Verl:
Configuration of Application Layer Protocols within Real-time I4.0 Components. INDIN 2019: 971-976 - [c22]Matthias Milan Strljic, Oliver Riedel, Armin Lechler:
Collective Cloud Manufacturing for Maintaining Diversity in Production through Digital Transformation. CBI (1) 2019: 594-603 - 2018
- [j7]Christian Friedrich, Akos Csiszar, Armin Lechler, Alexander Verl:
Efficient Task and Path Planning for Maintenance Automation Using a Robot System. IEEE Trans Autom. Sci. Eng. 15(3): 1205-1215 (2018) - [c21]Frederick Prinz, Michael Schoeffler, Armin Lechler, Alexander Verl:
End-to-end Redundancy between Real-time I4.0 Components based on Time-Sensitive Networking. ETFA 2018: 1083-1086 - [c20]Christoph Hinze, Timur Tasci, Armin Lechler, Alexander Verl:
Towards Real-Time Capable Simulations with a Containerized Simulation Environment. M2VIP 2018: 1-6 - [c19]Matthias Milan Strljic, Daniella Brovkina, Tobias Korb, Oliver Riedel, Armin Lechler:
Platform architecture concept for the composition of collective cloud manufacturing*. M2VIP 2018: 1-6 - [c18]Peter Weßeler, Benjamin Kaiser, Jürgen te Vrugt, Armin Lechler, Alexander Verl:
Camera based path planning for low quantity - high variant manufacturing with industrial robots. M2VIP 2018: 1-6 - 2017
- [c17]Christian Friedrich, Christian von Arnim, Armin Lechler, Alexander Verl:
Visual perception for robot based maintenance automation. AIM 2017: 388-393 - [c16]Ali Karim, Julian Hitzer, Armin Lechler, Alexander Verl:
Analysis of the dynamic behavior of a six-axis industrial robot within the entire workspace in respect of machining tasks. AIM 2017: 670-675 - [c15]Christian Friedrich, Akos Csiszar, Armin Lechler, Alexander Verl:
Fast robot task and path planning based on CAD and vision data. AIM 2017: 1633-1638 - [c14]Christian Friedrich, Viktor Zielke, Marc Toussaint, Armin Lechler, Alexander Verl:
Environment modeling for maintenance automation-a next-best-view approach for combining space exploration and object recognition tasks. CASE 2017: 1445-1450 - [c13]Oliver Gerlach, Florian Frick, Armin Lechler, Alexander Verl:
Parallelization of Real-time Control Algorithms on Multi-core Architectures using Ant Colony Optimization. IJCCI 2017: 192-199 - [c12]Christoph Hinze, Weiliang Xu, Armin Lechler, Alexander Verl:
A cloud-based control architecture design for the interaction of industrial robots with soft objects. M2VIP 2017: 1-6 - [c11]Markus Wnuk, Andreas Pott, Weiliang Xu, Armin Lechler, Alexander Verl:
Concept for a simulation-based approach towards automated handling of deformable objects - A bin picking scenario. M2VIP 2017: 1-6 - [p1]Armin Lechler, Jan Schlechtendahl:
Steuerung aus der Cloud. Handbuch Industrie 4.0 (1) 2017: 61-74 - 2016
- [j6]Philipp Eberspaecher, Armin Lechler, Alexander Verl:
Control-integrated consumption graph-based optimisation method for energy reduction of machine tools with automated parameter optimisation. Int. J. Comput. Integr. Manuf. 29(12): 1307-1316 (2016) - [j5]Aitor Oyanguren, Peter Zahn, A. H. Alberdi, Jon Larrañaga, Armin Lechler, Ibai Ulacia:
Preload variation due to temperature increase in double nut ball screws. Prod. Eng. 10(4-5): 529-537 (2016) - [c10]Jens Friedrich, Christoph Hinze, Armin Lechler, Alexander Verl:
On-line learning artificial neural networks for stability classification of milling processes. AIM 2016: 357-364 - [c9]Christian Scheifele, Armin Lechler, Christian Daniel, Weiliang Xu:
Real-time extension of ROS based on a network of modular blocks for highly precise motion generation. AMC 2016: 129-134 - [c8]Matthias Keinert, Armin Lechler, Alexander Verl:
Concept of a computerized numerical control kernel for execution on multi-core processors. AMC 2016: 581-586 - [c7]Marian Vorderer, Stefan Junker, Armin Lechler, Alexander Verl:
CESA3R: Highly versatile plug-and-produce assembly system. CASE 2016: 745-750 - [c6]Christian Friedrich, Armin Lechler, Alexander Verl:
A planning system for generating manipulation sequences for the automation of maintenance tasks. CASE 2016: 843-848 - [c5]Felix Kretschmer, Sebastian Friedl, Armin Lechler, Alexander Verl:
Communication extension for cloud-based machine control of simulated robot processes. ICIT 2016: 54-58 - [c4]Christian Friedrich, Armin Lechler, Alexander Verl:
The control architecture RoViDiAsS - A robotic visual disassembly and assembly system. ICIT 2016: 113-118 - 2015
- [j4]Jan Schlechtendahl, Matthias Keinert, Felix Kretschmer, Armin Lechler, Alexander Verl:
Making existing production systems Industry 4.0-ready. Prod. Eng. 9(1): 143-148 (2015) - [j3]Tim Engelberth, Stefanie Apprich, Jens Friedrich, Daniel Coupek, Armin Lechler:
Properties of electrically preloaded rack-and-pinion drives. Prod. Eng. 9(2): 269-276 (2015) - [c3]Philipp Neher, Armin Lechler:
Using game physics engines for hardware-in-the-loop material flow simulations: benefits, requirements and experiences. AIM 2015: 1002-1007 - [c2]Akos Csiszar, Philipp Sommer, Armin Lechler:
EcoBotics: Advantages and challenges of building a bamboo robot arm. ICIT 2015: 192-197 - 2014
- [c1]Agus Atmosudiro, Matthias Keinert, Ali Karim, Armin Lechler, Alexander Verl, Akos Csizar:
Productivity Increase through Joint Space Path Planning for Robot Machining. EMS 2014: 257-262 - 2012
- [j2]Alexander Verl, Armin Lechler, Jan Schlechtendahl:
Glocalized cyber physical production systems. Prod. Eng. 6(6): 643-649 (2012) - 2010
- [j1]Christian Brecher, Alexander Verl, Armin Lechler, Michael Servos:
Open control systems: state of the art. Prod. Eng. 4(2-3): 247-254 (2010)
Coauthor Index
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last updated on 2024-10-07 21:21 CEST by the dblp team
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