Ali Noormohammadi-Asl scite author profile

The attitude control of a quadrotor is a fundamental problem, which has a pivotal role in a quadrotor stabilization and control. What makes this problem more challenging is the presence of uncertainty such as unmodelled dynamics and unknown parameters. In this paper, to cope with uncertainty, an H ∞ control approach is adopted for a real quadrotor. To achieve H ∞ controller, first a continuous-time system identification is performed on the experimental data to encapsulate a nominal model of the system as well as a multiplicative uncertainty. By this means, H ∞ controllers for both roll and pitch angles are synthesized. To verify the effectiveness of the proposed controllers, some real experiments and simulations are carried out. Results verify that the designed controller does retain robust stability, and provide a better tracking performance in comparison with a well-tuned PID and a µ synthesis controller.

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Multi-goal motion planning using traveling salesman problem in belief space

Noormohammadi-Asl

2019

Information Sciences

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Control of leader–follower formation and path planning of mobile robots using Asexual Reproduction Optimization (ARO)

Noormohammadi-Asl

Menhaj

Sajedin

2014

Applied Soft Computing

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Task Selection and Planning in Human-Robot Collaborative Processes: To be a Leader or a Follower?

Noormohammadi-Asl

Ayub

Smith

et al. 2022

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With the introduction of collaborative robots, humans and robots can now work together in close proximity and share the same workspace. However, this collaboration presents various challenges that need to be addressed to ensure seamless cooperation between the agents. This paper focuses on task planning for human-robot collaboration, taking into account the human's performance and their preference for following or leading. Unlike conventional task allocation methods, the proposed system allows both the robot and human to select and assign tasks to each other. Our previous studies evaluated the proposed framework in a computer simulation environment. This paper extends the research by implementing the algorithm in a real scenario where a human collaborates with a Fetch mobile manipulator robot. We briefly describe the experimental setup, procedure and implementation of the planned user study. As a first step, in this paper, we report on a system evaluation study where the experimenter enacted different possible behaviours in terms of leader/follower preferences that can occur in a user study. Results show that the robot can adapt and respond appropriately to different human agent behaviours, enacted by the experimenter. A future user study will evaluate the system with human participants.

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Neural Control of Mobile Robot Motion Based on Feedback Error Learning and Mimetic Structure

Noormohammadi-Asl

Saffari

Teshnehlab

2018

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