Aliasghar Arab, Ph. D.
Research Professor in | AI & Robotics | Autonomous Vehicles | Safety & Security | Control Theories

Building safe and secure robotic solutions ...
bio
  • I was born in Shiraz, a historical city in south of Iran, famous for the red wine and poetry.
  •  Robotic became a major part of my life since 2007
  • I enjoy solving robotic problems, from mathematical modeling to system level and building hardware
  • I was a student-athlete with multiple championships 
Education
  • Ph.D. - Mechanical & Aerospace Engineering / Design and Control – 2015-2020

Safe motion control and planning for autonomous race vehicles

  • M.S. - Electrical Eng. (Control) – 2011-2013

Robust control of wheeled mobile robots

  • BSc - Robotics Eng. – 2007-2011

Design, build and control of a non-holonomic mobile robot using camera for localization

Work Experience
  • Senior Autonomous Vehicle System Engineer at Nuro.ai – 2023-Now

Designing system theory methods for safety verification and validation

  • Robotics Research Engineer at Nokia Bell Labs – 2020-2023

Designed controller architecture for a four-wheel independent steering and drive robot

  • System Engineer at Verizon – 2016-2020

Designed system architecture for IoT enabled sensor networks using mobile edge computing

  • Algorithm Engineer at Zoomi.Inc – 2015

Developed AI algorithms to individualize the course content in an online course application

  • Research and Teaching Assistant at Rutgers – 2015-2021

Led RU-Racer project

  • Robotics Engineer at TAM – 2011-2014

Designed, built and Integrated a vision system to an industrial robot (KUKA)

Selected Projects
  • Wheeled mobile robots 2007-2014
  • Industrial Visual-Servoing - 2013
  • Optimal Control Design using Memetic Algorithm - 2014

  • Impedance control of Mobile Manipulators - 2015

  • IoT Enabled Sensor Network - 2017

About Dr. Aliasghar Arab

As an Adjunct Professor in Robotics at NYU and Entrepreneurial Lead at Agile Safe Autonomous Systems, I am deeply engaged in the advancement of autonomous robotic vehicles. My expertise, honed through a Doctorate in Mechanical and Aerospace Engineering, focuses on the development of sophisticated control and system theories. This specialization is crucial for enhancing the safety, security and efficiency of socio-technological autonomous systems. My commitment is not just academic; it’s about pioneering practical applications that push the boundaries in the field of robotics, aiming to revolutionize how these systems integrate into and impact our daily lives.

Work Experience

Research Professor in Robotics

Tandon School of Engineering New York University - 2023 to now

- Safety and security of AI powered autonomous systems

- Socially aware navigation using AI and autonomy explainability system to enhance human robot collaboration
- Safe motion control for collaborative robotic and autonomous vehicles


Senior Autonomous Vehicle System Engineer

Nuro - 2023 to 2024
- Developed a novel Safety Analysis approach using STPA and HARA
- Defined and developed an ODD based method for minimum risk maneuver selection of Nuro’s fault response
- Developed verification and validation methods by defining proper metrics and coverage using large scale simulations to evaluate safety cases
Systems engineering is a discipline that follows a principled technical approach to breaking down a complex system — such as Nuro’s autonomy stack — into layered subsystems and components in terms of form and function.

Robotics Research Scientists

Nokia Bell Labs - 2020 to 2023
- Designed a safety system for industrial mobile robots to increase the awareness for both human and robots in a collaborative industrial environment.
- Designed a control system for a four-wheel mobile robot with independent steering and drive (4ISD) with various steering wheel rotation limits.
- Proposed a new nonlinear control method named safe iterative feedback linearization to avoid unsafe states smoothly during operation in close proximity of people.
- Mentored PhD students as an intern, one of the interns won the Bell labs award in 2022.Designed a system architecture for connected autonomous vehicles, robotic systems, IoT devises and drones using 5G technology.

Principal System Engineer

Verizon - 2016 to 2020 - Emerging Technologies Team | Connected Vehicles | 5G | Drones | Robotics | AR/XR

- Designed a system architecture for connected autonomous vehicles, robotic systems, IoT devises and drones using 5G technology.
- Led an end-to-end LTE based IoT solution for a network of battery powered wireless sensors.
- Developed and patented power optimization and synchronization methods.
- Optimized the power consumption and increased the battery life from 2 years to 10 years.

Adjunct Lecturer

Rutgers University - 2020
Analytical Dynamics - Mobile Robots and Autonomous Vehicles

AI Algorithm Research Engineer

Zoomi - 2015 to 2016

Developed algorithms for Zoomi’s Analytic and Artificial Intelligence dashboard to individualize the course content for students by analyzing their performance and behavior in the class.

Selected Projects

Wheeled mobile robots 2007-2014

  • Motivations
    • Wide range of applications, such as smart wheelchair, firefighter, rescue robots
    • Make an smart waiter for a robotic restaurant
  • Challenges
    • Design a robust controller for a nonlinear nonholonomic system with model uncertainties
    • Integrate ML with the control loop
    • Connected robot control with wireless communication
  • Accomplishments
    • Built my first smart mobile robot for my undergraduate final project. I used a image processing and ML for perception
    • Tested various communication methods
    • Neural networks and Fuzzy logic for uncertainty estimations

Industrial Visual-Servoing – 2013

  • Motivations
    • TAM was using a mechanical machine to centralize the windshield before the robot put the glue on the edge of the windshield, which was expensive, difficult to maintenance.
  • Challenges
    • The glazing tolerance should not exceed 2mm and it should be able to work for various type of windshields. 
  • Accomplishments
    • Designed the algorithms, developed the image processing program and integrated the industrial robot and a digital camera within a visual-servoing control loop.
    • Enhanced the machine vision system to adjust to different type of work conditions and being robust against lighting disturbances.