Bio-Robotics Research Portfolio

Bridging biological intelligence with robotic embodiment.

Developing autonomous systems through computational modeling, hardware-software co-design, and decentralized AI to create sustainable, scalable solutions for unstructured environments.

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Research Vision

Developing autonomous systems that bridge biological intelligence with robotic embodiment through computational modeling, hardware-software co-design, and decentralized AI—creating sustainable, scalable solutions for real-world challenges in unstructured environments.

Core Research Domains

Bio-inspired Navigation Systems

Translating biological strategies into robust navigation behaviors.

Swarm Robotics & Collective Intelligence

Designing decentralized coordination frameworks for scalable autonomy.

Medical & Assistive Robotics

Building human-centered platforms that extend mobility and care.

Sensor Fusion & Edge AI

Integrating heterogeneous sensing with lightweight, deployable AI.

Energy-Efficient Autonomous Systems

Optimizing control, perception, and actuation for constrained hardware.

Featured Research Projects

FormicaBot: Bio-inspired Swarm Robotics Platform

Principal Researcher  |  BIT Robotics Lab  |  2024–Present

Holistic framework closing the simulation-to-reality gap in swarm robotics through biological validation and hardware-software co-design.

  • Dual-modality virtual pheromone system (optical/thermal) for perturbation-resilient communication
  • Stochastic PDE modeling of ant foraging under environmental stressors
  • Edge-AI pipeline with quantized MobileNetV3 for decentralized target recognition
  • Bio-inspired hexapedal locomotion achieving ≤1.2W power consumption

Outcomes: 89% foraging efficiency in complex navigation • Patent pending • Published in Nature Reviews Bioengineering and Sensors.

GitHub Repository Research Paper Demo Video

Robust Navigation Framework for GPS-Denied Environments

Lead Developer  |  BIT Navigation Lab  |  2023–Present

Autonomous operations in unstructured, GPS-denied scenarios through resilient sensor fusion and adaptive planning.

  • Multi-modal sensor fusion (LiDAR-IMU-Vision) with Extended Kalman Filter
  • Bio-inspired Ant Colony Optimization integrated with deep Q-learning
  • ROS 2 and Gazebo simulation stack with realistic perturbation modeling
  • Real-time SLAM and motion planning within dynamic environments

Performance: Validated in cluttered indoor/outdoor environments with successful obstacle avoidance under sensor degradation.

GitHub Repository Conference Paper

Smart Wheelchair & Cloud-Assistive System

System Architect  |  BIT Assistive Robotics  |  2024–Present

IoT-enabled assistive technology integrating real-time monitoring, cloud analytics, and human-robot interaction.

  • Cloud-connected wheelchair platform capturing real-time telemetry
  • Adaptive control interfaces supporting diverse user capabilities
  • Predictive analytics for preventative maintenance and usage optimization
  • Secure REST API architecture enabling remote assistance features

Impact: Enhances independence for mobility-impaired users while offering scalable monitoring for healthcare providers.

GitHub Repository System Design

Aerospace Sensor Systems & Reliability Analysis

Research Contributor  |  Multi-institutional Collaboration  |  2021–2023

Wearable cardiorespiratory monitoring and reliability evaluation for aerospace platforms.

  • Designed sensor fusion algorithms for cognitive workload assessment
  • Implemented performance degradation modeling for aerospace engine diagnostics
  • Awarded Best Paper at IEEE IATMSI 2022 for reliability framework
  • Published in multiple aerospace engineering journals
GitHub Repository Award Certificate

Technical Infrastructure

Robotics & AI Stack

Core Competencies

Robotics_Frameworks = ["ROS/ROS2", "Gazebo", "Webots", "Co-simulation"]

Navigation_Algorithms = ["SLAM", "Sensor Fusion", "ACO", "Deep RL", "Motion Planning"]

AI_ML = ["PyTorch", "TensorFlow", "Reinforcement Learning", "CNN Optimization"]

Simulation = ["Physics-based Modeling", "Multi-agent Systems", "Perturbation Analysis"]

Hardware & Embedded Systems

System Integration Expertise

Sensing = ["LiDAR", "RGB-D", "IMU", "Custom Sensor Design"]

Computation = ["NVIDIA Jetson", "Embedded AI", "Edge Processing"]

Actuation = ["Dynamixel Servos", "Hexapedal Locomotion", "Control Systems"]

Fabrication = ["3D Printing", "PCB Design", "Prototype Development"]

Research Output

High-Impact Publications

  • Nature Reviews Bioengineering (2025) — Bio-inspired navigation systems for robots
  • Sensors (2025) — Marine-inspired multimodal sensor fusion for autonomous navigation
  • IEEE IATMSI (2022) — Best Paper Award for reliability evaluation framework
  • Multiple manuscripts under review in leading robotics journals

Intellectual Property

  • Patent pending — Bio-inspired fusion navigation framework for autonomous robots
  • Open source release — Complete FormicaBot hardware/software framework

Academic Trajectory

2025–2029

PhD in Mechatronical Engineering

Beijing Institute of Technology

2023–2025

MEng in Mechanical Engineering

Beijing Institute of Technology · First Class

2019–2023

BEng in Mechatronics Engineering

Hebei University of Technology · Rank: 2 / 61

Honors

CSC Scholarship · Best Paper Award · International Student Leadership

Contact & Collaboration

Open for PhD research collaborations, research internships, and academic discourse.

This portfolio showcases ongoing research at the intersection of biological intelligence and autonomous systems, translating nature’s principles into engineering innovation.

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