Lead HMI Designer

Humanoid is the first AI and robotics company in the UK, creating the world’s most advanced, reliable, commercially scalable, and safe humanoid robots. Our first humanoid robot HMND 01 is a next-gen labour automation unit, providing highly efficient services across various use cases, starting with industrial applications.


We are looking for Investor Relations Lead to join our team based in London, UK.

Our mission

At Humanoid we strive to create the world’s leading, commercially scalable, safe, and advanced humanoid robots that seamlessly integrate into daily life and amplify human capacity.

Vision

In a world where artificial intelligence opens up new horizons, our faith in its potential unveils a new outlook where, together, humans and machines build a new future filled with knowledge, inspiration, and incredible discoveries. The development of a functional humanoid robot underpins an era of abundance and well-being where poverty will disappear, and people will be able to choose what they want to do. We believe that providing a universal basic income will eventually be a true evolution of our civilization.

Solution

As the demands on our built environment rise, labour shortages loom. With the world’s workforce increasingly moving away from undesirable tasks, the manufacturing, construction, and logistics industries critical to our daily lives are left exposed. By deploying our general-purpose humanoid robots in environments deemed hazardous or monotonous, we envision a future where human well-being is safeguarded while closing the gaps in critical global labour needs.

Responsibilities

• Safety Standards Compliance: Ensure compliance with relevant functional safety standards and regulations applicable to humanoid robotics systems, such as ISO 13482, ISO 13849, ISO 10218, and ISO 26262.
• Safety Analysis: Perform safety analysis activities, including hazard identification, risk assessment, and safety requirements derivation, to identify potential hazards and assess safety risks associated with robotic systems.
• Safety Requirements Definition: Define functional safety requirements for robotic systems, subsystems, and components, specifying safety functions, performance criteria, and safety integrity levels (SIL) based on risk assessment.
• Safety Architecture Design: Design safety architectures for robotic systems, including hardware and software safety features, redundancy mechanisms, fault detection, and fault tolerance strategies, to achieve required safety goals.
• Safety Validation and Verification: Develop validation and verification plans and procedures for safety-critical systems, including testing, simulation, and analysis, to ensure compliance with safety requirements and standards.
• Safety Documentation: Prepare safety documentation, including safety plans, safety cases, hazard analysis reports, safety requirements specifications, and verification reports, to support certification and regulatory compliance.
• Safety Management: Establish safety management processes and procedures, including safety reviews, change management, and safety audits, to ensure that safety requirements are integrated into the development lifecycle.
• Safety Certification Support: Support safety certification efforts for robotic systems, including liaising with certification authorities, preparing documentation for safety assessments, and addressing certification findings and requirements.
• Safety Training and Awareness: Provide training and awareness sessions on functional safety principles, processes, and methodologies to engineering teams, ensuring understanding and compliance with safety requirements.
• Continuous Improvement: Drive continuous improvement initiatives to enhance functional safety processes, tools, and methodologies, leveraging lessons learned from previous projects to improve safety practices and outcomes.

Expertise

• Functional Safety Standards: Deep understanding of functional safety standards and regulations applicable to robotics systems, including ISO 13482, ISO 13849, ISO 10218, and ISO 26262, and familiarity with their requirements and guidelines.
• Safety Analysis Techniques: Proficiency in safety analysis techniques, such as hazard analysis and risk assessment (HARA), failure modes and effects analysis (FMEA), fault tree analysis (FTA), and safety integrity level (SIL) determination.
• Safety Requirements Engineering: Experience in safety requirements engineering processes, including derivation, allocation, and validation of safety requirements, and familiarity with safety integrity level (SIL) concepts.
• Safety Architecture Design: Knowledge of safety architecture design principles and practices, including hardware redundancy, software fault tolerance, and fail-safe/fail-operational design strategies, applied to robotic systems.
• Validation and Verification: Experience in validation and verification activities for safety-critical systems, including testing, simulation, model-based verification, and formal methods, applied to functional safety requirements.
• Safety Documentation: Proficiency in preparing safety documentation, including safety plans, hazard analysis reports, safety requirements specifications (SRS), safety cases, and verification reports, to support certification and regulatory compliance.
• Safety Management Processes: Familiarity with safety management processes and practices, including safety reviews, change management, configuration management, and safety audits, applied to safety-critical systems development.
• Certification Support: Understanding of safety certification processes and requirements, including familiarity with certification standards and guidelines, and experience in supporting certification efforts for safety-critical systems.
• Communication Skills: Effective communication skills, both verbal and written, with the ability to communicate technical concepts and safety requirements clearly and concisely, and collaborate with cross-functional teams and stakeholders.
• Problem-Solving Skills: Strong analytical and problem-solving skills, with the ability to analyze complex safety issues, identify root causes, and develop effective solutions to ensure safety and reliability of robotic systems.

Benefits

• High competitive salary.
• 28 calendar days of vacation per year.
• Flexible working hours.
• Opportunity to work on the latest technologies in AI/ML, Robotics and others.
• Startup model, offering a dynamic and innovative work environment.

How to Apply

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