Fatigue Management Training Course
Comprehensive Fatigue Management training aligned with ICAO Annex 6 and CASA guidelines.
Course Title
Fatigue Management
Course Duration
1 Day
Competency Assessment Criteria
Practical Assessment and Knowledge Assessment
Training Delivery Method
Classroom (Instructor-Led) or Online (Instructor-Led)
Service Coverage
Saudi Arabia - Bahrain - Kuwait - Philippines
Course Average Passing Rate
98%
Post Training Reporting
Post Training Report(s) + Candidate(s) Training Evaluation Forms
Certificate of Successful Completion
Certification is provided upon successful completion. The certificate can be verified through a QR-Code system.
Certification Provider
Tamkene Saudi Training Center - Approved by TVTC (Technical and Vocational Training Corporation)
Certificate Validity
2 Years (Extendable with additional training hours)
Instructors Languages
English / Arabic / Urdu / Hindi / Pashto
Training Services Design Methodology
ADDIE Training Design Methodology
.png)
Course Overview
This comprehensive Fatigue Management training course provides participants with essential knowledge and practical skills required for identifying, assessing, and managing fatigue risks in safety-critical operations. The course covers fundamental fatigue science principles along with advanced techniques for implementing Fatigue Risk Management Systems (FRMS), sleep optimization, and operational risk mitigation.
Participants will learn to apply ICAO Annex 6 standards and CASA Advisory Circular AC 119-18 methodologies to ensure compliance with international fatigue management requirements throughout various operational environments. This course combines theoretical concepts with practical applications and real-world case studies to ensure participants gain valuable skills applicable to their professional environment while emphasizing safety performance and human factors integration.
Key Learning Objectives
Understand fundamental fatigue science principles and human circadian rhythms
Apply Fatigue Risk Management System (FRMS) development and implementation strategies
Implement effective sleep hygiene practices and fatigue countermeasures
Develop comprehensive fatigue risk assessment and monitoring procedures
Support operational safety through proper shift scheduling and workload management
Apply fatigue detection techniques and performance monitoring systems
Evaluate organizational factors affecting fatigue management effectiveness
Implement incident investigation and continuous improvement processes
Group Exercises
Fatigue risk assessment workshop including (shift pattern evaluation, biomathematical modeling, risk scoring)
FRMS development simulation including (policy creation, procedure design, implementation planning)
Sleep optimization planning including (individual assessment, schedule design, countermeasure selection)
Incident investigation exercise including (fatigue factor analysis, root cause identification, corrective actions)
Knowledge Assessment
Fatigue science principles including (sleep physiology, circadian rhythms, performance effects)
FRMS implementation including (system components, regulatory requirements, performance monitoring)
Risk assessment methods including (evaluation techniques, monitoring tools, mitigation strategies)
Workplace interventions including (scheduling practices, environmental controls, technology solutions)
Course Outline
1. Introduction to Fatigue Management
Fatigue fundamentals including (physiological fatigue, psychological fatigue, acute fatigue, chronic fatigue)
Regulatory framework including (ICAO Annex 6, CASA AC 119-18, FAA AC 120-103A, local requirements)
Safety management integration including (Safety Management Systems, risk management, performance monitoring)
Human factors principles including (human limitations, error causation, performance degradation, situational awareness)
Economic impact including (operational costs, productivity loss, incident consequences, business continuity)
2. Sleep Science and Circadian Rhythms
Sleep physiology including (sleep stages, REM cycles, sleep architecture, sleep debt accumulation)
Circadian rhythm principles including (biological clock, light exposure effects, melatonin production, shift work impacts)
Sleep disorders including (sleep apnea, insomnia, restless leg syndrome, narcolepsy effects)
Recovery strategies including (power napping, strategic caffeine use, light therapy, sleep scheduling)
Performance implications including (reaction time degradation, decision-making impairment, memory consolidation, alertness maintenance)
3. Fatigue Risk Management System (FRMS)
FRMS components including (policies, procedures, risk assessment, performance monitoring, continuous improvement)
System development including (hazard identification, risk analysis, mitigation strategies, implementation planning)
Regulatory compliance including (documentation requirements, audit preparation, reporting obligations, approval processes)
Performance measurement including (safety indicators, fatigue metrics, trend analysis, benchmarking)
Change management including (system updates, training requirements, communication strategies, stakeholder engagement)
4. Fatigue Risk Assessment and Monitoring
Risk assessment methodologies including (biomathematical models, subjective scales, objective measures, predictive tools)
Monitoring techniques including (Psychomotor Vigilance Test, fatigue surveys, wearable technology, performance tracking)
Data collection including (work schedules, sleep logs, incident reports, performance metrics)
Risk matrix development including (probability assessment, consequence evaluation, risk tolerance, mitigation priorities)
Trend analysis including (pattern recognition, seasonal variations, operational impacts, predictive analytics)
5. Workplace Fatigue Mitigation Strategies
Shift scheduling including (rotation patterns, rest period optimization, workload distribution, flexibility considerations)
Environmental controls including (lighting design, temperature management, noise reduction, workspace ergonomics)
Operational procedures including (task rotation, break scheduling, workload limits, handover protocols)
Technology solutions including (alertness monitoring, automated systems, decision support tools, fatigue apps)
Individual strategies including (lifestyle management, nutrition guidance, exercise programs, stress management)
6. HSE in Fatigue Management
Occupational health including (medical screening, fitness for duty, health monitoring, wellness programs)
Safety culture including (reporting systems, non-punitive policies, leadership commitment, employee engagement)
Regulatory compliance including (work time limits, rest requirements, documentation standards, audit compliance)
Emergency procedures including (fatigue-related incident response, medical emergencies, operational contingencies)
Risk communication including (hazard awareness, safety briefings, performance feedback, continuous education)
7. Quality Assurance in Fatigue Management
ISO 45001 occupational health including (management systems, hazard identification, risk control, performance evaluation)
System effectiveness including (validation methods, performance metrics, audit findings, corrective actions)
Training quality including (competency assessment, curriculum validation, instructor qualification, learning evaluation)
Documentation control including (procedure updates, record keeping, version control, accessibility)
Continuous improvement including (system reviews, stakeholder feedback, best practice integration, innovation adoption)
8. Case Studies & Group Discussions
Transportation industry scenarios including (aviation fatigue incidents, maritime watch systems, rail operations)
Healthcare shift work including (medical error prevention, nurse scheduling, emergency department operations)
Industrial operations including (process control rooms, maintenance activities, emergency response)
The importance of proper training in developing effective fatigue management systems and maintaining operational safety
Practical Assessment
Fatigue management plan development including (risk assessment, mitigation strategies)
Schedule optimization exercise including (shift pattern design, rest period planning)
Gained Core Technical Skills
Comprehensive Fatigue Risk Management System (FRMS) development using ICAO Annex 6 standards
Advanced fatigue risk assessment and monitoring using biomathematical modeling techniques
Sleep science application for optimal rest and recovery planning
Workplace fatigue mitigation strategy implementation for operational safety enhancement
Performance monitoring and data analysis for continuous fatigue management improvement
Regulatory compliance management including documentation and audit preparation
Training Design Methodology
ADDIE Training Design Methodology
Targeted Audience
Safety Managers responsible for fatigue risk management
Human Resources Personnel managing shift work and scheduling
Operations Managers overseeing safety-critical activities
Occupational Health Specialists working in shift-work environments
Training Managers developing fatigue awareness programs
Supervisors managing 24/7 operations
Risk Management Personnel conducting safety assessments
Technical Personnel working extended or irregular hours
Why Choose This Course
Comprehensive coverage of fatigue management from science to practical implementation
Integration of ICAO Annex 6 and CASA regulatory requirements with industry best practices
Focus on evidence-based fatigue risk management and performance optimization
Hands-on exercises with real operational scenarios and case studies
Exposure to modern fatigue monitoring technologies and assessment tools
Emphasis on integrated safety management and human factors principles
Opportunity to learn from case studies based on regional operational challenges
Development of critical skills for effective fatigue management system implementation
Note
Note: This course outline, including specific topics, modules, and duration, is subject to change and also can be customized based on the specific needs and requirements of the client.
Course Outline
1. Introduction to Fatigue Management
Fatigue fundamentals including (physiological fatigue, psychological fatigue, acute fatigue, chronic fatigue)
Regulatory framework including (ICAO Annex 6, CASA AC 119-18, FAA AC 120-103A, local requirements)
Safety management integration including (Safety Management Systems, risk management, performance monitoring)
Human factors principles including (human limitations, error causation, performance degradation, situational awareness)
Economic impact including (operational costs, productivity loss, incident consequences, business continuity)
2. Sleep Science and Circadian Rhythms
Sleep physiology including (sleep stages, REM cycles, sleep architecture, sleep debt accumulation)
Circadian rhythm principles including (biological clock, light exposure effects, melatonin production, shift work impacts)
Sleep disorders including (sleep apnea, insomnia, restless leg syndrome, narcolepsy effects)
Recovery strategies including (power napping, strategic caffeine use, light therapy, sleep scheduling)
Performance implications including (reaction time degradation, decision-making impairment, memory consolidation, alertness maintenance)
3. Fatigue Risk Management System (FRMS)
FRMS components including (policies, procedures, risk assessment, performance monitoring, continuous improvement)
System development including (hazard identification, risk analysis, mitigation strategies, implementation planning)
Regulatory compliance including (documentation requirements, audit preparation, reporting obligations, approval processes)
Performance measurement including (safety indicators, fatigue metrics, trend analysis, benchmarking)
Change management including (system updates, training requirements, communication strategies, stakeholder engagement)
4. Fatigue Risk Assessment and Monitoring
Risk assessment methodologies including (biomathematical models, subjective scales, objective measures, predictive tools)
Monitoring techniques including (Psychomotor Vigilance Test, fatigue surveys, wearable technology, performance tracking)
Data collection including (work schedules, sleep logs, incident reports, performance metrics)
Risk matrix development including (probability assessment, consequence evaluation, risk tolerance, mitigation priorities)
Trend analysis including (pattern recognition, seasonal variations, operational impacts, predictive analytics)
5. Workplace Fatigue Mitigation Strategies
Shift scheduling including (rotation patterns, rest period optimization, workload distribution, flexibility considerations)
Environmental controls including (lighting design, temperature management, noise reduction, workspace ergonomics)
Operational procedures including (task rotation, break scheduling, workload limits, handover protocols)
Technology solutions including (alertness monitoring, automated systems, decision support tools, fatigue apps)
Individual strategies including (lifestyle management, nutrition guidance, exercise programs, stress management)
6. HSE in Fatigue Management
Occupational health including (medical screening, fitness for duty, health monitoring, wellness programs)
Safety culture including (reporting systems, non-punitive policies, leadership commitment, employee engagement)
Regulatory compliance including (work time limits, rest requirements, documentation standards, audit compliance)
Emergency procedures including (fatigue-related incident response, medical emergencies, operational contingencies)
Risk communication including (hazard awareness, safety briefings, performance feedback, continuous education)
7. Quality Assurance in Fatigue Management
ISO 45001 occupational health including (management systems, hazard identification, risk control, performance evaluation)
System effectiveness including (validation methods, performance metrics, audit findings, corrective actions)
Training quality including (competency assessment, curriculum validation, instructor qualification, learning evaluation)
Documentation control including (procedure updates, record keeping, version control, accessibility)
Continuous improvement including (system reviews, stakeholder feedback, best practice integration, innovation adoption)
8. Case Studies & Group Discussions
Transportation industry scenarios including (aviation fatigue incidents, maritime watch systems, rail operations)
Healthcare shift work including (medical error prevention, nurse scheduling, emergency department operations)
Industrial operations including (process control rooms, maintenance activities, emergency response)
The importance of proper training in developing effective fatigue management systems and maintaining operational safety
Why Choose This Course?
Comprehensive coverage of fatigue management from science to practical implementation
Integration of ICAO Annex 6 and CASA regulatory requirements with industry best practices
Focus on evidence-based fatigue risk management and performance optimization
Hands-on exercises with real operational scenarios and case studies
Exposure to modern fatigue monitoring technologies and assessment tools
Emphasis on integrated safety management and human factors principles
Opportunity to learn from case studies based on regional operational challenges
Development of critical skills for effective fatigue management system implementation
Note: This course outline, including specific topics, modules, and duration, is subject to change and also can be customized based on the specific needs and requirements of the client.
Practical Assessment
Fatigue management plan development including (risk assessment, mitigation strategies)
Schedule optimization exercise including (shift pattern design, rest period planning)
Course Overview
This comprehensive Fatigue Management training course provides participants with essential knowledge and practical skills required for identifying, assessing, and managing fatigue risks in safety-critical operations. The course covers fundamental fatigue science principles along with advanced techniques for implementing Fatigue Risk Management Systems (FRMS), sleep optimization, and operational risk mitigation.
Participants will learn to apply ICAO Annex 6 standards and CASA Advisory Circular AC 119-18 methodologies to ensure compliance with international fatigue management requirements throughout various operational environments. This course combines theoretical concepts with practical applications and real-world case studies to ensure participants gain valuable skills applicable to their professional environment while emphasizing safety performance and human factors integration.
Key Learning Objectives
Understand fundamental fatigue science principles and human circadian rhythms
Apply Fatigue Risk Management System (FRMS) development and implementation strategies
Implement effective sleep hygiene practices and fatigue countermeasures
Develop comprehensive fatigue risk assessment and monitoring procedures
Support operational safety through proper shift scheduling and workload management
Apply fatigue detection techniques and performance monitoring systems
Evaluate organizational factors affecting fatigue management effectiveness
Implement incident investigation and continuous improvement processes
Knowledge Assessment
Fatigue science principles including (sleep physiology, circadian rhythms, performance effects)
FRMS implementation including (system components, regulatory requirements, performance monitoring)
Risk assessment methods including (evaluation techniques, monitoring tools, mitigation strategies)
Workplace interventions including (scheduling practices, environmental controls, technology solutions)
Targeted Audience
Safety Managers responsible for fatigue risk management
Human Resources Personnel managing shift work and scheduling
Operations Managers overseeing safety-critical activities
Occupational Health Specialists working in shift-work environments
Training Managers developing fatigue awareness programs
Supervisors managing 24/7 operations
Risk Management Personnel conducting safety assessments
Technical Personnel working extended or irregular hours
Main Service Location
Suggested Products
Duration:
Duration:
Duration:
Duration:
