a |
activity system | Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective |
AI | The Role of USVs for the Australian Navy |
AMC Test | The AMC Test for Maritime Autonomous Navigation Systems |
Autonomous | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
autonomous navigation | The AMC Test for Maritime Autonomous Navigation Systems |
Autonomous ship | Autonomous Shipping and the Future Workplace of Marine Engineers |
Autonomous Shipping | Developing and Implementing a Skills and Competency Framework for MASS Operators: Opportunities and Challenges Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training |
Autonomous ships | Dynamic Windowing Algorithm to Improve Ship Response Prediction in Transitory Conditions |
Autonomous Surface Vessels (ASV) | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
b |
boundary object | Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective |
business case | Factors Influencing the Business Case for Autonomous Ships |
c |
chat | Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective |
ColRegs Compliance | The AMC Test for Maritime Autonomous Navigation Systems |
competency framework | Developing and Implementing a Skills and Competency Framework for MASS Operators: Opportunities and Challenges |
d |
Defence | Survey of Autonomous Drone Hangars – Opportunities and Challenges for Maritime Platforms |
Drones | Survey of Autonomous Drone Hangars – Opportunities and Challenges for Maritime Platforms |
e |
Equipment/machinery breakdown | Factors Influencing the Business Case for Autonomous Ships |
f |
Future Ready | Developing and Implementing a Skills and Competency Framework for MASS Operators: Opportunities and Challenges Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision |
h |
Human-Technology coexistence | Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training |
Hydro Regeneration | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
i |
Industry 4.0 | Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective Social Mindset Restructuring: A Critical Requirement for Implementing Maritime Autonomy |
Intelligent Systems | Dynamic Windowing Algorithm to Improve Ship Response Prediction in Transitory Conditions |
m |
Maintenance | Factors Influencing the Business Case for Autonomous Ships |
Marine Engineer | Autonomous Shipping and the Future Workplace of Marine Engineers |
Maritime Autonomous Surface Ship (MASS) | Factors Influencing the Business Case for Autonomous Ships Social Mindset Restructuring: A Critical Requirement for Implementing Maritime Autonomy |
Maritime Autonomy | Social Mindset Restructuring: A Critical Requirement for Implementing Maritime Autonomy |
maritime education | Developing and Implementing a Skills and Competency Framework for MASS Operators: Opportunities and Challenges |
Maritime Education and Training | Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision |
Maritime Policy | Social Mindset Restructuring: A Critical Requirement for Implementing Maritime Autonomy |
maritime safety | The AMC Test for Maritime Autonomous Navigation Systems |
Maritime workforce | Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training |
mass | Developing and Implementing a Skills and Competency Framework for MASS Operators: Opportunities and Challenges Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective Autonomous Shipping and the Future Workplace of Marine Engineers |
MET | Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective |
modular | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
mooring | Autonomous Shipping and the Future Workplace of Marine Engineers |
n |
naval missions | The Role of USVs for the Australian Navy |
p |
Payloads | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
r |
Reliability | Factors Influencing the Business Case for Autonomous Ships |
s |
Safe Return to Port | Autonomous Shipping and the Future Workplace of Marine Engineers |
Seakeeping | Dynamic Windowing Algorithm to Improve Ship Response Prediction in Transitory Conditions |
Ship Landing | Survey of Autonomous Drone Hangars – Opportunities and Challenges for Maritime Platforms |
short-term prediction | Dynamic Windowing Algorithm to Improve Ship Response Prediction in Transitory Conditions |
simulation | Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training |
Simulator Evaluation | The AMC Test for Maritime Autonomous Navigation Systems |
skills and competency framework | Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision |
sociocultural perspective | Social Mindset Restructuring: A Critical Requirement for Implementing Maritime Autonomy |
Solar Powered | A Case Study in the Application of Trusted Autonomous Systems (TAS) Australian Code of Practice to the Design, Construction, Survey, and Operation of New Build Autonomous & Remotely Operated Vessels |
STCW | Future Shipping Operations and Transitioning Maritime Higher Education: An Activity System Perspective |
STCW Code | Skills and Competency Framework for Future Autonomous Ship Operators: A Feasibility Study for STCW Code Revision |
t |
The Royal Australian Navy | The Role of USVs for the Australian Navy |
time series analysis | Dynamic Windowing Algorithm to Improve Ship Response Prediction in Transitory Conditions |
training | Human-Technology Coexistence in the Industry 4.0: The Role of Advanced Simulation Technology in Training |
u |
Unattended engine room | Autonomous Shipping and the Future Workplace of Marine Engineers |
USV | The Role of USVs for the Australian Navy |