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Apprenticeship training course

High speed rail and infrastructure technician (level 4)

There is 1 training provider who offers this course.

Apprentice's work location: SW1A 2AA

Apprentice can travel: 10 miles

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Information about High speed rail and infrastructure technician (level 4)

Providing technical solutions across the construction, maintenance and operation of a high speed railway.

Knowledge, skills and behaviours
View knowledge, skills and behaviours

Knowledge

  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management
  • The critical importance of safety and security in the conventional and the high speed railway industries, the principles of safe by design, system assurance, and health and safety legislation
  • The relationships of health and welfare strategies with safety in the workplace
  • The relevance of standards, policy, regulation and guidelines for the UK rail industry.
  • Risk assessment and hazard analysis identification, management and mitigation.
  • The context and scope of high speed rail in the UK and internationally, and its integration into the wider transportation system.
  • The distinction and interface between conventional and high speed rail.
  • The role of specialist areas within conventional and high speed rail; civil engineering, track systems, traction and rolling stock, command, control and communication, power, digital and information operations, business management, systems engineering and integration.
  • Appropriate fundamental engineering principles.
  • The relevance and importance of sustainability, environmental, social and economic considerations in the development and operation of a high speed railway.
  • How the rail network system is designed, built, installed, operated, maintained, renewed and decommissioned.
  • The impact of ergonomics and human factors on the design and operation of the railway.
  • The importance of forward thinking to future innovation, technology and ways of working.
  • The requirements for, and characteristics of, leadership, collaboration and management
  • The principles of effective project management, stakeholder management and quality management.
  • The principles of asset management.
  • The importance of commercial awareness, including the relationship with the supply chain
  • The procurement process and its importance to the business and industry
  • The basics of working with Building Information Modelling (BIM) and the Common Data Environment.
  • How to identify, eliminate and mitigate safety and health risks in the whole project lifecycle;
  • The social and environmental factors arising from civil engineering activities;
  • Legislation and standards regarding the design and construction of high speed rail systems;
  • The civil engineering components, considerations, techniques, methods and software used in high speed rail;
  • The interface between civil engineering, track and other network systems;
  • The impact of structures, drainage, geotechnics and lineside equipment on the construction and durability of a high speed rail system;
  • Procedures for gaining necessary planning consents;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Processes for planning and delivering both on-site and off-site construction; how to effectively estimate, manage and control costs, resources and programme;
  • Quality control and assurance, the link to productivity, and the application of lean principles and Business Improvement Techniques (BIT);
  • The industry software used to achieve BIM requirements.
  • Health and safety regulations pertaining to track;
  • Identification, avoidance and mitigation of safety and health risks in design, construction, operation, maintenance and decommissioning
  • The components of a track system, especially as applied to high speed rail;
  • The differences between conventional and high speed track and the interfaces between the two systems;
  • The essentials of constructing properly supported track bed;
  • The impact of alignment, hydrodynamics (chiefly drainage) and geotechnics on track;
  • Track geometry and the influence of speed;
  • Impact of assets and structures on the track system;
  • Processes associated with the planning, design, construction, monitoring, ongoing inspection, maintenance, renewal, repair and failure mechanisms of track;
  • Manufacturing and construction methodology behind track;
  • The range and use of specialist equipment and plant for track;
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • Environmental impact of the whole track lifecycle.
  • Processes to identify safety and health risk and their integration in an operational system;
  • The concept, significance and meaning of systems thinking and the systems engineering discipline, and the impact of relevant standards;
  • The necessity of taking a holistic approach to managing the lifecycle of a project from specification to decommissioning;
  • Appropriate systems engineering approaches for different situations, types of assurance, validation and verification (from traditional ‘V’ model to Agile systems engineering);
  • The necessity of designing, planning, coordinating and supervising temporary works;
  • System architecture, hardware, software and interfaces;
  • Available software and tools to support systems engineering, including BIM; requirements capture management theory and practical methods;
  • Interface management theory and methods;
  • RAMSS (Reliability, Availability, Maintainability, Safety, Security) analysis;
  • Documentation hierarchy.
  • The design factors that embed health and safety into the CCC system;
  • In-depth knowledge of Common Safety Method (CSM) and application of change within the CSM context;
  • Risk and failure modes and how to build protection into the design;
  • What is meant by CCC, and the differences between legacy, modern and future rail signalling and train control systems;
  • Ergonomic and human factors relating to design and operation of a CCC system;
  • Operation and maintenance requirements for CCC systems and how to demonstrate that they can be achieved;
  • The commissioning certification process relating to the design, implementation and operation of a CCC system;
  • IT hardware, software and technical architecture as appropriate;
  • Security technology and systems including cyber security and levels of access;
  • The function and operation of the European Rail Traffic Management System (ERTMS) including the European Train Control System (ETCS);
  • Telecoms systems including the Global System for Mobile Communications – Railway (GSM-R) and subsequent evolutions to communicate between train and track-side;
  • Purpose and processes for data management, configuration management and change management.
  • Health and safety standards, regulations and their application to high speed rolling stock;
  • Rolling stock systems, subsystems and components for high speed rail;
  • Factors that influence specific design considerations for high speed rail, including ergonomics and human factors;
  • Principles and application of train design including materials, energy sources, legislation and standards;
  • Current, future and alternative technologies impacting on the design and operation of high speed rail rolling stock;
  • The interaction between rolling stock and the track and aspects that may impact on stability and fatigue;
  • How noise and vibration is generated and methods of minimising impact between track and train;
  • The interface between the energy source and the train and electromagnetic compatibility;
  • Maintenance, vehicle examination and inspection processes, and related recording requirements;
  • Operational processes relating to in-service engineering and diagnostics;
  • Train care facility requirements to optimise train lifespan;
  • The potential impact of contractual commitments and penalties on the business and how this impacts on working practice.
  • Specific health and safety regulations and best practice while working with electrical power, emergency first aid for electrical hazards, safe working at height;
  • Electrical, electronic and mechanical engineering theories that underpin the field of power and distribution in the high speed rail context;
  • Industry standards that cover specific skills used for overhead lines, cable jointing and substation fitting activities;
  • Design of the electrification systems and components for a high speed rail system;
  • Power supply, transmission, protection and isolation devices for high speed rail
  • Planning, installation and maintenance of OLE and related equipment;
  • The process of managing electrification from receipt from the National Grid transformers to use at track-side or Overhead Line Equipment (OLE);
  • The key roles of Electrical and Plant Distribution Engineers and Electrification Engineers;
  • Fault-finding techniques, common faults and repair procedures;
  • New technologies used on high speed rail in Britain and abroad
  • Safety management for high speed rail operations;
  • The role of emergency planning and the function of responders;
  • Incident, accident, disaster and emergency management;
  • Cyber and other security threats to railway operations and mitigation factors;
  • The passenger market and management of revenue sources;
  • Importance of excellent customer service and the impact of quality assurance systems;
  • Procedures for delivering high speed passenger services;
  • Network management and operational management of timetabling and traffic management within high speed rail;
  • Principles of performance management

Skills

  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.
  • Develop and maintain an effective safety culture.
  • Embed a culture of health, welfare and safety compliance to ensure the health and safety of employees, customers, visitors and members of the public.
  • Rigorously apply security procedures.
  • Apply rigorous health and safety practices, comply with legislation and safety processes.
  • Design safety into all aspects of the rail network, accounting for end-user requirements.
  • Comply with relevant standards and regulations.
  • Identify and manage risk, and prepare contingency plans
  • Apply effective systems engineering practice, considering the interfaces between work packages and promoting and maintaining effective communications between disciplines.
  • Embed the principles of sustainability and environmental considerations into the design, development, installation and operation of high speed rail projects.
  • Design and implement innovative solutions using new technologies to improve efficiency, cost effectiveness, customer service and safety to work-based problems.
  • Demonstrate effective management, supervising and managing resources as appropriate.
  • Implement project management processes and tools to effectively manage work packages such as Gantt Charts, Logic Network, PERT Chart, Product and Work Breakdown Structure, Risk Register
  • Work effectively with stakeholders
  • Comply with quality assurance processes
  • Implement appropriate asset management tools to manage assets throughout their life cycle
  • Apply BIM and Asset Information Modelling (AIM) requirements effectively.
  • Interpret and manage information, which could include multi-dimensional modelling, complex work plans, technical drawings and schematics, including change control.
  • Undertake and implement a high standard of technical work taking responsibility for efficient and effective delivery of work packages.
  • Communicate effectively across all levels.
  • Use appropriate IT systems and applications
  • Apply and influence safety and health principles in order to ensure a safe and healthy working environment;
  • Implement processes that identify, eliminate, avoid and mitigate safety and health risks in design or construction;
  • Comply with industry standards and legislation;
  • Create, read, interpret and implement detailed plans and schedules;
  • Contribute to the design, planning or implementation of high speed rail civil engineering projects, which could include lineside equipment, tunnels, cuttings, bridges, viaducts, or embankments;
  • Contribute to the design, planning, implementation or decommissioning of temporary works;
  • Estimate, manage and control costs, programme, risk and resources within area of responsibility;
  • Effectively use industry software as appropriate to achieve BIM requirements;
  • Establish dimensional control by surveying and setting out;
  • Specify and select and manage a range of labour, plant and materials;
  • Implement procedures that take account of structures, geotechnics and drainage for the construction, durability and safe operation of a high speed railway;
  • Lead a team to efficiently manage a work package and achieve planned outcomes; apply processes for planning and delivery of both on-site and off-site construction.
  • Engage in processes that identify, avoid and mitigate safety and health risks in design and construction;
  • Apply systematic safety and health practice during planned and unplanned activities across the whole track lifecycle;
  • Comply with legislation, processes and standards relating to the planning, design, construction, monitoring, maintenance, renewal, repair, manufacturing and construction methodology, disposal and environmental impact of track;
  • Contribute to the design, construction, monitoring, maintenance, renewal, repair and decommissioning of track;
  • Contribute to determining appropriate manufacturing and construction methodologies, including the decommissioning and environmental impact of track;
  • Produce and interpret detailed technical documents, including the application of BIM and other regulated information systems;
  • Account for the impact of alignments and geotechnics on track design, construction, maintenance and final system needs;
  • Contribute to testing and commissioning including integration with other systems.
  • Ensure safety and health risks are identified and captured;
  • Identify and comply with relevant standards and regulations;
  • Apply systems thinking to a broad range of challenges in the context of high speed rail;
  • Identify system interfaces, contribute to interface management and communicate effectively across multiple disciplines and levels; The
  • Recognise different situations, plan systems engineering activities and apply systems engineering approaches;
  • Identify project or system lifecycles and apply modelling principles to test system-level functionalities, interrelationships and scenarios;
  • Select and apply appropriate system modelling techniques incorporating ergonomic and human factors;
  • Contribute to the identification of testing, commissioning and hand-over requirements;
  • Contribute to the capture, development, and management of requirements;
  • Contribute to the development of systems architecture;
  • Use available software and tools as appropriate, including the application of BIM;
  • Estimate the production availability of a system by assessing failure modes, frequencies and consequences;
  • Contribute to system analysis activities.
  • Fully comply with all safety guidance and regulations consistent with critical safety integrity levels;
  • Assess risk and report failure modes and various scenarios in order to build protection into the design, including the application of ergonomics and human factors;
  • Identify and describe modern systems for CCC as applicable to High Speed Rail;
  • Identify and manage issues resulting from the interface between peripheral systems with modern digital and electronic CCC systems;
  • Capture and manipulate survey and geographical data across all interfaces to inform design;
  • Contribute to the selection, design, installation, maintenance, operation and decommissioning of CCC systems including within the CSM framework;
  • Plan and implement monitoring, maintenance and repair of CCC systems; diagnose faults and implement solutions for a modern CCC system;
  • Apply data, configuration and change management;
  • Develop and apply security processes.
  • Develop and maintain safety critical competencies, knowledge and behaviours;
  • Apply principles of product safety design and maintenance and safe working practice to include the impact of ergonomics and human factors;
  • Safely operate the rolling stock system and subsystem to be able to analyse and fault find;
  • Demonstrate the ability to interpret and apply legislation and standards as applied to rolling stock design, maintenance and operation;
  • Contribute to the design of systems, subsystems and components;
  • Use monitoring and inspection equipment to measure parameters of major rolling stock subsystems and components;
  • Effectively use diagnostic tools and methods to diagnose faults and defects in rolling stock and plan and implement solutions to maximise rolling stock use and ensure safe and operational service;
  • Dynamically risk assess non-routine work;
  • Accurately capture and maintain all necessary documentation, records and data analysis.
  • Consistently apply health and safety best practice and compliance, apply safe working at height and safety harness use and apply emergency first aid for electrical hazard;
  • Use and direct the use of lifting and access equipment
  • Safely, accurately and efficiently install and commission track-side and overhead power supply and transmission systems for high speed rail;
  • Erect and direct the erection of different types of overhead line structures, pre-fabrication and installation of main structure and small part steelwork and running wire systems
  • Take account of sectioning, insulation, registration and in-span components and the installation, enhancement and renewal of earthing and bonding
  • Plan, monitor, implement and maintain track-side and overhead line equipment using appropriate systems, standards, procedures and tools;
  • Conduct dynamic risk assessment for non-routine occurrences;
  • Read and interpret both paper-based and digital technical design drawings, models and schematics;
  • Effectively supervise teams and allocate work schedules;
  • Accurately complete and maintain necessary documentation.
  • Implement high speed railway standards, procedures and regulations to ensure effective, safe, secure and efficient operation;
  • Use historical and real-time data to accurately predict likely sources of incidents and make comprehensive plans for mitigation;
  • Implement appropriate training received in a response to an emergency situation;
  • Apply standard network code and operational code and interpret ERCO, ASSET and Ordnance Survey maps;
  • Implement tools and systems to effectively manage timetabling and high speed rail operations to ensure efficiency;
  • Apply performance management principles effectively;
  • Develop, implement and monitor policies and procedures designed to deliver excellent customer service and experience; demonstrate a commitment to outstanding customer service;
  • Interpret financial reports and manage revenue sources.

Behaviours

  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
  • Fosters a safe, secure and healthy working environment through personal responsibility and behaviour
  • Is customer focused and is dedicated to improving the customer experience
  • Effective self-manage, prioritise and a proactively approaches work and continuous professional development.
  • Effectively lead
  • Acts professionally, shows commitment to the industry and employer, and is an effective ambassador for the employer
  • Is committed to equality, diversity and inclusion, and act ethically with integrity and respect
  • Works flexibly, embraces change, handles ambiguity and accepts new ideas and ways of working
  • Uses effective communication skills to work collaboratively and to exchange constructive feedback
Apprenticeship category (sector)
Engineering and manufacturing
Qualification level
4
Equal to higher national certificate (HNC)
Course duration
36 months
Funding
£21,000
Maximum government funding for
apprenticeship training and assessment costs.
Job titles include
  • civil engineers
  • operations managers

View more information about High speed rail and infrastructure technician (level 4) from the Institute for Apprenticeships and Technical Education.