PRINCE2® 6th Edition Practitioner Passport: On-Demand PRINCE2® 6th edition Practitioner Passport is your route to achieving the PRINCE2® certification at your own pace. This on-demand course is accredited by AXELOS to support self-study distance learning for the PRINCE2® 6th edition Foundation and Practitioner examinations. What You Will Learn You'll learn how to: Identify the purpose and major content of all roles, components, processes, and themes as described in the manual Identify the source or derivation of process groups, from their purpose and / or key content Indicate the relationships between processes and themes of a project Apply PRINCE2® in an actual project environment, simulated via a case study provided as part of the exam Processes-CS and MP Processes-SU and IP Introduction to PRINCE2® Getting Started Processes-DP, SB, and CP Organization Theme Business Case Theme Risk Theme Plans Theme Quality Theme Change Theme Progress Theme
Students who complete the PV201L workshop will be able to: Perform power and energy calculations Obtain and apply specifications for PV modules and determine their performance given various environmental and operating conditions Safely operate various types of digital multimeters Diagram and determine the power, current, and voltage characteristics of PV modules in different series and parallel configurations Install various mounting systems (ground, pole, roof, and trackers). Decipher balance-of-system equipment specification sheets to determine the critical information needed for system design Install a residential grid-direct system including the array, inverter, circuit conductors, and overcurrent protection Safely operate equipment grounding, system grounding, and components and conductors used for grounding Work with wires and components on schematics of residential grid-direct systems: disconnects, inverter, equipment grounding conductors, ungrounded conductors, grounded conductors, the grounding electrode(s), and the AC and DC system grounds Identify potential safety hazards and demonstrate the proper use of personal protective equipment for working on grid-direct PV systems List the order of installation, commissioning, and decommissioning of a grid-direct PV system Note: This class is a great complement to PV301L, the Solar Electric Lab Week (Battery-Based). This Women's Solar Electric Lab Week is powered by:
Students who complete the PV201L workshop will be able to: Perform power and energy calculations Obtain and apply specifications for PV modules and determine their performance given various environmental and operating conditions Safely operate various types of digital multimeters Diagram and determine the power, current, and voltage characteristics of PV modules in different series and parallel configurations Install various mounting systems (ground, pole, roof, and trackers). Decipher balance-of-system equipment specification sheets to determine the critical information needed for system design Install a residential grid-direct system including the array, inverter, circuit conductors, and overcurrent protection Safely operate equipment grounding, system grounding, and components and conductors used for grounding Work with wires and components on schematics of residential grid-direct systems: disconnects, inverter, equipment grounding conductors, ungrounded conductors, grounded conductors, the grounding electrode(s), and the AC and DC system grounds Identify potential safety hazards and demonstrate the proper use of personal protective equipment for working on grid-direct PV systems List the order of installation, commissioning, and decommissioning of a grid-direct PV system Note: This class is a great complement to PV301L, the Solar Electric Lab Week (Battery-Based).
Students who complete the PV301L workshop will be able to: Identify and describe the basic functions of each component in a PV system Describe the configuration of various types of PV systems: PV direct, Stand-alone, PV/hybrid, Multimode, Zero-sell, Micro-grid, Utility-scale energy storage Calculate the capacity & voltage of different batteries Determine the state of charge of a battery by testing voltage and specific gravity List safety precautions & equipment required to work with batteries Demonstrate safe procedures for connecting and disconnecting batteries Demonstrate the process of adding water to batteries Identify appropriate battery enclosures Diagram and wire battery banks in series and parallel configurations, given various system parameters Make cables and lug connections for battery wiring Install temperature sensors on batteries Wire the battery bank for a live system Wire and test charge controllers through the various stages of operation Install and test PWM and MPPT charge controllers Program MPPT charge controllers based on battery and array values Wire and program battery SOC meters in different PV system configurations Set up and operate batteries during bulk, absorption, float, and equalization cycles Describe how maximum power point tracking and voltage step-down affect a PV system Identify some features, options, and metering available on different types of battery chargers Identify appropriate inverter types for different battery-based system configurations Compare available features and capabilities of battery-based inverters Identify specifications critical for battery-based inverters Wire test and program battery based inverters Discuss when and why breakers would be used rather than fuses Use a 3-line diagram to wire a system Discuss the order and perform safe installation practices Demonstrate the order of safe commissioning Demonstrate the order of shut-down and how to establish an electrically safe working environment
Students who complete the PV351 workshop will be able to: Determine use and analyze results from various test tools used during commissioning, performance evaluation, operations and maintenance, and troubleshooting. Define the theory, procedures, and processes behind insulation resistance testing, IV curve tracing, infrared cameras and thermal imaging, performance evaluation, and troubleshooting Demonstrate proper set-up, use, and function of PV test tools including: IV curve tracers, insulation resistance testers, and thermal cameras Evaluate the performance of working systems using correct and complete field procedures Troubleshoot and locate common PV array and system faults using appropriate methodologies and testing tools
Managing Successful Programmes (MSP®) 5th Edition Practitioner: On-Demand Understand how to apply the MSP principles in context Understand how to apply and tailor relevant aspects of the MSP themes in context Understand how to apply and tailor relevant aspects of the MSP processes in context What you will Learn At the end of this course, participants will be able to: Understand how to apply the MSP principles in context Understand how to apply and tailor relevant aspects of the MSP themes in context Understand how to apply and tailor relevant aspects of the MSP processes in context Course Introduction Application of MSP Principles Program Strategy and Themes Application of Organization Theme Application of Design Theme Application of Justification Theme Application of Structure Theme Application of Knowledge Theme Application of Assurance Theme Application of Decisions Theme Application of MSP Processes
ISO 13485 Foundation training enables you to learn the basic elements to implement and manage a Medical Devices Quality Management System (MDQMS) as specified in ISO 13485. During this training course, you will be able to understand the different modules of a MDQMS, including MDQMS policy, procedures, performance measurements, management commitment, internal audit, management review and continual improvement. After completing this course, you can sit for the exam and gain "Certified ISO 13485 Foundation' Certification. This Certificate shows that you have understood the fundamental methodologies, requirements, framework and management approach. About This Course Learning Objectives Understand the elements and operations of a Medical Devices Quality Management System (MDQMS) Acknowledge the correlation between ISO 13485 and other standards and regulatory frameworks Understand the approaches, methods and techniques used for the implementation and management of a MDQMS Course Agenda Day 1: Introduction to Medical Devices Quality Management System (MDQMS) concepts as required by ISO 13485 Day 2: Medical Devices Quality Management System requirements and Certification Exam Assessment Delegates sit a combined exam, consisting of in-course quizzes and exercises, as well as a final 40 question, multiple choice exam on Day 2 of the course. The overall passing score is 70%, to be achieved within the 60 minute time allowance. Exam results are provided within 24 hours, with both a Certificate and a digital badge provided as proof of success. Prerequisites None What's Included? Certification fees are included on the exam price Training material containing over 200 pages of information and practical examples will be distributed An attestation of course completion worth 14 CPD (Continuing Professional Development) credits will be issued to the participants who have attended the training course. Who Should Attend? Individuals involved in Medical Devices Quality Management Individuals seeking to gain knowledge about the main processes of Medical Devices Quality Management Systems (MDQMS) Individuals interested to pursue a career in Medical Devices Quality Management Accreditation Provided by This course is Accredited by NACS and Administered by the IECB
MSP® certification provides guidance for programme managers, business change managers and the next step for project managers to develop their knowledge and skills to be able to positively respond to the challenges for managing programmes and larger, more strategic or multiple projects. MSP 5th edition emphasizes flexibility, adaptability, and responsiveness by adopting an incremental approach to the programme lifecycle and thus enabling organizational agility. AXELOS offers two levels of MSP Examination: MSP Foundation and MSP Practitioner. The MSP Foundation Examination is intended to assess whether the candidate can demonstrate sufficient recall and understanding of the MSP programme management framework. The MSP Foundation qualification is a prerequisite for the MSP Practitioner Examination, which assesses the ability to apply understanding of the MSP programme management framework in context. The MSP® 5th Edition Foundation course is a training based on the exam specification for MSP Foundation certification and is aligned with the Managing Successful Programmes (5th Edition) guide from AXELOS.
Management of Portfolios (MoP®) Practitioner: On-Demand The Practitioner certification allows you to demonstrate an understanding of how to apply and tailor the MoP guidance and to analyse portfolio data, documentation and roles in relation in a practical context. What you will Learn Individuals certified at the MoP Practitioner level will be able to: Define the business case to get senior management approval for portfolio management Plan the implementation of portfolio management Select and adapt MoP principles, practices, and techniques to suit different organizational environments Evaluate examples of MoP information including documents and role descriptions Analyze the solutions adopted in relation to a given scenario Day 1 Introduction Overview MoP Portfolio Definition Portfolio Management Roles Portfolio Management Documents MoP Practitioner Assignments Day 2 Recap Day 1 Portfolio Management Documents Portfolio Delivery How to Implement Practice Exam MoP Practitioner Exam
Managing Multiple Projects: Virtual In-House Training Succeeding in today's competitive marketplace often requires cycle time reduction - reducing the duration of projects and getting results faster. This workshop will address managing multiple projects within the context of program or product management. Are your projects taking longer and longer to complete? Are results less than optimal because of time pressures on resources? Would you like to increase project 'throughout'? Succeeding in today's competitive marketplace often requires cycle time reduction - reducing the duration of projects and getting results faster. This workshop will address managing multiple projects within the context of program or product management. Planning and managing individual projects is challenging. When introducing the real-life limitation of resources and other outside influences into the multi-project environment, those challenges are magnified, and new challenges are introduced. This interactive workshop will position you for immediate action. The goal of this course is to equip you with the necessary knowledge, skills, and techniques so that you can effectively and productively manage multiple projects. What you Will Learn You'll learn how to: Manage stakeholder relationships and expectations Prioritize and sequence multiple projects Manage time and stress within a multiple project environment Effectively manage logical dependencies among projects Optimize the use of resources across multiple projects using concepts from Critical Chain methods Manage risk and communications in a multiple project environment Getting Started Introductions Course structure Course goals and objectives Foundation Concepts Portfolio, program, and project management principles The multiple project environment The MMP Process Model Developing the Multiple Project List Multiple project portfolio management Project selection Project categories and types The multiple project list Multiple Project Logical Dependencies Project dependencies Types of multiple project portfolios Categories of logical dependencies across multiple projects Project priorities in the multiple project schedule Multiple Project Resource Management Multiple project resources and resource management concepts Multiple project resource loading Resource pool and resource database Multiple project resource issues and outsourcing Critical chain resource management, including drum resources and multi-tasking Managing Risk Across Multiple Projects Multiple project risk management process Identifying, assessing, and responding to multiple project risks Critical chain and multiple project risks Risk interrelationship management methods Creating and Executing the Multiple Project Plan The multiple project plan Multiple project scheduling Multiple project budgeting Executing and maintaining the multiple project plan Controlling in the multiple project environment Tools in multiple project management Multiple Project Communications Effective communication in the multiple project environment Common communication barriers Multiple project communications plan Resolving multiple project conflicts Summary and Next Steps What did we learn, and how can we implement this in our work environments?