4184 Courses

DWDM training course description A concise overview of Wave Division Multiplexing (WDM) with both Coarse Wave Division Multiplexing (CWDM) and Dense Wave Division Multiplexing (DWDM) being covered. The course starts with a review of the relevant elements of fibre transmission and multiplexing before then studying WDM components and architectures. Reliability, resilience and management are then followed by WDM services and futures. What will you learn Explain the benefits of WDM. Describe Dispersion and four way mixing. Describe the different WDM equipment components. Describe different WDM architectures. Explain How DWDM works. DWDM training course details Who will benefit: Anyone working with CWDM/DWDM. Prerequisites: Telecommunications Introduction Duration 2 days DWDM training course contents Fibre communications review Optical transmission, Fibre characteristics, Fibre component parts. Multi Mode Fibre (MMF). Single Mode Fibre (SMF). Fibre connections. Lasers. Attenuations, dispersion, optical signal noise ratios (OSNR) and their effects. Channel Spacing and Signal Direction. Limiting factors to single wavelength. WDM overview Multiplexing, TDM, WDM benefits. WDM standards. CWDM vs. DWDM. Four Wave Mixing (FWM). Impact and countermeasures to FWM on WDM. CWDM ITU G.694.2, channels, channel spacing. DWDM ITU G.694.1, channels, channel spacing. WDM Equipment Components Equipment components and building blocks. Optical Terminal Multiplexers (OTM). Optical Add/Drop Multiplexers (OADM). Adding versus dropping. Optical Amplifiers. Erbium Doped Fibre Amplifiers (EDFA). Transponders and Combiners. WDM/DWDM Hubs. Optical and Electrical Cross Connects (OXCs/DXCs). Types of Cross Connects (Transparent/Opaque). Advantages and disadvantages of various Optical cross connects. WDM Architectures WDM network sections. Point-to-Point, Optical switches, mesh, ring and star topology. Example of combined WDM and other technology network. Wavelength converting transponders, 1R, 2R, 3R. Protection for WDM Sub 50ms failover. Equipment protection. Card protection. Y cable, Splitter protection. Far end laser control. Line protection. OMSP 1+1, OMSP 1:1, OMSP 1: N. Self healing optical ring. Sub Network Connection Protection (SNCP). Automatically Switched Optical Networks (ASON). WDM Management Options In band management. Out of band management. The Optical Supervisory Channel (OSC). OSC capabilities. WDM services WDM Access. Bit rates, Transparent Networks. Modulation, DQPSK. SDH over WDM. Migrating from SDH to DWDM. Ethernet over WDM, IP over WDM. Optical Transport Networks G.709, 'digital wrapper', Optical Channel Payload Unit (OPU), Optical Channel Transport Unit ( OTU), Optical Channel Data Unit (ODU). OTU1, OTU2, OTU3, OTU4. WDM Futures All optical amplification, Raman amplification, distributed, lumped. Bit rates. Solitons. Coherent technologies.

GPON and FTTx networks training course description Designed to benefit those requiring an in depth knowledge of the principles and applications of Ten Gigabit and Gigabit Passive Optical Networking and Fibre to the X in NG Networks applications and their associated equipment, its flexibility and function within a modern transmission network. Using an effective mix of 'hands on' equipment instruction and correlation to theory based learning the delegate will gain a complete understanding of the equipment and the tasks to be undertaken in a real life situation. What will you learn Compare PON/FTTx systems. Explain network elements and designs. Support applications and network interfaces. List circuit provisioning and bandwidth requirements. Understand upstream & downstream issues. Describe headend & network elements/OLT-ONT. Perform network testing with OTDR test sets. GPON and FTTx networks training course details Who will benefit: Anyone working with GPON and FTTx. Prerequisites: Introduction to data communications and networking. Duration 5 days GPON and FTTx training course contents FTTN, FTTC, FTTH SMF, MMF, Fibre safety and properties (dispersion/attenuation), Fibre reel cables and types, Fibre installation and air blown fibre, Transmitters and receivers - power budget/laser classes. Fibre to the home (FTTH), FTTC (Fibre to the Cabinet), FTTN (Fibre to the node) , FTTD (Fibre to the desk), FFTH topologies and wavelengths, Active or passive optical network. WDM equipment and GPON OSP design Wavelength considerations, WDM/DWDM/CWDM, EDFA optical amplification, AWG (Arrayed Waveguide Grating) splitters , Couplers (splitters) and losses, Optical splitters 1x2, 1x4, 1x8, 1x16, 1x32, 1x64, 2x64. PON variants Gigabit passive optical network (GPON), Gigabit Ethernet passive optical network (GEPON), Time division PON (TDM-PON), Wave Division Multiplexing PON (WDM-PON), 1Gbps, 10Gbps, 40Ggps, 100Gbps FSAN (Full Service Access Network) NGA (Next Generation Access), Strategies for TDM-PON to WDM-PON migration, Architecture of NG-PON (hybrid WDM/TDM PON), Additional services than triple play. GEPON design GPON OSP centralized and distributed design, GPON PON splitters x4 x8 x32, Fibre splice trays /cassette trays & enclosures, GPON field testing and installation verification, GPON physical layer testing, Optical time domain reflectometer (OTDR), Optical power source & meter, Optical return loss (ORL), APON/BPON/GPON/EPON comparisons. GPON ITU-T G.984.1 Reference model, terminology & architecture, Access network system management functions. ONT & OLT functional block examples. FTTx scenarios, 4 switching arrangements for external access network backup. GPON ITU-T G.984.2 Physical layer, Enhancement band, Bit rate and wavelengths, FEC and RAMAN. GPON ITU-T G.984.3 Frame structure, GPON encapsulation method (GEM), GTC adaptation and framing sublayer protocol stack, Status reporting & traffic monitoring DBA (SR-DBA & TM-DBA), Transmission container (T-CONT) types, Downstream & upstream multiplexing, GEM port identifier, Media access control and ONU registration, Extended bandwidth assignment model scheduling architecture, PLOAM & alarm messages, Downstream & Upstream FEC, Process order in a GTC transmit flow. GPON ITU-T G.984.4 and G.988 ONT management and control interface (OMCI) Management interface, Reference model, Typical ONT with SCTE 55-1 or SCTE 55-2 compliancy. GPON ITU-T G.984.5 enhancement band Band options, GPON NGA, Wavelength allocation. GPON ITU-T G.984.6 optical reach extension (G.984.re) Reach extension (RE), OA-based and OEO-based reach extenders, Protection, Reach extender with OTDR blocking filters (BF) and bypass (BYP) filters. GPON ITU-T G.984.7 long reach Quiet Window. 10-GPON ITU-T G.987.1 (XG-PON) Scenarios, reference access network architecture, XG-PON with G-PON through WDM1r, G-PON and XG-PON wavelength allocation, G-PON and XG-PON co-existence with video overlay option, RE migration scenarios. G.989 40Gbps XG-PON2 Functional reference architecture, NG-PON2 system coexistence with legacy systems, Definitions of legacy compatibility terminology. GPON issues and standards GPON components GPON OLT / GPON ONT, GPON management, Operational support systems (OSS), Network management systems (NMS), OMCI (ONT Management control interface), RG (Residential gateway), Data and prioritised voice channel product, GPON broadband-forum standards, Broadband-forum , TR-069 and TR-156, HPNA (home phone network alliance), Powerline carrier (PLC), GPON DLNI G.hn or G.9960, MOCA, FTTH council certification standard for network certification. Fibre-connected home badge, Ethernet in the first mile (EFM), GPON frame synchronization to network timing, Direct clock synchronization interface (BITS), Multiservice access platform (MSAP), Software planning tool, Superconnected cities / voucher scheme. Hands on practical assignments Single and multimode fibre recognition, Fibre Cleaning methods, Checking cleaning with an optical microscope, Optical light source and optical power meter referencing, PON splitter and fibre drum testing with an optical power meter, 6km classroom passive optical network testing with an OTDR at 1310/1550nm, Using decibels (dB's) and decibel milliwats (dBm's), Designing networks up to 20km long using vendor specifications (power budget), Fault finding with a visible fault locator.

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About this Training Course Managed Pressure Drilling (MPD) offers opportunities to improve safety and efficiency in drilling, and it is increasingly recognised by operators and regulators. MPD aims to cost effectively resolve chronic drilling problems that contribute to non-productive time. This 3 full-day course provides participants with an understanding of the MPD techniques and equipment. The course starts with the design requirements for an MPD operation. It covers all MPD methods, including constant bottom hole pressure and mud cap drilling operations. It also includes all of the rig types - both onshore and offshore - and MPD. MPD equipment is presented in detail and the design aspects of the well are also examined. Training Objectives This course aims to provide participants with a good understanding of the various aspects of managed pressure drilling. It also enables participants to gain knowledge of planning MPD operations, type of equipment and the equipment requirements for both onshore and offshore and MPD operations. At the end of the course, participants will be able to: Understand the variations in MPD Design MPD operations for various techniques Understand the engineering requirements of MPD Define MPD equipment requirements Understand operational and well control aspects of MPD Target Audience This course is designed for engineers, managers and service providers who are about to use MPD techniques and are trying to better understand the associated complexities and challenges surrounding MPD. Trainer Your expert course leader was born and raised in Nijmegen, Netherlands. He holds an MSc in Drilling Engineering from The Robert Gordon University in Aberdeen and has over 39 years of oilfield experience. He started in the industry back in 1977 as a Mud logger before becoming a wellsite drilling engineer in 1980 working mainly in the Middle East and West Africa. In 1988, he joined Shell in in the Southern North Sea. In 1995, he joined Smedvig in Norway and worked on a number of deepwater wells as well as on underbalanced drilling operations. In 1999, he started Leading Edge Advantage in Aberdeen and worked in coiled tubing, underbalanced and managed pressure drilling. In 2004, he joined Weatherford as Regional Engineering Manager in Singapore and developed the first ultra deepwater MPD systems. In 2010, he joined SPT Group specializing in well control and hydraulics modelling. SPT Group was later acquired by Schlumberger in 2012. At Schlumberger, he was Drilling Adviser, with a focus on well control, relief well planning and MPD. During that time, he was also an instructor for NExT teaching numerous well engineering courses. In 2015, he joined Wild Well as Engineering Manager in Asia and in February 2017, he became an independent consultant concentrating on provision of drilling engineering training. He has written and presented numerous papers and authored several chapters in the SPE Advanced Technology books. He is an active committee member and speaker on numerous SPE Workshops around the world. POST TRAINING COACHING SUPPORT (OPTIONAL) To further optimise your learning experience from our courses, we also offer individualized 'One to One' coaching support for 2 hours post training. We can help improve your competence in your chosen area of interest, based on your learning needs and available hours. This is a great opportunity to improve your capability and confidence in a particular area of expertise. It will be delivered over a secure video conference call by one of our senior trainers. They will work with you to create a tailor-made coaching program that will help you achieve your goals faster. Request for further information post training support and fees applicable Accreditions And Affliations

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Event Planning 1 Day Training in Brighton

QA Level 1 Award In Fire Safety Awareness (RQF) Face to Face: Half-day course Virtual Classroom: Spread over 2 sessions of 2½ hr duration This course is an ideal way to ensure that all employees have a good understanding of fire safety Candidates will learn basic fire safety principles in order to ensure they are keeping themselves and others in the workplace safe at all times Benefits of this course: Candidates will learn basic fire safety principles in order to ensure they are keeping themselves and others in the workplace safe at all times Candidates will also learn what to do in the event of an emergency and the simple measures that can be taken to control the risk of fires With subjects covered in just half a day, this course is an ideal way to ensure that all employees have a good understanding of fire safety, whilst minimising disruption to your organisation’s day to day activity This course is also good for those who just want to know a bit more about keeping themselves and loved ones safe from possible fires Course Contents: Causes of Fire in the Workplace The Costs of Fires in the Workplace for Employers, Employees and Society Basic Fire Safety Duties and Responsibilities Actions to be taken in the event of a Fire Principles of Fire Risk Control Safe Use of Portable Fire Fighting Equipment Fire Safety Equipment Checks CPD Accredited Course Our Fire Warden course is a CPD Accredited course, and thus counts towards your CPD hours. If you'd like to do an Ofqual Regulated course instead, please see here: Fire Safety Level 1 Fire Safety level 2 We also run an Annual Fire Safety Refresher, where we cover the most important aspects of fire safety in just two hours. This course is run via Virtual Classroom, and is also CPD Accredited.

About this Training Course Managing process hazards in the hydrocarbon and chemical processing industries is a critical function that requires relevant knowledge and skills due to the risks involved. The Advanced Process Safety Engineering course will discuss the interrelation of the various techniques of process safety for analysing, with a particular emphasis on engineering design aspects, as well as how to manage process hazards in a safe and effective way and how they can potentially be avoided. In this 3 full-day advanced level course, the expert course leader will provide participants with insights and examples from his career and experience to show how their learning should be applied in real-life situations. Feedback and questioning is highly encouraged. Reference material and reports can be provided to give more information on any particular topic of interest. Individual and group exercises, tutored exercises and video case studies will be provided throughout the course to underpin the key learning points. Training Objectives Upon completion of this course, participants will acquire in-depth knowledge of: Risk management and 'As Low as Reasonably Practicable' (ALARP) principles. Different aspects of process design that influence process safety. Approach to 'inherently safer' design. Defence in depth using 'layers of protection'. Process for ensuring the technical integrity of safety-critical equipment. Hazards associated with process materials. Range of hazard identification and consequence modelling techniques. Causes and mitigation of human error. Reliability and availability of safety-critical protection equipment. Role of engineered safety-critical equipment and systems. Target Audience This course is suitable for industry professionals who need to acquire a comprehensive understanding of process safety. This includes those who are required to make managerial decisions where process safety is a key consideration, those who are moving into process safety positions or those who wish to broaden their process safety knowledge within their existing discipline. It is particularly suited for anyone involved in the design, operation, modification or maintenance of a major hazard installation, and will demonstrate a substantial understanding of process safety for those engaged in Continuous Professional Development or aiming for Chartered Engineer status. This course will benefit professionals such as: Operations and maintenance supervisors Process, mechanical and chemical engineers and technicians Design engineers, project engineers and HSE managers Control, automation and instrumentation engineers Course Level Advanced Trainer Your expert course leader has 50 years' experience in chemical and process safety engineering. His early career included 20 years in design and project engineering with various fine chemical and pharmaceutical companies where he designed chemical processes, specified plant equipment and selected materials for highly corrosive and toxic processes, often where textbook data was not available. This was followed by 10 years in offshore oil and gas design projects where he was responsible for setting up a Technical Safety group to change design safety practices in the aftermath of the 1988 Piper Alpha disaster. In recent years, he has been called upon to conduct various offshore and onshore incident investigations. His career has given him experience in project engineering, project management, process design and operations, safety engineering and risk management. He is a Fellow of the UK Institution of Chemical Engineers. He served on the Scottish Branch committee, and was elected chairman for a two-year term in 1991. He has also been chairman of the Safety and Reliability Society - North of Scotland Branch. He has delivered training courses in Process Hazard Analysis (HAZOP and HAZID), Process Safety Management, Hazard Awareness, Risk Assessment, Root Cause Analysis, Failure Modes & Effect Analysis and has lectured on Reliability Analysis to the M.Sc. course in Process Safety and Loss Prevention at Sheffield University. In addition to delivering training courses, he currently facilitates HAZOP / HAZID / LOPA studies and undertakes expert witness roles advising lawyers engaged in contractual disputes, usually involving the design or construction of chemical plants or Oil & Gas production facilities, or criminal prosecutions. POST TRAINING COACHING SUPPORT (OPTIONAL) To further optimise your learning experience from our courses, we also offer individualized 'One to One' coaching support for 2 hours post training. We can help improve your competence in your chosen area of interest, based on your learning needs and available hours. This is a great opportunity to improve your capability and confidence in a particular area of expertise. It will be delivered over a secure video conference call by one of our senior trainers. They will work with you to create a tailor-made coaching program that will help you achieve your goals faster. Request for further information post training support and fees applicable Accreditions And Affliations

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).