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Our Professional Certificate Course in Understanding the Role of Information Technology in Logistics and Supply Chain is designed to provide participants with a comprehensive understanding of the impact of IT on supply chain management. The course covers a wide range of topics including the concept of Information Logistics (IL) and the Information Logistics Model, Logistics Information Systems and the role of information elements. Participants will also learn about Big Data logistics and the Enterprise Application Integration (EAI) approach. Additionally, the course will cover Logistics Processes Integration Framework (ELPIF) based on Web Services, and the Resource Integration Framework of Logistics Resource Grid (LRG). Upon completion of this course, participants will have a deep understanding of how IT can be used to optimize supply chain management processes and drive success in the logistics industry. Our Professional Certificate Course provides a thorough overview of the crucial role played by Information Technology in modern logistics and supply chain management. Upon completion, participants will have the skills and knowledge needed to drive success in the ever-evolving field of logistics and supply chain management. After the successful completion of the course, you will be able to learn about the following, The role of IT in Supply Chain Management. The concept of Information Logistics (IL). Information Logistics Model. Logistics Information System. The concept of information element. Big data logistics. Enterprise application integration. Logistics Processes Integration Framework(ELPIF) Based on Web Services Resource Integration Framework of Logistics Resource Grid (LRG). Our Professional Certificate Course in Understanding the Role of Information Technology in Logistics and Supply Chain is designed to provide participants with a comprehensive understanding of the impact of IT on supply chain management. The course covers a wide range of topics including the concept of Information Logistics (IL) and the Information Logistics Model, Logistics Information Systems and the role of information elements. Participants will also learn about Big Data logistics and the Enterprise Application Integration (EAI) approach. Additionally, the course will cover Logistics Processes Integration Framework (ELPIF) based on Web Services, and the Resource Integration Framework of Logistics Resource Grid (LRG). Upon completion of this course, participants will have a deep understanding of how IT can be used to optimize supply chain management processes and drive success in the logistics industry. VIDEO - Course Structure and Assessment Guidelines Watch this video to gain further insight. Navigating the MSBM Study Portal Watch this video to gain further insight. Interacting with Lectures/Learning Components Watch this video to gain further insight. Understanding the Role of Information Technology in Logistics and Supply Chain Self-paced pre-recorded learning content on this topic. Understanding the Role of Information Technology in Logistics and Supply Chain Put your knowledge to the test with this quiz. Read each question carefully and choose the response that you feel is correct. All MSBM courses are accredited by the relevant partners and awarding bodies. Please refer to MSBM accreditation in about us for more details. There are no strict entry requirements for this course. Work experience will be added advantage to understanding the content of the course. The certificate is designed to enhance the learner's knowledge in the field. This certificate is for everyone eager to know more and get updated on current ideas in their respective field. We recommend this certificate for the following audience, Logistics and Supply Chain Professionals IT Professionals looking to specialize in Logistics and Supply Chain Business owners and Entrepreneurs seeking to improve supply chain operations Students pursuing a career in Logistics and Supply Chain Management Anyone interested in understanding the impact of IT on Logistics and Supply Chain. Average Completion Time 2 Weeks Accreditation 3 CPD Hours Level Advanced Start Time Anytime 100% Online Study online with ease. Unlimited Access 24/7 unlimited access with pre-recorded lectures. Low Fees Our fees are low and easy to pay online.

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

LTE Architecture and Protocols course description This course provides a comprehensive tour of the LTE architecture along with services provided and the protocols used. What will you learn Describe the overall architecture of LTE. Explain the information flows through LTE. Describe the LTE security. Describe LTE mobility management. Recognise the next steps for LTE. LTE Architecture and Protocols course details Who will benefit: Anyone working with LTE. Prerequisites: Mobile communications demystified Duration 3 days LTE Architecture and Protocols course contents Introduction History, LTE key features. The 4G ITU process. The LTE 3GPP specifications. Specifications. System Architecture LTE hardware architecture. UE architecture and capabilities. E-UTRAN and eNB. EPC, MME functions, SGW, PGW and PCRF. System interfaces and protocol stacks. Example information flows. Dedicated and default bearers. EMM, ECM, RRC state diagrams. Radio transmission and reception OFDMA, SC-FDMA, MIMO antennas. Air interface protocol stack. Logical, transport and physical channels. Frame and slot structure, the resource grid. Resource element mapping of the physical channels and signals. Cell acquisition, data transmission and random access. MAC, RLC, PDCP protocols. LTE spectrum allocation. Power-on procedures Network and cell selection. RRC connection establishment. Attach procedure, including IP address allocation and default bearer activation. LTE detach procedure. Security in LTE networks LTE security features, identity confidentiality, ciphering and integrity protection. Architecture of network access security in LTE. Secure key hierarchy. Authentication and key agreement procedure. Security mode command procedure. Network domain security architecture. Security associations using IKE and IPSec. Mobility management RRC_IDLE, RRC_CONNECTED. Cell reselection, tracking area updates. Measurement reporting. X2 and S1 based handovers. Interoperation with UMTS, GSM and non-3GPP technologies such as cdma2000. QoS, policy control and charging QoS in LTE, EPS bearers, service data flows and packet flows. The architecture and signalling procedures for policy and charging control. Data transport using GPRS, differentiated services and MPLS. Offline and online charging in LTE. Delivery of voice and text messages over LTE Difficulties and solutions for Voice over LTE. Architecture and call setup procedures for circuit switched fallback. Architecture, protocols and call setup procedures in IP multimedia subsystem. Enhancements in release 9 LTE location services. Multimedia broadcast / multicast service and MBSFN. Cell selection, commercial mobile alert service. LTE Advanced and release 10 Impact of carrier aggregation on LTE air interface. Enhanced MIMO processing on uplink and downlink. Relaying. Release 11 and beyond. OAM and self organising networks Operation, administration, maintenance and provisioning for LTE. Self-configuration of base station parameters. Fractional frequency re-use, inter-cell interference co-ordination. Self-optimisation of base station procedures. Self-healing to detect and recover from faults.

Rapid shutdown for PV systems on buildings Expansion of ground-fault and arc-fault requirements Changes that further enable 1,000 Vdc PV systems Updates to disconnect and fuse servicing requirements New standards for field-applied hazard markings Major changes for interconnecting PV systems to the grid New requirements for battery-based PV systems, both stand-alone and interactive Additional changes in Articles 690 and 705, as well as other relevant Articles Join SEI instructors and Code experts Rebekah Hren and Brian Mehalic for a fast-paced and fun three-hour long look at how PV design and installation requirements changed with the adoption of the 2014 Code.

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LTE Airside training course description This course provides a concise insight into the LTE airside. Key parts of the course are detailed looks at the air interface protocol stack, cell acquisition, transmission and reception of data and of he layer 1 procedures along with layer 2 procedures. What will you learn Explain the RF optimisation flowchart. Describe the importance of Reference Signal Received Power (RSRP). List many of the 3GPP recommended KPIs. Describe the concept of APN AMBR and UE AMBR within LTE. Describe the use of planning and optimisation computer tools. LTE Airside training course details Who will benefit: Anyone working with LTE. Prerequisites: Essential LTE Duration 2 days LTE Airside training course contents Introduction and review of LTE This section describes the requirements of LTE and key technical features, and reviews the system architecture. LTE Architecture, UE, E-UTRAN and EPC. Specifications. OFDMA, SC-FDMA and MIMO antennas This section describes the techniques used in the LTE air interface, notably orthogonal frequency division multiple access (OFDMA) and multiple input multiple output (MIMO) antennas. Communication techniques for fading multipath channels. OFDMA, FFT processing and cyclic prefix insertion. SC-FDMA in the LTE uplink. Multiple antenna techniques including transmit & receive diversity and spatial multiplexing. Introduction to the air interface This section covers the operation of the air interface, the channels that it uses, and the mapping to the time and frequency domains of OFDMA and SC-FDMA. Air interface protocol stack. Logical, transport and physical channels. Frame and slot structure, the resource grid. Resource element mapping of the physical channels and physical signals. LTE spectrum allocation. Cell acquisition This is the first of three sections covering the air interface physical layer. Here, we cover mobile procedures to start low-level communications with the cell, and base station transmission of the corresponding information. Primary/secondary synchronisation signals. Downlink reference signals. The master information block. Physical control format indicator channel. Organisation and transmission of the system information. Data transmission and reception In this section, we cover procedures used for data transmission and reception on the shared channels, and describe in detail the individual steps. Data transmission and reception on the uplink and downlink. Scheduling commands and grants on the PDCCH. DL-SCH and UL-SCH. Physical channel processing of the PDSCH and PUSCH. Hybrid ARQ indicators on the PHICH. Uplink control information on the PUCCH. Uplink demodulation and sounding reference signals. Additional physical layer procedure This section concludes our discussion of the air interface physical layer, by discussing a number of procedures that support its operation. Transmission of the physical random access channel. Contention and non-contention based random access procedures. Discontinuous transmission in idle and connected modes. Uplink power control and timing advance. Air interface layer 2 This section describes the architecture and operation of layer 2 of the air interface protocol stack. MAC protocol, interactions with the physical layer, use for scheduling. RLC protocol, transparent, unacknowledged and acknowledged modes. PDCP, including header compression, security functions and recovery from handover.

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Students who complete PV203 will be able to: Recognize demand and PV production curves Identify the common types of PV systems and their major components Describe DC and AC coupled systems Discuss load profiles and modes of operation, including: peak load shaving, time-of-use, zero-sell, self-consumption prioritization, demand-side management Introduce utility-scale storage and microgrids Explain the relationship between real power, apparent power, and reactive power Complete a load estimate for different system types and for seasonal loads; evaluate electrical requirements of loads Identify phantom loads and efficiency upgrades Estimate starting surge and power factor requirements Describe the differences when sizing battery-based systems compared to grid-direct systems Choose a peak sun hour value based on design criteria for various systems Review battery basics and terminology Describe and compare different battery chemistries and technologies Find the capacity and voltage of different batteries; determine state of charge List safety precautions and hazards to be aware of when working with batteries; list appropriate personal protective equipment (PPE) Identify appropriate battery enclosures Calculate values for current, voltage, and energy for different battery bank configurations Review battery bank design parameters Complete a lithium-ion battery bank design example Review and compare different design example costs List features, options, and metering available for different types of battery chargers Explain basics of lithium battery charging Compare generator types and duty cycle ratings, including fuel options Identify specifications critical for choosing appropriate battery-based inverters Discuss different overcurrent protection devices and equipment disconnects and when/where they are required Define the maximum voltage drop slowed for the proper functioning of a battery-based PV system Identify safe installation procedures List basic commissioning tests which should be completed before and after a system is operating