Photovoltaic Systems at Coursera Overview
Duration | 12 hours |
Total fee | Free |
Mode of learning | Online |
Difficulty level | Intermediate |
Official Website | Explore Free Course  |
Credential | Certificate |
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Photovoltaic Systems at Coursera Highlights
- Shareable Certificate Earn a Certificate upon completion
- 100% online Start instantly and learn at your own schedule.
- Flexible deadlines Reset deadlines in accordance to your schedule.
- Intermediate Level B.Sc. in the field of engineering or a few years of industrial experience from the energy sector
- Approx. 12 hours to complete
- English Subtitles: English
Photovoltaic Systems at Coursera Course details
- This course offers you advanced knowledge within the field of photovoltaic system technology. We'll learn about the solar resource and how photovoltaic energy conversion is used to produce electric power. From this fundamental starting point we'll cover the design and fabrication of different solar cell and module technologies, the various photovoltaic system components, how to design a photovoltaic plant and carry out energy yield simulations, essentials in energy economics, O&M and reliability assessment, as well as the role of photovoltaic energy in sustainable energy systems.
- This course is unique in that it takes you from the nanoscale physics of a solar cell to the modelling of a utility scale solar farm. The course is made up of 9 sections with an estimated workload of 2-3 hours each. The academic level is targeted at master students at technical universities and engineers from the energy industry. Passing this course offers you a great basis for a career in the field of photovoltaics.
Photovoltaic Systems at Coursera Curriculum
Introduction to Photovoltaics
Welcome
The Terminology of PV
A Brief History of PV
The PV Learning Curve
Fundamentals of PV
The Solar Resource and Geometry
Introduction: The Sun
The Solar Spectrum
Components of Solar Radiation
Solar Resource Facility at DTU Risø
Example: Estimation of PV Power Production
The Solar Resource
Physics of Solar Cells
Formation of Solids and Electronic Band Structures
Light Absorption and the Photovoltaic Effect
Recombination and Transport of Charge Carriers
Doping of Semiconductors and pn-Junctions
Working principles of Solar Cells
Introduction: The IV-curve
The Maximum Power Point
The Non-ideal Diode Equation
Intrinsic Semiconductors
The Working Principle of Solar Cells
The IV-curve
Cell Interconnection and Module Design
Electrical Cell Interconnection
Mismatch Losses and Bypass Diodes
Module Components
Module Fabrication Process
Module Fabrication Facilities at DTU Risø
Module Design Guidelines and Qualification Tests
Cell Cutting
Advanced Module Designs
Cell Interconnection and Shading
Module Components and Fabrication
Module Design and Advanced Concepts
PV Power Electronics
PV Power Characteristics
PV loading techniques
Maximum power point tracking
Power Converters in PV Applications
DC-DC Converters
PV Inverters
Efficiency of power converters
PV inverter types
Interfacing PV Systems with the Electric Grid
Introduction to Balance of System
Electrical Balance of System
Mechanical Balance of System
End of the Course
Extracting Energy from a PV Panel
PV Power Conversion (DC-DC)
PV Power Conversion (DC-AC)
Balance of System (BOS)
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