stand-alone systems (which use batt

stand-alone systems (which use batteries). In grid-connected PV systems, batteries are not needed since all of the power generated by the PV plant is uploaded to the grid for direct transmission, distribution, and consumption. Hence, the generated PV power reduces the use of other energy sources feeding the grid, such as hydro or fossil fuels, whose savings act as
energy storage in the system, providing the same function of power regulation and backup as a battery would deliver in a stand-alone system. Since grid-connected systems do not need batteries, they are more cost-effective and require less maintenance and reinvestment than stand-alone systems. This concept together with the cost reduction, technology development, environmental awareness, and the right incentives and regulations has unleashed the power of the sun.In Figure 1, a typical configuration of a grid-connected PV system is represented [2]. In a conventional PV system, the PV cells (arranged in a single module, a string of series-connected modules, or an array of parallel-connected strings) generate a dc current that greatly depends on the solar irradiance, temperature, and voltage at the terminals of the PV system. This dc power is transformed and interfaced to the grid via a PV inverter. Additional elements include a grid connection filter, a grid monitor or interaction unit (for synchronization, measurements, antiisland detection, etc.), and a low frequency transformer (which is optional
depending on local regulations, the
converter topology, and the modulation
used to control it [3]). Another option is an intermediate dc–dc power stage between the PV modules and the grid-tied
inverter. This optional stage decouples
the PV system operating point from the
PV inverter grid control. Additionally,
it can boost the PV system dc output
voltage if required or provide galvanic
isolation and perform maximum power
point tracking (MPPT) control.
The increase in the PV installed capacity has also sparked a continuous evolution of the PV power conversion stage. Gradually, PV power converters have become extremely efficient, compact, and reliable, allowing the maximum power to be obtained from the sun in domestic, commercial, and industrial applications [3], [4]. The PV converter industry has evolved rapidly from childhood to adulthood in the last two decades and has become a distinct power converter category in its own right. One of the drivers behind this progress is that the PV converter market demanded very hard-to-meet specifications, including high
efficiency (above 98%), long warranty
periods (to get closer to PV module warranties of 25 years), high power quality, transformerless operation, leakage current minimization (imposes restrictions on the topology or modulation), and special control requirements such as