Integration of solar photovoltaic (PV) systems into a microgrid is accomplished with the help of a dual-diode, dual-capacitor, and single-switch DC-DC boost converter. At the output, a power of 400W transfer is achieved together with a voltage gain of 3.92. The converter may be operated in two primary forms, both of that are based on the ON/OFF switches. The benefits that may be noticed in practice from the hardware output are high reliability and decreased s. Integration of solar photovoltaic (PV) systems into a microgrid is accomplished with the help of a dual-diode, dual-capacitor, and single-switch DC-DC boost converter. At the output, a power of 400W transfer is achieved together with a voltage gain of 3.92. The converter may be operated in two primary forms, both of that are based on the ON/OFF switches. The benefits that may be noticed in practice from the hardware output are high reliability and decreased switching losses. The properties of the converter are determined via an open loop system that uses pulse width modulation (PWM) switching at 20 kHz. An examination of the step response is carried out. The validations of the proposed converter topology has been compared with the recent converter topologies. The performance of the converter has been evaluated in terms of voltage gain.••••The DC/DC converter is designed for solar PV applications.••At the output, a power of 400 W transfer is achieved together with a voltage gain of 3.92••The hardware output are high reliability and decreased switching losses.••The converter raises the 50 V DC input voltage to provide 200 V DC output voltage with 0.75 duty cycle.••The. DC-DC boost converterMicrogridSolar PVSwitching lossesVM voltage across the switchVC voltage across the capacitorVin input voltageVO output voltageiin source currentPV In recent years, there has been an increase in the use of DC microgrids for the distribution and utilization of electrical energy provided by renewable sources such as solar PV, wind turbines and fuel cells (FCs). The DC microgrid has the potential of either functioning independently or attached to the main power grid. As electrical and electronic engineering advances and research expands, renewable energy sources (RES) are becoming more important in the design of power systems. On the other hand, natural disasters and other alterations to the environment have raised awareness of the need of renewable energy sources. Solar PV systems are being utilized to produce electricity daily in greater amounts as part of a global drive to lower CO2 emissions and accelerate the adoption of RES. Before a solar photovoltaic system may interface with a high-voltage load or grid, it is required to have a DC/DC converter stage is needed. The longevity of solar PV panels may be increased by using a converter that has a constant input current, that is the primary benefit of this type of converter. Over the past decade, there has been a significant rise in the installation of solar PV panels. Connecting PV panels in series raises the voltage output of photovoltaic generators to a higher level. The DC/DC converters employed in PV systems must have a low ripple with constant input current to achieve a high voltage gain. Additionally, simple design and comprise a smaller number of components. In addition to these criteria, switches must b.