A DC-DC converter is a vital electronic device used to convert one level of DC voltage to another, ensuring efficient power management in various applications (Babaei et al., 2018a; Abbasi and Lam, 2019; Azizkandi et al., 2019; Mirzaee and Moghani, 2019; Elsayad et al., 2020; Folmer and Stala, 2021; Hasanpour et al., 2021; Rahimi et al., 2021; Abbasian et al., 2022; Mohammadi et al., 2022; Rahimi et al., 2022; Farahani et al., 2023; Hasanpour et al., 2023; Rajesh and Prabaharan, 2023). This versatile device accepts a DC input voltage and delivers a regulated output voltage of a different level, allowing compatibility between power sources and loads. DC-DC converters are extensively employed in diverse fields such as telecommunications, automotive, renewable energy, and portable electronics (Abbasi and Lam, 2019; Rahimi et al., 2021; Rajesh and Prabaharan, 2023). By utilizing switching techniques and control circuitry, these converters efficiently step up or step down the voltage levels while minimizing power loss (Babaei et al., 2018b; Fardahar and Sabahi, 2019; Premkumar et al., 2019; Allehyani, 2021; Zaid et al., 2021a; Zaid et al., 2021b; Pashaie et al., 2023). Their compact size, high efficiency, and reliable performance make them indispensable for optimizing power utilization and meeting the voltage requirements of modern electronic systems (Mirzaee and Moghani, 2019; Farahani et al., 2023; Hasanpour et al., 2023). Many researchers have put forth various technologies for DC-DC converters, which can be broadly divided into two types: isolated converters that use coupled inductors or transformers, and non-isolated converters that use coupled inductors without transformers. Several modified DC-DC converters have been proposed to address specific requirements and improve performance. In (Abbasian et al., 2022) introduces a modified DC-DC boost converter that utilizes extendable capacitor voltage multiplier cells (VMCs) and coupled inductors (CIs) with a clamp circuit. This design aims to reduce leakage inductances and achieve a higher voltage gain. Similarly, in reference (Azizkandi et al., 2019), a modified DC-DC converter based on coupled-inductor with three windings is presented, incorporating a passive clamp circuit to recycle the energy of leakage inductance and a voltage multiplier cell to achieve a very high-voltage conversion ratio. For renewable energy applications, in (Hasanpour et al., 2021; Rahimi et al., 2021; Hasanpour et al., 2023; Rajesh and Prabaharan, 2023) proposes a modified interleaved high step-up DC-DC converter that employs coupled inductors (CIs) and integrates switched-capacitor (SC) (VMCs) with a passive diode-capacitor clamp built-in transformer (BIT). Furthermore, in (Hasanpour et al., 2021) suggests a modified configuration of a quasi-resonant high-gain single-ended primary inductor converter (SEPIC)-based DC-DC converter, incorporating a coupled inductor (CI), (VM), and a regenerative passive lossless clamp circuit to enhance the voltage conversion ratio. In the context of photovoltaic (PV) applications, in (Rahimi et al., 2022) proposes a modified DC-DC converter utilizing a dual-switch structure with a three-winding coupled inductor (3WCI) and (SC), achieving a high-voltage gain suitable for PV systems. Additionally, in (Li et al., 2024) presents a modified quadratic boost converter that integrates a (CI) with a clamp circuit and a (VM). In (Das and Agarwal, 2016; Ardi and Ajami, 2018; Shaw and Sahoo, 2018; Sundaramoorthy, 2019; Kumar et al., 2020; Mansour and Zaky, 2023) focus on modifying the SEPIC converter by employing a (CI), with two (VM), and incorporating a passive clamp circuit to enhance its performance.

These converters have achieved significant advancements in terms of generating high voltage output. However, they suffer from various limitations that hinder their overall performance. These drawbacks include the excessive use of both passive and active components, a large number of diodes, increased resistance in inductors and capacitors, resulting in reduced efficiency. Additionally, attempting to increase the voltage gain by increasing the turn ratio of coupled inductors leads to higher internal resistance, further compromising system efficiency. Another challenge arises from the low switching frequency used in these converters, which necessitates the use of bulky inductors and capacitors. Moreover, the voltage gain is negatively affected by the on-resistance (Ron) of the power MOSFET, leading to decreased system efficiency. Furthermore, the presence of coupled inductor converters results in high spike voltages during the power switch’s off state due to the inductance of the parasitic capacitance associated with the power MOSFET switch. To address this issue, a clamped circuit can be implemented with the power switch. However, this solution introduces higher costs and reduced efficiency due to parasitic effects.

Several topologies have been proposed that incorporate the interleaving of conventional and modified converters. In (Babaei et al., 2018a), a nonisolated high DC-DC converter is presented, which utilizes Active-Passive Inductor Cells (APICs) operating based on parallel charging and series discharging of the inductors. In (Rajesh and Prabaharan, 2023) introduces a high gain nonisolated DC-DC converter achieved by combining the modified quadratic boost converter (MQDBC) with the unique (VMC). Similarly, in reference (Farahani et al., 2023), a modified non-isolated DC-DC converter based on a switched-inductor/switched-capacitor network is proposed, taking advantage of both active and passive switched inductor cells. In (Elsayad et al., 2020) proposes a modified SEPIC-based step-up DC-DC converter that integrates a discontinuous-current quasi-Z-source (qZS) and (SC) networks. In (Shaw and Sahoo, 2018; Sundaramoorthy, 2019; Kumar et al., 2020) describe a novel non-isolated high gain DC-DC (NHGDC) converter utilizing a switched inductor-capacitor network. In reference (Kumar et al., 2020), a modified conventional quadratic boost converter (QBC) is presented, incorporating a switched capacitor-inductor network (SCLN) to achieve voltage gain. For renewable energy applications, in (Babaei et al., 2018b; Zaid et al., 2021b; Khan et al., 2021; Dhananjaya et al., 2023; Mansour and Zaky, 2023) proposes a high gain DC-DC boost converter that utilizes (SL) and (SC), along with a (VMC). Lastly, reference (Gu et al., 2018) presents a modified DC-DC converter with an active switched LC-network, which introduces an active switched capacitor (ASC) network based on a transformerless DC-DC converter with an active switched inductor (ASL) network. Notwithstanding their impressive ability to achieve significant voltage gain ratios, these converters have certain limitations. The high gain ratio requires an excessively high duty ratio, unfortunately leading to increased switching and conduction losses, reduced efficiency, and compromised power density. Furthermore, the elevated duty ratio puts significant voltage stress on crucial components such as power switches, diodes, and inductors. Consequently, these components experience substantial strain, potentially impacting their reliability and lifespan. Additionally, these converters often incorporate multiple inductors and operate at a low switching frequency. While this design approach aims to improve performance and efficiency, it inadvertently introduces higher levels of parasitic resistance. Consequently, the converters suffer a decline in overall performance and efficiency, thereby limiting their effectiveness in practical applications.

On the other hand, some scientists have investigated different methods and created non-isolation DC-DC converters that can achieve significant voltage amplification without using transformers or linked inductors. These converters rely on the (SL) and (SC) technique. In (Folmer and Stala, 2021) introduces a modified DC-DC converter that utilizes resonant (SC) circuits with five MOSFET switches. In (Veerachary and Sen, 2022) proposes a topological evolution of a (SC) based boost converter, where a dual-switch configuration with a common ground feature is employed. In (Mansour et al., 2022), a non-isolated high-voltage gain DC-DC converter is presented by merging a dual boost converter with a (SL) structure. In (Allehyani, 2021) proposes a new transformerless DC-DC converter for renewable energy systems by incorporating a (SL/SC) and a (VM) stage into the traditional boost converter. Furthermore, in (Zaid et al., 2021a) describes an improved high-gain DC-DC boost converter that utilizes two (VMCs) consisting of (SC) and (SL) to enhance the voltage gain. Finally, in (Fardahar and Sabahi, 2019; Allehyani, 2021; Zaid et al., 2021a; Mansour et al., 2022; Singh et al., 2022; Pashaie et al., 2023) discuss a proposed basic bidirectional converter with five switches based on the (SC-SI) configuration. However, these converters have the advantage of achieving high voltage gain ratios. Nonetheless, they also suffer from certain limitations that impact their performance and restrict their practicality. These limitations encompass the requirement for high duty ratios, leading to increased losses and decreased efficiency. Moreover, these converters can adversely affect component durability and introduce elevated parasitic resistance due to the use of multiple inductors and low switching frequency. Despite their capability to achieve substantial voltage gain, these converters are hindered by a large number of components that detrimentally influence both system efficiency and performance. Furthermore, the power switch is subjected to high voltage and current stress, while the gate control circuit is intricate and demands a considerable amount of space for implementation.

In this paper, a DC-DC converter that employs a modified triple boosting architecture interleaved with modified switched inductor capacitors is presented to achieve ultra-high voltage gain in photovoltaic applications. The converter design also includes a modified switched inductor with a modified voltage multiplier mode, which interleaves with the main switch and effectively doubles the voltage transfer gain. Furthermore, a modified triple boosting mode technique, utilizing interleaved components and an auxiliary switch, is integrated into the converter design. The main switch and auxiliary switch, combined with modified switched capacitors, contribute to achieving high voltage gain. Additionally, the diode of (MTB) D₅ operates at ZCS (Zero Current Switching) when the converter operates in DCM (Discontinuous Conduction Mode) and the capacitor charge becomes zero at (β) as shown in Figure 2B. Moreover, D₅ operates at ZCS when the proposed converter operates in CCM (Continuous Conduction Mode) while supplying high current. Furthermore, the diode of MTB D₆ operates at ZCS when the capacitor charge becomes zero at (α) as shown in Figures 2B, 4B. Moreover, the diode of (MVM) D₃ operates at ZCS at time (δ) as shown in Figures 2B, 4B. Additionally, dual PI controllers for current and voltage are designed to verify a fixed output voltage.

A DC-DC converter has been introduced to achieve ultra-high voltage gain and high efficiency. Its purpose is to boost a low input voltage, ranging from 30 V to 40 V, to a variable output voltage of 200 V–400 V while accommodating a 360 W load. The designed converter specifically caters to Renewable Energy Sources (RES). Figure 1A illustrates the integration of the proposed converter with PV Panels and Battery, showcasing its suitability for a low input voltage source. The schematic diagram of this new interleaved converter is presented in Figure 1B, which comprises three primary inductors, six capacitors, seven diodes, and two power MOSFET switches. This converter offers numerous notable advantages. Firstly, it eliminates the necessity for isolated coupled inductors and transformers typically required for voltage stepping. By operating at a high switching frequency, the values of inductors and capacitors can be significantly reduced, resulting in enhanced overall efficiency of the converter. Moreover, the converter’s structure is straightforward and easy to implement. The absence of pulsation in the input current at very low duty cycles enhances its reliability, particularly for photovoltaic applications. In the proposed converter, the diode (MTB) D₅ exhibits (ZCS) behavior during operation in (DCM). This occurs when the capacitor charge reaches zero at (β), as depicted in Figure 2B. Additionally, when the converter operates in (CCM) and supplies high current, D₅ also operates at ZCS. Similarly, the diode of (MTB) D₆ achieves ZCS when the capacitor charge becomes zero at (α), as shown in both Figures 2B, 4B. Furthermore, the diode (MVM) D₃ attains ZCS at time (δ), as illustrated in Figures 2B, 4B. This characteristic leads to reduced overall losses and significantly improved efficiency in the converter’s operation. In summary, the converter employs ZCS in various scenarios, providing enhanced performance and efficiency in different conduction modes and under specific conditions for the mentioned diodes. Additionally, the proposed converter guarantees low voltage stress on both the main and auxiliary switches, leading to enhanced reliability, longevity, and overall performance. This feature effectively manages voltage stress, providing a robust and durable solution for high voltage gain applications. Compared to previous DC-DC converters, the proposed design achieves a higher voltage gain while utilizing fewer inductors and capacitors. The PWM generator controlling the MOSFET switches is simple, with both devices turning on and off simultaneously, simplifying the control mechanism.

In this section, the voltage transfer gain of the proposed converter is calculated in both DCM and CCM.

The proposed converter has two power switches, six capacitors and seven power diodes. Therefore, in this section, the voltage stress across power MOSFETs are calculated. Furthermore, the voltages across the power diodes and capacitors are calculated. V D 1 = V g 1 − D (32) V D 2 = V g 1 − D (33) V D 3 = 2 V g 1 − D (34) V D 4 = 2 V g 1 − D (35) V D 5 = 2 V g 3 − D 1 − D 2 (36) V D 6 = 2 V g 3 − D 1 − D 2 (37) V D 7 = 2 V g 3 − D 1 − D 2 (38)

By utilizing Eqs 32, 33, one can determine the voltage stress across the diode, thereby finding the voltage across D1 and D2. These voltages are relatively small and contingent on the input voltage during the period, which ranges from 30 V to 40 V. Furthermore, Eqs 34, 35 provide insights into the voltage across D3 and D4, which also remain minor and rely on the input voltage during the given time frame. With the aid of Eqs 36–38, it becomes feasible to ascertain the voltage across D5, D6, and D7. Notably, the proposed converter exhibits reduced voltage stress across the power diodes, particularly when operating at high currents. V s w 1 = 2 V g 1 − D (39) V s w 2 = 4 V g 1 − D 2 (40)

The voltage across MOSFETs Sw1 and Sw2 can be calculated from Eqs 39, 40, which also yield very small values. Additionally, the voltage stress across MOSFETs is significantly reduced when the proposed converter operates at high voltage gain. V c 1 = V g (41) V c 2 = 2 V g 1 − D (42) V c 3 = 2 V g 1 − D (43) V c 4 = 4 V g 1 − D 2 (44) V c 5 = 2 V g 3 − D 1 − D 2 (45) V c 6 = 2 V g 5 − D 1 − D 2 (46)

To determine the voltage across capacitors, we can utilize Eq. 41 to calculate the voltage stress across C1, which is equivalent to the input voltage. Eqs 41, 42 are used to represent the voltage across C2 and C3, respectively. Likewise, Eqs 44–46 pertain to the voltage across C4, C5, and C6, respectively. Notably, when the converter provides a 360 W load, and L3 operates in DCM while L1 and L2 function in CCM, the voltage stress across the power diodes and power MOSFETs is significantly diminished.

In this section, the primary constituents of the 360 W prototype for the proposed converter include inductors, capacitors, power diodes, power MOSFETs, and a gate drive circuit. Designing these components is essential to validate the high voltage gain of the converter.

To achieve this, the converter necessitates three small-value inductors and six small-value capacitors. The specific parameter values can be located in Table 1, which outlines the prototype design parameters for the proposed converter. A proposed converter utilizing a high switching frequency has the potential to significantly reduce the size of inductors and capacitors required for its design. As a result, the prototype becomes smaller, lighter, and more cost-effective. To meet the inductor specifications, the converter employs flat wire with remarkably low internal resistance, which greatly minimizes losses. Referring to the inductor specifications in Table 1, it is observed that the internal resistance for all inductors is very small when using flat wire inductors with ferrite cores sized at (3cm 2.75cm 2.2cm). L 1 = V g D T s Δ i L 1 = L 2 (47) L 3 = 4 V g D T s 1 − D Δ i L 3 (48)

To design inductors for the proposed converter, we can use Eq. 47 to design inductors L1 and L2. Additionally, Eq. 48 can be used to design inductor L3. C 1 = 4 V o D + 1 Δ v c 1 R L f s 1 − D (49) C 2 = 2 V o D 2 Δ v c 2 f s 1 − D R L C 3 = 4 V o D + 1 Δ v c 3 f s 1 − D (50) C 4 = V o D D + 1 Δ V c 4 . F s R L 1 − D (51) C 5 = V o D D + 1 Δ V c 5 . F s R L 1 − D (52) C 6 = V o D Δ V o F s R L (53)

To select the best values of capacitors, we can use Eqs 49–54 to find the values of C₁, C₂, C₃, C₄, C₅, and C₆, respectively. In order to calculate input filter of DC DC converter, Cin filter and Lin filter can be used equation below in Eq. 54. C i n F i l t e r = P o Δ V s η V s L i n F i l t e r = V s D 1 − D 2 4 I o 1 + D F s (54)

To calculate the filter volume with respect to the total volume of the converter, the filter volume is 15 cm³, and the total volume of the proposed converter is 185 cm³. Thus, the filter volume in relation to the total volume of the converter is 0.01, accounting for 1% of the total volume.

In this section, we conduct a comparative analysis of the proposed converter in contrast to previous DC-DC converters. The simulations for the previous DC-DC converters were performed using Matlab Simulink under identical conditions. From the results depicted in Figure 6A, it is evident that the proposed converter achieves a significantly higher voltage gain when compared to the previous boosting converters. Notably, the proposed converter exhibits a considerable gain at low duty cycles, starting from D = 0.25. This characteristic leads to reduced conduction losses, switching losses, improved overall efficiency, and a notable reduction in the required number of inductors and capacitors. Additionally, Figure 6B reveals that the power MOSFET device in the proposed converter experiences notably lower voltage stress in comparison to the power MOSFET devices utilized in the previously mentioned converters. Moreover, concerning the voltage across diodes, Figure 6C demonstrates that the diodes in the proposed converter are subjected to lower voltage stress when compared to their counterparts in previous converter designs.

Consequently, the suggested converter demonstrates exceptional performance by attaining both a high voltage gain and low voltage stress across power devices, surpassing its predecessors. This is clearly depicted in Figure 6D, where the stress current through the MOSFET in the proposed converter is considerably lower than that experienced by the power MOSFET in prior boosting converters.

Table 2 presents a comprehensive comparison between the proposed converter and its predecessors, examining various critical factors such as the number of inductors, capacitors, diodes, switching frequency, input current, duty cycle percentage, and MOSFETs utilized in both the new and previous boosting converters.

The innovative design of the proposed converter incorporates a higher switching frequency, resulting in the utilization of smaller inductors and capacitors while effectively reducing parasitic resistance. Consequently, this advancement renders the entire system more compact, lightweight, and cost-efficient. In direct comparison to its forerunners, the proposed converter exhibits superior performance in terms of efficiency, size, and cost-effectiveness. Previously employed boosting converters were capable of elevating low voltage to high voltage ratios, albeit requiring significant high duty ratios. In contrast, the newly devised converter demonstrates remarkable efficiency in elevating low voltage sources to variable output voltage levels ranging from 200V to 400V, necessitating substantially lower duty ratios than its predecessors.

The proposed converter’s distinct advantage lies in its reduced number of power diodes, which leads to minimized losses attributed to forward voltage and internal resistance when juxtaposed with earlier converter models. Moreover, this novel converter boasts a heightened voltage gain, rendering it particularly suitable for renewable energy sources, as it can deliver both variable and fixed high output voltage levels with an extensive range in duty ratio, culminating in an impressive 96.5% efficiency rating.

Figure 7 illustrates the proposed converter controller, employing two Proportional Integral (PI) controllers to ensure its effective operation. The initial PI controller functions as an internal controller, stabilizing the load current. Meanwhile, the second PI controller acts as an external controller, responsible for maintaining the desired output voltage. The PI voltage controller operates by taking the discrepancy between the target voltage and the actual output voltage as its input. Using this input, it generates a reference current for the load. To prevent excessive current draw, the reference current is intentionally limited. The disparity between the reference current and the actual current is then fed into the PI current controller, governed by Eq. 55. To properly tune the Ki and Kp parameters of the controller, it is essential for the parameters of the PI voltage controller to be faster than those of the PI current controller. This measure guarantees that the steady-state error remains at zero. U t = K p e t + K i ∫ e t (55)

Figure 8A portrays the dynamic adaptability of the proposed converter, exemplifying its capacity to vary the output voltage while maintaining a constant input voltage, thus catering to diverse application demands. Similarly, in Figure 8B, the stability of the proposed converter’s output is depicted, illustrating its ability to remain constant even when subjected to varying load conditions throughout the day, while maintaining a consistent input voltage. Moreover, Figure 8C presents compelling evidence of the proposed converter’s exceptional performance, as it demonstrates its proficiency in supplying a stable output voltage despite fluctuations in the input voltage. This remarkable attribute is achieved through the implementation of a voltage and current PI-controller for the converter, facilitating swift and precise responses to varying conditions.

Significantly, the proposed converter exhibits an impressive power density, owing to its broader range of duty ratios. This distinctive feature renders it exceptionally well-suited for applications requiring a consistently high fixed output voltage. Overall, the amalgamation of these remarkable characteristics establishes the proposed converter as an exemplary and versatile solution for a wide array of practical applications.

The proposed converter comprises three inductors, six capacitors, two power switches, and seven diodes. While these components are integral to the converter’s functionality, it is important to acknowledge that they are not ideal. Each inductor, for example, possesses an inherent internal resistance. Similarly, the capacitors exhibit equivalent series resistances denoted by rc. Notably, the power diode entails two types of power losses—one due to its internal resistance and the other due to its forward voltage Vf. Additionally, the power MOSFET devices contribute to power losses through conduction and switching processes. Consequently, a comprehensive evaluation of the proposed converter must account for all these losses. For a visual reference, Figure 9 depicts the internal resistances of both active and passive elements.

Eq. 56 is the general equation for calculating the RMS current. I r m s = 1 T s ∫ 0 T s I 2 d t (56) I s w 1 r m s = 4 I o 1 + D D 1 − D 2 (57) I s w 2 r m s = I o D 1 + D 1 − D (58)

In order to calculate the RMS current through power MOSFETs, Eqs 57, 58 can be used to describe the RMS current flowing through MOSFETs. Additionally, Eqs 59–65 can be utilized to calculate the RMS current through diodes. I D 1 r m s = 2 I o 1 + D D 1 − D 2 (59) I D 2 r m s = 2 I o 1 + D D 1 − D 2 (60) I D 3 r m s = 2 I o D 1 − δ 1 − D (61) I D 4 r m s = I o 1 + D 1 − D 3 (62) I D 5 r m s = I o D 1 + D 1 − D (63) I D 6 r m s = I o α 1 + D 1 − D (64) I D 7 r m s = I o 1 + D 1 − D (65)

To determine the RMS current through inductors L₁, L₂, and L₃, you can use Eqs 66, 67 respectively. Meanwhile, the RMS current through capacitors can be obtained by utilizing Eqs 68–73. i L 1 r m s = 2 I o D + 1 1 − D 2 = i L 2 r m s (66) i L 3 r m s = I o 1 + D 1 − D (67) I c 1 r m s = 2 I o 1 + D 3 D + 1 1 − D 2 (68) I c 2 r m s = I o D + 1 16 + D − D 2 1 − D 3 (69) I c 3 r m s = 2 I o 1 + D D + 1 + 2 D 2 1 − D 1 − D (70) I c 4 r m s = I o 1 + D α + 1 − D 1 − D (71) I c 5 r m s = I o 1 + D α + 1 − D 1 − D (72) I c 6 r m s = I o 4 + 9 D + 2 D 2 1 − D (73)

In this section, we developed a prototype design of a 360 W converter to validate the accuracy of both simulation and experimental outcomes, as shown in Figure 10A.

The converter was subjected to rigorous evaluation in a laboratory environment, as depicted in Figure 10B. To further validate the laboratory results across diverse conditions, MATLAB and PLECS software were employed. It’s important to note that the converter integrated non-ideal inductors and capacitors, and all parasitic resistances were taken into account in the proposed DC-DC converter design.

Figure 11A shows the inductor current when the proposed converter operates in CCM. Figure 11B displays the voltage across the inductor during the on and off states. It can be observed that the voltage across L₃ is very small, equating to half of the output voltage. In Figure 11C, it is evident that the proposed converter can supply 360 W at a load current of 0.91 A and an output voltage of 400 V, with a gain of (Mdc = 13.3).

From Figure 11D, it can be seen that the voltage across D₆ and the current through D₆ operate at ZCS when capacitor C₄ becomes zero at (α). Figure 11E illustrates the voltage across D₃ and the current through D₃ when D₃ operates at ZCS. Additionally, the current through D₅ operates at ZCS when the proposed converter is in DCM2. In Figure 11F, it is apparent that D₅ operates at ZCS when the proposed converter operates in CCM.

In terms of the experimental results, the proposed converter was designed and tested to verify its high voltage gain. In Figure 12A, the inductor currents of L₁ and L₂ are shown, and both of them operate in (CCM). Figure 12B displays the inductor currents of L₁ and L₃, where L₃ operates in (DCM) under a load current of 0.91 A, 400 V output voltage, and 360 W load.

Moving on to Figure 12C, it illustrates the voltage across C₁, which is equal to the input voltage. Figure 12D shows the current through the power MOSFETs when the proposed converter supplies a 360 W load. In Figure 12E, we can observe the load current of 0.91 A at a load voltage of 400 V and an input voltage of 32 V, as depicted in Figure 12F.

Additionally, the proposed converter can supply a variable load voltage of 300 V at 1 A, as demonstrated in Figure 12G, where the voltage across C₄ is equal to 250 V, and the voltages across C₂ and C₃ are equal to 85 V, as shown in Figure 12H.

Overall, a DC-DC converter represents a significant advancement in the field, combining outstanding voltage gain, high efficiency, and reliability. Its simple structure, reduced component count, and effective management of voltage stress make it an appealing choice for various applications requiring high voltage conversion.

From Figure 13A, we observe that the voltage across SW1 is very small at high load voltage. Additionally, Figure 13B shows the voltage across Sw₂, which also remains very small when the load voltage is equal to 400 V. Figure 13C displays the voltage across D₁ and D₂, which is equal to the input voltage. In Figure 13D, we can observe the voltage across D₃ and D₄. In Figures 13E–G, we can see the voltage across D₅, D₆, and D₇ respectively. Turning to Figure 13H, the voltage across C₆ is visible, and in Figure 13I, we can see the voltage across C₅.

From Figure 14A, we can observe the current through D₇ in DCM and the current through capacitor C₁ during on and off state. In Figure 14B, we can see the current through D₅ and D₆ in DCM1. Figure 14C shows the current through D₃ and the voltage across D₃, with D₃ operating at ZCS. Figure 14D allows us to observe the current through C₅ and C₆ in DCM1. Finally, from Figure 14E, we can see the current through capacitor C₄ and C₂ when the proposed converter operates in DCM1, with a load current of 0.9 A, 400 V output voltage, and 360 W power. Figure 14F it can see the Dynamic response of the proposed converter at changing the load from 200 to 300 W at fixed load voltage.

From Figure 15A it can see that the proposed converter archive high efficiency at high load current. In addition, the proposed converter can supply high load voltage at low duty cycle as shown in Figure 15B. Figure 15C it can see the efficiency of the proposed converter at output load power at different input voltage.

In Figure 15D, the graph depicts the power losses of flat wire inductors under the operation of the suggested converter while catering to a 360 W load. Evidently, the power losses exhibited by these inductors are notably minimal after using inductors with low internal resistance. This observation underscores the efficient and high-performance operation of the suggested converter.

The proposed converter achieved a higher voltage gain than previous converters and can supply a variable high output voltage at a very low duty ratio compared to previous converters. Specifically, the proposed converter achieves an efficiency of 96.5% when the input voltage is 30 V, and the output voltage is 400 V at a duty ratio of 33%. The proposed converter can supply loads greater than 360 W while maintaining high efficiency. Additionally, the diode of MTB D₅ operates at ZCS when the converter operates in DCM, and the capacitor charge becomes zero at (β). Moreover, D5 operates at ZCS when the proposed converter operates in CCM while supplying high current. Furthermore, the diode of MTB D₆ operates at ZCS when the capacitor charge becomes zero at (α). Moreover, the diode of MVM D₃ operates at ZCS at time (δ). By incorporating WBG power MOSFETs and power diodes into the converter’s design, it exhibits exceptional performance and efficiency. Additionally, the implementation of a high switching frequency allows for significant reductions in the values of inductors and capacitors, resulting in a compact and lightweight converter design. Consequently, the proposed converter surpasses its predecessors by achieving higher voltage gain, while the power MOSFETs and power diodes experience reduced voltage stress compared to conventional boosting converters. Moreover, the proposed converter offers the ability to supply high load currents at variable output voltages, accommodating a wide range of duty ratios. Its enhanced efficiency, surpassing that of previous DC-DC converters, further establishes its high-performance capabilities.

The described converter is capable of providing a maximum power output of 360 W at an output voltage of 400 V with high efficiency. Furthermore, it is well-suited for applications demanding elevated output voltage, such as LED street lights and specific medical equipment. The design considerations encompass aspects like input current, available input voltage, converter efficiency, thermal management, and component ratings.

However, as power demand escalates, certain limitations come into play. At higher power levels, the converter’s components might experience heightened stress, potentially resulting in overheating, decreased efficiency, and compromised overall reliability. To address these concerns, the proposed converter boasts the flexibility to deliver varying output voltages tailored to specific applications. Additionally, it excels at efficiently transforming low input voltages into high output voltages, effectively achieving the 360 W output.

To effectively manage these challenges and maintain optimal performance, careful attention must be paid to factors such as thermal management, prudent component selection, and meticulous system design when upscaling power requirements. This approach will effectively mitigate the risks linked with intensified component stress and ensure continued efficient and reliable operation, even when confronted with elevated power demands.

A DC-DC converter employs a modified triple-boosting architecture, interleaved with modified switched inductor capacitors, to achieve ultra-high voltage gain in photovoltaic applications. The simulation results of the proposed converter were verified by fabricating a 360 W PCB. A comparison was made between the proposed converter and previous boosting converters. The proposed converter achieved a higher voltage gain than previous converters and can supply a variable high output voltage at a very low duty ratio compared to previous converters. Specifically, the proposed converter achieves an efficiency of 96.5% when the input voltage is 30 V, and the output voltage is 400 V at a duty ratio of 33%. The proposed converter can supply loads greater than 360 W while maintaining high efficiency. Additionally, the diode of MTB D5 operates at ZCS when the converter operates in DCM, and the capacitor charge becomes zero at (β). Moreover, D5 operates at ZCS when the proposed converter operates in CCM while supplying high current. Furthermore, the diode of MTB D6 operates at ZCS when the capacitor charge becomes zero at (α). Moreover, the diode of MVM D3 operates at ZCS at time (δ).

In summary, the development of this novel converter exemplifies the immense potential for achieving high voltage gain and addresses the challenges associated with efficient energy conversion in photovoltaic systems. Further exploration and experimentation in this field hold the promise of even more efficient and effective converter designs for renewable energy applications.