2nd German-West African Conference on Sustainable and Renewable Energy Systems SusRES - Kara 2021 

Photovoltaic  

https://doi.org/10.52825/thwildauensp.v1i.8 

© Authors. This work is licensed under a Creative Commons Attribution 4.0 International License 

Published: 15 June 2021 

Evaluation of power losses in a DC-DC Boost 
converter 

Komi Boniface EHLAN1, Edjadessamam AKORO 1,2, Hodo-Abalo SAMAH 1, N’detigma 
KATA1,2, Amadou Séidou MAIGA 2 

1 Faculté des Sciences et Techniques (FaST), Université de Kara, Togo 
2 Département de Physique Appliquée, Université Gaston Berger, Saint-Louis, Sénégal 

Abstract. DC-DC converters are dynamic systems consisting of the passive components. 
These components under the effect of thermal stress in a PV system generate power losses. 
The knowledge of these power losses is necessary to evaluate the conversion efficiency of 
the system. Using the polynomial approximation method, the equations for calculating losses 
in the different components were determined. The system is implemented under the 
MATLAB / Simulink software. The results show that for a PV application of 240 W supplied to 
the load, 18% are lost, only 82% are transferred  
Keywords: Photovoltaic conversion chain, DC-DC converter, Power losses. 

Introduction 

Photovoltaic solar energy comes from the direct conversion of solar radiation into electrical 
energy through Photovoltaic (PV) cells. Depending on the desired power, these cells are 
connected in series and or in parallel to give a photovoltaic generator (GPV) [1], [2]. 
Nevertheless, the production of this energy varies according to the light intensity and the 
temperature of the cell. On the other hand, [3] states that a direct connection of the PV 
generator to the load does not guarantee the transfer of the maximum available power. In 
order to extract the maximum power available at each moment at the terminals of the PVG, 
the technique classically used is the insertion of a matching stage composed of a DC-DC 
converter and a MPPT (maximum power point tracking) controller between the GPV and the 
load [2]. The latter acts as an interface between the GPV and the load by ensuring, through a 
control action, the transfer of the maximum power supplied by the GPV so that it is as close 
as possible to the maximum available power. Therefore, several works on photovoltaic 
systems have led to the development of algorithms to extract the maximum energy from the 
GPV to increase the system efficiency. Therefore, the main objective of this paper is to shed 
light on the different losses generated by a converter in a PV conversion chain. To do this, 
we have based ourselves on the polynomial approximation method and on the 
manufacturer’s, data sheets to derive the equations of the losses as a function of the global 
current. In order to confirm our theory, we proceeded by programming these equations under 
the MATLAB / Simulink software. The rest of the paper is organized as follows: the block 
diagram of the studied PV conversion chain is described in section 2 and the loss equations 
are established in section 3. Section 4 presents the discussions on the obtained results and 
section 5 concludes the paper. 

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Ehlan et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 
Synoptic diagram of a PV conversion chain connected to a DC load 

A photovoltaic system consists of four (04) blocks as shown in Figure 2. The first block 
represents the energy source (PV panel), the second block is a static DC-DC converter, the 
third block represents the load and the fourth block represents the control system. This 
MPPT control system is in charge of modifying the cyclic ratio of the converter's switching 
cell in order to force the panel to deliver the maximum of its energy at each moment. 

 
Figure 1: Synoptic diagram of the photovoltaic system 

Global study of the losses for a static converter 

As described in the previous section, the constituents of the Boost converter are: MOSFET, 
Diode, Inductance and Capacitance. The conversion efficiency can be written as:  

𝛈𝐂𝐨𝐧𝐯𝐞𝐫𝐬𝐢𝐨𝐧 =  
𝐏𝐨𝐮𝐭

𝐏𝐢𝐧
=

𝐏𝐢𝐧−𝐏𝐥𝐨𝐬𝐬𝐞𝐬

𝐏𝐢𝐧
      (1) 

With 𝑃𝑖𝑛 and 𝑃𝑜𝑢𝑡 the powers respectively at the input and output of the converter, 𝑃𝑙𝑜𝑠𝑠𝑒𝑠 the 
power lost in the converter 

Losses in the MOSFET  

The transistor dissipates energy during the firing phase WA, the conduction phase WC, and 
the blocking phase WB corresponding to a Total energy WT: per switching period. For a 
MOSFET, the behavior in conduction regime is similar to that of a resistor, the powers 
dissipated during this phase and during the switching phases are defined according to [4] by 
the following equations: 

PCond  = 𝑓. W𝐶𝑜𝑛𝑑 =  
TCond

T
 . Von. Iin = α. I²in. RDSon    (2) 

PCond = (WA +  WB). 𝑓 =
1

2
. Vin. Iin(𝑡𝑐𝑜𝑚 + 𝑡𝐵𝑙𝑜𝑐 )𝑓 +

1

2
. Vin. IRM. 𝑓. 𝑡𝑐𝑜𝑚  (3) 

With : WA: Energy dissipated during the firing phase, WB: Energy dissipated during the 
blocking phase, W𝐶𝑜𝑛𝑑: Energy dissipated during the conduction phase, WT: Total energy 
dissipated by the MOSFET, RDSon: Source drain resistance of the MOSFET, Vin∶ Voltage at 
the terminals of the transistor in the blocked state, Iin : current delivered by the generator, 
IRM: amplitude of the diode's overlay current, 𝛂: the duty cycle, 𝑓: the switching frequency of 
the MOSFET, 𝑡𝑐𝑜𝑚: duration of the switching phase, and𝒕𝑩𝒍𝒐𝒄: duration of the blocking phase. 
In summary, the total losses at the MOSFET can be evaluated by:  

𝐏 = 𝒇. 𝐖𝐓 = 𝛂. 𝐈²𝐢𝐧. 𝐑𝐃𝐒𝐨𝐧 +
𝟏

𝟐
. 𝐕𝐢𝐧. 𝐈𝐢𝐧(𝒕𝒄𝒐𝒎 + 𝒕𝑩𝒍𝒐𝒄)𝒇 +   

𝟏

𝟐
. 𝐕𝐢𝐧. 𝐈𝐑𝐌. 𝒇. 𝒕𝒄𝒐𝒎  (4) 

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Ehlan et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 
Losses in the diode 

When the diode is blocked, it behaves like a perfect capacitor because there is virtually no 
current flowing through it and only the voltage across it varies. When it is on, the voltage and 
the current vary. The other losses of the diode have been taken into account in the switching 
losses of the MOSFET, only the conduction losses are considered here. These are in the 
form of: 

𝑃𝐹  = 𝑉𝑑 . 𝐼𝑜𝑢𝑡   with    𝑉𝑑 =  𝑅𝑑 . 𝐼𝑖𝑛 +  𝑉𝐹                                  (5) 

𝐏𝐅 = (𝟏 − 𝛂) [𝐑𝐝. 𝐈²𝐢𝐧 +  𝐈𝐢𝐧. 𝐕𝐅 ]                                           (6) 

with 𝑅𝑑  : differential resistance or dynamic resistance et 𝑉𝐹  : direct voltage. 

Losses in the capacitor 

In most cases, a capacitor is a simple capacitance C expressed in Farad but as a component 
the capacitor is not limited to its simple capacity: 

𝐏𝐂𝐚𝐩 = 𝐑𝐂. 𝑰𝑹𝑴𝑺
𝟐        (7) 

We can rewrite (7) thanks to the expressions of the effective currents in the various 
components of the circuit developed in [5] in the form: 

𝐏𝐜𝐚𝐩𝐚𝐜𝐢𝐭𝐨𝐫 =  𝐑𝐜𝛂(𝟏 − 𝜶)𝐈𝐢𝐧
𝟐 +

𝑹𝒄

𝟏𝟐
(𝟏 − 𝛂) (

𝛂∗𝐕𝐢𝐧

𝐋∗𝐟
)

𝟐
    (8) 

Losses in the inductor 

The equivalent electrical model of a wound inductor can be reduced to an ideal inductor in 
series with a resistor RL. The presence of the latter generates direct losses by Joule effect 
linked to the conductors and to the losses induced in the magnetic core (losses by hysteresis 
and by eddy currents) which depend on the frequency and the variation of the flux. 

𝐏𝐈𝐧𝐝𝐮𝐜𝐭𝐨𝐫 =  RL. IL,RMS
2            (9) 

𝐏𝐈𝐧𝐝𝐮𝐜𝐭𝐨𝐫 = 𝐑𝐋𝐈𝐢𝐧
𝟐 +

𝐑𝐋

𝟏𝟐
(

𝛂∗𝐕𝐢𝐧

𝐟∗𝐋
)

𝟐
     (10) 

The expressions (11) and (12) of the average voltage of the inductance and the average 
current of the capacitor of a boost converter, make it possible to establish a relation showing 
the influence of the losses generated by RL of the inductance on the output of this converter 
according to the electric quantities of the circuit [6]. 

〈𝑉𝐿 〉 = 0 = 𝑉𝑖𝑛  − 𝑅𝐿 𝐼𝑖𝑛 − (1 − 𝛼). 𝑉     (11) 

〈𝑖𝐶 〉 = 0 = (1 − 𝛼). 𝐼𝑖𝑛 −
𝑉

𝑅
      (12) 

𝛈 =
𝐏𝐨𝐮𝐭

𝐏𝐢𝐧
=

𝟏

𝟏+
𝐑𝐋

𝐑.𝛂′²

      (13) 

For application, we used a MOSFET type IRFZ44E [7], a Standard silicon rectifier diodes1N 
5059...1N 5062 [8], a capacitor APSA100ESS680MFA5S [9] and an inductor muRata|Ps 
49101sc [10]. 
Using the datasheets of all these components, the equations for calculating the losses as a 
function of the current through them are summarized in Table 1. 

 

 

 

 

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Ehlan et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 
Table 1: Loss evaluation equations 

Parameters Equations 

𝐏𝐌𝐨𝐬𝐟𝐞𝐭 (𝟖. 𝟔𝟐𝟓𝒆−𝟑)𝑰𝒊𝒏
𝟐 + (𝟎. 𝟐𝟑𝟒)𝑰𝒊𝒏 + 𝟑𝟒. 𝟓𝟑𝒆

−𝟑 

𝐏𝐃𝐢𝐨𝐝𝐞 (𝟐. 𝟓𝟔𝟐𝐞−𝟐)𝐈𝐢𝐧
𝟐  +  𝟎. 𝟔𝟖𝟖𝐈𝐢𝐧 

𝐏𝑪𝒂𝒑𝒂𝒄𝒊𝒕𝒐𝒓 (𝟓. 𝟖𝟔𝐞−𝟑)𝐈𝐢𝐧
𝟐 + 𝟎. 𝟎𝟕𝟑𝟐 

𝐏𝑰𝒏𝒅𝒖𝒄𝒕𝒐𝒓 (𝟎. 𝟏𝟔𝟓)𝐈𝐢𝐧
𝟐 + 𝟎. 𝟗𝟑𝟖 

Loss calculation method  

From the equations listed in Table 1, the block model in Figure 2 has been developed in 
Simulink to calculate the losses generated by a single-inverter PV system. Each of its blocks 
modeling the losses whose sum represents the total loss of the converter receives at its input 
the current 𝑰𝒊𝒏 which is the equivalence of the current 𝑰𝑷𝑽. This calculation block is 
associated with the MPPT control system that is implemented in the converter. 

 
Figure 2: Total loss calculation blocks of a DC-DC converter in a PV system. 

Results and discussions 

We have evaluated the losses in the components including the switching cells (MOSFET, 
diode) and passive components of a DC-DC converter. On figure 3 showing the 
characteristic curves of the losses generated by these components as a function of the 
global current, we can notice that the losses in the capacitor, the MOSFET and in the diode 
are almost linear while the losses in the inductor evolve exponentially with the global current. 
In terms of efficiency, a cross analysis between figure 3 and 4 shows that the influence of 
these losses on the conversion efficiency is directly proportional to the losses generated by 
each component of the converter. 

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Ehlan et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 
Figure 3: Changes in losses based on global current 

 
Figure 4: Influence of losses on efficiency 

 

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Ehlan et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 
Figure 5: Loss distribution diagram 

 
Figure 6: Total loss diagram. 

Then, the simulation is performed under MATLAB / Simulink with a 240 KW PV generator 
and a purely resistive charge of 9.6 Ω. By applying the Figure 1 loss calculation block, Figure 
6 shows that for a 240W PV source, a converter can encroach on conversion output up to 
18% of the total power available at its in, reducing conversion power to 82%. Figure 5 shows 
that 53% of its losses are caused by the inductor, 33% by the diode, 11% by the MOSFET 
and only 2% by the capacitor. 

Conclusion  

The total efficiency of the converter is strongly influenced by the efficiency of the induction 
since the efficiency of the capacitor and MOSFET always remain above 95% and 90% 
respectively. While the efficiency of the diode which is 67% is still acceptable, the induction 
seems to impose its losses on the converter we simulated. Thus, in order to boost the 
efficiency of the converter, we must try to work a lot on the effectiveness of the inductor. 

ACKNOWLEDGEMENTS 

The authors offer their sincere thanks to the German Academic Exchange Service DAAD 
through the Technical University of Applied Sciences (WILDAU) for their unwavering support 
throughout the implementation of this work. 

References 

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