TRANSACTIONS ON ENVIRONMENT AND ELECTRICAL ENGINEERING ISSN 2450-5730 Vol 4, No 1 (2020) 

© Vinícius Henrique Farias Brito, José Carlos de Oliveira, Fabricio Parra Santilio 

 

Abstract— Although there currently exists a wide range of 

voltage regulators that are commercially available, the search for 

devices with a simpler physical design remains the focus of 

research studies. Following this line, an electromagnetic voltage 

regulator (EVR) arrangement has been proposed. The EVR is 

constituted of an autotransformer that supplies, via discrete taps, 

a series transformer that injects voltage for regulating the feeder 

voltage. Even though its operating principle is shown as being 

similar to that of other devices on the market, the physical 

arrangement and operating strategy of EVR show novelties 

which result in properties such as: economic attractiveness, 

constructive simplicity, and operational reliability. Moreover, 

when installing voltage regulators, efficacy studies must be 

carried out to optimize equipment design. In this context, this 

paper aims at evaluating the factors that influence the 

effectiveness of the EVR in restoring voltage variations according 

to the determinations imposed by regulatory agencies. The 

ultimate goal of this study is to determine the voltage deviation 

range that the EVR is able to restore. To achieve this goal, a 

mathematical modeling of the EVR is given and study cases are 

computationally carried out to investigate its performance when 

connected to a typical distribution feeder. 

 
Index Terms—Computational Modelling, Distribution System, 

Electromagnetic Voltage Regulator, Performance Evaluation, 

Power Quality, Voltage Regulation.  

 

I. INTRODUCTION 

MONG the electrical power supply requirements 

imposed on power utilities, power quality indices are 

included, such as long-duration and short-duration voltage 

variations, harmonic distortions, unbalances, etc. In this 

scenario, the issues related to the voltage magnitude variations 

at power frequency are particularly highlighted, since 

distinguished normative documents establish limits for these 

phenomena in terms of long and short duration [1].  

In Brazil, the definitions of voltage variation severity and 

 
 

This study was financed by the Coordenação de Aperfeiçoamento de 

Pessoal de Nível Superior – Brazil (CAPES) – Finance Code 001. 

Vinícius Henrique Farias Brito and José Carlos de Oliveira are with the 

Faculty of Electrical Engineering, Federal University of Uberlandia, 

Uberlandia, Brazil (e-mail: vinicius.brito@ufu.br; jcoliveira@ufu.br).  

Fabricio Parra Santilio is with the Electrical Engineering Department, 

Federal University of Mato Grosso, Cuiaba, Brazil. (e-mail: 

fabricio.qee@gmail.com.br). 

duration are set by the Brazilian Electricity Regulatory 

Agency (ANEEL) in the technical standard titled Electricity 

Distribution Procedures in the National Electric System 

(PRODIST) - Module 8 [2]. This document classifies long-

duration voltage variations as changes in the RMS value of the 

voltage over a period longer than 3 minutes. On the other 

hand, short-duration phenomena include those voltage 

variations manifested for periods shorter than the 3-minute 

limit. Moreover, the directive also establishes the magnitude 

limits for long and short duration voltage variation events. 

When the voltage magnitude infringes the established 

limits, regulation or compensation processes are carried out in 

order to regulate the voltages to the acceptable levels defined 

by legislation. A wide range of equipment is currently 

employed to perform this task. In general, it is recognized that 

compensation devices are based on two basic strategies. The 

first comprises of voltage compensation by indirect methods, 

such as voltage control via static or dynamic devices 

associated with the control of reactive power flow. The second 

performs its function by acting directly on the voltage 

magnitudes using devices that change the voltage values via 

tap changers or direct injections of compensating voltage [3]. 

In the context of devices based on the control of reactive 

power, the simplest devices are capacitor and reactor banks – 

fixed or automatic [4]. Another possibility, widely used in the 

past in large power systems, is the synchronous compensator 

[5]. Further still, with the evolution of electronic switching 

technologies, commercial products that make use of the well-

known FACTS technology have arisen [6]. This group 

includes the Static Var Compensators (SVCs) and 

Synchronous Static Compensators (STATCOMs). 

Regarding compensation technology which acts directly on 

voltage magnitudes, traditional transformers with on-load tap 

changer (OLTC) and no-load tap changer (NLTC) [7] stand 

out, as well as other electromagnetic regulators based on tap 

changes to adjust the electrical quantities, such as the Step 

Voltage Regulator (SVR) [8]. Additionally, other devices, 

based on electronic switching, are available on the market. 

This is, for example, the case of the Dynamic Voltage 

Regulator (DVR) [9]. 

In light of the above, one recognizes, therefore, that there is 

a diversity of devices available on the market with operating 

properties capable of regulating the voltage at the load in 

Modeling and Performance Evaluation of an 

Electromagnetic Voltage Regulator via Series 

Compensation 

 Vinícius Henrique Farias Brito, José Carlos de Oliveira, Fabricio Parra Santilio 

A 

mailto:vinicius.brito@ufu.br


accordance with the required standards. However, the most 

widely used strategy to mitigate long-duration voltage 

variations, in distribution systems, is the direct compensation 

of the voltage magnitude [10]. 

Furthermore, in terms of the voltage regulators based on the 

direct compensation of the voltage magnitudes mentioned 

previously, there exists in this same category a device 

proposed in [11], which is called the electromagnetic voltage 

regulator (EVR). This device consists of a shunt 

autotransformer with taps supplying a transformer connected 

in series with the electrical feeder focused on the regulation 

process. The series transformer is responsible for the injection 

of a controlled reinforcement voltage, being that additive or 

subtractive, which aims at compensating the voltage at the 

load terminals. The fundaments that govern this proposal are 

found in [12], which shows that, via discrete switching, 

different taps of the autotransformer can be used to make the 

reinforcement voltage compatible with the required 

compensation level. The possibility of disconnecting the shunt 

autotransformer, as well as the switches, provides greater 

operational reliability for the network to which the EVR is 

connected. That is, in the event of a failure or maintenance of 

the regulator, despite the loss of the regulation process, the 

power flow between the source and the load is not interrupted. 

In line with the aforementioned topological proposition, 

more recent works, such as [10] and [13], covering similar 

physical structures and commercial products have shown the 

feasibility of the arrangement focused upon in this paper. In 

fact, with a topology similar to the EVR, [14] describes a new 

conception for a voltage compensator, which was installed on 

a rural medium voltage feeder in Germany with high presence 

of distributed generation. The commercial equipment was 

called the line voltage regulator (LVR) and the results of its 

performance indicated great improvements in the voltage 

profiles of the rural medium voltage feeder. In addition to the 

operational effectiveness, the work highlights that the LVR 

presented a cost-benefit ratio higher than other options for 

voltage compensation, which significantly increased the 

network distributed generation capacity. Within the same 

constructive and operational strategy, [15] showed that the 

solution proved to be efficient for different voltage levels.  

Even though the efficacy of the EVR injection has been 

verified for a constant load consumption [11] [12], its 

effectiveness for a load with dynamic behavior must be further 

investigated. In fact, variables such as the long-duration 

voltage variation magnitudes, the feeder and load parameters, 

and the available taps of the EVR are features that will 

strongly affect the performance of the device. 

In this context, this paper aims at evaluating the relationship 

among these influencing factors since they define the range of 

voltage variations that the EVR can restore to the adequate 

voltage level set in the standards. 

For a better understanding, initially, the physical 

arrangement and operating principle of EVR are presented, as 

well as the development of its mathematical modeling in the 

frequency domain. In the following, a detailed performance 

evaluation study and computational case studies are carried 

out to achieve the goal proposed in this paper. 

II. ELECTROMAGNETIC VOLTAGE REGULATOR: PHYSICAL 
ARRANGEMENT AND MATHEMATICAL MODELING 

Before deriving the mathematical model of the EVR, its 

physical arrangement is shown in the schematic diagram given 

in Fig. 1. It can be noted that the device enables the control of 

the load voltage (Bus 2) by injecting a series compensation 

voltage (additive or subtractive reinforcement), which, when 

summed to the supply voltage, leads to a controlled voltage at 

the load terminals. 

In Fig. 1, the regulator is operating to restore the load 

voltage (Bus 2) when an undervoltage occurs on Bus 1. Once 

this phenomenon happens, the control on the regulator detects 

it and selects the tap of the autotransformer that offers the 

most adequate level of compensating voltage for injection into 

the system. This compensation voltage when summed to the 

supply voltage restores the voltage at Bus 2 to its required 

value or close to it. Subtractive voltages are also feasible for 

injection by the series transformer, in the case of overvoltages. 

This can be carried out by changing the contacts using the 

SWpp and SWpn switches. 

 

 
Fig. 1.  Schematic diagram of the Electromagnetic Voltage Regulator. 

Adapted from [11]. 

 

 

The equivalent electrical circuit of the EVR and overall 

system arrangement, related to a specific steady state 

operational condition, is given in Fig. 2. Noteworthy here is 

that the equivalent circuit shown is applicable to a given 

selected tap when operating to restore undervoltages. 

The corresponding equation to establish the relationship 

among the system (EVR, load, and feeder) parameters and the 

load voltage is given by (1). Noted also is that the magnetizing 

branches of the transformers are disregarded. The variables in 

(1) are identified in (2) to (5). 

 



 
Fig. 2.  Equivalent electrical circuit of the EVR, feeder and load. 

 

1 21

S
L

ST

AT

V
V

K K







 


  

 (1) 

 

2

1

.
*

ATST AT

AT ST L

Z
K

Z

 

 






 
  

 

 (2) 

 

 
2 *

ST S
AT

AT ST L

Z Z
K

Z



 

 






 

  
 

 (3) 

 

1 2

2

AT AT
AT

AT

E E

E



  (4) 

 

1

2

ST
ST

ST

E

E
   (5) 

 

where: 

•  
SV



 is the supply voltage. 

•  
LV



 is the voltage at the load terminals. 

• 
AT

  is the transformation ratio of the autotransformer. 

• 
ST

  is the transformation ratio of the series transformer. 

•  
SZ



 is the supply network short-circuit impedance. 

•  
STZ



 is the total impedance of the series transformer 

referred to the primary side. 

•  
ATZ



 is the total impedance of the autotransformer 

referred to the secondary side. 

•  
1STE



 and 
2STE



 are the voltages on the primary and 

secondary sides of the series transformer, respectively. 

•  
1ATE



 and 
2ATE



 are the voltages on the primary and 

secondary sides of the autotransformer, respectively. 

III. A CASE STUDY OF THE EVR PERFORMANCE  

In order to carry out the performance investigation of the 

overall system arrangement and the EVR effectiveness during 

the occurrence of voltages deviations from the standard 

values, a typical electrical system has been utilized. It consists 

of a radial feeder, whose parameters are found in Table I. It is 

noteworthy that, without the action of the regulator, the 

connection of the rated load to the feeder leads to a voltage 

drop of about 3.5% at the series impedance, assuming the 

supply voltage is 1 pu.  

 
TABLE I 

FEEDER AND LOAD CHARACTERISTICS 

Parameter Value 

Rated Voltage 13.8 kV 

Network Short Circuit Power 200 MVA 

R/X ratio 0.5 

Load Power Factor 0.94 (lag)
 

Rated Load Power 10 MVA 

 

As for the EVR, the compensator is connected to the feeder, 

in accordance with the electrical circuit of Fig. 2. Its 

regulation range (Reg. Range) goes up to ± 20% in steps of 

2.5%. The autotransformer has 8 taps, therefore, the EVR, via 

its tap 8, is capable of providing a maximum line voltage of: 

 

 1

1

Re . *

0.2*13.8 2.76

ST RATED

ST

V g Range pu V

V kV kV



 

 (6) 

 

In order to reduce the current level of the switches of the 

taps, the transformation ratio of the series transformer was 

chosen as αTS = 0.5. One is reminded that under this condition, 

the current on the primary side of the series transformer will 

be 50% of the feeder (load) current. Therefore, due to this 

transformation ratio of the series transformer, the voltage on 

the secondary side of the autotransformer must be twice the 

voltage value intended for injection. Taking tap 8 as an 

example, to achieve a compensating voltage of 20%, it is 

necessary that the voltage on the secondary side of the 

autotransformer be 40% of the feeder rated voltage. Similar 

reasoning applies to the other taps. 

Regarding the rated power of the transformers, both 

autotransformer and series transformer have the same rated 

power, as determined by (7). 

 

 
 

Re

1 Re

2.5

ST AT LOAD

ST AT

g Range pu
S S S

g Range pu

S S MVA

 
   

 

 

 (7) 

 

where: 

• 
ST
S  is the rated power of the series transformer. 

• 
AT
S  is the rated power of the autotransformer. 

• 
LOAD
S   is the rated load power. 



Table II provides the characteristics of the two 

electromagnetic units that make up the EVR. The impedances 

and resistances are in line with typical designs. 

 
TABLE II 

SERIES TRANSFORMER AND AUTOTRANSFORMER CHARACTERISTICS 

Data 
Power  

(MVA) 

Primary/Secondary 

Winding Voltages 

Zcc 

(%) 

Rcc 

(%) 

Series 

Transformer 
2.5 2.76/5.52 kV 5 1 

 

Autotransformer  

 

2.5 13.8 kV/Taps 5 1 

Autotransformer 

taps – Secondary 

Winding Voltage 

5.52 kV (Tap 8) – 4.83 kV (Tap 7) 

4.14 kV (Tap 6) – 3.45 kV (Tap 5) 

2.76 kV (Tap 4) – 2.07 kV (Tap 3) 

1.38 kV (Tap 2) – 0.69 kV (Tap 1) 

    

 

Once the feeder, the load, and the design characteristics of 

the regulator are defined, the premises for the studies are listed 

as follow: 

 

 The studies performed are associated with 

phenomena classified as long-duration voltage 

variations. 

 According to the criteria defined in [2], the voltage 

values between 0.93 pu and 1.05 pu are considered as 

adequate. This voltage range is delimited by the 

green region of Fig. 3.  

 When the limits of this range are violated, the action 

of the voltage regulator is represented, for each tap of 

the autotransformer, by lines that are changed 

according to the tap used. 

 

Fig. 3 shows, initially, that the supply network suffers a 

0.15 pu voltage drop. Then, with the load disconnected, the 

load voltage reaches the value of 0.85 pu. Once such a voltage 

variation is detected by the equipment control, the EVR starts 

to operate using tap 4 of the autotransformer – the 

corresponding reinforcement voltage is 2.76 kV, therefore, 

AT-TAP4 is equal to 5, as shown in (8). Thus, still in the 

condition of the disconnected load, (9) shows that the load 

voltage increases to 0.94 pu. This value is obtained by (1) 

when K1 and K2 are equal to zero, as such; it corresponds to 

the maximum compensation achieved by tap 4. 

 

4

13.8
5

2.76
AT TAP

kV

kV



   (8) 

 

4

0.85
0.94

0.5
1 1

5

S
L

ST

AT TAP

V
puV










  

 

 (9) 

 

where: 

4AT TAP



 is the transformation ratio of the autotransformer 

when tap 4 is selected. 

Therefore, under the above-mentioned conditions, tap 4 was 

sufficient for restoring the voltage to the appropriate range. 

However, as the load is connected and its power increases the 

complex coefficients K1 and K2 change, and despite the 

injection of the voltage from tap 4 being maintained, as 

expected, the load voltage gradually decreases; the decay rate 

is defined by the feeder and series transformer impedances. 

Fig. 3 shows that, starting from a 3 MVA load, tap 4 is no 

longer sufficient to adjust the load voltage to the adequate 

range. Then, the control changes to tap 5, and a new line starts 

in Fig. 3, with a similar decay behavior, however, starting with 

an adequate voltage value. When the load becomes equal to 

7.9 MVA, the situation repeats once more. 

 

 
Fig. 3.  Correlation between the load voltage and the load power for an 

undervoltage of 0.85 pu. 

 

The results of the performance studies carried out so far 

reveal that the voltage compensation efficacy decreases with 

the increase of the load power, for each tap, as expected. 

Therefore, in order to maintain the load voltage within the 

adequate range, it becomes necessary to change the tap to 

compensate for the loss of regulation efficiency caused by the 

increase in the K1 and K2 coefficients, according to (1). 

Moreover, the dynamics of the control and switching 

system will define the regulator response time for the voltage 

regulation. 

From another evaluative aspect, performance studies are 

now carried out for a constant 10 MVA load under different 

undervoltages that occurred on the network. In doing so, the 

behavior of the set source-feeder-EVR-load is considered for 

various undervoltage magnitudes, and the effectiveness of the 

voltage regulation is evaluated for the 8 taps, as shown in Fig. 

4. 

Fig. 4 shows that under different undervoltages, as the taps 

of the autotransformer change from 1 to 8 (increasing the 

reinforcement voltage), the load voltage also rises as desired. 

The graph shows that each tap determines an undervoltage 

limit for which the EVR is able to ensure that the load voltage 

is within the adequate range. Consequently, the most critical 

undervoltage magnitude that the EVR is effective in restoring 

is set by tap 8. The figure indicates that for a 10 MVA load the 

regulator is capable of compensating, for the adequate range, 

undervoltage magnitudes up to 0.8 pu at the supply voltage. 

 



 
Fig. 4.  Undervoltage magnitudes compensated by the EVR according to the 

autotransformer tap for a 10 MVA load. 

IV. DYNAMIC RELATIONSHIP BETWEEN UNDERVOLTAGES 
PHENOMENA AND THE EVR EFFECTIVENESS 

In addition to the studies related to the previously presented 

operational limits, this section aims at showing the dynamic 

performance of the EVR under specific operating conditions. 

Hence, the system used as a case study was implemented in 

the MATLAB Simulink, as shown in Fig. 5. The parameters of 

the system are the same as those shown in Tables I and II. 

The two operational situations considered are the following: 

 Case 01: Initially, the 13.8 kV voltage supply (1 

pu) feeds the rated load (10 MVA). At t = 0.5 s, the 

supply voltage drops to 11.73 kV (0.85 pu). Then, 

the EVR is set to turn on at t = 1 s with tap 8 

selected. 

 Case 02: This situation is similar to the previous 

one, except for the fact that the voltage drop is 

more severe (10.35 kV or 0.75 pu). 

 

A. Case 01 - Undervoltage of 0.85 pu 

Fig. 6 presents the voltage profile at the load terminals. It is 

shown that, between t = 0 and 0.5 s, the load voltage has a 

value of 13.25 kV (0.96 pu). The 0.04 pu voltage drop is due 

to the feeder impedance. At t = 0.5 s, the load voltage reduces 

to 11.27 kV (0.82 pu), due to the voltage variation imposed on 

the supplier. Next, at t = 1 s the regulator starts operating, with 

the autotransformer switched to tap 8. Under these conditions, 

the load voltage is restored to 13.69 kV (0.99 pu), thus 

showing the effectiveness of the regulator. 

 

 
Fig. 6.  Load voltage profile for Case 01. 

 

B. Case 02 - Undervoltage of 0.75 pu 

The results associated with a more drastic undervoltage are 

indicated in Fig. 7. As one notes, from 0 to 0.5 s the load 

voltage remains at 13.25 kV (0.96 pu) and, then, the load 

voltage is suddenly reduced to 9.94 kV (0.72 pu). After the 

regulator insertion, at t = 1 s, with the autotransformer 

switched to tap 8, the load voltage is increased to 12.08 kV 

(0.87 pu). Therefore, for this situation, the EVR does not have 

sufficient characteristics to restore the load voltage to the 

adequate range. In fact, the specified regulator is capable of 

restoring undervoltages up to 0.80 pu for a 10 MVA load. 

Despite the demonstrated limitation, the load voltage 

increased from 0.72 pu to 0.87 pu, which lessens the voltage 

variation at the load bus. 

 

 
Fig. 7.  Load voltage profile for Case 02. 

 

 

 
Fig. 5.  System implemented in the MATLAB Simulink. 



 

The main electrical quantities associated with the operating 

conditions of the EVR, for the two cases analyzed, are 

summarized in Table III. Comparing those to the rated 

currents of the series transformer (105 A) and the 

autotransformer (523 A), the values obtained are within the 

rated characteristics of these electromagnetic components. The 

same applies to the voltage on the primary side of the series 

transformer. 

 
TABLE III 

CURRENTS AND VOLTAGES ASSOCIATED WITH THE STUDIED CASES 

Electrical Quantity Case 01 Case 02 

IL 

 
415.1 A 366.2 A 

IS 

 
518.9 A 457.8 A 

I1AT 

 
103.8 A 91.6 A 

V1ST 2.61 kV 2.3 kV 

 

Finally, Fig. 8 highlights the EVR performance for other 

load power values, previously fixed at 10 MVA. The figure 

shows the undervoltage magnitudes that the regulator is 

capable of restoring to the adequate range at the load bus. As 

expected, as the load power is reduced, the EVR can restore 

more severe undervoltage magnitudes. 

 

 
Fig. 8.  Undervoltage magnitudes compensated by the EVR for the adequate 

range according to load power. 

V. CONCLUSIONS 

This paper presented an electromagnetic device for 
compensating voltage variations. The proposal acts directly on 

the load voltage by inserting a reinforcement – additive or 

subtractive – to restore the voltage magnitude to the standards 

established by legislation. The device has an attractive 

operating strategy given the use of components that offer 

constructive and operational simplicity, reliability, attractive 

costs, versatility of installation in uncontrolled environments, 

among other attributes. In order to contextualize the theme, 

general information concerning the physical arrangement and 

mathematical modeling of the regulation process was 
synthesized. As exposed in the introduction, the EVR was 

initially proposed by [11] and a similar device was 

materialized as a commercial product by [14] [15]. Once the 

device physical and mathematical model were presented, 

studies related to the effectiveness of the device when faced 

with typical influence quantities of electrical networks were 

carried out. The results clearly showed that the EVR, in the 

terms designed and defined by its basic characteristics, also 

presents a strong dependence on the feeder and load 

parameters. Its efficacy may be full, partial or insufficient, 

depending on the variables involved in the voltage regulation 

process. In general, the results obtained are encouraging for 

the diffusion of the technology contemplated herein. 
Regarding the discrete response and the use of the EVR for 

restoring short-duration voltage variations, it can be 

implemented with fine-tunes based on the use, for example, of 

electronic techniques for controlling switches continuously, 

which is a subject for future works. Finally, it should be noted 

that, although the study presented has explored phenomena 

associated with undervoltages in the supply network, the 

regulator can also be used when overvoltages occur on the 

network.  

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