The problem of parameters identification for transformer equivalent circuit can be solved by optimizing a nonlinear formula. The objective function attempts to minimize the sum of squared relative errors amongst the accompanying calculated and actual points of currents, powers, and secondary voltage during the load test of the transformer subject to a set of parameters constraints. The authors of this paper propose applying a new and efficient stochastic optimizer called the slime mold optimization algorithm (SMOA) to identify parameters of the transformer equivalent circuit. The experimental measurements of load test of single- and three-phase transformers are entered to MATLAB code for extracting the transformer parameters through minimizing the objective function. Experimental verification of SMOA for parameter estimation of single- and three-phase transformers shows the capability and accuracy of SMOA in estimating these parameters. SMOA offers high performance and stability in determining optimal parameters to yield precise transformer performance. The results of parameters identification of transformer using SMOA are compared with the results using three optimization algorithms namely atom search optimizer, interior search algorithm, and sunflower optimizer. The comparisons are fairly performed in terms of the smallness of objective function. Comparisons shows that SMOA outperforms other contemporary algorithms at this task.
Transformers are major components in power systems that are important in both transmission and distribution networks. They are also used in industrial and household devices. Transformer maloperation significantly affects system performance, reliability, and stability [1,2].
A transformer’s equivalent circuit has parameters for resistance and reactance that should be identified for accurate analysis of electric power grids. Transformer parameters also have a major effect on the transformer’s performance in different operating conditions. Accurately estimating transformer parameters arises from the need to improve transformer performance in both steady-state and transient operating conditions. Realistic studies in system behavior require a reasonable transformer model, which plays an important role in the integration between the other components [3].
A transformer is modeled by considering its nonlinearities [2,4]. Additionally, the presence of saturation, harmonics, and transient situations affects the estimation parameters of the transformer. Actual real-time measurements are needed to perform the time-domain [5,6] and frequency response [7,8] analyses when estimating accurate transformer parameters.
Generally, transformer parameters can be computed in various ways: standard test executions (no-load and short circuit tests) [9,10], geometrical dimensions of a transformer’s construction [11], data from product nameplates [12,13], and various load details [10,14]. Techniques using the geometrical dimensions of the transformer require data obtained from terminal measurements, external tank dimensions, and nameplates. Determining the cross-sectional area of both the yokes and the limb as well as the core dimensions requires solving system equations that are limited by the dimensions of the transformer tank [11]. The standard no-load and short-circuit tests cannot be utilized when the transformers are in operation in the circuit. In addition to the defects of methods other than the load data method, estimating parameters using the measured load data values minimizes the difference between estimated and measured values [10].
Recent optimization techniques have made major strides in solving power problems such as optimal power flow [15], load frequency control [16,17], energy management [18], and parameter estimation for electrical instruments such as photovoltaic modules [19,20], and fuel cells [21]. However, all these estimation methods use optimizers that compare estimated values with measured values to minimize deviations.
Other researchers have implemented numerous optimization techniques for identifying transformer parameters such as a chaotic optimization algorithm [10], imperialist competitive and gravitational search algorithms [12], an evolutionary programming algorithm [13], a bacterial foraging algorithm [14], particle swarm optimization [22], a genetic algorithm [23], an artificial bee colony algorithm [24], a coyote optimization algorithm [25], and a manta ray foraging optimization (MRFO) method and a chaotic variant [26]. These algorithms can be implemented using load data or nameplate data for the transformer, while the transformer is in service (i.e., without disconnecting it). Finally, these algorithms can estimate transformer parameters in both single- and three-phase systems.
Despite this brief survey, the no-free-lunch theorem demonstrates that the possibility of further improvement in estimating transformer parameters remains. To this end, the authors of this paper consider using slime mold optimization algorithm (SMOA), which was created in 2020 to estimate unknown transformer parameters. SMOA was inspired as a novel meta-heuristic algorithm by slime mold oscillation modes in nature and applied effectively to the designs of pressure containers and the welded beams [27]. In this paper, single- and three-phase transformers are investigated using load tests to demonstrate the effectiveness of SMOA and make essential comparisons. Our performance evaluations show that our proposed method outperforms existing approaches.
The main contribution of this paper can be summarized as follows:
• Application of SMOA to estimate transformer parameters.
• Experimentation of single- and three-phase transformers for validation of the proposed method.
• Comparison of SMOA with other optimization techniques based on their results.
The paper is organized as follows. In Section 2, introduce the equivalent circuit of a transformer. Section 3 gives a short overview of the SMOA method. Section 4 presents our experiment, the numerical results of the application of SMOA, and discussion. Finally, Section 5 introduces our conclusions.
Problem Formulation
The per-phase equivalent circuit of a three-phase power transformer with respect to its primary side is shown in Fig. 1. There are six parameters: R1,X1,R2′,X2′,Rc,and Xm.
Per phase equivalent circuit of electric power transformer with respect to its primary side
Using the fundamental laws of electric circuits, the following equations can be formulated:
V1=E1+Z1I1
V2′=E1−Z2′I2′=ZLoad′I2′
E1=ZmIo
Z1=R1+jX1
Z2′=R2′+jX2′
Zm=jXm.RcRc+jXm
Z=Z1+Zm(Z2′+ZLoad′)Zm+(Z2′+ZLoad′)
I1=V1Z1=Io+I2′
Io=E1Zm=E1Rc+E1jXm=Ic−jIm
I2′=I1×ZmZm+Z2′+ZLoad′
P1=ℜ(V1I1∗)
P2=ℜ(V2′I2′∗)
η=P2P1
Minimizing the sum of squared relative errors (SSRE) amongst the estimated and measured points is the objective function (Fobje) for the transformer parameters. It is extracted as,
where Fobje is subject to constraints, which are defined by the lower and upper limits of the transformer parameters.
SMOA
SMOA is inspired by slime mold oscillation modes in nature. The slime mold that inspired this algorithm is physarum polycephalum, which is classified as a fungus and termed a slime mold by Howard. It is a eukaryote that lives in humid and cold places. The plasmodium is the main nutritional stage of slime mold where its organic matter pursues food, borders it, and excretes enzymes to predigest it. Throughout the migration stage, the front end of the slime mold spreads out like a fan-shaped tailed from a structured intravenous tie that lets cytoplasm stream inside. A distinctive feature of slime mold, it can exploit numerous sources of food simultaneously forming a venous network connecting them. They can even propagate to large areas, if the environment is suitable and food is sufficient [27].
The SMOA method has several features. It is characterized by a unique mathematical model. The adaptive weights permit the SMOA to maintain a specific perturbation rate and guarantee fast convergence that prevents the falling into local optima. It also displays exceptional exploratory and exploitative abilities. To establish the optimal route for obtaining food, SMOA uses adaptive weights to simulate a slime mold’s generation of positive and negative feedback as it spreads, a bio-oscillator created by its search for food. SMAO can also make correct decisions based on historical data due to its excellent utilization of individual fitness values. The description of SMOA model in mathematical terms is in the following paragraphs.
Food Approaching
The slime mold uses odors in the air to find food. Eq. (15) emulates this behavior in contraction mode.
In these equations, the condition referring to S(i) is arranged in the first half of the population, and SmellIndex is the individual fitness ranked in descending order as stated in Eq. (19).
SmellIndex=sort(S)
Food Wrapping
The location of the slime mold (X∗)→ is updated according to Eq. (20).
The value of vb changes randomly between [−a, a], and it steadily approaches zero as the iterations increase, while vc oscillates between [1,0] and approaches zero. Tab. 1 presents the SMOA.
Results with Discussion
The experiments were conducted with two test cases: a single-phase transformer rated at 300 VA, 230/2·115 V, and a three-phase transformer rated at 300 VA, 400/2·200 V. One primary winding and two secondary windings were in the single-phase transformer and in each phase of the three-phase transformer. The load test was carried out on the two transformers and used the measurements to calculate SSRE as Fobje to be minimized by SMOA for estimating transformers parameters. SMOA’s results are compared to those from ASO [28], ISA [29], and SFO [30]. Our results were obtained using MATLAB-R2016b under Windows 10 running on a laptop with an Intel Core i7−4702MQ CPU at 2.2 GHz with 8 GB of RAM.
SMOA
Algorithm 1
Initialize the parameters, population (popu), kmax;
Initialize the slime mold positions X;
While (k≤kmax)
Determine the fitness of all slime mold;
Update the bestFitness, Xb;
Determine W using Eq. (18);
For each search
Update p, vb, vc;
Update the positions using Eq. (20);
End For
k=k+1;
End While
Return bestFitness, Xb;
Fig. 2 shows the experimental setup of the transformers in the laboratory at Taif University. The potentiometers were employed to load the transformers from 10% to 100%. The digital multimeters were used to measure currents and voltages and wattmeters for measuring electrical power.
Tabs. 2 and 3 show the transformer load test measurements. Eleven and eight measurements were obtained for the single- and three-phase transformers, respectively. The population, maximum number of iterations, and control parameters used by all the optimization algorithms (SMOA, ASO, ISA, and SFO) are listed in Tab. 4. The population and maximum number of iterations were identical for all optimizers to guarantee fairness in comparison. The control parameters of SMOA and ISA are not included because they are changed dynamically throughout the iterations. The best (fittest) values of the transformer parameters are obtained after many independent runs of SMOA, generating a minimum Fobje as these optimizers are stochastic.
Load test of the single-phase transformer
RL (Ω)
V1 (V)
V2 (V)
I1 (A)
I2 (A)
P1 (W)
P2 (W)
η (%)
492.0
230
114.5
0.24
0.19
36.40
23.2
63.7
445.0
230
114.5
0.24
0.20
37.00
24.4
65.9
398.0
230
114.4
0.25
0.23
40.30
28.1
69.7
351.0
230
114.4
0.26
0.27
43.10
32.7
75.9
304.0
230
114.4
0.28
0.34
50.90
41.1
80.7
257.0
230
114.3
0.34
0.47
65.79
56.9
86.5
210.0
230
114.1
0.41
0.63
83.00
76.2
91.8
163.0
230
113.9
0.44
0.72
95.50
90.4
94.7
116.0
230
113.4
0.58
1.00
125.40
120.0
95.7
92.5
230
113.0
0.70
1.22
153.00
146.4
95.7
69.0
230
112.5
0.94
1.66
209.70
197.5
94.2
Load test of the three-phase transformer
RL (Ω)
V1ph(V)
V2ph(V)
I1 (A)
I2 (A)
P11−ph(W)
P21−ph(W)
η (%)
4920
242
241
0.10
0.05
16.0
11.5
71.9
3980
242
240
0.11
0.06
18.5
14.5
78.4
3040
242
239
0.12
0.08
22.6
19.0
84.1
2100
242
238
0.15
0.11
30.0
26.5
88.3
1160
242
235
0.23
0.20
52.0
47.0
90.4
690
242
230
0.36
0.34
86.0
79.0
91.9
502
242
226
0.47
0.45
110.0
100.0
90.9
361
242
220
0.63
0.60
150.0
132.0
88.0
Optimizer control parameters
SMOA
popu = 30, kmax = 50
ASO
popu = 30, kmax = 50, α = 50, β = 0.2
ISA
popu = 30, kmax = 50
SFO
popu = 30, kmax = 50, p = 0.05, m = 0.05
After applying SMOA, the estimated transformer parameters are utilized to calculate the currents, powers, and secondary voltages via the fundamental laws of electric circuits. The smallest values of the resultant SSRE were 0.601768 and 1.16306 for the single- and three-phase transformers, respectively.
The parameters of single- and three-phase transformers are extracted using SMOA and calculated the percentage error as shown in Tabs. 5 and 6, respectively. The low error percentages demonstrate the precision of the parameters optimized via SMOA. Comparing the results from SMOA, ASO, ISA, and SFO show that the SSRE obtained using SMOA was the smallest for single- and three-phase transformers, as shown in Tabs. 7 and 8, respectively. Tab. 7 shows that the SSREs of the other methods exceed the SSRE obtained from SMOA by 0.566% for ASO, 0.006% for ISA, and 2.4085% for SFO. Tab. 8 shows the SSRE values for the other techniques were higher by 2.5536% for ASO, 0.1994% for ISA, and 5.8999% for SFO. With reference to the SSRE convergence curves in Fig. 3, SMOA had a fast and smooth convergence curve without oscillations until it obtained the optimal SSRE when compared with other techniques. Tabs. 7 and 8 show the computation time, with SMOA achieving the fastest performance for the single-phase transformer and a close second place behind ISA for the three-phase transformer. There were more measurements for the load test with the single-phase transformer, which explains the longer computation time of all the optimizers in that case.
Optimized parameters obtained from SMOA for the single-phase transformer
R1 (Ω)
R2′ (Ω)
X1 (Ω)
X2′ (Ω)
Rc (Ω)
Xm (Ω)
SMOA
3.0024
0.750
0.0375
0.0070
4000
1453
Datasheet
3.1000
0.775
0.0382
0.0067
3933
1437
Error
3.1%
−3.2%
−1.8%
4.5%
1.7%
1.1%
Optimized parameters obtained from SMOA for the three-phase transformer
The plots of I1-RL, I2-RL, V2-RL, P1-RL, P2-RL, and η-RL of the transformers extracted by SMOA and their measured values are displayed in Figs. 4–11. The closeness between the measured and calculated currents, voltages, and powers using SMOA shows the precision of our estimation method.
Primary and secondary currents of the single-phase transformer versus load resistance (a) I1-RL plot (b) I2-RL plot
The secondary voltage of the single-phase transformer versus load resistance
Input and output powers of the single-phase transformer versus load resistance (a) P1-RL plot (a) P2-RL plot
Efficiency of the three-phase transformer versus load resistance
Primary and secondary currents of the three-phase transformer versus load resistance (a) I1-RL plot (b) I2-RL plot
The secondary voltage of the three-phase transformer versus load resistance
Input and output power of the three-phase transformer versus load resistance (a) P1-RL plot (b) P2-RL plot
Efficiency of the three-phase transformer versus load resistance
Tab. 9 lists the statistical results obtained when using SMOA to obtain parameters of the two transformers. The best and worst results and the standard deviation (SD) of Fobje are written. Smaller SD values emphasize the effectiveness of SMOA in identifying the unknown parameters of the two transformers.
The statistical results of SMOA for two transformers
Indicator
Single-phase transformer
Three-phase transformer
Best
0.601768
1.16306
Worst
0.638345
1.22699
SD
0.010234
0.01718
Conclusions
Obtaining unknown parameters of the transformer equivalent circuit by load tests, is preferred because it requires less data than other methods. The use of optimization algorithms minimizes the deviations between the estimated and measured values of load test data. The authors of this paper propose using SMOA as a precise, quick, and reliable means for generating the best values of the unknown transformer parameters. Our proposed objective function seeks to minimize the sum of squared relative errors (SSREs) between the computed and measured currents, powers, and secondary voltages in a load test of the transformer. Our investigation into a test implementation of SMOA for transformer parameter estimation reveals its improved speed and accuracy compared to existing optimizers. The results show that our proposed SMOA is efficient and dependable, outperforms other approaches in terms of quicker convergence, and has superior accuracy. The authors of this paper conclude that SMOA is a precise algorithm that can be used to optimize a broad variety of parameters in the field of electrical engineering.
NomenclatureSMOA:
slime mould optimization algorithm
R1:
the resistance of the primary winding (Ω)
X1:
the leakage reactance of primary winding (Ω)
R2′:
the refereed resistance of the secondary winding (Ω)
X2′:
the refereed leakage reactance of secondary winding (Ω)
Rc:
the core loss resistance (Ω)
Xm:
the magnetizing reactance (Ω)
V1:
the primary voltage (V)
V2′:
the refereed secondary voltage (V)
Z1:
the impedance of the primary winding (Ω)
Z2′:
the refereed impedance of the secondary winding (Ω)
Zm:
the magnetizing impedance (Ω)
Z:
the total transformer impedance (Ω)
I1:
the input current (A)
I2′:
the refereed secondary current (A)
Io:
the no-load current (A)
P1:
the input power (W)
P2:
the output power (W)
η:
the efficiency (%)
SSRE:
the sum of squared relative errors
N:
the number of measurements
m:
the measured values
e:
the estimated values
Fobje:
the objective function
X:
the location of the slime mould
Xb→(k):
the candidate with the highest order concentration in the iteration k
k:
iteration number
kmax:
the maximum number of iterations
XAandXB:
two randomly selected candidates from the slime mould swarm
υb:
variable lies in the range [-a, a]
υc:
variable that linearly decreased from one to zero
W:
the slime mould weight
bF:
the best fitness in the current iteration
wF:
the worst fitness in the current iteration
S(i):
the fitness of candidate X
Bs:
the best-obtained fitness throughout all iterations
randand r:
and r random vector in the range of [0,1]
Max and Min:
the border limits of search space
popu:
population
ASO:
atomic search optimizer
ISA:
interior search algorithm
SFO:
sunflower optimizer
The authors gratefully acknowledge the approval and the support of this research study by Taif University Researchers Supporting Project number (TURSP-2020/86), Taif University, Taif, Saudi Arabia.
Funding Statement: This work was supported by Taif University Researchers Supporting Project number (TURSP-2020/86), Taif University, Taif, Saudi Arabia.
Conflicts of Interest: The authors declare that they have no conflicts of interest to report regarding the present study.
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