1. Introduction
Economic load dispatch (ELD) is one of the major mathematical optimization issues in power system operation. It seeks “the best” generation schedule for the generating plants to supply the required demand with the minimum production cost. The input-output characteristics of modern generators are nonlinear by nature. To solve ELD problem, a lot of conventional methods such as the lambda iteration method, the gradient method, Newton’s method etc. have been employed. Unfortunately, for generating units with nonlinear characteristics, the conventional methods can hardly achieve the optimal or near optimal solution. Recently more and more interests have been focused on the application of artificial intelligent technology for solution of ELD problems. Several artificial intelligence methods, such as genetic algorithms [1], evolutionary programming algorithm [2], clonal algorithm [3], neural network [4] etc. have been developed and applied successfully to ELD problems.
Electromagnetism-like mechanism algorithm originates from the electromagnetism theory of physics [5], which considering potential solutions as electrically charged particles spread around the solution space. It has been effectively used in different sorts of research and engineering problems, such as neural network training [6], vehicle routing problems [7] flow shop scheduling problems [8], communication [9], array pattern optimization in circuits [10], image processing [11], intelligent forecasting [12], and control systems [13] and so on. But EMA exist some defects such as premature convergence etc.
Quantum-behaved electromagnetism-like mechanism Algorithm (QEMA) is proposed and used to solve ELD problem. QEMA merges quantum computing theory with electromagnetism-like mechanism algorithm. The superposition characteristic and probability representation of quantum methodology are combined into electromagnetism-like mechanism Algorithm. This can make a single particle be expressed by several certain probability states. And the quantum rotation gates are used to realize update operation of particles. The algorithm is tested for 13-generator system and 40-generator system, which validates it can effectively solve ELD problem.
2 ELD Problem Formulation
2.1 Objective function considering valve-point loading effects
The main objective is to minimize the fuel cost while satisfying the load demand with operating constraints. The objective function can be described as an minimization process with the objective:
where F is the cost function; s is the number of generators in the system; Pi is the power of generator i (in MW); fi (Pi) is the total fuel cost for the ith generator(in $/h).
Cost functions comprise very different input-output curves, since each generator has multi-valve steam turbines. A sinusoidal function is incorporated into a quadratic function to consider the value-point loadings. Cost functions addressing the valve-point loadings of generating units are given by
where ai, bi, ci are the fuel cost coefficients of the ith unit; gi and hi are the coefficients of generator i reflecting the valve point effects; is the output of the minimum operation of the generating unit i (in MW).
2.2 Constraint conditions
The above objective function is to be minimized subject to the following constraints.
2.2.1 Thermal power limits constraint
Thermal units can generate power between specified maximum and minimum limits. These inequality constraints are expressed as
where is the output of the maximum operation of the generating unit i (in MW).
2.2.2 System active load balance constraint
Total generated power is equal to the total demand in the dispatch interval, as shown in (4).
where PL is the system load demand (in MW).
3. Quantum-behaved Electromagnetism-like Mechanism Algorithm
3.1 Basic electromagnetism-like mechanism algorithm
EMA imitates the attraction-repulsion mechanism between charged particles in an electromagnetic field. In EMA methodology, every particle represents a solution and carries a certain amount of charge which is proportional to the solution quality. Solutions are in turn defined by position vectors which give the real positions of particles in a multi-dimensional space. Moreover, objective function values of particles are calculated based on these position vectors. Each particle exerts repulsion or attraction forces on other population members and a resultant force on a particle is used to update its position. The idea behind the EMA methodology is to move particles towards the optimum solution by exerting attraction or repulsion forces.
There are three particles in schematic diagram of attraction and repulsion mechanism for particles (see Fig. 1). If particle 2 is better than particle 1, while particle 3 is worse than particle 1, the attraction force exerted on particle 1 by particle 2 is F21, and the repulsion force exerted on particle 1 by particle 3 is F31. F1 is the total force exerted on particle 1 by particle 2 and particle 3. Particle 1 will move along with the total force F1, and it can move to better region.
Fig. 1.Schematic diagram of attraction and repulsion mechanism for particles
3.2 Quantum-behaved electromagnetism-like mech-anism algorithm
The concept of quantum computing was proposed in the early 1980s [14]. Many efforts on quantum computing have progressed actively because these computing shown to be more powerful that classical computing on various specialized problems [15, 16]. QEMA merges quantum computing theory with EMA. Superposition characteristic of quantum methodology can make a single particle present several states, and the characteristic potentially increases population diversity. Probability representation of quantum methodology is to make particle state be presented according to a certain probability. And the quantum rotation gates are used to realize update operation of particles.
3.2.1 Qubit
A particle is denoted by Qubit for QEMA. A Qubit may be in the “1” state, in the “0” state, or in any superposition of the two, while a bit in EMA can only hold a single state, either 0 or 1. The state of a Qubit can be represented as
where α and β are complex numbers, satisfying
| 0 > represents the state of spin up, while | 1 > represents the state of spin down, so a Qubit can represent two state information (| 0 > and | 1 > ) simultaneously. The superposition state can also expressed in (7).
where θ is phase of Qubit, the relation among θ and α and β, satisfying
Then m particles can be expressed by (9) or (10).
3.2.2 Steps of QEMA
The steps of QEMA is described as Fig. 2.
Fig. 2.The Flowchart of QEMA
Some core steps of QEMA can be introduced in following parts.
3.2.3 Initialization of Qubit encoding of particles
There are m particles ( X1, X2,⋯, Xi, ⋯, Xm) in n-dimensional search space. The ith particle can be recorded as Xi = (θi,1, θi,2, ⋯θi,j, ⋯, θi,n). S is matrix composing with probability amplitude of particles. s(1, j, i) expressed αij (α of jth dimension of ith particle). s(2, j, i) denoted βij ( β of jth dimension of ith particle). The initialization process can be described in (11) and (12).
where r is random number from 0 to 1.
According to above description, the relation among θi,j, αij and βij can be described in (13).
3.2.4 Decoding of particles
When a particle collapses into a basic state, the probability of occurrence of the basic state need be expressed to participate in the fitness assessment of particles. Supposed the actual parameter space searched by algorithm is [a, b], and the occurred probability of some state is [0, 1], then the probability need to be decoded into the actual parameter space [a, b]. The decoding process can be expressed by (14).
Where p is the choice probability of state expression; r is random number from 0 to 1; s(1, j, i) expressed α of jth dimension of ith particle. s(2, j, i) denoted β of jth dimension of ith particle. c(i, j) denotes actual parameter values of jth dimension of ith particle.
3.2.5 Evaluating particles
Evaluating particles is based on the minimum of the total fuel cost. (Seeing section 2.1)
3.2.6 Changing particles form
In the course of changing particles form, the probability amplitude expression transforms into phase expression according to (8).
3.2.7 Updating particles
The first step of updating particles is to calculating the phase correction, which includes calculation of force and movement of particles.
(1) Calculation of force
QEMA is via calculating the resultant force in the population to determine moving direction of the current particle by Coulomb’s law and superposition principle. The resultant force is inversely proportional to the distance between the particles and directly proportional to their charges.
The first step in the force calculation is the calculation of the charge for each particle. The charge of particle can decide the size of own attraction or repulsion force, and can affect the size of attraction or repulsion force of other particles.
The charge of the ith particle Xi = (θi,1, θi,2, ⋯θi,j, ⋯, θi,n) is shown as follows:
where qi is the charge for the ith particle; m is the population size; n is the dimension number of particle; f(Xi), f(Xk) and f(Xbest) denote the objective value of the ith particle, the kth particle and the best solution.
After the charge is calculated, the resultant force of the ith particle can be calculated as
where f(Xj) < f(Xi) represents attraction and f(Xj) < f(Xi) represents repulsion. As can be seen from Eq.(17) above, Fi is directly proportional to the the charge values of the particles and is inversely proportion to the distance between the ith particle and the jth particle. Because the objective value of the particle Xbest is best, it is an absolute attraction particle, and it can attract other particles.
(2) Movement of particles
Each particle moves according to the resultant force which can be given as
where ΔXi = (Δθi,1, Δθi,2, ⋯Δθi,j, ⋯Δθi,n) . λ is a random step length, which is uniformly distributed between 0 and 1. V denotes the allowed range of movement toward the lower or upper bound for the corresponding dimension.
Next step is calculating quantum rotation gate to update particles.
where denotes phase correction of jth dimension of ith particle in the t+1th iterative course; , are probability amplitudes of jth dimension of ith particle in the tth iterative course; , are probability amplitudes of jth dimension of ith particle in the t+1th iterative course.
4. Simulation Results
The applicability and validity of QEMA for practical applications has been tested on two test cases.
• Test Case 1
A system with 13 generators with value-point loading is used here to check the feasibility of QEMA. The unit characteristics like cost coefficients along with value-point loading coefficient, operating limits of generators are given in Table 1. The data shown in Table 1 are also available in [17]. The total load is 1800MW.
Table 1.Units data for test case 1
The following QEMA parameters have been used after a number of careful experimentation: Number of particles m =100; Dimension number of particles n =13.
Simulation results can be described in Table 2.
Table 2.Simulation results of case 1 for QEMA
In order to verify the performance advantages of QEMA further, the simulation results were compared with that of other optimized algorithm, and the comparison results in Table 3. Algorithm 1 is QEMA which have been applied in this paper; Algorithm 2~Algorithm 5 is evolutionary programming algorithm which have been proposed in [18]; Algorithm 6 is improved genetic algorithm which have been proposed in [19]. Algorithm 7 is EMA.
Table 3.The performance comparison of case 1 for some optimization algorithm
It can be seen from Table 3 that QEMA is superior to EMA, other evolutionary programming algorithms and improved genetic algorithm.
• Test Case 2
This case study consisted of 40 thermal units of generation with the effects of valve-point loading, as given in Table 2. The data shown in Table 4 are also available in [13]. In this case, the total load is 10500MW.
Table 4.Units data for test case 2
The following QEMA parameters have been used after a number of careful experimentation: Number of particles m =300; Dimension number of particles n =40.
Simulation results can be described in Table 5.
Table 5.Simulation results of case 2 for QEMA
In order to verify the performance advantages of QEMA further, the simulation results were compared with that of other optimized algorithm, and the comparison results in Table 6. Algorithm 1 is QEMA which have been applied in this paper; Algorithm 2 ~ Algorithm 5 are evolutionary programming algorithm which have been proposed in [13]; Algorithm 6 ~ Algorithm 9 are MPSO algorithm, ESO algorithm, GA-MU algorithm and IGAMU algorithm which have been presented in [1]. Algorithm 10 is EMA.
Table 6.The performance comparison of case 2 for some optimization algorithm
It can be seen from Table 6 that QEMA is superior to EMA and other algorithms. It can solve ELD problem effectively.
5. Conclusion
This paper presents a new algorithm called QEMA which is used to solve economic load dispatch of power system. QEMA merges quantum computing theory with electromagnetism-like mechanism algorithm. Superposition characteristic of quantum methodology can make a single particle present several states, and the characteristic potentially increases population diversity. Probability representation of quantum methodology is to make particle state be presented according to a certain probability. And the quantum rotation gates are used to realize update operation of particles. Through performance comparison, it is obvious the solution is superior to EMA and other optimization algorithm. QEMA can effectively solve ELD problem in power systems.
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