Engineering:Pareto front

In multi-objective optimization, the Pareto front (also called Pareto frontier or Pareto curve) is the set of all Pareto efficient solutions.^[1] The concept is widely used in engineering.^{[2]:111–148} It allows the designer to restrict attention to the set of efficient choices, and to make tradeoffs within this set, rather than considering the full range of every parameter.^{[3]:63–65[4]:399–412}

The Pareto frontier, P(Y), may be more formally described as follows. Consider a system with function ${\displaystyle f:X\to {\mathbb{ℝ}}^m}$, where X is a compact set of feasible decisions in the metric space ${\displaystyle {\mathbb{ℝ}}^n}$, and Y is the feasible set of criterion vectors in ${\displaystyle {\mathbb{ℝ}}^m}$, such that ${\displaystyle Y=\{y\in {\mathbb{ℝ}}^m:y=f(x),x\in X\}}$.

We assume that the preferred directions of criteria values are known. A point ${\displaystyle y^{\prime \prime }\in {\mathbb{ℝ}}^m}$ is preferred to (strictly dominates) another point ${\displaystyle y^{\prime }\in {\mathbb{ℝ}}^m}$, written as ${\displaystyle y^{\prime \prime }\succ y^{\prime }}$. The Pareto frontier is thus written as:

${\displaystyle P(Y)=\{y^{\prime }\in Y:\{y^{\prime \prime }\in Y:y^{\prime \prime }\succ y^{\prime },y^{\prime }\ne y^{\prime \prime }\}=\mathrm{\varnothing }\}.}$

A significant aspect of the Pareto frontier in economics is that, at a Pareto-efficient allocation, the marginal rate of substitution is the same for all consumers.^[5] A formal statement can be derived by considering a system with m consumers and n goods, and a utility function of each consumer as ${\displaystyle z_i=f^i(x^i)}$ where ${\displaystyle x^i=(x_1^i,x_2^i,\dots ,x_n^i)}$ is the vector of goods, both for all i. The feasibility constraint is ${\displaystyle {\displaystyle \sum _{i=1}^m}{x}_j^i=b_j}$ for ${\displaystyle j=1,\dots ,n}$. To find the Pareto optimal allocation, we maximize the Lagrangian:

${\displaystyle L_i((x_j^k{)}_{k,j},({\lambda }_k{)}_k,({\mu }_j{)}_j)=f^i(x^i)+{\displaystyle \sum _{k=2}^m}{\lambda }_k(z_k-f^k(x^k))+{\displaystyle \sum _{j=1}^n}{\mu }_j(b_j-{\displaystyle \sum _{k=1}^m}{x}_j^k)}$

where ${\displaystyle ({\lambda }_k{)}_k}$ and ${\displaystyle ({\mu }_j{)}_j}$ are the vectors of multipliers. Taking the partial derivative of the Lagrangian with respect to each good ${\displaystyle x_j^k}$ for ${\displaystyle j=1,\dots ,n}$ and ${\displaystyle k=1,\dots ,m}$ gives the following system of first-order conditions:

${\displaystyle \frac{\partial L_i}{\partial x_j^i}=f_{x_j^i}^1-{\mu }_j=0\text{ for }j=1,\dots ,n,}$

${\displaystyle \frac{\partial L_i}{\partial x_j^k}=-{\lambda }_k{f}_{x_j^k}^i-{\mu }_j=0\text{ for }k=2,\dots ,m\text{ and }j=1,\dots ,n,}$

where ${\displaystyle f_{x_j^i}}$ denotes the partial derivative of ${\displaystyle f}$ with respect to ${\displaystyle x_j^i}$. Now, fix any ${\displaystyle k\ne i}$ and ${\displaystyle j,s\in \{1,\dots ,n\}}$. The above first-order condition imply that

${\displaystyle \frac{f_{x_j^i}^i}{f_{x_s^i}^i}=\frac{{\mu }_j}{{\mu }_s}=\frac{f_{x_j^k}^k}{f_{x_s^k}^k}.}$

Thus, in a Pareto-optimal allocation, the marginal rate of substitution must be the same for all consumers.^{[citation needed]}

Algorithms for computing the Pareto frontier of a finite set of alternatives have been studied in computer science and power engineering.^[6] They include:

• "The maxima of a point set"
• "The maximum vector problem" or the skyline query^[7][8][9]
• "The scalarization algorithm" or the method of weighted sums^[10][11]
• "The ${\displaystyle ϵ}$-constraints method"^[12][13]
• Multi-objective Evolutionary Algorithms

Since generating the entire Pareto front is often computationally-hard, there are algorithms for computing an approximate Pareto-front. For example, Legriel et al.^[14] call a set S an ε-approximation of the Pareto-front P, if the directed Hausdorff distance between S and P is at most ε. They observe that an ε-approximation of any Pareto front P in d dimensions can be found using (1/ε)^d queries.

Zitzler, Knowles and Thiele^[15] compare several algorithms for Pareto-set approximations on various criteria, such as invariance to scaling, monotonicity, and computational complexity.

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