背包问题最优解的结构

讨论背包问题的最优解,引入背包问题的阶的概念,并对背包问题的阶作出深入的讨论,在此基础上得到背包问题的最优解的一般形式。     

求解0-1背包问题的混合贪婪遗传算法

求解0-1背包问题（KP）的最优解的时候,传统遗传算法（GA）的局部求精能力不足而简单局部搜索算法的全局探索能力有限,针对上述问题,将这两个算法整合并提出了混合贪婪遗传算法（HGGA）。在GA全局搜索框架下增加局部搜索模块,并改进传统仅基于物品价值密度的修复算子,增加基于物品价值的贪婪混合选项,从而加速寻优过程。HGGA一方面引导种群在进化的优质解空间中展开精细搜索,另一方面依靠GA的经典操作算子开拓全局搜索空间,从而达到算法求精能力和开拓能力的良好平衡。HGGA分别在三组数据上做了测试,结果表明在第一组15个测试用例中的12个上,HGGA能够百分百找到最优解,成功率达到80%;在第二组小规模数据集上,HGGA的性能明显好于其他同类GA和其他元启发算法;在第三组大规模数据集上,HGGA较其他元启发式算法具有更好的稳定性和高效性。     

改进蚁群优化算法求解折扣{0-1}背包问题

折扣{0-1}背包问题（Discounted {0-1} Knapsack Problem,DKP）是一个NP-困难的组合优化问题,尽管已经存在一些求解DKP的智能优化算法,但目前尚没有用蚁群优化（Ant Colony Optimization,ACO）算法求解DKP的研究。提出了一个求解DKP的改进ACO（Modified ACO,MACO）算法。MACO算法使用整数编码以保证每组物品最多只有一个物品被选中,在MACO算法构造解的每一步,采用组内竞争选择来降低算法的时间复杂性,对计算选择概率的公式,放弃启发式信息以减少参数并简化算法参数设置,对蚂蚁构造出的解,经修复后使用基于价值密度和价值的混合贪婪优化算子来提高算法的寻优能力。在四类测试用例上对MACO算法进行了测试并与其他算法进行比较,实验结果表明MACO算法的性能明显优于其他算法。     

随机背包公钥密码的分析与改进

针对随机背包公钥密码方案,提出一种私钥恢复攻击方法.发现Wang等人所构造的随机背包公钥方案实际上是隐含使用了一个特殊的超递增背包.通过使用普通超递增背包代替该特殊超递增背包,将超递增背包隐藏在随机选择的背包中,对原方案进行了改进,提出一种新的基于中国剩余定理的背包公钥密码方案.改进后的方案消除了原方案存在的设计缺陷,能够抵抗针对原方案提出的格规约攻击、低密度攻击以及shamir攻击.     

基于蚁群混沌行为的离散粒子群算法及其应用

考虑蚁群算法与粒子群算法的各自特点,在粒子群算法的基础上借鉴蚁群算法的信息素机制,对粒子群算法的速度位置更新公式重新定义,提出了一种基于蚁群混沌行为的离散粒子群算法,并将其应用到背包问题中。实验结果表明,该算法可以得到较优解。     

Hard multidimensional multiple choice knapsack problems, an empirical study

Recent advances in algorithms for the multidimensional multiple choice knapsack problems have enabled us to solve rather large problem instances. However, these algorithms are evaluated with very limited benchmark instances. In this study, we propose new methods to systematically generate comprehensive benchmark instances. Some instances with special correlation properties between parameters are found to be several orders of magnitude harder than those currently used for benchmarking the algorithms. Experiments on an existing exact algorithm and two generic solvers show that instances whose weights are uncorrelated with the profits are easier compared with weakly or strongly correlated cases. Instances with classes containing similar set of profits for items and with weights strongly correlated to the profits are the hardest among all instance groups investigated. These hard instances deserve further study and understanding their properties may shed light to better algorithms.     

A study on a quantum-inspired evolutionary algorithm based on pair swap

A quantum-inspired evolutionary algorithm (QEA) is proposed as a stochastic algorithm to perform combinatorial optimization problems. The QEA is evolutionary computation that uses quantum bits and superposition states in quantum computation. Although the QEA is a coarse-grained parallel algorithm, it involves many parameters that must be adjusted manually. This paper proposes a new method, named pair swap, which exchanges each best solution information between two individuals instead of migration in the QEA. Experimental results show that our proposed method is a simpler algorithm and can find a high quality solution in the 0-1 knapsack problem. This work was presented in part at the 12th International Symposium on Artificial Life and Robotics, Oita, Japan, January 25–27, 2007     

A computational study on the quadratic knapsack problem with multiple constraints

The quadratic knapsack problem (QKP) has been the subject of considerable research in recent years. Despite notable advances in special purpose solution methodologies for QKP, this problem class remains very difficult to solve. With the exception of special cases, the state-of-the-art is limited to addressing problems of a few hundred variables and a single knapsack constraint.In this paper we provide a comparison of quadratic and linear representations of QKP based on test problems with multiple knapsack constraints and up to eight hundred variables. For the linear representations, three standard linearizations are investigated. Both the quadratic and linear models are solved by standard branch-and-cut optimizers available via CPLEX. Our results show that the linear models perform well on small problem instances but for larger problems the quadratic model outperforms the linear models tested both in terms of solution quality and solution time by a wide margin. Moreover, our results demonstrate that QKP instances larger than those previously addressed in the literature as well as instances with multiple constraints can be successfully and efficiently solved by branch and cut methodologies.     

一种求解背包问题的混合差异演化算法

为增强差异演化算法在求解背包问题时的局部搜索能力,提出拉马克-鲍德温混合差异演化算法。该算法采用双种群协同进化,以差异演化算法为主体,在演化过程中分别引入拉马克进化和鲍德温效应2种局部搜索算子,引导种群进化方向。仿真实验结果表明,该算法求解精度高,收敛速度快,能够高效求解背包问题。     

基于蚁群系统的多选择背包问题优化算法

提出了一种用蚁群系统求解多选择背包问题的优化算法。该方法利用蚂蚁算法所具有的正反馈特性，再结合变异参数，使算法既有较快的求解速度又有较高的求解精度。实验结果表明，采用此算法能快速有效地解决背包问题。