A more general case of assignment problem












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Recently I've learned hungarian algorithm for solving the assignment problem, Now I'm curious about how to solve more general problem: for given $n times m$ table select several numbers, maximizing their sum with following constraints: in each row the number of selected numbers is not less than $R_{min}$ and not more than $R_{max}$, and for each column the number of selected numbers is not less than $C_{min}$ and not more than $C_{max}$.



If $R_{min} = R_{max} = 1$ and $C_{min} = C_{max} = 1$ this is the standard assignment problem. But what can we say about more general case? Any ideas about this (maybe, at least in case $R_{min} = R_{max} = R$, $C_{min} = C_{max} = C$)? Any thoughts would be greatly appreciated.










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    1












    $begingroup$


    Recently I've learned hungarian algorithm for solving the assignment problem, Now I'm curious about how to solve more general problem: for given $n times m$ table select several numbers, maximizing their sum with following constraints: in each row the number of selected numbers is not less than $R_{min}$ and not more than $R_{max}$, and for each column the number of selected numbers is not less than $C_{min}$ and not more than $C_{max}$.



    If $R_{min} = R_{max} = 1$ and $C_{min} = C_{max} = 1$ this is the standard assignment problem. But what can we say about more general case? Any ideas about this (maybe, at least in case $R_{min} = R_{max} = R$, $C_{min} = C_{max} = C$)? Any thoughts would be greatly appreciated.










    share|cite|improve this question









    $endgroup$















      1












      1








      1





      $begingroup$


      Recently I've learned hungarian algorithm for solving the assignment problem, Now I'm curious about how to solve more general problem: for given $n times m$ table select several numbers, maximizing their sum with following constraints: in each row the number of selected numbers is not less than $R_{min}$ and not more than $R_{max}$, and for each column the number of selected numbers is not less than $C_{min}$ and not more than $C_{max}$.



      If $R_{min} = R_{max} = 1$ and $C_{min} = C_{max} = 1$ this is the standard assignment problem. But what can we say about more general case? Any ideas about this (maybe, at least in case $R_{min} = R_{max} = R$, $C_{min} = C_{max} = C$)? Any thoughts would be greatly appreciated.










      share|cite|improve this question









      $endgroup$




      Recently I've learned hungarian algorithm for solving the assignment problem, Now I'm curious about how to solve more general problem: for given $n times m$ table select several numbers, maximizing their sum with following constraints: in each row the number of selected numbers is not less than $R_{min}$ and not more than $R_{max}$, and for each column the number of selected numbers is not less than $C_{min}$ and not more than $C_{max}$.



      If $R_{min} = R_{max} = 1$ and $C_{min} = C_{max} = 1$ this is the standard assignment problem. But what can we say about more general case? Any ideas about this (maybe, at least in case $R_{min} = R_{max} = R$, $C_{min} = C_{max} = C$)? Any thoughts would be greatly appreciated.







      optimization algorithms linear-programming






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      asked May 13 '16 at 23:14









      SwistackSwistack

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      425211






















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          The general case can be modeled as a flow problem in a bipartite graph $G=(V_1cup V_2,E)$, with $|V_1|=n$ and $|V_2|=m$.



          To take into account your constraints, add a source $s$ and link to all vertices of $V_1$, and a sink $t$, linked to all vertices of $V_2$. Impose that the entering flow in each node of $V_1$ is at least $R_{min}$ and at most $R_{max}$, and that the exiting flow from each node of $V_2$ is at least $C_{min}$ and at most $C_{max}$, and you are done.






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            $begingroup$

            The general case can be modeled as a flow problem in a bipartite graph $G=(V_1cup V_2,E)$, with $|V_1|=n$ and $|V_2|=m$.



            To take into account your constraints, add a source $s$ and link to all vertices of $V_1$, and a sink $t$, linked to all vertices of $V_2$. Impose that the entering flow in each node of $V_1$ is at least $R_{min}$ and at most $R_{max}$, and that the exiting flow from each node of $V_2$ is at least $C_{min}$ and at most $C_{max}$, and you are done.






            share|cite|improve this answer









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              1












              $begingroup$

              The general case can be modeled as a flow problem in a bipartite graph $G=(V_1cup V_2,E)$, with $|V_1|=n$ and $|V_2|=m$.



              To take into account your constraints, add a source $s$ and link to all vertices of $V_1$, and a sink $t$, linked to all vertices of $V_2$. Impose that the entering flow in each node of $V_1$ is at least $R_{min}$ and at most $R_{max}$, and that the exiting flow from each node of $V_2$ is at least $C_{min}$ and at most $C_{max}$, and you are done.






              share|cite|improve this answer









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                1





                $begingroup$

                The general case can be modeled as a flow problem in a bipartite graph $G=(V_1cup V_2,E)$, with $|V_1|=n$ and $|V_2|=m$.



                To take into account your constraints, add a source $s$ and link to all vertices of $V_1$, and a sink $t$, linked to all vertices of $V_2$. Impose that the entering flow in each node of $V_1$ is at least $R_{min}$ and at most $R_{max}$, and that the exiting flow from each node of $V_2$ is at least $C_{min}$ and at most $C_{max}$, and you are done.






                share|cite|improve this answer









                $endgroup$



                The general case can be modeled as a flow problem in a bipartite graph $G=(V_1cup V_2,E)$, with $|V_1|=n$ and $|V_2|=m$.



                To take into account your constraints, add a source $s$ and link to all vertices of $V_1$, and a sink $t$, linked to all vertices of $V_2$. Impose that the entering flow in each node of $V_1$ is at least $R_{min}$ and at most $R_{max}$, and that the exiting flow from each node of $V_2$ is at least $C_{min}$ and at most $C_{max}$, and you are done.







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                share|cite|improve this answer










                answered May 14 '16 at 2:22









                KuifjeKuifje

                7,2722726




                7,2722726






























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