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- Sat Oct 21, 2017 1:47 pm
#40817
Setup and Rule Diagram Explanation
This is an Advanced Linear: Unbalanced: Overloaded, Numerical Distribution, Identify the Templates game.
The game scenario establishes that seven departments of a law firm are distributed over three floors of an office building. With seven departments for three floors, you should immediately watch for rules and conditions that help establish numerical guidelines for each floor.
While the game scenario establishes a maximum of four departments per floor, there is no clear stipulation that there must be a department on each floor. However, the rules work in a manner that establishes that there is always at least one department per floor.
The initial scenario appears as follows:
The first rule establishes a horizontal PT block:
The second rule creates a vertical block:
The third rule stipulates that L must occupy a floor by itself:
F and S are thus randoms.
These rules, while individually simple, interact in powerful ways. The most powerful interaction is between the blocks created in the second and third rules. Because the HI block is stretched across two floors, and L is alone on its floor, these blocks cannot overlap. Thus, there are only two basic scenarios that can occur:
Thus, just from the interaction of these two rules, each of the floors must have at least one department assigned to it. Of course, the placement of L then affects all of the remaining departments, including the PT block, F, and S. Of particular note, the PT block is limited to two positions in each scenario, leaving just F and S uncertain (although limited too, of course, as they cannot be assigned to the same floor as L). More sub-templates could be made, but the rules seem clear enough that making those extra templates seems like it could be wasteful; if a scenario is needed in a question, you can simply make it at that time.
At the start of the analysis, the numerical restrictions were mentioned. Let us revisit those now that we have a better understanding of the game.
The numerical distribution in this game must account for seven departments assigned to three floors, with a minimum of one department per floor, and a maximum of four departments per floor. One of the floors must always have exactly one department (L). Thus, only two partially unfixed numerical distributions exist of departments to floors:
With the two distributions identified, let us examine each more closely, as many of the variables can be determined within each distribution.
Distribution #1: 4 - 2 - 1
In the 4-2-1, the floor with 1 department is L, as L occupies an entire floor. Because H and I are on different floors, they then occupy one space within the floors with 2 and 4 departments. This forces the PT block onto the floor with 4 departments (as there is not enough remaining spaces on the floor with 2 departments), leaving F and S to rotate between the floors with 2 and 4 departments. Thus, the composition of each group is largely determined:
Distribution #2: 3 - 3 - 1
In the 3-3-1, the 1 is L, as L occupies an entire floor. Because H and I are in different floors, they then occupy one space within the 3 and 3 groups. This forces the PT block onto one of the floors with 3 departments, leaving F and S to fill the other floor with 3 departments. Thus, the composition of each group is again largely determined:
This is an Advanced Linear: Unbalanced: Overloaded, Numerical Distribution, Identify the Templates game.
The game scenario establishes that seven departments of a law firm are distributed over three floors of an office building. With seven departments for three floors, you should immediately watch for rules and conditions that help establish numerical guidelines for each floor.
While the game scenario establishes a maximum of four departments per floor, there is no clear stipulation that there must be a department on each floor. However, the rules work in a manner that establishes that there is always at least one department per floor.
The initial scenario appears as follows:
The first rule establishes a horizontal PT block:
The second rule creates a vertical block:
The third rule stipulates that L must occupy a floor by itself:
F and S are thus randoms.
These rules, while individually simple, interact in powerful ways. The most powerful interaction is between the blocks created in the second and third rules. Because the HI block is stretched across two floors, and L is alone on its floor, these blocks cannot overlap. Thus, there are only two basic scenarios that can occur:
Thus, just from the interaction of these two rules, each of the floors must have at least one department assigned to it. Of course, the placement of L then affects all of the remaining departments, including the PT block, F, and S. Of particular note, the PT block is limited to two positions in each scenario, leaving just F and S uncertain (although limited too, of course, as they cannot be assigned to the same floor as L). More sub-templates could be made, but the rules seem clear enough that making those extra templates seems like it could be wasteful; if a scenario is needed in a question, you can simply make it at that time.
At the start of the analysis, the numerical restrictions were mentioned. Let us revisit those now that we have a better understanding of the game.
The numerical distribution in this game must account for seven departments assigned to three floors, with a minimum of one department per floor, and a maximum of four departments per floor. One of the floors must always have exactly one department (L). Thus, only two partially unfixed numerical distributions exist of departments to floors:
With the two distributions identified, let us examine each more closely, as many of the variables can be determined within each distribution.
Distribution #1: 4 - 2 - 1
In the 4-2-1, the floor with 1 department is L, as L occupies an entire floor. Because H and I are on different floors, they then occupy one space within the floors with 2 and 4 departments. This forces the PT block onto the floor with 4 departments (as there is not enough remaining spaces on the floor with 2 departments), leaving F and S to rotate between the floors with 2 and 4 departments. Thus, the composition of each group is largely determined:
Distribution #2: 3 - 3 - 1
In the 3-3-1, the 1 is L, as L occupies an entire floor. Because H and I are in different floors, they then occupy one space within the 3 and 3 groups. This forces the PT block onto one of the floors with 3 departments, leaving F and S to fill the other floor with 3 departments. Thus, the composition of each group is again largely determined:
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Dave Killoran
PowerScore Test Preparation
Follow me on X/Twitter at http://twitter.com/DaveKilloran
My LSAT Articles: http://blog.powerscore.com/lsat/author/dave-killoran
PowerScore Podcast: http://www.powerscore.com/lsat/podcast/
PowerScore Test Preparation
Follow me on X/Twitter at http://twitter.com/DaveKilloran
My LSAT Articles: http://blog.powerscore.com/lsat/author/dave-killoran
PowerScore Podcast: http://www.powerscore.com/lsat/podcast/
