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Fractional List Packing for Layered Graphs: Exploring Bounds and Algorithmic Implications


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This research paper explores the fractional list packing number (χℓp) and fractional correspondence packing number (χcp) for layered graphs, demonstrating that these parameters can be bounded by graph width measures like treedepth and pathwidth, leading to improved bounds on flexible list coloring.
Kivonat
  • Bibliographic Information: Cambie, S., & Cames van Batenburg, W. (2024). Fractional list packing for layered graphs. arXiv preprint arXiv:2410.02695v1.
  • Research Objective: This paper investigates the fractional list packing number (χℓp) and fractional correspondence packing number (χcp) for various classes of layered graphs, aiming to establish upper bounds based on structural properties like treedepth and pathwidth.
  • Methodology: The authors employ a combinatorial approach, utilizing inductive arguments and probabilistic methods to analyze the behavior of χℓp and χcp in the context of layered graph decompositions. They leverage existing tools like Lemma 3.7, which provides conditions for the existence of fractional packings in correspondence covers.
  • Key Findings: The paper demonstrates that for a graph G: (1) χcp(G) is bounded by its treedepth, (2) χcp(G) is bounded by its pathwidth plus one, and (3) for the Cartesian product of graphs G1 and G2, χℓp(G1 x G2) and χcp(G1 x G2) are bounded by χℓp(G1) + Δ(G2) and χcp(G1) + Δ(G2) respectively, where Δ(G2) represents the maximum degree of G2.
  • Main Conclusions: The findings provide new insights into the relationship between fractional packing numbers and graph width parameters. Notably, the results imply that graphs with bounded treedepth or pathwidth admit weighted flexible list colorings with specific guarantees.
  • Significance: This research contributes to the understanding of fractional graph packing and its connections to graph structure, with implications for flexible list coloring and potential applications in algorithmic graph theory.
  • Limitations and Future Research: The authors acknowledge that the optimal bounds on χℓp and χcp in terms of degeneracy remain open questions. Further research could explore tighter bounds for specific graph classes and investigate the algorithmic complexity of determining these parameters.
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Statisztikák
χℓp(G) ≤ χcp(G) ≤ χ′cp(G) for any graph G. χcp(Kn) ≥ n+1 for complete graphs Kn with odd n. There exist bipartite d-degenerate graphs with χ′c = 2d for all d ≥ 1. There are d-degenerate graphs with χℓ ≥ d + 2 for all d ≥ 2. For a graph G with pathwidth 2, χcp(G) ≤ 3.
Idézetek
"If χcp(G) ≤ k for some integer k, then G is weighted 1/k-flexibly k-choosable." "While a degeneracy ordering is thus not universally adequate for (fractional) packing numbers, in this work we identify a type of layering that does always work for χcp."

Főbb Kivonatok

by Stijn Cambie... : arxiv.org 10-04-2024

https://arxiv.org/pdf/2410.02695.pdf
Fractional list packing for layered graphs

Mélyebb kérdések

Can the bounds on fractional packing numbers derived from treedepth and pathwidth be utilized to develop efficient algorithms for finding flexible list colorings in these graph classes?

Answer: Yes, the bounds on fractional packing numbers derived from treedepth and pathwidth can indeed guide the development of efficient algorithms for finding flexible list colorings in these graph classes. Here's how: 1. Treedepth: Key Insight: Theorem 2.2 establishes that χc*(G) ≤ td(G), meaning a graph with treedepth k is weighted 1/k-flexibly k-choosable. This implies that for any k-fold list assignment, a probability distribution over proper colorings exists where each color appears at each vertex with probability 1/k. Algorithmic Implication: This probabilistic interpretation motivates a randomized algorithm. By repeatedly sampling colorings from this distribution (which can be done efficiently given a treedepth decomposition), we can obtain a list coloring that is likely to satisfy a significant portion of pre-coloring requests. The success probability is directly tied to the weighted flexibility guarantee (1/k in this case). 2. Pathwidth: Key Insight: Theorem 2.3 provides a similar bound for pathwidth: χc*(G) ≤ pw(G) + 1. This implies weighted 1/(pw(G) + 1)-flexible (pw(G) + 1)-choosability. Algorithmic Implication: The connection to pathwidth is even more conducive to algorithmic design. Path decompositions naturally lend themselves to dynamic programming approaches. We can process the bags of the path decomposition sequentially, building up partial colorings and ensuring that at each step, the probability distribution of colors at the interface vertices aligns with the desired flexibility. Important Considerations: Finding Decompositions: Efficient algorithms for computing optimal treedepth and pathwidth decompositions are crucial for these strategies to be practically viable. Approximation: In cases where finding optimal decompositions is computationally expensive, approximate decompositions can still yield useful bounds and guide the design of heuristic algorithms.

While the paper focuses on upper bounds, are there corresponding lower bounds on χℓ(G) and χc(G) that can be established in terms of other graph parameters, potentially shedding light on the tightness of the existing results?

Answer: Yes, establishing lower bounds on χℓ(G) and χc(G) in relation to other graph parameters is essential for understanding the tightness of the upper bounds. Here are some approaches and relevant parameters: 1. Clique Number (ω(G)): Key Relationship: χℓ(G) ≥ χ(G) ≥ ω(G). The list chromatic number is always at least the chromatic number, which in turn is always at least the size of the largest clique in the graph. Implication: This provides a simple yet powerful lower bound. If a graph contains a large clique, its list chromatic number (and consequently, its fractional list packing number) cannot be smaller. 2. Girth (g(G)): Key Relationship: For graphs with high girth (length of the shortest cycle), probabilistic arguments can be used to establish lower bounds on χℓ(G). This is because in graphs with large girth, locally the graph appears acyclic, allowing for more flexibility in constructing adversarial list assignments. Examples: Explicit constructions of graphs with high girth and high chromatic number (and hence, high list chromatic number) are known. 3. Fractional Chromatic Number (χf(G)): Key Relationship: χℓ(G) ≥ χf(G). The fractional chromatic number provides a lower bound on the list chromatic number. Implication: This connection is particularly relevant when dealing with graphs where the fractional chromatic number is significantly larger than the clique number, such as Kneser graphs or certain random graphs. 4. Other Parameters: Independence Number (α(G)): A lower bound can sometimes be derived by considering the relationship χ(G) ≥ |V(G)| / α(G). Connectivity: Highly connected graphs tend to have higher chromatic numbers. Tightness of Existing Results: Comparing Upper and Lower Bounds: By establishing lower bounds using these parameters, we can assess how close the upper bounds derived from treedepth, pathwidth, or other structural properties are to being tight. Identifying Gaps: Discrepancies between the upper and lower bounds highlight potential areas for further research and refinement of our understanding of these coloring parameters.

Given the connection between fractional packing and the distribution of colors in proper colorings, how can these findings be applied to problems involving resource allocation or scheduling, where a balanced distribution is desirable?

Answer: The concept of fractional packing, particularly in the context of fractional list-coloring, has direct and insightful applications in resource allocation and scheduling problems where achieving a balanced distribution is crucial. Here's how: 1. Modeling Resources and Tasks: Resources as Colors: Imagine a scenario where you have a set of resources (e.g., time slots, frequencies, machines) represented by colors. Tasks as Vertices: Tasks or processes that require these resources can be modeled as vertices in a graph. Conflicts as Edges: An edge between two vertices indicates that the corresponding tasks cannot be assigned the same resource simultaneously (due to conflicts or constraints). 2. Fractional Packing for Balanced Allocation: Flexibility and Fairness: Fractional packing, as captured by the fractional list packing number χℓ(G), provides a measure of how flexibly we can assign resources while ensuring a certain degree of balance. A low χℓ(G) implies that even with limited resource availability (represented by list sizes), we can find assignments where each resource is used relatively evenly across tasks. Probability Distribution as Allocation Strategy: The probability distribution over proper colorings inherent in the definition of fractional packing can be interpreted as a randomized resource allocation strategy. By sampling from this distribution, we obtain allocations that are likely to be both feasible (respecting conflicts) and balanced. 3. Concrete Applications: Frequency Assignment in Wireless Networks: Allocate frequency bands to wireless devices (vertices) while minimizing interference (edges). Fractional packing can help ensure fair and balanced spectrum usage. Job Scheduling on Machines: Assign tasks (vertices) to machines (colors) with varying processing times (list sizes) while minimizing the makespan (completion time of the last task). Fractional packing can guide the development of scheduling algorithms that balance the load across machines. Time Slot Allocation in Time-Division Multiple Access (TDMA): Allocate time slots to users in a communication system to maximize throughput while ensuring fairness. Fractional packing can help design TDMA schemes that distribute time slots equitably. Advantages of Fractional Packing Approach: Robustness: Handles situations where resources are limited and demands may vary. Fairness: Promotes balanced resource utilization, preventing starvation or overload. Flexibility: Allows for probabilistic allocation strategies, which can be advantageous in dynamic or uncertain environments.
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