partial order
Hierarchical Partial-Order Models for Ranking
Li, Dongqing, Nicholls, Geoff K., Lee, Jeong Eun, Chuxuan, null, Jiang, null
Rank aggregation combines information from ordered lists ranking items by preference. Classical parametric models for such data, including the Mallows and Plackett-Luce models, assume the orders concentrate around one or more complete consensus rankings. Recent work relaxes the total-order assumption by allowing the consensus structure to be a partial order (poset), allowing for incomparabilities in preferences. However, in many applications preference data exhibit group structure. We introduce hierarchical partial order (HPO) models, which extend poset-based models to accommodate grouped data through a hierarchy of latent posets. This framework, which parallels mixture model extensions of the Mallows and Plackett-Luce models, enables principled sharing of information across groups while preserving partial-order structure. We show that the Plackett-Luce model and its hierarchical variants are special cases of HPO-models. We develop a hierarchical clustering extension (HCPO) for unsupervised clustering in settings where group labels are unknown. Bayesian inference for the latent poset hierarchy is performed using Markov chain Monte Carlo methods. Experiments on synthetic and real-world datasets, including pairwise acoustic preference data and LLM agent traces, demonstrate that the proposed HPO and HCPO models outperform existing approaches in both predictive performance and structural interpretability.
Median Selection with Noisy and Structural Information
We study the problem of computing the exact median by leveraging side information to minimize costly, exact comparisons. We analyze this problem in two key settings: (1) using predictions from unreliable "weak" oracles, and (2) exploiting known structural information in the form of a partial order. In the classical setting, we introduce a modified LazySelect algorithm that combines weak comparisons with occasional strong comparisons through majority voting. We show that this hybrid strategy has near-linear running time and can achieve high-probability correctness using only sublinear strong comparisons, even when the weak oracle is only slightly better than random guessing. Our theoretical results hold under the persistent comparison model, where resampling will not amplify the probability of correctness. In the partially ordered setting, we generalize the notion of median to directed acyclic graphs (DAGs) and show that the complexity of median selection depends heavily on the DAG's width. We complement our analysis with extensive experiments on synthetic data.
A Differentiable Bayesian Relaxation for Latent Partial-Order Inference
Li, Dongqing, Nicholls, Geoff K., Sun, Shiyi, Luo, You
Rank-data and action-trace datasets are typically recorded as linear sequences, although the constraints governing valid outcomes are often only partially ordered. These constraints may be temporal or process-based [24, 23, 16], causal [5], or dominance-based [28], and are usually not observed directly. Inferring them is important because they encode interpretable structure and support feasibility evaluation on new sequences. In these settings, however, the underlying relation is often incomplete: the latent structure is a partial order, or poset, in which pairs of items that can occur in either order have no precedence relation. Consequently, an observed order need not imply a true prerequisite relation; it may reflect scheduling, logging, or a single valid linearization of the latent partial order. Treating all observed precedences as real can therefore produce overly sequential and unrealistic structures, especially in workflow or LLM-agent settings where unnecessary ordering induces extra execution steps and compute.
Pard: Permutation-Invariant Autoregressive Diffusion for Graph Generation
Graph generation has been dominated by autoregressive models due to their simplicity and effectiveness, despite their sensitivity to ordering. Yet diffusion models have garnered increasing attention, as they offer comparable performance while being permutation-invariant. Current graph diffusion models generate graphs in a one-shot fashion, but they require extra features and thousands of denoising steps to achieve optimal performance. We introduce PARD, a Permutation-invariant Auto Regressive Diffusion model that integrates diffusion models with autoregressive methods.
PARD: Permutation-invariantAutoregressiveDiffusion forGraphGeneration
Specifically, we show that contrary to sets, elements in a graph are not entirely unordered and there is a unique partial order for nodes and edges. With this partial order,PARD generates a graph in a block-by-block, autoregressivefashion, where each block'sprobability isconditionally modeled by a shared diffusion model with an equivariant network.