Dunam Kim

Dunam Kim, Jeeeun Kim

We propose a new technique for computational language representation called elementwise embedding, in which a material (semantic unit) is abstracted into a horizontal concatenation of lower-dimensional element (character) embeddings. While elements are always characters, materials are arbitrary levels of semantic units so it generalizes to any type of tokenization. To focus only on the important letters, the $n^{th}$ spellings of each semantic unit are aligned in $n^{th}$ attention heads, then concatenated back into original forms creating unique embedding representations; they are jointly projected thereby determining own contextual importance. Technically, this framework is achieved by passing a sequence of materials, each consists of $v$ elements, to a transformer having $h=v$ attention heads. As a pure embedding technique, elementwise embedding replaces the $w$-dimensional embedding table of a transformer model with $256$ $c$-dimensional elements (each corresponding to one of UTF-8 bytes) where $c=w/v$. Using this novel approach, we show that the standard transformer architecture can be reused for all levels of language representations and be able to process much longer sequences at the same time-complexity without "any" architectural modification and additional overhead. BERT trained with elementwise embedding outperforms its subword equivalence (original implementation) in multilabel patent document classification exhibiting superior robustness to domain-specificity and data imbalance, despite using $0.005\%$ of embedding parameters. Experiments demonstrate the generalizability of the proposed method by successfully transferring these enhancements to differently architected transformers CANINE and ALBERT.

Sohee Kim, Jisu Kang, Dunam Kim et al.

In this paper, we demonstrate that CLIP can also be adapted to downstream tasks where its vision-language alignment is suboptimally learned during pre-training on web-crawled data, all without requiring fine-tuning. We explore the case of monocular depth estimation, where CLIP's contrastive prior struggles to generalize, compared to its success in domains such as generative modeling and semantic segmentation. Since CLIP fails to consistently capture similarities between image patches and natural language prompts describing distance, we eliminate the use of its pre-trained natural language token embeddings and distill the semantic prior of its frozen text encoder into a single learnable embedding matrix called "mirror". The main design goal of mirror is to derive a non-human language prompt that approximates an optimal natural language prompt: "How far is this location from the camera?" Using this approach, we jointly train two lightweight modules, a mirror and a compact decoder, on top of a frozen CLIP for dense depth prediction. Compared to conventional depth models, our framework is significantly more efficient in terms of parameters and computation. The resulting model exhibits impressive performance, matching several state-of-the-art vision models on the NYU Depth v2 and KITTI benchmark datasets, while outperforming all vision-language depth models based on a frozen CLIP prior. Experiments demonstrate that the suboptimal depth understanding of CLIP in terms of spatial and temporal consistency can be significantly corrected without either fine-tuning it or concatenating mirror with its pre-trained subword token embeddings. Furthermore, an ablation study on the convergence status of mirror shows that it is implicitly trained to capture objects, such as humans and windows, where semantic cues play an important role in detection.