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Main Authors: Suissa, Omri, Ali, Muhiim, Chen, Shengmai, Cai, Yinuo, Pradhan, Shekhar
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.12771
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author Suissa, Omri
Ali, Muhiim
Chen, Shengmai
Cai, Yinuo
Pradhan, Shekhar
author_facet Suissa, Omri
Ali, Muhiim
Chen, Shengmai
Cai, Yinuo
Pradhan, Shekhar
contents Humans can recognize an image as an instance of a general concept, beyond simply identifying its objects and their relationships. In this paper, we investigate 1. The extent to which VLMs have this concept abstraction capacity, and 2. Strategies for encoding the sort of higher-concept information in images that would enable the resulting VLM model (CLEAR GLASS model) to have this capability to a greater degree. To this end, we introduce a grouped image-caption dataset (MAGIC), which consists of several groups of image captions and for each group a set of associated images and higher-level conceptual labels. We use a novel contrastive loss technique to induce the model to encode in the representation of each image (caption) in a group the information that is common to all members of the image-caption group. Our main contribution is a grouped contrastive loss function based on text-image contrastive groups (outer contrastive loss) as well as an inner loss which measures the distances between image-caption instances in the group. Our training methodology results in the CLEAR GLASS model having the concept abstraction capacity as an emergent capacity because the model is not exposed to the higher-level concepts associated with each group. Instead, the training forces the model to create for each image-caption group a semantic representation that brings it closer to the semantic representation of the higher-level concepts in the latent semantic space. Our experiments show that this training methodology results in a model which shows improvement in abstract concept recognition compared to SOTA models.
format Preprint
id arxiv_https___arxiv_org_abs_2509_12771
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Contrastive Learning with Enhanced Abstract Representations using Grouped Loss of Abstract Semantic Supervision
Suissa, Omri
Ali, Muhiim
Chen, Shengmai
Cai, Yinuo
Pradhan, Shekhar
Computation and Language
Humans can recognize an image as an instance of a general concept, beyond simply identifying its objects and their relationships. In this paper, we investigate 1. The extent to which VLMs have this concept abstraction capacity, and 2. Strategies for encoding the sort of higher-concept information in images that would enable the resulting VLM model (CLEAR GLASS model) to have this capability to a greater degree. To this end, we introduce a grouped image-caption dataset (MAGIC), which consists of several groups of image captions and for each group a set of associated images and higher-level conceptual labels. We use a novel contrastive loss technique to induce the model to encode in the representation of each image (caption) in a group the information that is common to all members of the image-caption group. Our main contribution is a grouped contrastive loss function based on text-image contrastive groups (outer contrastive loss) as well as an inner loss which measures the distances between image-caption instances in the group. Our training methodology results in the CLEAR GLASS model having the concept abstraction capacity as an emergent capacity because the model is not exposed to the higher-level concepts associated with each group. Instead, the training forces the model to create for each image-caption group a semantic representation that brings it closer to the semantic representation of the higher-level concepts in the latent semantic space. Our experiments show that this training methodology results in a model which shows improvement in abstract concept recognition compared to SOTA models.
title Contrastive Learning with Enhanced Abstract Representations using Grouped Loss of Abstract Semantic Supervision
topic Computation and Language
url https://arxiv.org/abs/2509.12771