Sun Dec 8th through Sat the 14th, 2019 at Vancouver Convention Center
Summary - The proposed approach to image captioning extends two prior works, object-based Up-Down method of  and Transformer of  (already used for image captioning in ). Specifically, the authors integrate spatial relations between objects in the captioning Transformer model, proposing the Object Relation Transformer. The modification amounts to introducing an object relation module  into the encoding layer of the Transformer model. - The authors evaluate the proposed approach on the Karpathy split of MSCOCO dataset, demonstrating state-of-the-art performance on automatic metrics, in particular in CIDEr-D score. (The compared approaches only include Att2All  and Up-Down .) - A few ablations and baselines are present, including comparison to a standard Transformer model. Tests of statistical significance show that the proposed model outperforms the standard Transformer in terms of CIDEr-D, BLEU-1 and ROUGE-L, while SPICE-attribute breakdown shows improvement for Relation and Count categories. Qualitative results include examples where Object Relation Transformer leads to more correct spatial Relation and Count predictions. Originality - The proposed approach combines ideas from [2,9,22] in a straightforward manner. - Several prior works are not cited [A,B,C,D]. [A] proposed context-aware visual policy network, significantly improving over Up-Down. [B] introduced a GCN-LSTM model which integrates semantic and spatial object relationships. [C] further made use of scene graphs to integrate object, attribute, and relationship knowledge. Finally, recently [D] proposed “relational captioning”, a new task where multiple captions need to be generated for an image to summarize different relationships present in the image. Comparison to these works, both conceptual and empirical is necessary. [A] D. Liu, Z.-J. Zha, H. Zhang, Y. Zhang, and F. Wu. Context-aware visual policy network for sequence-level image captioning. In 2018 ACM Multimedia Conference on Multimedia Conference, pages 1416–1424. ACM, 2018. [B] T. Yao, Y. Pan, Y. Li, and T. Mei. Exploring visual relationship for image captioning. In Computer Vision–ECCV 2018, pages 711–727. Springer, 2018. [C] Yang, Xu, et al. "Auto-encoding scene graphs for image captioning." Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. 2019. [D] Kim, Dong-Jin, et al. "Dense relational captioning: Triple-stream networks for relationship-based captioning." Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. 2019. Quality - The proposed approach appears technically sound, as it extends prior work in a straightforward manner. - The very similar prior work , which also utilized Transformer for image captioning, is cited, but no empirical comparison is included. Also, recent results from other works are not included [A,B,C]. - Although comparison to state-of-the-art is incomplete (see above), the authors provide an informative ablation/baseline study, including tests of statistical significance, etc. - No evaluation on the online MSCOCO test server is included. The online test set is meant to demonstrates models’ performance in a blind scenario, where overfitting is less likely. - No human evaluation is included, although the authors are aware that some of the automatic metrics poorly reflect human preference (L178); in fact, all automatic metrics fall short of capturing human preference, thus human evaluation is desirable. - It would have been interesting to see some failure cases in additional to the presented (cherry-picked) success cases, or to see some discussion on that. Clarity - The paper is clearly written and was mostly easy to follow. - I do not find Figure 1 helpful in terms of illustrating the proposed approach, e.g. no explicit visualization of spatial relationships is present. The main idea is not obvious from looking at this figure. - It is somewhat confusing that different tables reflect different settings, e.g. with/without self-critical training, with beam size 5, 2 or 1 (?), and it is not always clear which case is shown and how different numbers in different tables relate to each other. - It would also be helpful to report the two standard settings, with beam size 5 with/without self-critical training, compared side-by-side, as in . Significance - The idea of harnessing spatial relations for image captioning is not new [B,C]. The proposed approach is not particularly technically innovative, but appears quite effective. The overall improvement over prior work  is impressive, but in comparison to more recent works [A,B,C], the results are on par / only marginally better. Thus, I rate the significance of the presented contributions as Medium/Low. UPDATE The authors did not include empirical comparison to prior work [A,B,C] or human evaluation, promising to do so in the final version. The results on the test server are not put in context with any of the baselines. With neither a clear comparison to state-of-the-art [A,B,C], nor human evaluation (which is always desirable for tasks like captioning), I am not convinced about the overall significance/impact of the proposed method.
1) Originality: The authors propose an incremental modification to the transformer network which accounts for spatial relationship between the objects. The ideas of using transformer encoder+decoder architecture, pre-training the network with cross-entropy loss and fine-tuning in self-critical setup using CIDER scores with rollout as reward are borrowed from previous literature. 2) Quality: The proposed modification i.e. the geometric attention weights are supposed to encode geometric relationships between objects. The accuracy or success of this modification is measured via a proxy of better performance on captioning metrics and spice sub-scores for relation/count/size etc. Though the captioning metrics show improved performance and some qualitative results indicate that the network understands spatial relationships, it is hard to tell if the network is learning meaningful spatial relationships in its geometric attention weights. A visualization for the attention weights for an appropriate layer (say for the qualitative examples in Tab. 7) may be useful to demonstrate that the network does indeed learn spatial relationship information. Also, the method does not get a statistically significant improvement for the "size" sub-score of SPICE metric in Tab. 5. The proposed geometric attention weights use relative size of bounding boxes in eq. 6, but this does not translate into performance gain. 3) Clarity: The paper is well written and easy to follow. The contributions are stated clearly and sufficient details of the method are present. The experimental evaluations are properly described with sufficient details. 4) Significance: The paper proposes an incremental modification to the transformer networks for image captioning, which can help boost performance on captioning metrics. The proposed method can be a useful trick in captioning network implementations for small performance gains. Post-rebuttal comments -- The paper proposes a modification that boosts performance in practice. The author feedback clarifies my concerns regarding experimental setup of the result tables and with this additional explanation, the tables are consistent. I still feel experimentation on different spatial features (the core idea of the method) is missing, the attention visualizations are interesting and should be discussed more in the final version.
Overall I liked the paper. It is well written and the task is interesting. I have some minor concerns regarding novelty at both the conceptual and technical levels. First, the reference supporting the claim that "incorporating spatial relationships has been shown to improve the performance of object detection" shows a lack of knowledge of important works in computer vision (prior to the deep learning era). For example, Hoiem et al.'s "Putting Objects in Perspective", ECCV 2006 showed the same thing over 10 years ago. Second, the object relation transformer model is a small variation of the standard transformer. I congratulate the authors on running and reporting statistical tests on their experimental results. They also provide sufficient implementation details to reproduce the models. Providing code on acceptance would help reproduceability further, and the authors should consider doing so. Some technical/minor comments: 1. In Section 3.2 it is not clear which parameters are shared between different heads and which are unique to each head. The authors should clarify and index the head-specific parameters. 2. In Eqn (6) the normalization in the second log term should be h_m. Moreover, what happens if the objects are aligned horizontally or vertically, i.e., x_m - x_n = 0? 3. L155 "\Sigma_A = with \Sigma" -> "\Sigma_A with \Sigma"