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1. TrackFlow: Multi-Object Tracking with Normalizing Flows

Author

Mancusi, Gianluca, Panariello, Aniello, Porrello, Angelo, Fabbri, Matteo, Calderara, Simone, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

The field of multi-object tracking has recently seen a renewed interest in the good old schema of tracking-by-detection, as its simplicity and strong priors spare it from the complex design and painful babysitting of tracking-by-attention approaches. In view of this, we aim at extending tracking-by-detection to multi-modal settings, where a comprehensive cost has to be computed from heterogeneous information e.g., 2D motion cues, visual appearance, and pose estimates. More precisely, we follow a case study where a rough estimate of 3D information is also available and must be merged with other traditional metrics (e.g., the IoU). To achieve that, recent approaches resort to either simple rules or complex heuristics to balance the contribution of each cost. However, i) they require careful tuning of tailored hyperparameters on a hold-out set, and ii) they imply these costs to be independent, which does not hold in reality. We address these issues by building upon an elegant probabilistic formulation, which considers the cost of a candidate association as the negative log-likelihood yielded by a deep density estimator, trained to model the conditional joint probability distribution of correct associations. Our experiments, conducted on both simulated and real benchmarks, show that our approach consistently enhances the performance of several tracking-by-detection algorithms., Comment: Accepted at ICCV 2023

Published
2023

2. Ecological constraints on highly evolvable olfactory receptor genes and morphology in neotropical bats

Author

Yohe, Laurel R, Fabbri, Matteo, Lee, Daniela, Davies, Kalina TJ, Yohe, Thomas P, Sánchez, Miluska KR, Rengifo, Edgardo M, Hall, Ronald P, Mutumi, Gregory, Hedrick, Brandon P, Sadier, Alexa, Simmons, Nancy B, Sears, Karen E, Dumont, Elizabeth, Rossiter, Stephen J, Bhullar, Bhart‐Anjan S, and Dávalos, Liliana M

Subjects
Genetics, Biotechnology, Neurosciences, Animals, Chiroptera, Receptors, Odorant, Phylogeny, Smell, Genome, Chemosensation, evolvability, gene family, morphology, olfaction, Ecology, Evolutionary Biology
Abstract

Although evolvability of genes and traits may promote specialization during species diversification, how ecology subsequently restricts such variation remains unclear. Chemosensation requires animals to decipher a complex chemical background to locate fitness-related resources, and thus the underlying genomic architecture and morphology must cope with constant exposure to a changing odorant landscape; detecting adaptation amidst extensive chemosensory diversity is an open challenge. In phyllostomid bats, an ecologically diverse clade that evolved plant visiting from a presumed insectivorous ancestor, the evolution of novel food detection mechanisms is suggested to be a key innovation, as plant-visiting species rely strongly on olfaction, supplementarily using echolocation. If this is true, exceptional variation in underlying olfactory genes and phenotypes may have preceded dietary diversification. We compared olfactory receptor (OR) genes sequenced from olfactory epithelium transcriptomes and olfactory epithelium surface area of bats with differing diets. Surprisingly, although OR evolution rates were quite variable and generally high, they are largely independent of diet. Olfactory epithelial surface area, however, is relatively larger in plant-visiting bats and there is an inverse relationship between OR evolution rates and surface area. Relatively larger surface areas suggest greater reliance on olfactory detection and stronger constraint on maintaining an already diverse OR repertoire. Instead of the typical case in which specialization and elaboration are coupled with rapid diversification of associated genes, here the relevant genes are already evolving so quickly that increased reliance on smell has led to stabilizing selection, presumably to maintain the ability to consistently discriminate among specific odorants-a potential ecological constraint on sensory evolution.

Published
2022

3. MOTSynth: How Can Synthetic Data Help Pedestrian Detection and Tracking?

Author

Fabbri, Matteo, Braso, Guillem, Maugeri, Gianluca, Cetintas, Orcun, Gasparini, Riccardo, Osep, Aljosa, Calderara, Simone, Leal-Taixe, Laura, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Deep learning-based methods for video pedestrian detection and tracking require large volumes of training data to achieve good performance. However, data acquisition in crowded public environments raises data privacy concerns -- we are not allowed to simply record and store data without the explicit consent of all participants. Furthermore, the annotation of such data for computer vision applications usually requires a substantial amount of manual effort, especially in the video domain. Labeling instances of pedestrians in highly crowded scenarios can be challenging even for human annotators and may introduce errors in the training data. In this paper, we study how we can advance different aspects of multi-person tracking using solely synthetic data. To this end, we generate MOTSynth, a large, highly diverse synthetic dataset for object detection and tracking using a rendering game engine. Our experiments show that MOTSynth can be used as a replacement for real data on tasks such as pedestrian detection, re-identification, segmentation, and tracking., Comment: ICCV 2021 camera-ready version

Published
2021

4. Inter-Homines: Distance-Based Risk Estimation for Human Safety

Author

Fabbri, Matteo, Lanzi, Fabio, Gasparini, Riccardo, Calderara, Simone, Baraldi, Lorenzo, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In this document, we report our proposal for modeling the risk of possible contagiousity in a given area monitored by RGB cameras where people freely move and interact. Our system, called Inter-Homines, evaluates in real-time the contagion risk in a monitored area by analyzing video streams: it is able to locate people in 3D space, calculate interpersonal distances and predict risk levels by building dynamic maps of the monitored area. Inter-Homines works both indoor and outdoor, in public and private crowded areas. The software is applicable to already installed cameras or low-cost cameras on industrial PCs, equipped with an additional embedded edge-AI system for temporary measurements. From the AI-side, we exploit a robust pipeline for real-time people detection and localization in the ground plane by homographic transformation based on state-of-the-art computer vision algorithms; it is a combination of a people detector and a pose estimator. From the risk modeling side, we propose a parametric model for a spatio-temporal dynamic risk estimation, that, validated by epidemiologists, could be useful for safety monitoring the acceptance of social distancing prevention measures by predicting the risk level of the scene.

Published
2020

5. Compressed Volumetric Heatmaps for Multi-Person 3D Pose Estimation

Author

Fabbri, Matteo, Lanzi, Fabio, Calderara, Simone, Alletto, Stefano, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In this paper we present a novel approach for bottom-up multi-person 3D human pose estimation from monocular RGB images. We propose to use high resolution volumetric heatmaps to model joint locations, devising a simple and effective compression method to drastically reduce the size of this representation. At the core of the proposed method lies our Volumetric Heatmap Autoencoder, a fully-convolutional network tasked with the compression of ground-truth heatmaps into a dense intermediate representation. A second model, the Code Predictor, is then trained to predict these codes, which can be decompressed at test time to re-obtain the original representation. Our experimental evaluation shows that our method performs favorably when compared to state of the art on both multi-person and single-person 3D human pose estimation datasets and, thanks to our novel compression strategy, can process full-HD images at the constant runtime of 8 fps regardless of the number of subjects in the scene. Code and models available at https://github.com/fabbrimatteo/LoCO ., Comment: CVPR 2020

Published
2020

9. Domain Translation with Conditional GANs: from Depth to RGB Face-to-Face

Author

Fabbri, Matteo, Borghi, Guido, Lanzi, Fabio, Vezzani, Roberto, Calderara, Simone, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Can faces acquired by low-cost depth sensors be useful to catch some characteristic details of the face? Typically the answer is no. However, new deep architectures can generate RGB images from data acquired in a different modality, such as depth data. In this paper, we propose a new \textit{Deterministic Conditional GAN}, trained on annotated RGB-D face datasets, effective for a face-to-face translation from depth to RGB. Although the network cannot reconstruct the exact somatic features for unknown individual faces, it is capable to reconstruct plausible faces; their appearance is accurate enough to be used in many pattern recognition tasks. In fact, we test the network capability to hallucinate with some \textit{Perceptual Probes}, as for instance face aspect classification or landmark detection. Depth face can be used in spite of the correspondent RGB images, that often are not available due to difficult luminance conditions. Experimental results are very promising and are as far as better than previously proposed approaches: this domain translation can constitute a new way to exploit depth data in new future applications., Comment: Accepted at ICPR 2018

Published
2019

10. Can Adversarial Networks Hallucinate Occluded People With a Plausible Aspect?

Author

Fulgeri, Federico, Fabbri, Matteo, Alletto, Stefano, Calderara, Simone, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

When you see a person in a crowd, occluded by other persons, you miss visual information that can be used to recognize, re-identify or simply classify him or her. You can imagine its appearance given your experience, nothing more. Similarly, AI solutions can try to hallucinate missing information with specific deep learning architectures, suitably trained with people with and without occlusions. The goal of this work is to generate a complete image of a person, given an occluded version in input, that should be a) without occlusion b) similar at pixel level to a completely visible people shape c) capable to conserve similar visual attributes (e.g. male/female) of the original one. For the purpose, we propose a new approach by integrating the state-of-the-art of neural network architectures, namely U-nets and GANs, as well as discriminative attribute classification nets, with an architecture specifically designed to de-occlude people shapes. The network is trained to optimize a Loss function which could take into account the aforementioned objectives. As well we propose two datasets for testing our solution: the first one, occluded RAP, created automatically by occluding real shapes of the RAP dataset (which collects also attributes of the people aspect); the second is a large synthetic dataset, AiC, generated in computer graphics with data extracted from the GTA video game, that contains 3D data of occluded objects by construction. Results are impressive and outperform any other previous proposal. This result could be an initial step to many further researches to recognize people and their behavior in an open crowded world., Comment: Under review at CVIU

Published
2019

11. First Steps Towards 3D Pedestrian Detection and Tracking from Single Image

Author

Mancusi, Gianluca, Fabbri, Matteo, Egidi, Sara, Verasani, Mattia, Scarabelli, Paolo, Calderara, Simone, Cucchiara, Rita, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Sclaroff, Stan, editor, Distante, Cosimo, editor, Leo, Marco, editor, Farinella, Giovanni M., editor, and Tombari, Federico, editor

Published
2022
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15. Learning to Detect and Track Visible and Occluded Body Joints in a Virtual World

Author

Fabbri, Matteo, Lanzi, Fabio, Calderara, Simone, Palazzi, Andrea, Vezzani, Roberto, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Multi-People Tracking in an open-world setting requires a special effort in precise detection. Moreover, temporal continuity in the detection phase gains more importance when scene cluttering introduces the challenging problems of occluded targets. For the purpose, we propose a deep network architecture that jointly extracts people body parts and associates them across short temporal spans. Our model explicitly deals with occluded body parts, by hallucinating plausible solutions of not visible joints. We propose a new end-to-end architecture composed by four branches (visible heatmaps, occluded heatmaps, part affinity fields and temporal affinity fields) fed by a time linker feature extractor. To overcome the lack of surveillance data with tracking, body part and occlusion annotations we created the vastest Computer Graphics dataset for people tracking in urban scenarios by exploiting a photorealistic videogame. It is up to now the vastest dataset (about 500.000 frames, almost 10 million body poses) of human body parts for people tracking in urban scenarios. Our architecture trained on virtual data exhibits good generalization capabilities also on public real tracking benchmarks, when image resolution and sharpness are high enough, producing reliable tracklets useful for further batch data association or re-id modules., Comment: Accepted at ECCV 2018

Published
2018

16. Face-from-Depth for Head Pose Estimation on Depth Images

Author

Borghi, Guido, Fabbri, Matteo, Vezzani, Roberto, Calderara, Simone, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Depth cameras allow to set up reliable solutions for people monitoring and behavior understanding, especially when unstable or poor illumination conditions make unusable common RGB sensors. Therefore, we propose a complete framework for the estimation of the head and shoulder pose based on depth images only. A head detection and localization module is also included, in order to develop a complete end-to-end system. The core element of the framework is a Convolutional Neural Network, called POSEidon+, that receives as input three types of images and provides the 3D angles of the pose as output. Moreover, a Face-from-Depth component based on a Deterministic Conditional GAN model is able to hallucinate a face from the corresponding depth image. We empirically demonstrate that this positively impacts the system performances. We test the proposed framework on two public datasets, namely Biwi Kinect Head Pose and ICT-3DHP, and on Pandora, a new challenging dataset mainly inspired by the automotive setup. Experimental results show that our method overcomes several recent state-of-art works based on both intensity and depth input data, running in real-time at more than 30 frames per second., Comment: Submitted to IEEE Transactions on PAMI, updated version (second round). arXiv admin note: substantial text overlap with arXiv:1611.10195

Published
2017

17. Generative Adversarial Models for People Attribute Recognition in Surveillance

Author

Fabbri, Matteo, Calderara, Simone, and Cucchiara, Rita

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In this paper we propose a deep architecture for detecting people attributes (e.g. gender, race, clothing ...) in surveillance contexts. Our proposal explicitly deal with poor resolution and occlusion issues that often occur in surveillance footages by enhancing the images by means of Deep Convolutional Generative Adversarial Networks (DCGAN). Experiments show that by combining both our Generative Reconstruction and Deep Attribute Classification Network we can effectively extract attributes even when resolution is poor and in presence of strong occlusions up to 80\% of the whole person figure., Comment: Accepted as oral presentation at AVSS 2017

Published
2017

22. Subaqueous foraging among carnivorous dinosaurs

Author

Fabbri, Matteo, Navalón, Guillermo, Benson, Roger B. J., Pol, Diego, O’Connor, Jingmai, Bhullar, Bhart-Anjan S., Erickson, Gregory M., Norell, Mark A., Orkney, Andrew, Lamanna, Matthew C., Zouhri, Samir, Becker, Justine, Emke, Amanda, Dal Sasso, Cristiano, Bindellini, Gabriele, Maganuco, Simone, Auditore, Marco, and Ibrahim, Nizar

Published
2022
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29. The first dinosaur egg was soft

Author

Norell, Mark A., Wiemann, Jasmina, Fabbri, Matteo, Yu, Congyu, Marsicano, Claudia A., Moore-Nall, Anita, and Varricchio, David J.

Subjects
Physiological aspects, Dinosaurs -- Physiological aspects, Eggs (Biology) -- Physiological aspects, Egg (Biology) -- Physiological aspects
Abstract

Author(s): Mark A. Norell [sup.1] , Jasmina Wiemann [sup.2] , Matteo Fabbri [sup.2] , Congyu Yu [sup.1] , Claudia A. Marsicano [sup.3] , Anita Moore-Nall [sup.4] , David J. Varricchio [...], Calcified eggshells protect developing embryos against environmental stress and contribute to reproductive success.sup.1. As modern crocodilians and birds lay hard-shelled eggs, this eggshell type has been inferred for non-avian dinosaurs. Known dinosaur eggshells are characterized by an innermost membrane, an overlying protein matrix containing calcite, and an outermost waxy cuticle.sup.2-7. The calcitic eggshell consists of one or more ultrastructural layers that differ markedly among the three major dinosaur clades, as do the configurations of respiratory pores. So far, only hadrosaurid, a few sauropodomorph and tetanuran eggshells have been discovered; the paucity of the fossil record and the lack of intermediate eggshell types challenge efforts to homologize eggshell structures across all dinosaurs.sup.8-18. Here we present mineralogical, organochemical and ultrastructural evidence for an originally non-biomineralized, soft-shelled nature of exceptionally preserved ornithischian Protoceratops and basal sauropodomorph Mussaurus eggs. Statistical evaluation of in situ Raman spectra obtained for a representative set of hard- and soft-shelled, fossil and extant diapsid eggshells clusters the originally organic but secondarily phosphatized Protoceratops and the organic Mussaurus eggshells with soft, non-biomineralized eggshells. Histology corroborates the organic composition of these soft-shelled dinosaur eggs, revealing a stratified arrangement resembling turtle soft eggshell. Through an ancestral-state reconstruction of composition and ultrastructure, we compare eggshells from Protoceratops and Mussaurus with those from other diapsids, revealing that the first dinosaur egg was soft-shelled. The calcified, hard-shelled dinosaur egg evolved independently at least three times throughout the Mesozoic era, explaining the bias towards eggshells of derived dinosaurs in the fossil record. Molecular analyses of newly discovered, embryo-bearing ornithischian and sauropod dinosaur eggs suggest that the ancestral dinosaur egg was soft-shelled, and that hard-shelled eggs evolved independently at least three times in the major dinosaur lineages.

Published
2020
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30. Tail-propelled aquatic locomotion in a theropod dinosaur

Author

Ibrahim, Nizar, Maganuco, Simone, Dal Sasso, Cristiano, Fabbri, Matteo, Auditore, Marco, Bindellini, Gabriele, and Martill, David M.

Subjects
Mechanical properties, Analysis, Usage, Theropods -- Mechanical properties -- Analysis -- Usage, Tail -- Usage -- Analysis -- Mechanical properties, Animal swimming -- Analysis -- Usage -- Mechanical properties, Theropoda -- Mechanical properties -- Analysis -- Usage
Abstract

Author(s): Nizar Ibrahim [sup.1] , Simone Maganuco [sup.2] [sup.3] , Cristiano Dal Sasso [sup.3] , Matteo Fabbri [sup.4] , Marco Auditore [sup.3] , Gabriele Bindellini [sup.3] [sup.5] , David M. [...], In recent decades, intensive research on non-avian dinosaurs has strongly suggested that these animals were restricted to terrestrial environments.sup.1. Historical proposals that some groups, such as sauropods and hadrosaurs, lived in aquatic environments.sup.2,3 were abandoned decades ago.sup.4-6. It has recently been argued that at least some of the spinosaurids--an unusual group of large-bodied theropods of the Cretaceous era--were semi-aquatic.sup.7,8, but this idea has been challenged on anatomical, biomechanical and taphonomic grounds, and remains controversial.sup.9-11. Here we present unambiguous evidence for an aquatic propulsive structure in a dinosaur, the giant theropod Spinosaurus aegyptiacus.sup.7,12. This dinosaur has a tail with an unexpected and unique shape that consists of extremely tall neural spines and elongate chevrons, which forms a large, flexible fin-like organ capable of extensive lateral excursion. Using a robotic flapping apparatus to measure undulatory forces in physical models of different tail shapes, we show that the tail shape of Spinosaurus produces greater thrust and efficiency in water than the tail shapes of terrestrial dinosaurs and that these measures of performance are more comparable to those of extant aquatic vertebrates that use vertically expanded tails to generate forward propulsion while swimming. These results are consistent with the suite of adaptations for an aquatic lifestyle and piscivorous diet that have previously been documented for Spinosaurus.sup.7,13,14. Although developed to a lesser degree, aquatic adaptations are also found in other members of the spinosaurid clade.sup.15,16, which had a near-global distribution and a stratigraphic range of more than 50 million years.sup.14, pointing to a substantial invasion of aquatic environments by dinosaurs. Discovery that the giant theropod dinosaur Spinosaurus has a large flexible tail indicates that it was primarily aquatic and swam in a similar manner to extant tail-propelled aquatic vertebrates.

Published
2020
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32. Best practices for vascular arterial access and closure: a contemporary guide for the cardiac catheterization laboratory

Author

Eltelbany, Moemen, primary, Fabbri, Matteo, additional, Batchelor, Wayne B., additional, Cilia, Lindsey, additional, Ducoffe, Aaron, additional, Endicott, Kendall, additional, Epps, Kelly, additional, McBurnie, Amika, additional, Neville, Richard, additional, Rosner, Carolyn, additional, Sherwood, Matthew W., additional, Spinosa, David, additional, Truesdell, Alexander G., additional, Vorgang, Cassandra, additional, Damluji, Abdulla A., additional, and Tehrani, Behnam N., additional

Published
2024
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33. Variation Of Prespecified Subgroups In Large-Scale HF Outcome Trials

Author

Dimond, Matthew, primary, Fabbri, Matteo, additional, Fiuzat, Mona, additional, Teerlink, John, additional, Abraham, William, additional, Mcmurray, John, additional, Psotka, Mitchell, additional, Konstam, Marvin, additional, Blumer, Vanessa, additional, Solomon, Scott, additional, Bristow, Michael, additional, Bozkurt, Biykem, additional, Butler, Javed, additional, Costanzo, Maria Rosa, additional, Felker, Michael, additional, Filippatos, Gerasimos, additional, Januzzi, James, additional, Metra, Marco, additional, Lindenfeld, JoAnn, additional, Mentz, Robert, additional, Saville, Ben, additional, Jessup, Mariell, additional, and O'Connor, Christopher, additional

Published
2024
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34. Exploring the X-Chromosomal Str Haplotype Database: Insights from Italian Population and Improved Recombination Rates Analysis

Author

Bini, Carla, primary, Aneli, Serena, additional, Sarno, Stefania, additional, Birolo, Giovanni, additional, Carnevali, Eugenia, additional, Colao, Emma, additional, Di Nunzio, Ciro, additional, Di Nunzio, Michele, additional, Fabbri, Matteo, additional, Fattorini, Paolo, additional, Grignani, Pierangela, additional, Piccinini, Andrea, additional, Ponzano, Elena, additional, Robino, Carlo, additional, Rocchi, Anna, additional, Scarnicci, Francesca, additional, Turchi, Chiara, additional, Verzeletti, Andrea, additional, and Pelotti, Susi, additional

Published
2024
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44. An mRNA Profiling Study of Vaginal Swabs from Pre- and Postmenopausal Women

Author

Chierto, Elena, primary, Alessandrini, Federica, additional, Bini, Carla, additional, Carnevali, Eugenia, additional, Fabbri, Matteo, additional, Fattorini, Paolo, additional, Grignani, Pierangela, additional, Scarnicci, Francesca, additional, Tozzo, Pamela, additional, Verzeletti, Andrea, additional, Pelotti, Susi, additional, Buscemi, Loredana, additional, and Robino, Carlo, additional

Published
2023
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46. Jeholornis

Author

Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe, and Benson, Roger B. J.

Subjects
Jeholornithiformes, Jeholornis, Animalia, Biodiversity, Jeholornithidae, Chordata, Aves, Taxonomy
Abstract

CRANIAL OSTEOLOGY OF JEHOLORNIS Premaxilla The premaxillae are complete in STM 3-8 (Fig. 2A–F). They are edentulous, as reported in previous publications (Zhou & Zhang, 2002, 2003; Lefèvre et al., 2014), and their external surfaces are marked by several nutrient foramina. No pits are present to receive the dentary teeth, which is different from the condition present in Ichthyornis Marsh, 1873 (Field et al., 2018). The tip of the corpus forms a ventral projection, suggesting that the tip of the beak might have been slightly hooked. Caudal to the rostral ‘hook’, the ventral margin of the premaxillary corpus is straight. The relative level of the ventral projection of this rostral ‘hook’ varies among previously reported specimens, being absent in Jeholornis YFGP-yb2 and exaggerated relative to STM 3-8 in Kompsornis AGB- 6997 (Lefèvre et al., 2014; Wang et al., 2020a). This is interpreted here as attributable to variation in preservation, but further studies are needed to exclude the possibility of intraspecific variation confidently. The premaxillary corpora are fused, whereas the frontal processes are separated (Hu et al., 2022). The frontal (nasal) process of the premaxilla is relatively short and therefore does not contact the frontal but instead articulates distally with the dorsal surface of the nasal, as in other non-ornithothoracine stem birds (e.g. Archaeopteryx and Sapeornis; Rauhut, 2014; Kundrát et al., 2018; Hu et al., 2020a) apart from Confuciusornis Hou et al., 1995 (Chiappe et al., 1999; Elżanowski et al., 2018; Wang et al., 2019a). This is evidenced by the extension level of the articular facet present in the frontal process of the premaxilla. The maxillary process of the premaxilla is short and articulates medially with the premaxillary process of the maxilla (Fig. 2A, B). It appears to be step-like, with the dorsal margin extending farther caudally than the ventral margin. The palatal process is crushed mediolaterally but could still be distinguished from the maxillary process in the 3D reconstruction. Maxilla The maxillae in Jeholornis STM 3-8 are well preserved, being almost in articulation with the premaxillae and the lacrimals (Fig. 2A, B, J–L). The premaxillary process bears a lateral depression that receives the dorsal part of the maxillary process of premaxilla. The jugal process is slender, being half of the dorsoventral height of the premaxillary process and more than twice its length. A shallow groove is present along the medial surface of the jugal process, indicating extensive contact area with the palatine, similar to Archaeopteryx (Mayr et al., 2007). The medial surface of the maxilla is rarely visible among Mesozoic bird specimens, precluding further comparisons. Although the palatal process is mostly crushed, it seems that it was sheet-like and well developed, and therefore most probably contacted the vomer, similar to the Late Cretaceous enantiornithine Gobipteryx Elżanowski, 1974 and the ornithuromorph Ichthyornis (Chiappe et al., 2001; Field et al., 2018), the only other Mesozoic birds in which the morphology of the palatal process of the maxilla is known so far. A dorsoventrally elongate oval fenestra is present between the jugal process and the ascending process in Jeholornis, being enclosed caudally by a thin, bony bar. We identify this tentatively as the maxillary fenestra (Witmer, 1997). However, it is unclear whether it is homologous with the maxillary fenestra or promaxillary fenestra of non-avian theropods and Archaeopteryx (Witmer, 1997; Barsbold & Osmólska, 1999; Xu & Wu, 2001; Mayr et al., 2007; Rauhut, 2014; Rauhut et al., 2018) or with the accessory fenestra present in the enantiornithine bird Pengornis Zhou, Clarke & Zhang, 2008 (O’Connor & Chiappe, 2011). Two alveoli are present in the maxilla. Two teeth are preserved in the left maxilla, and another two similar-sized teeth are dislocated beside the right maxilla. The maxillary teeth are straight and subconical, with blunt crowns and an expanded root. Lacrimal Both lacrimals are well preserved in articulation with the maxillae in Jeholornis STM 3-8 (Fig. 2A, B, G–I). The rostrodorsal ramus is remarkably short, approximately one-quarter the length of the long caudodorsal ramus. This differs from most other Early Cretaceous birds and non-avian theropods (e.g. Archaeopteryx and Sinornithosaurus Xu, Wang & Wu, 1999; Xu & Wu, 2001; Rauhut, 2014; Kundrát et al., 2018; Rauhut et al., 2018), in which the rostrodorsal ramus is long and the caudodorsal ramus short. The ventral ramus is caudally recurved in Jeholornis, such that the caudal margin formed by the ventral and caudodorsal processes is concave, forming the rostral/ rostrodorsal margin of the orbit. This is similar to the morphology in more crownward birds (e.g. the Late Cretaceous ornithurine bird Ichthyornis), although the rostrodorsal ramus is even more strongly reduced in Ichthyornis and does not contact the maxilla, unlike in Jeholornis (Field et al., 2018). The lacrimal morphology of Jeholornis also contrasts with the morphology of most other Early Cretaceous birds and non-avian theropods, in which the ventral ramus is almost perpendicular to the ventral margin of the skull or is inclined cranially (Wang et al., 2021). The lacrimal of the confuciusornithiforms appears to be slender and reduced, also presenting a short or totally absent rostrodorsal ramus and slightly caudally recurved ventral ramus (Elżanowski et al., 2018; Wang & Zhou, 2018; Wang et al., 2019a), potentially similar to Jeholornis. However, owing to the potential uncertainty from 2D preservation of currently published skulls of confuciusornithiforms, 3D data are needed to confirm this in future analyses. Disarticulation prevents detailed reconstruction of articulations between the lacrimal, the nasal and the preorbital ossification in Jeholornis STM 3-8. The ventral ramus of the lacrimal is interpreted as contacting the jugal process of the maxilla and, potentially, might have contacted the rostral tip of the jugal, whereas the lacrimal contacts the jugal in other theropods (Xu & Wu, 2001; Rauhut, 2014; Kundrát et al., 2018; Rauhut et al., 2018). The caudal margin of the lacrimal, which forms the cranial margin of the orbit, is remarkably excavated, and the excavation extends across both the ventral and caudodorsal processes. A lacrimal foramen lies within the centre of the excavation, entering medially into the main body of the lacrimal at around its mid-height, at the junction of the ventral ramus and the caudodorsal ramus. The size and central position of this foramen resemble the condition in Ichthyornis (Field et al., 2018), although the lacrimal of Ichthyornis differs in lacking the rostrodorsal ramus and thus the contact with the maxilla. In contrast, this foramen is much smaller and penetrates lateromedially in enantiornithine IVPP V12707, which also lacks any excavation on the lacrimal on the rostral orbit margin of the lacrimal (Wang et al. 2021). This contrasts with the craniocaudal extension of the lacrimal foramen in Jeholornis. Nasal The left nasal is well preserved (Fig. 3A, B). The nasal corpus is mediolaterally broad, similar to Sapeornis (Hu et al., 2019, 2020a) but unlike the more elongated condition present in Archaeopteryx (Mayr et al., 2007; Rauhut, 2014; Kundrát et al., 2018), confuciusornithiforms (Elżanowski et al., 2018; Wang et al., 2019a) and enantiornithines (O’Connor & Chiappe, 2011). Both the premaxillary and the maxillary processes are delicate and sharply tapered rostrally. The premaxillary process is slightly longer than the maxillary process, and the deflections of both processes in the left nasal are taphonomic, resulting from crushing between the right nasal and left lacrimal. The premaxillary process does not extend to the base of the frontal process of the premaxilla, therefore leaving the premaxilla to form most of the rostrodorsal margin of the external naris. This is different from the condition in Archaeopteryx, in which the premaxillary process is substantially longer than the maxillary process and forms part of the dorsal–rostrodorsal margin of the external naris (Rauhut, 2014; Kundrát et al., 2018). The maxillary process of the premaxilla of Jeholornis is also relatively short and does not extend to the base of the ascending process of the maxilla, therefore not contacting the premaxilla. This leaves the maxilla to form the caudoventral margin of the external naris, similar to Archaeopteryx (Rauhut, 2014). Preorbital ossification Specimen STM 3-8 preserves a mysterious pair of sheet-like elements previously referred to as ‘preorbital ossifications’ (Fig. 3C, D; Hu et al., 2022), which might represent prefrontals based on their overall shape and location. This is supported by their location almost parallel to the craniodorsal process of the lacrimal, which rules out identification as the ectethmoid, especially considering that other rostral elements are mostly preserved in situ. If this element is the prefrontal, it differs from the prefrontals of all other pennaraptorans so far, which are strongly reduced or absent, being typically smaller than the nasal (e.g. in Archaeopteryx and Sinornithosaurus; Xu & Wu, 2001; Rauhut et al., 2018). This could suggest that an unfused, expanded prefrontal might be a derived feature of Jeholornis and challenges the hypothesis based on the embryonic observations that the prefrontal fused to form the caudodorsal ramus of the lacrimal in all birds (Smith-Paredes et al., 2018). If correctly identified, this suggests that a broad prefrontal co-exists with a lacrimal with a well-developed caudodorsal process in Jeholornis. However, owing to the lack of available comparisons of any similar ossifications among non-avian dinosaurs and birds, we cannot exclude the possibility that this bone represents some other element that is rarely preserved or developed in Mesozoic birds. For example, the preorbital ossification described here could be a palpebral, although we consider this to be much less likely owing to its preserved location, close to the midline of the skull. Jugal Only the left jugal is preserved in STM 3-8 (Fig. 3G, H). The maxillary process is as slender as the jugal process of the maxilla, similar to the jugal of Archaeopteryx (Elżanowski & Wellnhofer, 1996; Kundrát et al., 2018; Rauhut et al., 2018) but in contrast to the relatively more robust condition in Sapeornis (Hu et al., 2020a). The rostral quarter of the maxillary process is slightly constricted and bears a depression in the distal end of the dorsal margin, defining the articulation with the maxilla. The articulation between the jugal and the maxilla is much shorter than in Sapeornis, in which the maxilla extends caudally almost to the base of the postorbital bar (Hu et al., 2020a). An oval concavity is present centrally on the lateral surface of the maxillary process. A similar depression is also present in Archaeopteryx, although in a more rostral position (Mayr et al., 2007; Rauhut, 2014), but is absent in most other Mesozoic birds (e.g. Sapeornis, Ichthyornis and enantiornithines; Wang & Hu, 2017; Field et al., 2018; Hu et al., 2020a). The quadratojugal process of the jugal of Jeholornis lacks the notch present in Sapeornis and many non-avian theropods, which is also absent in known enantiornithines but possibly present in Ichthyornis (Rauhut, 2003; Xu et al., 2015; Wang & Hu, 2017; Field et al., 2018; Hu et al., 2020b). Because of this, the quadratojugal of Jeholornis articulates with the dorsolateral surface of the quadratojugal process of the jugal, differing from the wedge-like articulation seen in Sapeornis and other Mesozoic theropods (e.g. Linheraptor Xu et al., 2015; Xu et al., 2015; Hu et al., 2020a). The postorbital process of the jugal of Jeholornis is triangular with a broad base and is dorsally oriented. This contrasts with the caudodorsal orientation seen in Archaeopteryx and Sapeornis (Mayr et al., 2007; Rauhut, 2014; Kundrát et al., 2018; Hu et al., 2020a). A shallow impression on the rostrolateral surface of the postorbital process defines the articulation with the postorbital, indicating the presence of a complete postorbital bar in Jeholornis. Quadratojugal The left quadratojugal is complete, but slightly disarticulated from the jugal (Fig. 3E, F). The jugal process is twice as long as the squamosal process and is more slender; both are bluntly tapered. The ventromedial surface of the jugal process contacts the jugal, in contrast to the inserting articulation with the caudal notch of the jugal in Sapeornis and most non-avian theropods (Xu et al., 2015; Hu et al., 2020a). The squamosal process is reduced and does not contact the squamosal dorsally, similar to the condition in other Mesozoic birds, including Archaeopteryx, Sapeornis and various others (e.g. RapaxaƲis pani Morschhauser et al., 2009 and Cruralispennia multidonta Wange et al., 2017; Mayr et al., 2007; O’Connor et al., 2011; Rauhut, 2014; Wang et al., 2017b; Hu et al., 2020a). Postorbital The left postorbital is completely preserved and the right is broken in STM 3-8 (Fig. 3I–K). The postorbital is triradiate and more robust than that of Archaeopteryx (Kundrát et al., 2018; Rauhut et al., 2018; Hu et al., 2020a). The jugal process is long and tapers ventrally, extending most of the skull height ventrally, and therefore forming most of the postorbital bar. In contrast, one specimen of Archaeopteryx preserves a slightly longer jugal process (Rauhut et al., 2018), whereas others preserve a jugal process almost equal in length to the other processes (Kundrát et al., 2018). The elongate jugal process of Jeholornis more closely resembles the condition in some enantiornithines (e.g. Longusunguis Wang et al., 2014 and enantiornithines LP4450 and IVPP V12707). However, it is much more robust than that of some other enantiornithines (Sanz et al., 1997; Hu et al., 2020b; Zhou et al., 2008). The squamosal process of the postorbital of Jeholornis is short, less than half the length of the frontal process, and has a sharply tapered end, whereas this process is longer in Sapeornis and Archaeopteryx (Rauhut et al., 2018; Hu et al., 2020a). The dorsal surface of the squamosal process bears a concave facet for articulation with the squamosal. Squamosal Both squamosals are preserved, although only the right is complete in STM 3-8 (Fig. 3L, M). The squamosal is not fused to the braincase, similar to the condition in non-avian theropods, Archaeopteryx and enantiornithines (e.g. LP4450 and IVPP V12707; Elżanowski & Wellnhofer, 1996; Sanz et al., 1997; Rauhut, 2003; Norman et al., 2004; Xu et al., 2015; Rauhut et al., 2018; Wang et al., 2021). The rarity with which squamosals are preserved in other stem birds complicates interpretation of the morphology seen in Jeholornis. However, the concavity in the medial surface of this bone fits the otic process of the quadrate, and thus could be interpreted as the quadrate cotyle of the squamosal, supporting our identification of this element as a squamosal. The triangular, sharply tapered, rostroventrally directed process is identified as the postorbital process, resembling that in enantiornithine IVPP V12707 (Wang et al., 2021), and contrasts with the forked condition in Archaeopteryx (Elżanowski & Wellnhofer, 1996; Kundrát et al., 2018). The ventrally oriented quadratojugal process is short, with a blunt ventral margin, not contacting the quadratojugal. This suggests that the loss of the quadratojugal–squamosal contact might have evolved independently in Jeholornis and in ornithurines, but remained present in at least some enantiornithines (e.g. IVPP 12707) [although it also could have been regained secondarily as a derived feature (Wang et al., 2021)]. It cannot be determined whether the dorsal portion is complete, hence the shape of the parietal and the paroccipital processes of the squamosal remain uncertain. Quadrate Both quadrates are almost completely preserved (Fig. 4A–C). The shaft of the quadrate extends from the otic process dorsally to the lateral condyle caudoventrally. The orbital process is broad and lateromedially thin, resembling that of Archaeopteryx (Rauhut et al., 2018), Sapeornis (Hu et al., 2020a) and known enantiornithines [e.g. Zhouornis Zhang et al., 2013 (Zhang et al., 2013) and Pterygornis Wang et al., 2014 (Wang et al., 2015)], and differs from the narrow and rostrally projecting condition in Ichthyornis and crown birds, including the Late Cretaceous Asteriornis Field et al., 2020 (Elżanowski & Stidham, 2010; Field et al., 2018, 2020). The otic process is plesiomorphically single headed, as in Sapeornis and enantiornithines (Wang et al., 2015, 2021; Hu et al., 2020a), but differing from the divided otic capitulum and squamosal capitulum in neognaths, including Asteriornis (Field et al., 2020). A dorsoventrally oriented longitudinal ridge is present caudally on the medial surface of the otic process, similar to the condition in Sapeornis and enantiornithines (Zhang et al., 2013; Wang et al., 2015; Hu et al., 2020a), defining the caudal margin of a gentle excavation on the medial surface of the orbital process. The lateral surface is also excavated by a similar dorsoventrally oriented longitudinal ridge, but it cannot be determined whether this is attributable to the lateromedially crushed preservation of the orbital process. No pneumatic foramen is observed, different from the condition in most modern birds and Late Cretaceous ornithurines (e.g. Ichthyornis and Asteriornis; Elżanowski & Stidham, 2010; Field et al., 2018, 2020). However, two potential pneumatic recesses could be identified on the lateral surface of the quadrate in Jeholornis. Both the lateral and medial condyles are of a similar size and project caudally, defining a concave caudal margin for the quadrate. Frontal The frontals are tightly articulated with each other in STM 3-8, but not entirely fused, with the interfrontal suture clearly visible (Fig. 4D, E), similar to the condition observed in other Jeholornis specimens (Lefèvre et al, Published as part of Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe & Benson, Roger B. J., 2023, Cranial osteology and palaeobiology of the Early Cretaceous bird Jeholornis prima (Aves: Jeholornithiformes), pp. 93-112 in Zoological Journal of the Linnean Society 198 (1) on pages 95-107, DOI: 10.1093/zoolinnean/zlac089, http://zenodo.org/record/7926859, {"references":["Zhou Z, Zhang F. 2002. A long-tailed, seed-eating bird from the Early Cretaceous of China. Nature 418: 405 - 409.","Zhou Z, Zhang F. 2003. Jeholornis compared to Archaeopteryx, with a new understanding of the earliest avian evolution. Naturaeissenschaften 90: 220 - 225.","Lefevre U, Hu D, Escuillie F, Dyke G, Godefroit P. 2014. A new long-tailed basal bird from the Lower Cretaceous of north-eastern China. Biological Journal of the Linnean Society 113: 790 - 804.","Field DJ, Hanson M, Burnham D, Wilson LE, Super K, Ehret D, Ebersole JA, Bhullar BAS. 2018. Complete Ichthyornis skull illuminates mosaic assembly of the avian head. Nature 557: 96 - 100.","Wang X, Huang J, Kundrat M, Cau A, Liu X, Wang Y, Ju S. 2020 a. A new jeholornithiform exhibits the earliest appearance of the fused sternum and pelvis in the evolution of avialan dinosaurs. Journal of Asian Earth Sciences 199: 104401.","Hu H, Wang Y, McDonald PG, Wroe S, O'Connor JK, Bjarnason A, Bevitt JJ, Yin X, Zheng X, Zhou Z, Benson RBJ. 2022. Earliest evidence for fruit consumption and potential seed dispersal by birds. eLife 11: e 74751.","Rauhut OWM. 2014. New observations on the skull of Archaeopteryx. Palaontologische Zeitschrift 88: 211 - 221.","Kundrat M, Nudds J, Kear BP, Lu J, Ahlberg P. 2018. The first specimen of Archaeopteryx from the Upper Jurassic Mornsheim Formation of Germany. Historical Biology 31: 3 - 63.","Hu H, O'Connor JK, McDonald PG, Wroe S. 2020 a. Cranial osteology of the Early Cretaceous Sapeornis chaoyangensis (Aves: Pygostylia). Cretaceous Research 113: 104496.","Chiappe LM, Ji SA, Ji Q, Norell MA. 1999. Anatomy and systematics of the Confuciusornithidae (Theropoda, Aves) from the late Mesozoic of northeastern China. Bulletin of the American Museum of Natural History 242: 1 - 89.","Elzanowski A, Peters DS, Mayr G. 2018. Cranial morphology of the Early Cretaceous bird Confuciusornis. Journal of Vertebrate Paleontology 38: e 1439832.","Wang M, Jingmai K, Zhou Z. 2019 a. A taxonomical revision of the Confuciusornithiformes (Aves: Pygostylia). Vertebrata Palasiatica 57: 1 - 37.","Mayr G, Pohl B, Hartman S, Peters DS. 2007. The tenth skeletal specimen of Archaeopteryx. Zoological Journal of the Linnean Society 149: 97 - 116.","Chiappe LM, Norell M, Clark J. 2001. A new skull of Gobipteryx minuta (Aves: Enantiornithes) from the Cretaceous of the Gobi Desert. American Museum NoVitates 3346: 1 - 15.","Witmer LM. 1997. The evolution of the antorbital cavity of archosaurs: a study in soft-tissue reconstruction in the fossil record with an analysis of the function of pneumaticity. Journal of Vertebrate Paleontology 17: 1 - 76.","Barsbold R, Osmolska H. 1999. The skull of Velociraptor [Theropoda] from the Late Cretaceous of Mongolia. Acta Palaeontologica Polonica 44: 189 - 219.","Xu X, Wu XC. 2001. Cranial morphology of Sinornithosaurus millenii Xu et al. 1999 (Dinosauria: Theropoda: Dromaeosauridae) from the Yixian Formation of Liaoning, China. Canadian Journal of Earth Sciences 38: 1739 - 1752.","Rauhut OWM, Foth C, Tischlinger H. 2018. The oldest Archaeopteryx (Theropoda: Avialiae): a new specimen from the Kimmeridgian / Tithonian boundary of Schamhaupten, Bavaria. PeerJ 6: e 4191.","Zhou Z, Clarke J, Zhang F. 2008. Insight into diversity, body size and morphological evolution from the largest Early Cretaceous enantiornithine bird. Journal of Anatomy 212: 565 - 577.","Wang M, Stidham TA, Li Z, Xu X, Zhou Z. 2021. Cretaceous bird with dinosaur skull sheds light on avian cranial evolution. Nature Communications 12: 3890.","Wang M, Zhou Z. 2018. A new confuciusornithid (Aves: Pygostylia) from the Early Cretaceous increases the morphological disparity of the Confuciusornithidae. Zoological Journal of the Linnean Society 185: 417 - 430.","Hu H, Sansalone G, Wroe S, McDonald PG, O'Connor JK, Li Z, Xu X, Zhou Z. 2019. Evolution of the vomer and its implications for cranial kinesis in Paraves. Proceedings of the National Academy of Sciences of the United States of America 116: 19571 - 19578.","Smith-Paredes D, Nunez-Leon D, Soto-Acuna S, O'Connor J, Botelho JF, Vargas AO. 2018. Dinosaur ossification centres in embryonic birds uncover developmental evolution of the skull. Nature Ecology & EVolution 2: 1966 - 1973.","Elzanowski A, Wellnhofer P. 1996. Cranial morphology of Archaeopteryx: evidence from the seventh skeleton. Journal of Vertebrate Paleontology 16: 81 - 94.","Wang Y, Hu H, O'Connor JK, Wang M, Xu X, Zhou Z, Wang X, Zheng X. 2017 a. A previously undescribed specimen reveals new information on the dentition of Sapeornis chaoyangensis. Cretaceous Research 74: 1 - 10.","Rauhut OW. 2003. Special papers in palaeontology, the interrelationships and eVolution of basal theropod dinosaurs. London: Blackwell Publishing.","Xu X, Pittman M, Sullivan C, Choiniere JN, Tan Q, Clark JM, Norell MA, Wang S. 2015. The taxonomic status of the Late Cretaceous dromaeosaurid Linheraptor exquisitus and its implications for dromaeosaurid systematics. Vertebrata Palasiatica 53: 29 - 62.","Hu H, O'Connor JK, Wang M, Wroe S, McDonald PG. 2020 b. New anatomical information on the bohaiornithid Longusunguis and the presence of a plesiomorphic diapsid skull in Enantiornithes. Journal of Systematic Palaeontology 18: 1481 - 1495.","Wang M, O'Connor JK, Pan Y, Zhou Z. 2017 b. A bizarre Early Cretaceous enantiornithine bird with unique crural feathers and an ornithuromorph plough-shaped pygostyle. Nature Communications 8: 14141.","Norman DB, Sues HD, Witmer LM, Coria RA. 2004. The Dinosauria. Berkeley: University of California Press, 393 - 412.","Zhang Z, Chiappe LM, Han G, Chinsamy A. 2013. A large bird from the Early Cretaceous of China: new information on the skull of enantiornithines. Journal of Vertebrate Paleontology 33: 1176 - 1189.","Wang M, Hu H, Li Z. 2015. A new small enantiornithine bird from the Jehol Biota, with implications for early evolution of avian skull morphology. Journal of Systematic Palaeontology 14: 481 - 497.","Field DJ, Benito J, Chen A, Jagt JWM, Ksepka DT. 2020. Late Cretaceous neornithine from Europe illuminates the origins of crown birds. Nature 579: 397 - 401.","Elzanowski A, Stidham TA. 2010. Morphology of the quadrate in the Eocene anseriform Presbyornis and extant galloanserine birds. Journal of Morphology 271: 305 - 323.","Clark JM, Norell MA, Rowe T. 2002. Cranial anatomy of Citipati osmolskae (Theropoda, Oviraptorosauria), and a reinterpretation of the holotype of OViraptor philoceratops. American Museum NoVitates 2002: 1 - 24.","Yin YL, Pei R, Zhou CF. 2018. Cranial morphology of SinoVenator changii (Theropoda: Troodontidae) on the new material from the Yixian Formation of western Liaoning, China. PeerJ 6: e 4977.","Fabbri M, Koch NM, Pritchard AC, Hanson M, Hoffman E, Bever GS, Balanoff AM, Morris ZS, Field DJ, Camacho J, Rowe TB, Norell MA, Smith RM, Abzhanov A, Bhullar BAS. 2017. The skull roof tracks the brain during the evolution and development of reptiles including birds. Nature Ecology & EVolution 1: 1543 - 1550.","Beyrand V, Voeten DFAE, Bures S, Fernandez V, Janacek J, Jirak D, Rauhut O, Tafforeau P. 2019. Multiphase progenetic development shaped the brain of flying archosaurs. Scientific Reports 9: 10807.","Watanabe A, Gignac PM, Balanoff AM, Green TL, Kley NJ, Norell MA. 2019. Are endocasts good proxies for brain size and shape in archosaurs throughout ontogeny? Journal of Anatomy 234: 291 - 305.","Alonso PD, Milner AC, Ketcham RA, Cookson MJ, Rowe TB. 2004. The avian nature of the brain and inner ear of Archaeopteryx. Nature 430: 666 - 669.","Balanoff AM, Bever GS, Rowe TB, Norell MA. 2013. Evolutionary origins of the avian brain. Nature 501: 93 - 96.","Tsuihiji T, Barsbold R, Watabe M, Tsogtbaatar K, Chinzorig T, Fujiyama Y, Suzuki S. 2014. An exquisitely preserved troodontid theropod with new information on the palatal structure from the Upper Cretaceous of Mongolia. Naturaeissenschaften 101: 131 - 142.","O'Connor JK, Sun C, Xu X, Wang X, Zhou Z. 2012. A new species of Jeholornis with complete caudal integument. Historical Biology 24: 29 - 41.","Elzanowski A. 1991. New observations of the skull of Hesperornis with reconstructions of the bony palate and otic region. Postilla 207: 1 - 20.","Xu L, Buffetaut E, O'Connor J, Zhang X, Jia S, Zhang J, Chang H, Tong H. 2021. A new, remarkably preserved, enantiornithine bird from the Upper Cretaceous Qiupa Formation of Henan (central China) and convergent evolution between enantiornithines and modern birds. Geological Magazine 158: 2087 - 2094.","O'Connor JK, Zhang Y, Chiappe LM, Meng Q, Quanguo L, Di L. 2013 b. A new enantiornithine from the Yixian formation with the first recognized avian enamel specialization. Journal of Vertebrate Paleontology 33: 1 - 12.","Dumont M, Tafforeau P, Bertin T, Bhullar BA, Field D, Schulp A, Strilisky B, Thivichon-Prince B, Viriot L, Louchart A. 2016. Synchrotron imaging of dentition provides insights into the biology of Hesperornis and Ichthyornis, the ' last' toothed birds. BMC EVolutionary Biology 16: 178.","O'Connor JK, Stidham TA, Harris JD, Lamanna MC, Bailleul AM, Hu H, Wang M, You H. 2022. Avian skulls represent a diverse ornithuromorph fauna from the Lower Cretaceous Xiagou Formation, Gansu Province, China. Journal of Systematics and EVolution 60: 1172 - 1198.","Zheng X, O'Connor J, Wang X, Wang M, Zhang X, Zhou Z. 2014. On the absence of sternal elements in Anchiornis (Paraves) and Sapeornis (Aves) and the complex early evolution of the avian sternum. Proceedings of the National Academy of Sciences of the United States of America 111: 13900 - 13905.","Zelenitsky DK, Therrien F, Ridgely RC, McGee AR, Witmer LM. 2011. Evolution of olfaction in non-avian theropod dinosaurs and birds. Proceedings of the Royal Society B: Biological Sciences 278: 3625 - 3634.","Choiniere JN, Neenan JM, Schmitz L, Ford DP, Chapelle KEJ, Balanoff AM, Sipla JS, Georgi JA, Walsh SA, Norell MA, Xu X, Clark JM, Benson RBJ. 2021. Evolution of vision and hearing modalities in theropod dinosaurs. Science 372: 610 - 613."]}

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2023
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47. Cranial osteology and palaeobiology of the Early Cretaceous bird Jeholornis prima (Aves: Jeholornithiformes)

Author

Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe, and Benson, Roger B. J.

Subjects
Jeholornithiformes, Animalia, Biodiversity, Jeholornithidae, Chordata, Aves, Taxonomy
Abstract

Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe, Benson, Roger B. J. (2023): Cranial osteology and palaeobiology of the Early Cretaceous bird Jeholornis prima (Aves: Jeholornithiformes). Zoological Journal of the Linnean Society 198 (1): 93-112, DOI: 10.1093/zoolinnean/zlac089, URL: https://academic.oup.com/zoolinnean/article/198/1/93/6768673

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2023

48. Jeholornis prima Zhou 2002

Author

Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe, and Benson, Roger B. J.

Subjects
Jeholornithiformes, Jeholornis, Animalia, Biodiversity, Jeholornithidae, Jeholornis prima, Chordata, Aves, Taxonomy
Abstract

EMENDED DIAGNOSIS OF J. PRIMA Based on the morphological study of this specimen, we provide the following revised diagnosis for J. prima. A large stem bird with the following combination of features: premaxilla edentulous with short maxillary process; two teeth with blunt crowns in maxilla and three relatively smaller teeth in dentary (new); paired, sheet-like preorbital ossifications present near the nasals (new, autapomorphy); C-shaped lacrimal with short rostrodorsal ramus and lacrimal foramen (new); unreduced postorbital forming a complete postorbital bar with jugal (new); pterygoid rami of vomer much longer than the fused rostral portion, expanded in the middle and lacking the caudodorsal process (new); palatine with broad pterygoid wing and jugal process (new); narrow and restricted mandibular fenestra between prearticular and surangular (new); 27 caudal vertebrae in total, with the transition point occurring after the fifth vertebra; lateral trabecula of sternum absent; caudalmost pair of sternal ribs expanded; first phalanx of the third manual digit twice as long as the second phalanx; ratio of forelimb (humerus plus ulna plus carpometacarpus) to hindlimb (femur plus tibiotarsus plus tarsometatarsus) of ~1.2:1; dorsal margin of the ilium nearly straight and craniodorsal–caudoventrally oriented (modified from Zhou & Zhang, 2002; O’Connor et al., 2012; Zheng et al., 2020)., Published as part of Hu, Han, Wang, Yan, Fabbri, Matteo, O, Jingmai K., Connor, Mcdonald, Paul G., Wroe, Stephen, Yin, Xuwei, Zheng, Xiaoting, Zhou, Zhonghe & Benson, Roger B. J., 2023, Cranial osteology and palaeobiology of the Early Cretaceous bird Jeholornis prima (Aves: Jeholornithiformes), pp. 93-112 in Zoological Journal of the Linnean Society 198 (1) on page 107, DOI: 10.1093/zoolinnean/zlac089, http://zenodo.org/record/7926859, {"references":["Zhou Z, Zhang F. 2002. A long-tailed, seed-eating bird from the Early Cretaceous of China. Nature 418: 405 - 409.","O'Connor JK, Sun C, Xu X, Wang X, Zhou Z. 2012. A new species of Jeholornis with complete caudal integument. Historical Biology 24: 29 - 41.","Zheng X, Sullivan C, O'Connor JK, Wang X, Wang Y, Zhang X, Zhou Z. 2020. Structure and possible ventilatory function of unusual, expanded sternal ribs in the Early Cretaceous bird Jeholornis. Cretaceous Research 116: 104597."]}

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2023
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