Viewing images: white hands that fish

Realizing that LSVD images are levelled for organizational purposes is an important first step towards understanding them as a perpetuation of historical practices and normativities. In the 1970s television series Ways of Seeing, art critic John Berger argues that the process of seeing ‘is less spontaneous and natural than we tend to believe’, and further limited by the fact our eyes can only ‘be in one place at a time’. This has changed with advancing technology, including widespread use of the photographic camera; now images can ‘travel across the world’. Berger died in 2017 and never wrote about images that train AI, but the warning he gives at the end of the first episode is still relevant. Looking straight into the camera, he says, ‘You receive images and meanings which are arranged … be sceptical of it.’Footnote ¹³ Relating Berger's warnings to computer vision, Mitra Azar, Geoff Cox and Leonardo Impett consider them a prescient reaction to an increasingly non-human contemporary visual field marked by ‘alienated forms of social interaction’.Footnote ¹⁴

The empirical work of looking (sceptically) at a subset of the millions of images in LSVDs allows us to confront an idea that some of their creators defend: that images, when compiled, are attempts to understand the world. In fact, computer vision does not do this, even if some experts view its datasets as ‘progress towards genuine scene understanding’, as a ‘new state of the art in class-conditional image synthesis’ and ‘large-scale groupings’.Footnote ¹⁵ They might be large-scale, but a close look at the images present in the many folders of four well-known LSVDs – ImageNet, Flickr-Faces-HQ, Tiny Images and Google Open Image – shows that the promise LSVDs offer to understand the world is not in fact fulfilled.

This idea of a limited understanding of the world can be seen in one of the best-known face image sets for training computers. The Flickr-Faces-HQ dataset contains about 70,000 images of human faces and is widely used to train algorithms capable of creating deep fakes. Algorithmically generated faces are part of the advancements in computer vision since 2014, with the development of a machine-learning infrastructure called Generative Adversarial Network – GAN – in which two networks compete (the generator and the discriminator).Footnote ¹⁶ More recently, this has enabled the production of more realistic images from StyleGAN and its successor StyleGAN2.Footnote ¹⁷

This Person Does Not Exist (TPDNE) is one of the models that results from using GANs. When GAIA researcher Lucas Nunes and I learned of it, we decided to try something simple: for one week, we ran this model endlessly to analyse what kind of faces came up as results. We generated thousands of faces and decided to look at them very quickly in sequence, projecting them onto the wall. The effect was a little nauseating, but it helped us see they were pretty much all white people's faces. After that, we carried out a set of clustering processes (Experimentation 1) that help exemplify limits of the models created from the Flickr-Faces-HQ dataset.Footnote ¹⁸ Nunes created cluster images by overlapping N random and unrepeated fake human faces available in a set of 4,500 images in TPDNE.

The results are near-identical faces (Figure 1) representing a person with seemingly white skin, dark eyes and brown hair, predominant characteristics regardless of how many fake faces are overlapped. Experimentation 1 shows that artist Giselle Beiguelman was correct in arguing that deep fakes are a kind of ‘eugenics of the gaze’, proving that these generated images are not harmless.Footnote ¹⁹ In addition, LSVDs like Flickr-Faces-HQ are created without the consent of those whose faces are used to train these algorithms. In the Big Data era, advancements in privacy resulting from international efforts in reaction to Nazism (such as the 1947 Nuremberg Code and the 1964 Declaration of Helsinki) ‘have gradually been eroded’.Footnote ²⁰

Figure 1. Experimentation 1. A set of three images resulting from the overlapping of different images from the TPDNE. Clusters A, B and C were generated from one hundred, five hundred and one thousand images respectively, taken from the Flickr-Faces-HQ dataset at random and without repetition. Credits: Lucas Nunes/GAIA–C4AI, InovaUSP.

As Experimentation 1 shows, models such TPDNE may contain a lot of data, but not necessarily much diversity; they are not actually suitable for providing a broader understanding of the world.Footnote ²¹ The main reason is that LSVDs like Flickr-Faces-HQ are characterized by ‘the absence of critical engagement with canonical datasets’ – women, as well as racial and ethnic minorities, are negatively impacted.Footnote ²² Recent studies have shown how algorithms based on machine learning discriminate against people on a phenotypic basis and offer readings of the world based on normative standards, almost always related to consumption and hegemonic cultures.Footnote ²³ What does not conform to this strict logic is the unexpected, a type of data that is not welcome in commercial AI.

Experimentation 1 shows the importance of carefully analysing computer vision images, as done with TPDNE. It is a simple approach, but one important to understanding the way machines see, enabled in part by these LSVD images. It is not a way of apprehending, but of prioritizing and decontextualizing, specific elements in visual content through the logic of categorization. This categorization logic can be better understood by focusing on LSVD images of nature. In the ImageNet dataset, a significant part of the ‘train’ subfolder in the ‘imagenet12’ folder was created to separate elements of fauna and flora based on visual characteristics. Snakes are separated into seventeen folders, roses into eight, elephants into two, and so on. Each ImageNet folder has exactly 1,252 images, with rare exceptions.

The practice of specifying becomes even more evident when we take into account that there are many computer vision datasets constituted for species and breeds in websites such as the UCI Machine Learning Repository.Footnote ²⁴ The Stanford Dogs Dataset, for example, is available for download with 20,580 images, divided into 120 dog breeds.Footnote ²⁵ Although it may be delightful to get lost in images of different dogs, by compiling them in this way this system implies an idea of totality that is an oversimplification; after all, where do stray dogs fit into this dataset?

Michel Foucault explains that the practice of taxonomy is not about discovering the names of things, but about the world only containing things with names. In Foucault's words, taxonomy implies ‘a certain continuum of things’.Footnote ²⁶ Kate Crawford also reminds us that this classificatory continuum of taxonomy is not just a movement in itself, but an instrument of power.Footnote ²⁷ In this instrumentalization, identified as ‘systems of classification’ by Vinay Prabhu and Ababa Birhane, power operates in an asymmetrical way, so that what is normal or acceptable is ‘often dictated by dominant ideologies’.Footnote ²⁸

The division logic of LSVDs such as ImageNet and Tiny Images is related more directly to the fact that its categories were taken from a lexical database of semantic relations between words: WordNet, a kind of dictionary of categories. WordNet is but one of the many possible formalizations of this broader logic process. In Google Open Image, for example, there are 1,900,000 images divided into categories, but no information about their origin. In the Leaf Dataset, forty different plant species were photographed over a contrasting background, causing them to look like images from the Rorschach test, a let-down for nature lovers. But for machines, there are specific attributes for each leaf image: ‘class, specimen number, eccentricity, aspect ratio, elongation, solidity, stochastic convexity and smoothness’.Footnote ²⁹ These datasets, and so many others associated with computer vision, are examples of the applicability of what the botanist and zoologist Carl Linnaeus popularized in the eighteenth century: the binomial nomenclature created by Gaspard Bauhin and scientific classification. Linnaeus's taxonomic logic is embedded in machine learning: from specific to general and from general to specific. Furthermore, the fact that important computer vision datasets ‘inherit’ the categories of previous structures – like WordNet or more general modes of taxonomic practice – shows the importance of understanding them beyond their individual structures: more than systems, we are discussing systemic continuities.Footnote ³⁰

Interpreting this process of specification by images in terms of Linnaeus's modern taxonomy places AI in a historical perspective, beyond the confines of engineers and programmers. Authors such as Aníbal Quijano are fundamental for deeper understanding of the relationship between coloniality and modernity. According Quijano, with the conquering of societies in places like Latin America and the African continent, there begins a new world characterized by a ‘global power covering the whole planet’.Footnote ³¹ This violent process is often described as ‘objective’ and ‘scientific’, something that decolonial studies vehemently refute, as it strips away its historical layers. Quijano calls for us not to consider this process a natural phenomenon, but a historical process of power perpetuation. These considerations help us to understand the transformation that Matteo Pasquinelli describes in his Nooscope Manifesto: the project of mechanization of human reason that characterized previous centuries is now a corporate regime of knowledge extractivism and epistemic colonialism.Footnote ³² My argument here serves to place computer vision and its ways of classifying the world in this same historical perspective.

From that perspective, LSVD images are imbricated in the many colonial projects under way between the sixteenth century and the late nineteenth, with their concomitant statistical processes, censuses and division of colonial territories, such as the Treaty of Tordesillas (1494) or the Berlin Conference (1884–5), where the South American and African continents were divided, respectively, from a distance.Footnote ³³ Imperialist initiatives such as these are arguably the historical antecedent to the decontextualized practices of computer vision. It is not hard to relate the straight geographical lines resulting from these two colonial episodes to the rectangles in computer vision referred to by experts as ‘meaning boxes’ – the lines of the latter also cutting out pieces of territories.Footnote ³⁴

What I propose in Experimentation 2 is to consider that this view that selects and extracts from a distance remains active in the practice of ‘seeing’ in AI. The historical continuum identified by Foucault and updated in considering digital infrastructures by Crawford is perceptible, for example, in the Python programming code created by GAIA programmer Bernardo Fontes and myself. This code was used to read the data present in the ‘meaning boxes’ of nature images in the Google Open Image dataset. The code was written to identify these selections and discard them, resulting in images that are no longer important for computer vision, as they were now made just by their unselected areas (Figure 2).

Figure 2. The decanonization process in two images of the Open Image dataset. The white rectangle corresponds to the area of the image that Google's AI considers relevant. Credits: Bernardo Fontes and Bruno Moreschi, GAIA–C4AI, InovaUSP.

The incomplete images provided by Experimentation 2 expose the practices that LSVDs impose on the natural world. These informational gaps not only indicate the idea of extractivism and exploitation, but also provoke us to think about the systemic destructuring that computer vision performs in territories, animals, plants and so on. We call this reverse-engineering experimentation ‘decanonization’, as technical articles about computer vision commonly use the term ‘canonization’ to describe the process of the machine seeing and choosing what should be highlighted in each image.Footnote ³⁵

Evidencing the white areas in these images also encourages me to think about who operates in these extraction spaces. As I write this article, I see an overwhelming majority of white men in the LSVDs. Little by little, I realize I am empirically confirming the fact that most of the images that train AI are taken from Flickr – a social network consisting of images of contemporary life and social practices, mostly from the United States, which produces 30 per cent of Flickr content.Footnote ³⁶ In this tour of normative US images (Halloween pumpkins, people eating pizza, road signs in English), I fix my eyes on a folder that seems like a synthesis of the idea that these images serve as material to enable domination.

ImageNet subfolder 0001 (imagenet10 > train) contains 1,252 images of people the moment they catch a fish. In those pictures, there are always smiling white men showing off their catch like trophies (Figure 3). There are no fishermen folders in Visual Genome, Tiny Image and Open Image, but they are often present in a more dispersed way. Added to this set of fisherman images are an infinite number of images in other folders of these four LSVDs that show small animals, vegetables and minerals, held in the palms of white hands. These images speak louder than words – the many fish caught by these hands are also possible representations of the historical domination of white men from the northern hemisphere over nature.

Figure 3. One of 1,252 images of white men holding their freshly caught fish in an Imagenet folder. The image is low-resolution (4KB), like many others in this dataset. Credits: https://image-net.org.

Looking at the images that make up LSVDs can give us an important understanding of their logic. A visual analysis (e.g. audit cards and institutional review boards) of their content can interfere in the curation process of what should and what should not be part of these datasets.Footnote ³⁷ These actions are not just welcome, but urgent. More careful curation of images and their categories is part of a review that could result in a less problematic computer vision field. However, as we intend to show below, there are, in addition to the millions of images in computer vision datasets, a set of human practices for organizing, labelling and validating those images that should also be looked at carefully.

Seeing through images: sleeping and tagging in the same room

Experimentation 3, called Exch w/ Turkers, is a website that allowed the general public to chat with Amazon Mechanical Turk microworkers (or turkers) for twenty-two days, to raise awareness around the fact that although often presented as autonomous, AI ‘is made of people’.Footnote ³⁸ Visitors communicate with turkers through website chats to understand the daily routine of those behind HITs – used, among other things, to organize and tag images for LSVDs.Footnote ³⁹ The work of turkers is characterized by low remuneration and anonymity in the face of what is being built.Footnote ⁴⁰

Once the interactive part of the Exch w/ Turkers was complete (its static content remains online), I continued a weekly exchange with the turkers where we went back and looked at their responses in the chats to further deepen their considerations. They had access to a file with the chat transcripts where they could insert footnotes for anything that they might like to complement or reconsider.Footnote ⁴¹

In our exchange, I insisted that they help me in the process of understanding the images they tag and describe. It is relevant to note that when talking about the images, the turkers almost never described them, but focused more on how they were organized. One of the participants, Pedro, mentioned more than once that he relates the HITs involving images to the sound of two plug-ins (HIT Catcher and HIT Finder) that he installed on his browser: ‘I like these HITs because they are quick. But, at the same time, it's common for this sound to wake me up at night. If it's a simple image-tagging task, for example, I'll get up to do it’.Footnote ⁴²

Another turker, Sonia, works on the platform to supplement household income and buy imported toys for her two children, like Baby Alive dolls and Lego boxes. To reconcile her work as a turker with being a housewife, she set a computer up in the living room, bedroom and kitchen. They are always on, but, for HITs with images, Sonia prefers to use the big monitor in the living room: ‘Not just because I see the images in a larger size, but because it is also a way to get the kids involved. Sometimes tagging images feels like a game to them’.Footnote ⁴³ We can relate this comment about working as entertainment to the idea of gamification that characterizes online work platforms.Footnote ⁴⁴

A third turker, Anand, was more succinct. He described the images used in his work as trivial and something he forgets about once he finishes a task. He did not send me screenshots of his monitor as he worked, but sent me a very valuable image for our analysis: a photograph of the place that is both his bedroom and his office (Figure 4). Months later, he came back to it in a conversation, asking if this scenario could be different.Footnote ⁴⁵ The question Anand posed is an attempt to contemplate fairer and more efficient ways to train machines. I argue that this image needs to be looked at as critically as the images found in LSVDs. This is because the images provided by turkers show precisely what LSVDs hide: the precarious work carried out by real people.

Figure 4. Turker Anand's bedroom and workspace in New Delhi, India. Credits: Exch w/ Turkers.

Organized by microworkers like Anand, Pedro and Sonia, Visual Genome is a computer vision model that promises to be many things: ‘an ongoing effort to connect structured image concepts to language’, ‘a state of art’, ‘a knowledge base’, ‘an unprecedented innovation in the field of computer vision’, and so on.Footnote ⁴⁶ According to its creator, Visual Genome is a milestone in computer vision because it solves tasks that computers have previously performed poorly; that is, ‘cognitive tasks’.Footnote ⁴⁷ Cognition, for these new image specialists, is a term for automated processes capable of describing images based on straightforward questions and answers. While this is definitely not cognition, it is no small feat. With Visual Genome, it is possible to identify not only that there is a person and a vehicle in an image, but also that there is an elderly man riding a horse-drawn carriage. For this, 108,000 images were marked so that each one had an average of thirty-five objects, twenty-six attributes and twenty-one listed pair relationships.

The article that explains Visual Genome has seventy-two paragraphs, thirty-seven figures (twenty in charts), nine tables with numbers and a mathematical formula, but only two short paragraphs relate not to the image annotations but to those who write them, the turkers. This is superficially explained in a topic called ‘Crowdsourcing strategies’.Footnote ⁴⁸ There, it is revealed that Visual Genome images were tagged entirely by turkers. In total, 33,000 workers from Amazon Mechanical Turk (93.02 per cent from the US and 6.98 per cent from other countries, divided equally between men and women) were responsible for the existence of this computer vision model, having carried out 800,000 HITs. For this, they received between six and eight dollars an hour. The result of this collective work is 108,077 images with 5.4 million regions described, 1.7 million answers and associated questions, 3.8 million identified objects and 2.3 million relations between these objects.

In considering Anand's photograph of his room/workspace and highlighting the low visibility of his work in the technical articles on Visual Genome, I aimed to show what is not commonly seen in LSVDs. Shedding light on the invisibility of turkers invites us to consider that part of the problem with computer vision is not only the limitations of the visual content, but the way in which it is operated/manipulated to be used as training data. Below, encouraged by Anand's question – can this be different? – I intend to think of an alternative way to train computer vision.

Revealing ‘coloniality of power’ with images from a historical museum

In highlighting the problems brought on by training computer vision in a decontextualized and precarious way, and rethinking alternatives, I have been particularly inspired by the expansion of contemporary art from the 1960s, especially the ‘dematerialization of art’.Footnote ⁴⁹ Attention to this history can inform contemporary debate about AI through the non-hegemonic collaborative mediation practices that it made possible. The exploration of new social communication technologies during the last four decades of the twentieth century allowed for artistic practices – partly using Futurism and Dadaism as references – to go beyond the notion of artwork as an object and thereby explore how art infiltrates everyday life. This change opens a field of opportunities for art to act as a cognitive instrument: epistemology replaces the abstract formalism of modern art.Footnote ⁵⁰ This complex ontological shift deeply interested the conceptual art of the time and was described by art critic and curator Walter Zanini as the ‘crisis of the art object and its substrate’.Footnote ⁵¹

Some artists and educators from that period were trying to address Norbert Wiener's concern that understanding society is only possible through the investigation of communication.Footnote ⁵² In some countries, referred to then as ‘Third World’, the transformation of art was more than a self-directed institutional critique, as was partially the case in the US and Europe.Footnote ⁵³ In Latin American countries such as Argentina and Brazil (from where I am writing), the dematerialization of art helped several artistic and educational projects open up space for collaborative exchanges as a reaction to political and social challenges. Some of them were only possible because of non-traditional ways of dealing with images. They interest me as possible alternative methodologies for machine-learning datasets.

Two examples might explain this further. The first is in the field of education, where the adult literacy teaching methodology proposed by Brazilian educator Paulo Freire in the 1960s made use of ‘generative words’ (palavras geradoras) – words related to the everyday lives of adult students, most of whom were lower-class rural and urban workers. The Freirian method proposes creating posters with vocabulary selected in collaboration with students, related to their everyday lives. In this learning context, images are used not as decontextualized illustrations, as is usually the case in textbooks (and in LSVDs), but as visual syntheses of collective and local mediations.

Freire initially tested his method with five rural workers, three of whom, according to him, learned to read and write in little more than a day. This feat caught the attention of the team under Brazilian president João Goulart, resulting in a national literacy campaign that benefited 2 million people from 20,000 different reading circles. However, the 1964 civil–military coup interrupted the project and Freire was forced to go into exile in Chile. The contextualized, localized and collaborative approach that Freire proposed informs my speculation about new ways of tagging images and, consequently, constituting less problematic datasets.

The second example of an alternative use of images, also in 1960s Latin America, was the Mail art exchange between artists in countries under dictatorships, such as Argentina, Brazil, Chile, Colombia, El Salvador, Mexico, Uruguay and Venezuela. Postcard art (drawings, photographs, instructions for performances) was made by art students in Brazil, and the exchange was coordinated by Walter Zanini, a professor at the University of São Paulo and curator at the Museum of Contemporary Art USP. The art critic Cristina Freire described this international ‘solidarity network’ as a social reaction in image form: ‘If collective memory was threatened in public spaces, it was reinforced in alternative networks through virtual encounters’.Footnote ⁵⁴ Zanini considered this exchange project via artistic postcards part of ‘an appeal to immaterial reality’ based on the means of communication of the time.Footnote ⁵⁵

Some sixty years later, at the same Brazilian university where Zanini and his students helped create the Mail art exchange in Latin America, now as a distance-learning experience during the COVID-19 pandemic, the demonumenta project (Experimentation 4) brought together around thitry undergraduates, graduates and professors from the School of Architecture and Urbanism at the University of São Paulo to empirically think of a new way to create machine-learning training datasets.Footnote ⁵⁶ The images used were history paintings from Museu Paulista, an institution inaugurated on 7 September 1895 (Brazilian Independence Day) that was and is fundamental for the construction and perpetuation of the history of Brazil narrated by the São Paulo elite.

For the demonumenta dataset, we chose fifty tags to categorize the museum works, taking into account Freire's method of considering our specific context. General categories were defined, such as ‘sky’, ‘fauna’ and ‘flora’, as well as more specific ones. Categories took into account a decolonial perspective such as ‘white man’,’ ‘indigenous man’, ‘black man’, ‘white woman’, ‘indigenous woman’, ‘black woman’, ‘indigenous child’, ‘black child’, ‘white child’, ‘enslaved’, ‘bandeirante’, ‘military’, ‘coffeemaker’, ‘farmer’ and so on. These categories resulted in our tagging process, which involved a repetitive overlapping of layers that revealed historical correlations (Figure 5). The category ‘white man’, for example, is always associated with other categories like ‘coffee producer’, ‘politician’, ‘military’, and/or ‘bandeirante’.Footnote ⁵⁷ From these categories it is also possible to see that while white men tend to be represented in portrait paintings (their names included in the titles), indigenous and black people almost always appear in groups, occupying smaller areas of the paintings.

Figure 5. An example of overlapping tagging that indicates historical associations – here, the category ‘white man’ is connected to that of ‘politician’. Portrait of Dom Pedro I, 1902, by Benedito Calixto. Credit: José Rosael/Hélio Nobre/Museu Paulista USP.

Working with the codes associated with these files helps reveal how images are selected and arranged differently in LSVDs than those activated by Freire and Zanini. In fuelling computer vision, LSVD images act as part of a ‘culture’ that datasets like ImageNet have helped create in the AI community. Part of this culture is to reduce complex interpretations of images, their elements and their interactions. Thus proposing exchanges and other not-so-traditional approaches is a way to reveal that this culture of levelling categories ‘simplifies and freezes nuanced and complex narratives, obscuring political and moral reasoning behind a category’.Footnote ⁵⁸

Unlike LSVDs, we explicitly indicated the origin of the choices made in constructing the demonumenta dataset. We were aware of our own limitations and the world views we brought to the classification process. The ‘quilombo’ category is a good illustration of this more critical tagging process. Quilombo is the name given to communities formed by fugitive enslaved people in Brazil. Initially, we created it because it was an element of black resistance. However, precisely for this reason, we did not find any representation of quilombos in the collection of the Museu Paulista – an institution in which practically all directors have been white, as well as most of the artists in its collection. Even with no corresponding images in the category quilombo, the demonumenta project team considered it important to maintain it to signal a possibility for future contemplation in other contexts. Even if this tag is never filled in other data collections, this absence will never be merely an empty space in our dataset; quite the contrary: it is revealing of how whiteness impacts the decision of what is and is not relevant in images.

The demonumenta dataset served as more than just an alternative tagging process. It also enabled results with GANs, which allowed us to use AI to identify what were the most characteristic elements of the categories perpetuated in the museum's collection and then to create composite images of them. The algorithmic images of white man and white woman produced by GANs via the demonumenta dataset are represented in formal clothes (including deep-fake ties and dresses). Comparatively, the algorithmic images of black man and black woman do not have a face and are in a working stance (the man is pulling something and the sensualized woman is carrying a vase on her head – Figure 6). Such results shift the discussion of artistic representation from that of an individual artist's decision to a broader aesthetic structure – part of ‘a certain continuum of things’, in Foucault's words (see above). The experience also evidences what Quijano refers to as the ‘coloniality of power’; in other words, that the relations and discourses imposed during the colonial period continue beyond colonization itself, refined through new modalities.Footnote ⁵⁹

Figure 6. Results of the experiences with GANs in the project dataset. From left to right: a white man and white woman, a black man and black woman. This stage of the project was carried out in partnership with Giselle Beiguelman and Bernardo Fontes, with support from the Intelligent Museum artist residency, Center for Art and Media/ZKM Karlsruhe.

It is also possible to relate the algorithmic images of black man and black woman resulting from the demonumenta project (Experimentation 4) with the workers participating in the Exch w/ Turker project (Experimentation 3). Despite being different (one is slavery per se, the other a precariousness of work), the labour exploitation in each has in common the anonymization of the workers. In the forced labour that so characterized colonial Brazil and in the current way of training machines, faces, names and personal life stories of workers are disregarded.

By carrying out a computer vision process from start to finish – in other words, selecting images, tagging some of their parts and training algorithmic models with this material – demonumenta shows that treating training datasets as collective and contextualized experiences can be important for exposing and interrogating the colonial and other logics of power informing the datasets on which computer vision is trained. Even though AI and its datasets present themselves to the world almost as ‘magic tricks’, they are the result of the sedimentation of the historical discourses that their data carry.Footnote ⁶⁰ This junction between colonization and the official cultural apparatus (including official images) is the real lexical and imagery basis for the categories present in computer vision.

Lastly, the notion that datasets are built collectively expands computer vision beyond its visual surfaces. Acknowledging those who organize the images encourages us to expand the idea of only looking at images critically to actions that also transform the field of computer vision, including its practices, spaces and working conditions. In the end, we are not only talking about images; we are talking about people and their relationship with images.