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A dolphin handler makes the signal for together with her hands, followed by create. The two trained dolphins disappear underwater, exchange sounds and then emerge, flip on to their backs and lift their tails. They have devised a new trick of their own and performed it in tandem, just as requested. It doesnt prove that theres language, says Aza Raskin. But it certainly makes a lot of sense that, if they had access to a rich, symbolic way of communicating, that would make this task much easier.

Raskin is the co-founder and president of Earth Species Project (ESP), a California non-profit group with a bold ambition: to decode non-human communication using a form of artificial intelligence (AI) called machine learning, and make all the knowhow publicly available, thereby deepening our connection with other living species and helping to protect them. A 1970 album of whale song galvanised the movement that led to commercial whaling being banned. What could a Google Translate for the animal kingdom spawn?

The organisation, founded in 2017 with the help of major donors such as LinkedIn co-founder Reid Hoffman, published its first scientific paper last December. The goal is to unlock communication within our lifetimes. The end we are working towards is, can we decode animal communication, discover non-human language, says Raskin. Along the way and equally important is that we are developing technology that supports biologists and conservation now.

Understanding animal vocalisations has long been the subject of human fascination and study. Various primates give alarm calls that differ according to predator; dolphins address one another with signature whistles; and some songbirds can take elements of their calls and rearrange them to communicate different messages. But most experts stop short of calling it a language, as no animal communication meets all the criteria.

Until recently, decoding has mostly relied on painstaking observation. But interest has burgeoned in applying machine learning to deal with the huge amounts of data that can now be collected by modern animal-borne sensors. People are starting to use it, says Elodie Briefer, an associate professor at the University of Copenhagen who studies vocal communication in mammals and birds. But we dont really understand yet how much we can do.

Briefer co-developed an algorithm that analyses pig grunts to tell whether the animal is experiencing a positive or negative emotion. Another, called DeepSqueak, judges whether rodents are in a stressed state based on their ultrasonic calls. A further initiative Project CETI (which stands for the Cetacean Translation Initiative) plans to use machine learning to translate the communication of sperm whales.

Yet ESP says its approach is different, because it is not focused on decoding the communication of one species, but all of them. While Raskin acknowledges there will be a higher likelihood of rich, symbolic communication among social animals for example primates, whales and dolphins the goal is to develop tools that could be applied to the entire animal kingdom. Were species agnostic, says Raskin. The tools we develop can work across all of biology, from worms to whales.

The motivating intuition for ESP, says Raskin, is work that has shown that machine learning can be used to translate between different, sometimes distant human languages without the need for any prior knowledge.

This process starts with the development of an algorithm to represent words in a physical space. In this many-dimensional geometric representation, the distance and direction between points (words) describes how they meaningfully relate to each other (their semantic relationship). For example, king has a relationship to man with the same distance and direction that woman has to queen. (The mapping is not done by knowing what the words mean but by looking, for example, at how often they occur near each other.)

It was later noticed that these shapes are similar for different languages. And then, in 2017, two groups of researchers working independently found a technique that made it possible to achieve translation by aligning the shapes. To get from English to Urdu, align their shapes and find the point in Urdu closest to the words point in English. You can translate most words decently well, says Raskin.

ESPs aspiration is to create these kinds of representations of animal communication working on both individual species and many species at once and then explore questions such as whether there is overlap with the universal human shape. We dont know how animals experience the world, says Raskin, but there are emotions, for example grief and joy, it seems some share with us and may well communicate about with others in their species. I dont know which will be the more incredible the parts where the shapes overlap and we can directly communicate or translate, or the parts where we cant.

He adds that animals dont only communicate vocally. Bees, for example, let others know of a flowers location via a waggle dance. There will be a need to translate across different modes of communication too.

The goal is like going to the moon, acknowledges Raskin, but the idea also isnt to get there all at once. Rather, ESPs roadmap involves solving a series of smaller problems necessary for the bigger picture to be realised. This should see the development of general tools that can help researchers trying to apply AI to unlock the secrets of species under study.

For example, ESP recently published a paper (and shared its code) on the so called cocktail party problem in animal communication, in which it is difficult to discern which individual in a group of the same animals is vocalising in a noisy social environment.

To our knowledge, no one has done this end-to-end detangling [of animal sound] before, says Raskin. The AI-based model developed by ESP, which was tried on dolphin signature whistles, macaque coo calls and bat vocalisations, worked best when the calls came from individuals that the model had been trained on; but with larger datasets it was able to disentangle mixtures of calls from animals not in the training cohort.

Another project involves using AI to generate novel animal calls, with humpback whales as a test species. The novel calls made by splitting vocalisations into micro-phonemes (distinct units of sound lasting a hundredth of a second) and using a language model to speak something whale-like can then be played back to the animals to see how they respond. If the AI can identify what makes a random change versus a semantically meaningful one, it brings us closer to meaningful communication, explains Raskin. It is having the AI speak the language, even though we dont know what it means yet.

A further project aims to develop an algorithm that ascertains how many call types a species has at its command by applying self-supervised machine learning, which does not require any labelling of data by human experts to learn patterns. In an early test case, it will mine audio recordings made by a team led by Christian Rutz, a professor of biology at the University of St Andrews, to produce an inventory of the vocal repertoire of the Hawaiian crow a species that, Rutz discovered, has the ability to make and use tools for foraging and is believed to have a significantly more complex set of vocalisations than other crow species.

Rutz is particularly excited about the projects conservation value. The Hawaiian crow is critically endangered and only exists in captivity, where it is being bred for reintroduction to the wild. It is hoped that, by taking recordings made at different times, it will be possible to track whether the speciess call repertoire is being eroded in captivity specific alarm calls may have been lost, for example which could have consequences for its reintroduction; that loss might be addressed with intervention. It could produce a step change in our ability to help these birds come back from the brink, says Rutz, adding that detecting and classifying the calls manually would be labour intensive and error prone.

Meanwhile, another project seeks to understand automatically the functional meanings of vocalisations. It is being pursued with the laboratory of Ari Friedlaender, a professor of ocean sciences at the University of California, Santa Cruz. The lab studies how wild marine mammals, which are difficult to observe directly, behave underwater and runs one of the worlds largest tagging programmes. Small electronic biologging devices attached to the animals capture their location, type of motion and even what they see (the devices can incorporate video cameras). The lab also has data from strategically placed sound recorders in the ocean.

ESP aims to first apply self-supervised machine learning to the tag data to automatically gauge what an animal is doing (for example whether it is feeding, resting, travelling or socialising) and then add the audio data to see whether functional meaning can be given to calls tied to that behaviour. (Playback experiments could then be used to validate any findings, along with calls that have been decoded previously.) This technique will be applied to humpback whale data initially the lab has tagged several animals in the same group so it is possible to see how signals are given and received. Friedlaender says he was hitting the ceiling in terms of what currently available tools could tease out of the data. Our hope is that the work ESP can do will provide new insights, he says.

But not everyone is as gung ho about the power of AI to achieve such grand aims. Robert Seyfarth is a professor emeritus of psychology at University of Pennsylvania who has studied social behaviour and vocal communication in primates in their natural habitat for more than 40 years. While he believes machine learning can be useful for some problems, such as identifying an animals vocal repertoire, there are other areas, including the discovery of the meaning and function of vocalisations, where he is sceptical it will add much.

The problem, he explains, is that while many animals can have sophisticated, complex societies, they have a much smaller repertoire of sounds than humans. The result is that the exact same sound can be used to mean different things in different contexts and it is only by studying the context who the individual calling is, how are they related to others, where they fall in the hierarchy, who they have interacted with that meaning can hope to be established. I just think these AI methods are insufficient, says Seyfarth. Youve got to go out there and watch the animals.

There is also doubt about the concept that the shape of animal communication will overlap in a meaningful way with human communication. Applying computer-based analyses to human language, with which we are so intimately familiar, is one thing, says Seyfarth. But it can be quite different doing it to other species. It is an exciting idea, but it is a big stretch, says Kevin Coffey, a neuroscientist at the University of Washington who co-created the DeepSqueak algorithm.

Raskin acknowledges that AI alone may not be enough to unlock communication with other species. But he refers to research that has shown many species communicate in ways more complex than humans have ever imagined. The stumbling blocks have been our ability to gather sufficient data and analyse it at scale, and our own limited perception. These are the tools that let us take off the human glasses and understand entire communication systems, he says.

See the rest here:
Can artificial intelligence really help us talk to the animals? - The Guardian

The European Commission proposedthe Artificial Intelligence Act (AI Act) last April, after over two years of public consultations. The Act lays down a uniform legal framework [across the EU] for the development, marketing and use of artificial intelligence in conformity with Union values. These values are indicated by democracy, freedom, and equality.

The Act uses a risk-based regulatory approach to all AI systems providers in the EU irrespective of whether they are established within the Union or in a third country. It prohibits certain kinds of AI, places higher regulatory scrutiny on High Risk AI, and limits the use of certain kinds of surveillance technologies, among other objectives.To implement the regulations, the Act establishes the formation of a Union-level European Artificial Intelligence Board. Individual Member States are to direct one or more national competent authorities to implement the Act.

The Act was introduced amid growing recognition of the usefulness of AI in the EUfor example investing in AI and promoting its use can provide businesses with competitive advantages that support socially and environmentally beneficial outcomes.However, it also appears cognizant of the many risks associated with AIwhich can harm protected fundamental rights as well as the public interest. The Act states that it is an attempt to strike a proportionate balance between supporting AI innovation and economic and technological growth, and protecting the rights and interests of EU citizens. Ultimately, the legislation aims to establish a legal framework for trustworthy AI in Europe that helps instil consumer confidence in the technology.

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Why it matters: Described by MIT Technology Review as the most important AI law youve never heard of, commentators suggest that if passed, the Act could once again shape the contours of global technology regulation according to European values. The European Unions (EU) General Data Protection Regulation (GDPR) is already an inspiration for data protection laws in multiple countriesa success story for the EUs brand of Internet regulation that the AI Act explicitly seeks to replicate amid geopolitical rifts in cyber governance. However, some commentators believe the Acts arbitrarilydefinedrisks may stifle innovation by batting so heavily for civil libertiesif not, the Act may prohibitively raise compliance costs for companies seeking to do business with the EU. Additionally, the proposed Act reportedly complements the GDPR, other IT laws in the Union, and various EU charters on fundamental rightsa relatively harmonious regulatory approach that may be useful to India as it negotiates IT legislation and harms across a battery of emerging sectors.

Article 3 of the AI Actdefines AI as any software that is developed with one or more of the techniques and approaches listed in Annex I and can, for a given set of human-defined objectives, generate outputs such as content, predictions, recommendations, or decisions influencing the environments they interact with.

This definition is intended to be technology neutral and future proofwhich means that it hopes to be broad enough to counter new uses of AI in the coming years.

Protecting citizen rights and freedoms is critical, as the Act notes. However, doing so should not outright hinder how all AI is used across the EUafter all, some AI systems demand higher levels of scrutiny than others. The Acts approach centres around maintaining regulatory proportionality.

What this means: it deploys a risk-based regulatory approach that casts restrictions and transparency obligations on AI systems based on their potential to cause harm. This, it hopes, will limit regulatory oversight to only sensitive AI systemsresulting in fewer restrictions on the trade and use of AI within the single market. Two types of AI systems are largely discussed in the Act: Prohibited and High Risk AI systems.

Unacceptable or Prohibited AI Systems: The Act prohibits the use of certain types of AI for the unacceptable risks they pose. These systems can be used for manipulative, exploitative and social control practices. They would violate Union values of freedom, equality and democracy, among others. They would also violate Fundamental Rights in the EU, including rights to non-discrimination and privacy, as well as the rights of a child.

What harms do these systems pose?: For example, AI systems that distort human behaviour may cause psychological harm through subliminal actions that humans cannot perceive. AI social scoring systems (parallels of which are seen in China) may discriminate against individuals or social groups based on data that is devoid of context. Facial Recognition Technologies used by law enforcement agencies are also considered violations of the right to privacy and should be prohibitedexcept in three narrowly defined scenarios where protecting the public interest outweighs the risks of the AI system. These include when searching for the victims of a crime, when investigating terrorist threats or threats to a persons life and safety, or the detection, localisation, identification or prosecution of the perpetrators of specific crimes in the EU.

High Risk AI Systems: High Risk AI systems are those which may significantly harm either the safety, health, or fundamental rights of people in the EU.These systems are often incorporated into larger human-operated services.

What harms do these systems pose?: Examples include autonomous robots performing complex tasks (such as in the automotive industry). In the education sector, testing systems powered by AI could perpetuate discriminatory and stigmatising attitudes toward specific students, affecting their education and livelihood. The same is the case for AI systems determining credit worthinessgiven that they can shape who has access to financial resources.

How are they regulated?:High Risk systems are not as concerning as Unacceptable systems in the Actbut they still face stronger regulatory scrutiny and can only be placed on the Union market or put into service if they comply with certain mandatory requirements. To develop a high level of trustworthiness of high-risk AI systems [among consumers], these systems have to pass a conformity assessment before entering the market, to ensure they meet these uniform standards.

Some ring-fencing initiatives that systems providers must comply with include ensuring that only high-quality data sets are used to power AI systemsto avoid errors and discrimination. Systems providers should also keep detailed records on how the AI system functions to ensure compliance with the Act. To inform users of potential risks better, High Risk systems should be accompanied by relevant documentation and instructions of use and include concise and clear information, including in relation to possible risks to fundamental rights and discrimination. They should be designed such that human beings can oversee their functioning, as well as be resilient to malicious cyber attacks that attempt to change their behaviours (leading to new harms). In certain cases, users should also be notified that they are interacting with an AI system. The proposal suggests that by 2025, compliance costs for suppliers of an average High Risk AI system worth 170,000 could range between 6,000-7,000.

In order to foster innovation, the Act encourages EU Member States to develop artificial intelligence regulatory sandboxeswhere research can be conducted on these technologies under strict supervision before they reach the market.

Non-High Risk AI Systems: Some AI systems may not induce harms as significant as those above. In this case, they could be assumed to be every AI system that is not Prohibited or High Risk. While the Acts provisions dont apply to these simpler systems, it encourages them to comply with them to improve public trust in these systems. The Act has little else to say on these systems.

In many ways, the Actre-emphasises the importance of harmonised business and trade across the EUs single marketas well as Brussels dominance in shaping overarching laws for the bloc. The language of the Act is categorically wary of Member State-level legislation on regulating AIreiterating that conflicting legislation will only complicate the protection of fundamental rights and ease of doing business in the EU. Thats why the Act positions itself as one that harmonises European values across Member States.

That being said, the language of the Act balances domestic interests with extra-territorial ambition. While it seeks to achieve the above objectives, it repeatedly speaks of the Acts potential to shape global regulation on AI, in line with European values. This is not an unfounded hope for a bloc now known to steer technology laws.

Such outward-looking planks can also be read against a growing discourse in global cyber governancewhere debatable dichotomies are drawn by States between the relatively free Internet of democracies, and the walled Internet of China.

While acknowledging the legitimate concerns of algorithmic biases and profiling, some commentators note that the Acts compliance requirements for High Risk AI Systems providers may be impossible to meet. For example, AI systems make use of massive data setsensuring that they are error-free may be a tall order. Additionally, it may not always be possible for a systems operator to fully comprehend how AI worksespecially given the increasing complexity of the technology. If these mechanisms cannot be entirely deciphered, then estimating their potential harms also becomes difficult. Others add that the scope of what constitutes High Risk AI is simply too wideand may stifle innovation due to exorbitant compliance costs.

Additionally, countries like France oppose prohibiting the use of Facial Recognition Technology, while Germany approves an all-out ban on its use in public spaces. Further deliberations and potential amendments may be the only way out of this intra-EU stalemate.

A report by the UK-based Ada Lovelace Institute further argues that the Act mistakenly conceives AI systems to be a final product. Instead, they are systems delivered dynamically through multiple hands,which means that they impact people not just at the implementation stage, but before that as well. The Act doesnt account for this life cycle of AI. Additionally, it focuses entirely on the risk-based approach, with little isolated discussion of the role played by citizens consuming these services. The report argues that this approach is incompatible with legislation concerned with Fundamental Rights. The report further describes the perceived risks of AI as arbitrary, calling for an assessment of these systems based on reviewable criteria. Finally, while the Act spends much time on reviewing the risks of prohibited and High Risk AI, it fails to review the risks of all AI services at large.

EU Member States are currently proposing changes to the Actwhether these deficiencies will be addressed, and when, remains to be seen.

This post is released under aCC-BY-SA 4.0 license. Please feel free to republish on your site, with attribution and a link. Adaptation and rewriting, though allowed, should be true to the original.

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Artificial Intelligence Act in the European Union (EU): Risks and regulations - MediaNama.com

Artificial intelligence is no longer tied to the realm of science fiction. Machine learning is here and can be found in your pocket, car, online, and offline.Machine learning looks for patterns, and any successful guesses are logged to create the next generation of AI. This duplication process continues until you have an algorithm able to make decisions for itself. There are, however, drawbacks to such learning technology, and the most obvious downsides concern our privacy, security, and individuality.

AI can be used by the powerful for wrongful actions. It currently helps governments find new ways to censor material online. Artificial Intelligence can collect data in secret and gain access to the personal information of users worldwide.This is where Virtual Private Networks (VPN) become seemingly necessary. VPNs work by serving as a middleman to trick the host website into thinking youre physically somewhere else. This means data collectors cant get an exact read on your geographic, historic, or personal information. Once you choose your VPN protocol, you can enjoy certain anonymity in a world where this is seemingly impossible.

AI is even more beneficial for VPN technology than it is for bad actors. A study from the Journal of Cyber Security Technology revealed that AI and machine learning allow modern VPNs to achieve 90 percent accuracy. Simply put, VPNs are critical to any action or conversation involving cyber security awareness.

This is done through AI-based routing, which allows Internet users to connect to a VPN server that is closest to the destination server. This not only optimizes ping but also makes connections more secure by allowing traffic to stay within the network. It also makes the user much harder to track.Home-based networks are much more secure with AI-powered VPNs. The average security breach is just as common on a home network as it is on corporate infrastructure.

Because VPNs using AI can help counter other AI-based algorithms, they play an especially important role in dodging censorship. Censorship is increasingly common in many nations, and one of the primary uses of VPNs is tricking a host server into thinking you are somewhere else. While this usually amounts to gaining access to streaming platforms not available in certain regions, this is also important for getting outside sources for news, information, and web services. Its a small wonder that VPNs are used frequently in regions like China where national firewalls prevent even basic services from companies like Google, PayPal, or Amazon.

Despite what VPNs can offer now, AI-powered changes to VPN technology are coming. Future versions of VPNs will offer the following technologies:

When it comes to AI, VPNs are using fire to fight fire. Machine learning can help combat the AI threats online which helps boost your ability to stay secure and private.When you go online, your actions are tracked and cataloged whether you like it or not. Each piece of information seems banal on its own, but when amalgamated, your online persona becomes apparent. This is why after browsing a retail site, you will often see advertisements for that same site.

VPNs, coupled with AI, help to counter this and more. Bad actors on the internet can use these pieces of information to breach your secure documents or invade your privacy for nefarious purposes. With AI helping to plug these breaches, VPNs are more secure than ever before.

The rapid advancement of internet technology has made it easy to overlook potential threats that come with it. Security breaches average damages of over $4 million as of 2021, and its only getting worse. VPN technology, coupled with AI and machine learning, serves as an example of important security measures that internet users worldwide should start to see as a necessity.

Read this article:
The Impact of AI on the Future of VPN Technology - IoT For All