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By Joyjit Chatterjee and Nina Dethlefs, University of Hull Cottingham

Artificial Intelligence (AI) is much more than just a buzzword nowadays. It powers facial recognition in smartphones and computers, translation between foreign languages, systems which filter spam emails and identify toxic content on social media, and can even detect cancerous tumours. These examples, along with countless other existing and emerging applications of AI, help make people's daily lives easier, especially in the developed world.

As of October 2021, 44 countries were reported to have their own national AI strategic plans, showing their willingness to forge ahead in the global AI race. These include emerging economies like China and India, which are leading the way in building national AI plans within the developing world.

Notably, the lowest-scoring regions in this index include much of the developing world, such as sub-Saharan Africa, the Carribean and Latin America, as well as some central and south Asian countries.

The developed world has an inevitable edge in making rapid progress in the AI revolution. With greater economic capacity, these wealthier countries are naturally best positioned to make large investments in the research and development needed for creating modern AI models.

In contrast, developing countries often have more urgent priorities, such as education, sanitation, healthcare and feeding the population, which override any significant investment in digital transformation. In this climate, AI could widen the digital divide that already exists between developed and developing countries.

The hidden costs of modern AI AI is traditionally defined as "the science and engineering of making intelligent machines". To solve problems and perform tasks, AI models generally look at past information and learn rules for making predictions based on unique patterns in the data.

AI is a broad term, comprising two main areas - machine learning and deep learning. While machine learning tends to be suitable when learning from smaller, well-organised datasets, deep learning algorithms are more suited to complex, real-world problems - for example, predicting respiratory diseases using chest X-ray images.

Many modern AI-driven applications, from the Google translate feature to robot-assisted surgical procedures, leverage deep neural networks. These are a special type of deep learning model loosely based on the architecture of the human brain.

Crucially, neural networks are data hungry, often requiring millions of examples to learn how to perform a new task well. This means they require a complex infrastructure of data storage and modern computing hardware, compared to simpler machine learning models. Such large-scale computing infrastructure is generally unaffordable for developing nations.

Beyond the hefty price tag, another issue that disproportionately affects developing countries is the growing toll this kind of AI takes on the environment. For example, a contemporary neural network costs upwards of US$150,000 to train, and will create around 650kg of carbon emissions during training (comparable to a trans-American flight). Training a more advanced model can lead to roughly five times the total carbon emissions generated by an average car during its entire lifetime.

Developed countries have historically been the leading contributors to rising carbon emissions, but the burden of such emissions unfortunately lands most heavily on developing nations. The global south generally suffers disproportionate environmental crises, such as extreme weather, droughts, floods and pollution, in part because of its limited capacity to invest in climate action.

Developing countries also benefit the least from the advances in AI and all the good it can bring - including building resilience against natural disasters.

Using AI for good While the developed world is making rapid technological progress, the developing world seems to be underrepresented in the AI revolution. And beyond inequitable growth, the developing world is likely bearing the brunt of the environmental consequences that modern AI models, mostly deployed in the developed world, create.

But it's not all bad news. According to a 2020 study, AI can help achieve 79 per cent of the targets within the sustainable development goals. For example, AI could be used to measure and predict the presence of contamination in water supplies, thereby improving water quality monitoring processes. This in turn could increase access to clean water in developing countries.

The benefits of AI in the global south could be vast - from improving sanitation, to helping with education, to providing better medical care. These incremental changes could have significant flow-on effects. For example, improved sanitation and health services in developing countries could help avert outbreaks of disease.

But if we want to achieve the true value of "good AI", equitable participation in the development and use of the technology is essential. This means the developed world needs to provide greater financial and technological support to the developing world in the AI revolution. This support will need to be more than short term, but it will create significant and lasting benefits for all. (This article is syndicated by PTI from The Conversation)

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Developing countries are being left behind in the AI race - and that's a problem for all of us - Economic Times

Children and young people are growing up in an increasingly digital age, where technology pervades every aspect of their lives. From robotic toys and social media to the classroom and home, artificial intelligence (AI) is a ubiquitous part of daily life. It's vital therefore that ethical guidelines protect them and ensure they get the best from this emerging technology.

Generation Z, who have grown up with AI, are uniquely placed to offer an insight into the potential issues of AI targeted at children and help create governance guidelines. With that in mind the World Economic Forum has set up the AI Youth Council, a global diverse group comprising young people interested in AI.

Members serve as part of the Generation AI project community and have been central to the creation of the Artificial Intelligence for Children Toolkit, published 29 March 2022. The AI Youth Council is designed to bring together young people from 14 to 21 years of age worldwide to discuss AI ethics and governance.

Born between 1996 and 2012, Generation Z is recognized as the digital native generation. We were raised in an era defined by the internet, a time characterized by massive digitalization: social networks were launched, new technologies were created, and AI began its cross-industry debut.

As a result, Gen Z evolved alongside technology, which impacted our childhood in multiple dimensions. With social media, our methods of interaction changed. Instant connectivity translated to spending time with friends 24/7. We easily absorbed new tech trends, and our education was augmented by the integration of new software.

Similarly, born between 2013-2024, Generation Alpha, the first true AI native generation, is experiencing the effects of AI right now. Kids seamlessly interact with AI chatbots and smart toys, use of IoT devices is second nature, and they are used to real-time information access. The effects of AI on childhood are evident: it makes kids crave optimized experiences and hyper-connectivity, whether at home, in school or with friends.

Jianyu Gao, Columbia University, BS in Computer Science, USA

I was raised on an unregulated internet with minimal literacy in privacy and safety, and the adults around me didnt know how to educate me to protect myself because they were just as ignorant as I was. I did stay out of danger because I knew what I was doing I was lucky, but too many other children were not. The internet has given us the opportunity to connect with people around the world who would otherwise be out of reach, but has also exposed children to disturbing content, harmful ideologies, brainwashing communities and social circles, cyberbullies and online stalkers, predators, or other dangerous elements who might not have had access to them in real life.

As we transition into a post-pandemic world that not only lives with the internet but lives on the internet, I reflect on my childhood as a girl with a laptop with worries for the future, but also with the resolve to do better for the youth that will grow up with AI. If we expect AI to be just as human as we are, then we must learn from my generations experiences growing up with technologies such as the internet and prepare for the prospect that AI will not always learn from the best of us.

Guido Putignano, Bachelor of Engineering and Biomedical Engineering, Politecnico di Milano

One of the first times I got in contact with technology was when I was 12. I went to the shop and I saw strange objects that could make you go into other dimensions. At that time, these devices were a one-hour distraction after my evening homework. From the beginning, I remember that technology being harmful to me. I wasted many days watching videos without being intentional about what I was learning. When I turned 16, I started to use these devices proactively. I started making these devices work for me, rather than the opposite.

I think that the best way to predict the future is to create it yourself. I am an optimist, and I think that personalisation and high-speed connectivity will make anything far better than it is today. In this case, AI systems go from being objects to being subjects. One example is in the fields of education and healthcare. Imagine how awesome it would be to have an AI system that could help you personalise many parts of your life and be at the centre of your growth. That system could track thousands of parameters, making astonishingly accurate predictions of your future self. Those opportunities will be a reality in the future.

Joy Fakude, University of Johannesburg, South Africa

Personally, growing up in South Africa, technology didnt have that great of an impact in my life because I didnt have access to it. The closest I came to a laptop was a toy laptop where I practised maths questions, English sentence construction and played some games. Then I advanced to my first cell phone a BlackBerry which I thought was the coolest thing on planet Earth. I then had access to the internet and social media, however access to WiFi became a serious problem and unfortunately that is the reality for a lot of South African youngsters today.

Not having access to data never mind smart phones or laptops in a world that is speeding into a digital era, many South African teens are left behind not even knowing what AI is or what a digital footprint is, or not even knowing how to protect your data. My biggest concern for future generations of South Africans is that the rapid developments of AI technologies leave them stuck in the mud. That they arent taught and because they arent taught cant adapt and, according to Darwins theory of evolution, dont survive.

Born in 2003, my childhood was situated in the transitional stage from floppy disks and BlackBerry phones to social media powerhouses and streaming services. Most of my early interaction with technology was limited to my Sony camera and Nintendo S4. By the time I was 11, I relented to peer pressure and created an Instagram account. As I pondered how to use my new platform, it seemed natural to present the version of myself that fit my current interests. I used the profile Gracie Dancer to perform self-choreographed dance routines or rave about my new tap shoes. Gracie Singer was where I posted all my off-pitched covers of the latest pop songs.

But what was on the surface an apparently innocuous search for a sense of community began affecting me in a way I didnt expect. As my interests evolved, I felt I was wrong for wanting to try different things. The uncertainty of not knowing who there was behind the screen made me feel as if though I was constantly being watched and judged. I began to fear mistakes at a time in my life when they should have been the most welcomed.

While technology has undeniable potential, I worry that the coming generation of children are growing up in a society where we are understood by others solely through our internet personas. Genuine relationships, interests, and activities will come second to keeping up the illusion of perfection, which so often means conformity.

Ecem Yilmazhaliloglu from Turkey, studying at Stanford University

As the last generation to learn navigating bulky, old system units in computer lessons at school and the first generation to grow up having a Facebook profile, I belong to what Id like to call the transition generation. As the new technologies social media, touch screens, cloud storage systems, and AI rapidly made their way into our world and our homes, we learned to adapt and experiment though trial and error, as there was no previous generation to show us the ropes.

When I got my first computer and opened up my first social media profile at eight, to play online games with my school friends, none of us thought about the consequences of our actions. Starting to engage in these technologies with the purest of intentions, in our attempt to fulfill the basic human need to socialize, to connect, we made ourselves vulnerable to the dangers that lurked in the technologys shadows. The world has since realized its mistake in being unprepared against these dangers, but many of us had already become victims of catfishing, hacking, and even stalking.

While technology offered us many benefits there was always equal amounts of risk involved. Having learnt this in the past decade, both adults and children, it is our responsibility to provide guidance, protect the next generations and help navigate these technologies responsibly and for the good of all. It is our job to take action on minimizing the risks and maximizing the benefits, and provide the necessary wisdom and support, which we, the transition generation, lacked.

Kathleen Esfahany, Computer Science & Neurology, MIT, USA

I was born in 2000 to two computer scientists. Although technological innovation dramatically changed my life with each passing year, the shift into a technology-filled world felt entirely natural to me. The phenomenon of mirrored growth helped cement my identity as a digital native: for much of my childhood, each milestone in my own cognitive development was mirrored by technological advances and a deepening immersion in technology as an educational and social tool.

As my curiosity about the world grew, online news and social media proliferated, making it possible for me to follow events and connect with others across the globe. I can also thank my parents, who used their expertise on computers to help me understand the seemingly magical devices around me, empowering me to think about how to use technology for my own purposes and create technology of my own.

Todays youth are growing up with rapid advances in AI. Already, we are seeing how the unprecedented efficiency and personalization of AI-powered technology can elevate todays youths ability to learn, form personal relationships, and create joy. To optimize it for childrens safety and emotional well-being, I believe it is critical that AI-powered technology is designed so that it can match the diverse needs and abilities found throughout childhood development. My hope is that the combination of well designed AI-powered technology for youth and educational programs about AI will empower and inspire todays youth to harness AI responsibly to bring to life their visions for the future.

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AI ethics: digital natives on protecting future generations | World Economic Forum - World Economic Forum

Have a look at the top 5 benefits of using Artificial intelligence in software testing

One of the recent buzzwords in the software development industry is artificial intelligence. Even though the use of artificial intelligence in software development is still in its infancy, the technology has already made great strides in automating software development. Integrating AI in software testing enhanced the quality of the end product as the systems adhere to the basic standards and also maintain company protocols. So, let us have a look at some of the other crucial benefits offered by AI in software testing.

A method of testing that is getting more and more popular every day is image-based testing using automated visual validation tools. Many ML-based visual validation tools can detect minor UI anomalies that human eyes are likely to miss.

Shared automated tests can be used by the developers to catch problems quickly before sending them to the QA team. Tests can be run automatically whenever the source code changes, checked in and notified the team or the developer if they fail.

Manual testing is a slow process. And every code change requires new tests that consume the same amount of time as before. AI can be leveraged to automate the test processes. AI provides for precise and continuous testing at a fast pace.

AI/ ML tools can read the changes made to the application and understand the relationship between them. Such self-healing scripts observe changes in the application and start learning the pattern of changes and then can identify a change at runtime without you having to do anything.

With software tests being repeated each time source code is changed, manually happening those tests can be not only time-consuming but also expensive. Interestingly, once created automated tests can be executed over and over, with zero additional cost at a much quicker pace.

Conclusion: The future of artificial intelligence and machine learning is bright. AI and its adjoining technologies are making new waves in almost every industry and will continue to do so in the future.

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Analytics Insight is an influential platform dedicated to insights, trends, and opinions from the world of data-driven technologies. It monitors developments, recognition, and achievements made by Artificial Intelligence, Big Data and Analytics companies across the globe.

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Top 5 Benefits of Artificial intelligence in Software Testing - Analytics Insight

While quantum computers exist in the lab, general-purpose quantum computers arent yet available for commercial use. How can businesses respond to potential disruptions from this technology before it has actually emerged into the mainstream market? One company that has been investing substantially into quantum computing is Infosys, and so the authors reached out to several researchers and business leaders at the company to learn more about their work. They found that Infosys has taken a hybrid approach, blending elements of classical and quantum computing in order to build a bridge from the reality of today to the disruptive technologies of tomorrow. This has helped the company make headway in leveraging quantum technology in a variety of applications, including optimization problems, machine learning, and cybersecurity. While theres still a long way to go when it comes to developing and applying quantum tech, a hybrid approach is enabling companies to serve customers today, while getting a leg up on the future even if some of the technology involved is still catching up.

Scientists have theorized about the potential of quantum computing that is, a new approach to computation that uses probabilities, rather than binary signals, to make calculations for decades. But in recent years, both private and public sector investment into developing quantum computers has grown significantly, with one report projecting investments of more than $800 million in 2021 alone.

Quantum technology could revolutionize everything from genomic sequencing to transport route optimization, from code-breaking to new materials development. But while quantum computers exist in the lab, general-purpose quantum computers arent yet available for commercial use. How can businesses respond to potential disruptions from this technology before it has actually emerged into the mainstream market?

To explore this question, its helpful to look to historical examples of major technological transitions, such as the shift from analog to digital photography, or from internal combustion to electric engines. In many of these cases, companies leveraged a hybrid approach to integrate new technologies: Rather than attempting to switch over to the new technology all at once, they developed products that combined elements of old and new technologies. For example, the hybrid-electric Prius enabled Toyota to learn about making electric cars while still leveraging its foundation of expertise with traditional gas engines. After launching this initial hybrid model, Toyota moved forward with plug-in hybrid cars and fuel cell electric cars, paving the way for its eventual launch of all-electric cars several years later.

So, what might a similar hybrid approach look like for quantum computing? One organization thats been investing substantially into quantum computing is Infosys, and so we reached out to several researchers and business leaders at the company to learn more about their work. Through a series of in-depth interviews, we found that Infosys has been experimenting with two hybrid approaches to begin commercializing existing innovations and build a bridge to the future of quantum computing:

Infosys has been leveraging these approaches in many different fields, both independently and in partnership with startups. Below, we describe three key applications of quantum computing in which Infosys has begun investing: optimization problems, in which the company has been exploring the potential of quantum-inspired algorithms, and machine learning and cybersecurity solutions, in which Infosys has begun leveraging hybrid models.

While classical algorithms are effective in many domains, they can be prohibitively slow and expensive when it comes to solving certain kinds of optimization problems. For example, in finance, it is difficult to use traditional computers to optimize portfolios, since this necessitates rapid, real-time analysis of the constantly fluctuating risk values associated with investing in each individual stock. To address this challenge, Infosys developed quantum-inspired algorithms to optimize the selection and allocation of assets. This enabled the company to build a diversified portfolio that maximized returns and minimized risks for more than 100 stocks in just one minute, ultimately achieving a 21% improvement in returns compared to conventional (i.e., non-quantum-inspired) asset allocation strategies.

Another area in which traditional computers can struggle to optimize accurately and cost-effectively is in supply chain. To explore the potential for quantum computing in this space, Infosys partnered with QpiAI, a startup developing quantum-inspired solutions for supply chain optimization. While these projects are still in development, the team has already shown that its algorithms enable a 60% cost reduction in vehicle routing optimization.

Machine learning algorithms depend on highly intensive (and expensive) computation power to extract learnings from large datasets. Especially when it comes to analyzing datasets that are highly imbalanced that is, where the cases you care about identifying are extremely rare quantum computing could both dramatically reduce costs and improve these models effectiveness.

In financial fraud detection, for example, the number of fraudulent transactions is tiny compared to the number of normal transactions. This makes it hard to develop classical machine learning algorithms that can identify fraud sufficiently quickly and accurately. But Infosys took a hybrid approach, building out a hybrid neural network algorithm in which most network layers used classical computing, while some layers incorporated input from a quantum computer. With this system, Infosys was able to achieve a 1.66% improvement in the accuracy of its fraud detection tool a difference that may seem small, but has the potential to translate to significant savings given the massive scale of the global financial system.

Current cybersecurity protocols typically use pseudo-random numbers to encrypt sensitive information such as passwords, personal data, or even blockchains. The problem is, quantum computers can easily crack the methods traditional computers use to generate random numbers, potentially posing a huge threat to any organization using these standard encryption tools. Yet, alongside this new threat, quantum technology also holds new possibilities: Quantum systems can produce a large, reliable stream of true random numbers that cannot be decrypted with either classical or quantum systems.

Infosys partnered with quantum cybersecurity firm Quintessence Labs to develop a hybrid solution that first generates true random keys with a quantum random number generator, and then funnels those keys into classical cryptographic algorithms and encryption systems. This approach makes it possible to generate truly random, unpredictable numbers for use in a wide variety of existing commercial applications, enabling a new level of cybersecurity for any organization that works with large quantities of sensitive data.

. . .

These applications might sound like science fiction, but they are very real. While quantum computers still have a long way to go before theyre ready for prime time, businesses are already leveraging quantum technologies in hybrid solutions, blending the old with the new to build a bridge between the reality of today and the potential of tomorrow. Investing in this hybrid strategy now is the best way for companies to develop the expertise in quantum principles and software development that will become critical as these technologies reach maturity. It also means that regardless of how exactly quantum hardware develops and which platforms ultimately emerge as industry standards, the algorithms being developed today will be able to operate on almost any type of quantum hardware (rather than being limited to just one system). Ultimately, taking a hybrid approach enables companies to serve customers today, while getting a leg up on the future even if some of the technology involved is still catching up.

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Making Quantum Computing a Reality - HBR.org Daily

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