User:Behatted/Applications of artificial intelligence

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Artificial intelligence (AI) has been used in applications to alleviate certain problems throughout industry and academia. AI, like electricity or computers, is a general purpose technology that has a multitude of applications. It has been used in fields of language translation, image recognition, credit scoring, e-commerce and other domains.^[1] - note to self, this short description is vacuous and should be totally replaced

Government

AI facial recognition systems are used for mass surveillance, notably in China.^[2][3]

In 2019, Bengaluru, India deployed AI-managed traffic signal. This system uses cameras to monitor traffic density and adjust signal timing based on the interval needed to clear traffic.^[4]

Military

Various countries are deploying AI military applications.^[5] The main applications enhance command and control, communications, sensors, integration and interoperability.^[6] Research is targeting intelligence collection and analysis, logistics, cyber operations, information operations, and semiautonomous and autonomous vehicles.^[5] AI technologies enable coordination of sensors and effectors, threat detection and identification, marking of enemy positions, target acquisition, coordination and deconfliction of distributed Joint Fires between networked combat vehicles involving manned and unmanned teams.^[6] AI was incorporated into military operations in Iraq and Syria.^[5]

Worldwide annual military spending on robotics rose from US$5.1 billion in 2010 to US$7.5 billion in 2015.^[7][8] Military drones capable of autonomous action are in wide use.^[9] Many researchers avoid military applications.^[6]

Military

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The

AI can also be used to operate planes analogously to their control of ground vehicles. Autonomous drones can fly independently or in swarms.^[11]

AOD uses the Interactive Fault Diagnosis and Isolation System, or IFDIS, which is a rule-based expert system using information from

Speech recognition allows traffic controllers to give verbal directions to drones.

Artificial intelligence supported design of aircraft,^[12] or AIDA, is used to help designers in the process of creating conceptual designs of aircraft. This program allows the designers to focus more on the design itself and less on the design process. The software also allows the user to focus less on the software tools. The AIDA uses rule based systems to compute its data. This is a diagram of the arrangement of the AIDA modules. Although simple, the program is proving effective.

NASA

In 2003 a

The 2016 Intelligent Autopilot System combined apprenticeship learning and behavioral cloning whereby the autopilot observed low-level actions required to maneuver the airplane and high-level strategy used to apply those actions.^[15]

Law

It has been suggested that this section be Artificial intelligence in legal informatics. (Discuss ) (April 2022)

Legal analysis

AI is a mainstay of law-related professions. Algorithms and machine learning do some tasks previously done by entry-level lawyers.^[16] While its use is common, it is not expected to replace most work done by lawyers in the near future.^[17]

The electronic discovery industry uses machine learning to reduce manual searching.^[18]

Law enforcement and legal proceedings

One concern relates to algorithmic bias, AI programs may become biased after processing data that exhibits bias.^[20] ProPublica claims that the average COMPAS-assigned recidivism risk level of black defendants is significantly higher than that of white defendants.^[19]

Industry

Automotive

AI in transport is expected to provide safe, efficient, and reliable transportation while minimizing the impact on the environment and communities. The major development challenge is the complexity of transportation systems that involves independent components and parties, with potentially conflicting objectives.^[21]

AI-based

There also are prototypes of autonomous delivery vehicles, sometimes including delivery robots.^{[29][30][31][32][33][34][35]}

AI has been used to optimize traffic management, which reduces wait times, energy use, and emissions by as much as 25 percent.^[36]

Transportation's complexity means that in most cases training an AI in a real-world driving environment is impractical. Simulator-based testing can reduce the risks of on-road training.^[37]

AI underpins self-driving vehicles. Companies involved with AI include

Autonomous vehicles require accurate maps to be able to navigate between destinations.[41] Some autonomous vehicles do not allow human drivers (they have no steering wheels or pedals).^[42]

Maritime

Neural networks are used by situational awareness systems in ships and boats.^[43] There also are autonomous boats.

Recommendation systems

A recommendation system predicts the "rating" or "preference" a user would give to an item.^[44][45] Recommendation systems are used in a variety of areas, such as generating playlists for video and music services, product recommendations for online stores, or content recommendations for social media platforms and open web content recommenders.^[46][47]

Web feeds and posts

Machine learning is also used in

Online gambling companies use AI to improve customer targeting.[56]

Personality computing AI models add psychological targeting to more traditional sociodemographic or behavioral targeting.^[57] AI has been used to customize shopping options and personalize offers.^[58]

Virtual assistants

^[relevant?]

Language translation

AI has been used to automatically translate spoken language and textual documents based context.^[60] There also is research and development to decode and conduct animal communication.^[61][62]

Facial recognition and image labeling

AI has been used in facial recognition systems, with a 99% accuracy rate.^[63] AI has also been demonstrated to generate speech to describe images to blind people.^[64]

Cyber security

Cyber security companies are adopting neural networks, machine learning, and natural language processing to improve their systems.^[65]

Applications of AI in cyber security include:

• Network protection: Machine learning improves intrusion detection systems by broadening the search beyond previously identified threats.
• Endpoint protection: Attacks such as ransomware can be thwarted by learning typical malware behaviors.
• Application security: can help counterattacks such as
  distributed denial-of-service
  .
• Suspect user behavior: Machine learning can identify fraud or compromised applications as they occur.^[66]

Google fraud czar Shuman Ghosemajumder has said that AI will be used to completely automate most cyber security operations over time.^[67]

Agriculture

In agriculture, AI has helped farmers identify areas that need irrigation, fertilization, pesticide treatments or increasing yield.^[68] Agronomists use AI to conduct research and development. AI has been used to predict the ripening time for crops such as tomatoes,^[69] monitor soil moisture, operate agricultural robots, conduct predictive analytics,^[70][71] classify livestock pig call emotions,^[61] automate greenhouses,^[72] detect diseases and pests,^[73][74] and save water.^[75]

Finance

It has been suggested that this section be Artificial intelligence in finance. (Discuss ) (April 2022)

Banks use AI to organize operations, for bookkeeping, invest in stocks, and manage properties. AI can react to changes when business is not taking place.[77] AI is used to combat fraud and financial crimes by monitoring behavioral patterns for any abnormal changes or anomalies.^[78][79][80]

The use of AI in applications such as online trading and decision making has changed major economic theories.^[81] For example, AI-based buying and selling platforms estimate individualized demand and supply curves and thus enable individualized pricing. AI machines reduce information asymmetry in the market and thus make markets more efficient.^[82]

Trading and investment

Algorithmic trading involves the use of AI systems to make trading decisions at speeds orders of magnitude greater than any human is capable of, making millions of trades in a day without human intervention. Such high-frequency trading represents is a fast-growing sector. Many banks, funds, and proprietary trading firms now have entire portfolios that are AI-managed. Automated trading systems are typically used by large institutional investors, but include smaller firms trading with their own AI systems.^[83]

Large financial institutions use AI to assist with their investment practices. BlackRock's AI engine, Aladdin, is used both within the company and by clients to help with investment decisions. Its functions includes the use of natural language processing to analyze text such as news, broker reports, and social media feeds. It then gauges the sentiment on the companies mentioned and assigns a score. Banks such as UBS and Deutsche Bank use SQREEM (Sequential Quantum Reduction and Extraction Model) to mine data to develop consumer profiles and match them with wealth management products.^[84]

Underwriting

Online lender

ZestFinance's Zest Automated Machine Learning (ZAML) platform is used for credit underwriting. This platform uses machine learning to analyze data including purchase transactions and how a customer fills out a form to score borrowers. The platform is particularly useful to assign credit scores to those with limited credit histories.[86]

Audit

AI makes continuous auditing possible. Potential benefits include reducing audit risk, increasing the level of assurance, and reducing audit duration.^{[87][quantify]}

History

In the 1980s, AI started to become prominent in finance as

One of the first expert systems to help with financial plans was PlanPowerm and Client Profiling System, created by Applied Expert Systems (APEX). It was launched in 1986. It helped create personal financial plans for people.[90]

In the 1990s AI was applied to fraud detection. In 1993 FinCEN Artificial Intelligence System (FAIS) launched. It was able to review over 200,000 transactions per week and over two years it helped identify 400 potential cases of money laundering equal to $1 billion.^[91] These expert systems were later replaced by machine learning systems.^[92]

Workplace health and safety

AI-enabled chatbots decrease the need for humans to perform basic call center tasks.^[93]

Machine learning in

AI can auto-code workers' compensation claims.^[96][97] AI‐enabled virtual reality systems can enhance safety training for hazard recognition.^[94] AI can more efficiently detect accident near misses, which are important in reducing accident rates, but are often under-reported.^[98]

Human resources

Another application of AI is in human resources. AI can screen resumes and rank candidates based on their qualifications, predict candidate success in given roles, and automate repetitive communication tasks via chatbots.^[99]

Job search

AI has simplified the recruiting /job search process for both recruiters and job seekers. According to

Online and telephone customer service

A Google app analyzes language and converts speech into text. The platform can identify angry customers through their language and respond appropriately.[103] Amazon uses a chatbot for customer service that can perform tasks like checking the status of an order, cancelling orders, offering refunds and connecting the customer with a human representative.^[104]

Hospitality

In the hospitality industry, AI is used to reduce repetitive tasks, analyze trends, interact with guests, and predict customer needs.^[105] AI hotel services come in the form of a chatbot,^[106] application, virtual voice assistant and service robots.

Energy system

Power electronics converters are used in renewable energy, energy storage, electric vehicles and high-voltage direct current transmission. These converters are failure-prone, which can interrupt service and require costly maintenance or catastrophic consequences in mission critical applications.^{[citation needed]} AI can guide the design process for reliable power electronics converters, by calculating exact design parameters that ensure the required lifetime.^[107]

Machine learning can be used for energy consumption prediction and scheduling, e.g. to help with

Telecommunications

Many telecommunications companies make use of heuristic search to manage their workforces. For example, BT Group deployed heuristic search^[112] in an application that schedules 20,000 engineers. Machine learning is also used for speech recognition (SR), including of voice-controlled devices, and SR-related transcription, including of videos.^[113][114]

Sensors

Artificial intelligence has been combined with digital spectrometry by IdeaCuria Inc.,^[115][116] enable applications such as at-home water quality monitoring.

Oil and gas

Games have been a major application^[

game, so a program that plays poker has to reason under uncertainty. The general game players work using feedback from the game system, without knowing the rules.

Healthcare

Main article: Artificial intelligence in healthcare

AI in healthcare is often used for classification, to evaluate a CT scan or electrocardiogram or to identify high-risk patients for population health. AI is helping with the high-cost problem of dosing. One study suggested that AI could save $16 billion. In 2016, a study reported that an AI-derived formula derived the proper dose of immunosuppressant drugs to give to transplant patients.^[139]

Microsoft's AI project Hanover helps doctors choose

ophthalmologist and recommended treatment referrals.^[144]

Another study demonstrated surgery with an autonomous robot. The team supervised the robot while it performed soft-tissue surgery, stitching together a pig's bowel judged better than a surgeon.[145]

EMR

software.

Other healthcare tasks thought suitable for an AI that are in development include:

• Screening^[147]
• Heart sound analysis^[148]
• Companion robots for elder care^[149]
• Medical record analysis
• Treatment plan design^{[citation needed]}
• Medication management
• Assisting blind people^[150]
• Consultations^{[citation needed]}
• Drug creation^[151] (e.g. by identifying candidate drugs^[152] and by using existing drug screening data such as in life extension research)^[153]
• Clinical training^[154]
• Outcome prediction for surgical procedures
• HIV prognosis
• Identifying genomic pathogen signatures of novel pathogens^[155] or identifying pathogens via physics-based fingerprints^[156] (including pandemic pathogens)
• Helping link genes to their functions,^[157] otherwise analyzing genes^[158] and identification of novel biological targets^[159]
• Help development of biomarkers^[159]
• Help tailor therapies to individuals in
  precision medicine^[159][160]

Chemistry and biology

See also: § Health, § Astrochemistry, § Quantum computing, Regulation of chemicals, Computational chemistry § Fields of application, and Laboratory robotics

Machine learning has been used for drug design. It has also been used for predicting molecular properties and exploring large chemical/reaction spaces.^[161] Computer-planned syntheses via computational reaction networks, described as a platform that combines "computational synthesis with AI algorithms to predict molecular properties",^[162] have been used to explore the origins of life on Earth,^[163] drug-syntheses and developing routes for recycling 200 industrial waste chemicals into important drugs and agrochemicals (chemical synthesis design).^[164] There is research about which types of computer-aided chemistry would benefit from machine learning.^[165] It can also be used for "drug discovery and development, drug repurposing, improving pharmaceutical productivity, and clinical trials".^[166] It has been used for the design of proteins with prespecified functional sites.^[167][168]

It has been used with databases for the development of a 46-day process to design, synthesize and test a drug which inhibits enzymes of a particular gene, DDR1. DDR1 is involved in cancers and fibrosis which is one reason for the high-quality datasets that enabled these results.^[169]

There are various types of applications for machine learning in decoding human biology, such as helping to map

DNA motifs.^[171] It is widely used in genetic research.^[172]

There also is some use of machine learning in

bionanotechnology),^[175][176] and materials science.^{[177][178][179]}

Biochemistry

AlphaFold 2 can determine the 3D structure of a (folded) protein in hours rather than the months required by earlier automated approaches and was used to provide the likely structures of all proteins in the human body and essentially all proteins known to science (more than 200 million).^{[180][181][182][183]}

Novel types of machine learning

See also: Artificial brain and Automated reasoning

There are also prototype robot scientists, including robot-embodied ones like the two Robot Scientists, which show a form of "machine learning" not commonly associated with the term.^[184][185]

Similarly, there is research and development of biological "wetware computers" that can learn (e.g. for use as biosensors) and/or implantation into an organism's body (e.g. for use to control prosthetics).^{[186][187][188]}

Moreover, if

whole brain emulation is possible via both scanning and replicating the bio-chemical brain – as premised in the form of digital replication in The Age of Em, possibly using physical neural networks – that may have applications as or more extensive than e.g. valued human activities and may imply that society would face substantial moral choices, societal risks and ethical problems^[189][190] such as whether (and how) such are built, sent through space and used compared to potentially competing e.g. potentially more synthetic and/or less human and/or non/less-sentient types of artificial/semi-artificial intelligence.^{[additional citation(s) needed]} An alternative or additive approach to scanning are types of reverse engineering of the brain.^[191][192]

A subcategory of artificial intelligence is embodied,[193]^[194] some of which are mobile robotic systems that each consist of one or multiple robots that are able to learn in the physical world.

This section is an excerpt from Robotic sensing § Collective sensing and sensemaking.[edit]

Robots may share,^[195] store, and transmit sensory data as well as data based on such. They may learn from or interpret the same or related data in different ways and some robots may have remote senses (e.g. without local interpretation or processing or computation such as with common types of telerobotics or with embedded^[196] or mobile "sensor nodes"). Processing of sensory data may include processes such as facial recognition,^[197] facial expression recognition,^[198] gesture recognition and integration of interpretative abstract knowledge.

Biological computing in AI and as AI

However,

values or data are inappropriate. Computer-aided is a phrase used to describe human activities that make use of computing as tool in more comprehensive activities and systems such as AI for narrow tasks or making use of such without substantially relying on its results (see also: human-in-the-loop).^{[citation needed]} A study described the biological as a limitation of AI with "as long as the biological system cannot be understood, formalized, and imitated, we will not be able to develop technologies that can mimic it" and that if it was understood this doesn't mean there being "a technological solution to imitate natural intelligence".^[199] Technologies that integrate biology and are often AI-based include biorobotics

.

Astronomy, space activities and ufology

See also: § Novel types of machine learning

Artificial intelligence is used in

gravitational wave astronomy.^[202] It could also be used for activities in space such as space exploration, including analysis of data from space missions, real-time science decisions of spacecraft, space debris avoidance,^[203] and more autonomous operation.^{[204][205][206][201]}

In the

'Oumuamua-like interstellar objects, and non-manmade artificial satellites.^[217][218]

Astrochemistry

AI can be used to produce datasets of spectral signatures of molecules that may be involved in the atmospheric production or consumption of particular chemicals – such as phosphine possibly detected on Venus – which could prevent miss assignments and, if accuracy is improved, be used in future detections and identifications of molecules on other planets.^[219]

Archaeology, history and imaging of sites

See also: Digital archaeology

Machine learning can help to restore and attribute ancient texts.^[220] It can help to index texts for example to enable better and easier searching^[221] and classify of fragments.^[222]

Artificial intelligence can also be used to investigate genomes to uncover

genetic history, such as interbreeding between archaic and modern humans by which for example the past existence of a ghost population, not Neanderthal or Denisovan, was inferred.^[223]

Further information: Ancient DNA § Human aDNA, and Genetic history of Europe

It can also be used for "non-invasive and non-destructive access to internal structures of archaeological remains".[224]

Further information: Remote sensing in archaeology

Physics

This section is an excerpt from Machine learning in physics.[edit]

Part of a series of articles about
Quantum mechanics
${\displaystyle i\hbar {\frac {d}{dt}}|\Psi \rangle ={\hat {H}}|\Psi \rangle }$ Schrödinger equation
Introduction Glossary History
Background Classical mechanics Old quantum theory Bra–ket notation Hamiltonian Interference
Fundamentals Complementarity Decoherence Entanglement Energy level Measurement Nonlocality Quantum number State Superposition Symmetry Tunnelling Uncertainty Wave function Collapse
Experiments Bell's inequality Davisson–Germer Double-slit Elitzur–Vaidman Franck–Hertz Leggett–Garg inequality Mach–Zehnder Popper Quantum eraser Delayed-choice Schrödinger's cat Stern–Gerlach Wheeler's delayed-choice
Formulations Overview Heisenberg Interaction Matrix Phase-space Schrödinger Sum-over-histories (path integral)
Equations Dirac Klein–Gordon Pauli Rydberg Schrödinger
Interpretations Bayesian Consistent histories Copenhagen de Broglie–Bohm Ensemble Hidden-variable Local Superdeterminism Many-worlds Objective collapse Quantum logic Relational Transactional Von Neumann–Wigner
Advanced topics Relativistic quantum mechanics Quantum field theory Quantum information science Quantum computing Quantum chaos EPR paradox Density matrix Scattering theory Quantum statistical mechanics Quantum machine learning
Scientists Aharonov Bell Bethe Blackett Bloch Bohm Bohr Born Bose de Broglie Compton Dirac Davisson Debye Ehrenfest Einstein Everett Fock Fermi Feynman Glauber Gutzwiller Heisenberg Hilbert Jordan Kramers Lamb Landau Laue Moseley Millikan Onnes Pauli Planck Rabi Raman Rydberg Schrödinger Simmons Sommerfeld von Neumann Weyl Wien Wigner Zeeman Zeilinger
v t e

Applying classical methods of machine learning to the study of quantum systems is the focus of an emergent area of physics research. A basic example of this is quantum state tomography, where a quantum state is learned from measurement.^[225] Other examples include learning Hamiltonians,^[226][227] learning quantum phase transitions,^[228][229] and automatically generating new quantum experiments.^{[230][231][232][233]} Classical machine learning is effective at processing large amounts of experimental or calculated data in order to characterize an unknown quantum system, making its application useful in contexts including quantum information theory, quantum technologies development, and computational materials design. In this context, it can be used for example as a tool to interpolate pre-calculated interatomic potentials^[234] or directly solving the Schrödinger equation with a variational method.^[235]

A deep learning system was reported to learn intuitive physics from visual data (of virtual 3D environments) based on an unpublished approach inspired by studies of visual cognition in infants.^[236][237] Other researchers have developed a machine learning algorithm that could discover sets of basic variables of various physical systems and predict the systems' future dynamics from video recordings of their behavior.^[238][239] In the future, it may be possible that such can be used to automate the discovery of physical laws of complex systems.^[238]

Materials science

AI could be used for materials optimization and discovery such as the discovery of stable materials and the prediction of their crystal structure.^{[240][241][242]}

Reverse engineering

Machine learning is used in diverse types of reverse engineering. For example, machine learning has been used to reverse engineer a composite material part, enabling unauthorized production of high quality parts,^[243] and for quickly understanding the behavior of malware.^[244] It can also design components by engaging in a type of reverse engineering of not-yet existent virtual components such as inverse molecular design for particular desired functionality^[245] or protein design for prespecified functional sites.^[167][168]

Environmental monitoring

See also: Climate-smart agriculture

Autonomous ships that monitor the ocean, AI-driven satellite data analysis, passive acoustics^[246] or remote sensing and other applications of environmental monitoring make use of machine learning.^{[247][248][249][206]}

For example, "Global Plastic Watch" is an AI-based

ocean pollution – by helping identify who and where mismanages plastic waste, dumping it into oceans.^[250][251]

Early-warning systems

Machine learning can be used to

cyanobacterial bloom outbreaks,^[261] and droughts.^{[262][263][264]}

Computer science

It has been suggested that this section be Artificial intelligence in computer science. (Discuss ) (April 2022)

Programming assistance

Main articles:

Programming environment

GitHub Copilot is an artificial intelligence model developed by GitHub and OpenAI that is able to autocomplete code in multiple programming languages.^[265]

Neural network design

AI can be used to create other AIs. For example, around November 2017, Google's AutoML project to evolve new neural net topologies created

NASNet, a system optimized for ImageNet and POCO F1. NASNet's performance exceeded all previously published performance on ImageNet.^[266]

Quantum computing

Further information: Quantum machine learning

See also: § Chemistry and biology

Machine learning has been used for noise-cancelling in

better source needed

Historical contributions

AI researchers have created many tools to solve the most difficult problems in computer science. Many of their inventions have been adopted by mainstream computer science and are no longer considered AI. All of the following were originally developed in AI laboratories:^[277]

• Time sharing
• Interactive interpreters
• Graphical user interfaces and the computer mouse
• Rapid application development environments
• The linked list data structure
• Automatic storage management
• Symbolic programming
• Functional programming
• Dynamic programming
• Object-oriented programming
• Optical character recognition
• Constraint satisfaction

Media

AI applications analyze media content such as movies, TV programs, advertisement videos or user-generated content. The solutions often involve computer vision.

Typical scenarios include the analysis of images using

for archival or other purposes, and the detection of logos, products or celebrity faces for ad placement.

This list is in prose. You can help by converting this list, if appropriate. Editing help is available. (April 2022)

• Motion interpolation^[278]
• Pixel-art scaling algorithms^[279]
• Image scaling^[280]
• Image restoration^[281][282]
• Photo colorization^[283]
• Film restoration^[284]
• Photo tagging[285]
• Automated species identification

Deep-fakes

In September 2018, U.S. Senator Mark Warner proposed to penalize social media companies that allow sharing of deep-fake documents on their platforms.^[292]

In 2018, Vincent Nozick found a way to detect faked content by analyzing eyelid movements.^[293] DARPA gave 68 million dollars to work on deep-fake detection.^[293]

Audio deep-fakes^[294][295] and AI software capable of detecting deep-fakes and cloning human voices have been developed.^[296][297]

Video content analysis, surveillance and manipulated media detection

AI algorithms have been used to detect deepfake videos.[298]^[299]

Music

AI has been used to compose music of various genres.

David Cope created an AI called Emily Howell that managed to become well known in the field of algorithmic computer music.^[300] The algorithm behind Emily Howell is registered as a US patent.^[301]

In 2012, AI Iamus created the first complete classical album.^[302]

Melomics creates computer-generated music for stress and pain relief.^[305]

At Sony CSL Research Laboratory, the Flow Machines software creates pop songs by learning music styles from a huge database of songs. It can compose in multiple styles.

The Watson Beat uses reinforcement learning and deep belief networks to compose music on a simple seed input melody and a select style. The software was open sourced^[306] and musicians such as Taryn Southern^[307] collaborated with the project to create music.

South Korean singer Hayeon's debut song, "Eyes on You" was composed using AI which was supervised by real composers, including NUVO.^[308]

Writing and reporting

Yseop, uses AI to turn structured data into natural language comments and recommendations. Yseop writes financial reports, executive summaries, personalized sales or marketing documents and more in multiple languages, including English, Spanish, French, and German.^[311]

TALESPIN made up stories similar to the fables of Aesop. The program started with a set of characters who wanted to achieve certain goals. The story narrated their attempts to satisfy these goals.^{[citation needed]} Mark Riedl and Vadim Bulitko asserted that the essence of storytelling was experience management, or "how to balance the need for a coherent story progression with user agency, which is often at odds."^[312]

While AI storytelling focuses on story generation (character and plot), story communication also received attention. In 2002, researchers developed an architectural framework for narrative prose generation. They faithfully reproduced text variety and complexity on stories such as Little Red Riding Hood.^[313] In 2016, a Japanese AI co-wrote a short story and almost won a literary prize.^[314]

South Korean company Hanteo Global uses a journalism bot to write articles.^[315]

Literary authors are also exploring uses of AI. An example is David Jhave Johnston's work ReRites (2017-2019), where the poet created a daily rite of editing the poetic output of a neural network to create a series of performances and publications.

Video games

In video games, AI is routinely used to generate behavior in non-player characters (NPCs). In addition, AI is used for pathfinding. Some researchers consider NPC AI in games to be a "solved problem" for most production tasks.^[who?] Games with less typical AI include the AI director of Left 4 Dead (2008) and the neuroevolutionary training of platoons in Supreme Commander 2 (2010).^[316][317] AI is also used in Alien Isolation (2014) as a way to control the actions the Alien will perform next.^[318]

Art

Art from language input

AI like "Disco Diffusion", "DALL·E" (1 and 2),^[320][321] Stable Diffusion,^[321][322] Imagen,^[323] "Dream by Wombo",^{[324][325][326]} Midjourney^[327] has also been used for visualizing conceptual inputs such as song lyrics, certain texts or specific imagined concepts (or imaginations) in artistic ways or artistic images in general.^[328] Some of the tools also allow users to input images and various parameters e.g. to display an object or product in various environments, some can replicate artistic styles of popular artists, and some can create elaborate artistic images from rough sketches.

History

GOFAI

AI has been used to produce visual art. The first AI art program, called AARON, was developed by Harold Cohen in 1968 at the University of California at San Diego. AARON is the most notable example of AI art in the era of GOFAI programming because of its use of a symbolic rule-based approach to generate technical images.^[329] Cohen developed AARON with the goal of being able to code the act of drawing. In its primitive form, AARON created simple black and white drawings. Cohen would later finish the drawings by painting them. Throughout the years, he also began to develop a way for AARON to also paint. Cohen designed AARON to paint using special brushes and dyes that were chosen by the program itself without mediation from Cohen.^[330]

GAN/Modern

In recent years, AI art has shifted into a new paradigm with the emergence of GAN computer programming, which generates technical images through machine learning frameworks that surpass the need for human operators.^[329] One example is Magenta, which began as a research project in 2016 from the Google Brain team that aimed to build programs and algorithms that can generate art and music, without need of human intervention. Other examples of GAN programs that generate art include Artbreeder and DeepDream.

AI art generated from GANs programming challenged the parameters of art and only recently entered the art auction market.^[331] On October 25, 2018, Portrait of Edmond Belamy by the Parisian collective, Obvious, was the first art piece created by artificial intelligence to be offered at Christie's Auction House and was sold for $432,500.^[332]

The exhibition "Thinking Machines: Art and Design in the Computer Age, 1959–1989" at MoMA provided an overview of AI applications for art, architecture, and design. Exhibitions showcasing the usage of AI to produce art include the 2016 Google-sponsored benefit and auction at the Gray Area Foundation in San Francisco, where artists experimented with the DeepDream algorithm and the 2017 exhibition "Unhuman: Art in the Age of AI", which took place in Los Angeles and Frankfurt. In spring 2018, the Association for Computing Machinery dedicated a magazine issue to the subject of computers and art. In June 2018, "Duet for Human and Machine", an art piece permitting viewers to interact with an artificial intelligence, premiered at the Beall Center for Art + Technology. The Austrian Ars Electronica and Museum of Applied Arts, Vienna opened exhibitions on AI in 2019. Ars Electronica's 2019 festival "Out of the box" explored art's role in a sustainable societal transformation.

Understanding art with AI

In addition to the creation of original art, research methods that utilize AI have been generated to quantitatively analyze digital art collections. This has been made possible due to large-scale digitization of artwork in the past few decades. Although the main goal of digitization was to allow for accessibility and exploration of these collections, the use of AI in analyzing them has brought about new research perspectives.^[333]

Two computational methods, close reading and distant viewing, are the typical approaches used to analyze digitized art.^[334] Close reading focuses on specific visual aspects of one piece. Some tasks performed by machines in close reading methods include computational artist authentication and analysis of brushstrokes or texture properties. In contrast, through distant viewing methods, the similarity across an entire collection for a specific feature can be statistically visualized. Common tasks relating to this method include automatic classification, object detection, multimodal tasks, knowledge discovery in art history, and computational aesthetics.^[333] Whereas distant viewing includes the analysis of large collections, close reading involves one piece of artwork.

Researchers have also introduced models that predict emotional responses to art such as ArtEmis, a large-scale dataset with machine learning models that contain emotional reactions to visual art as well as predictions of emotion from images or text.^[335]

List of applications

This section is in splitting the content into a new article. (April 2022)

See also

• Applications of artificial intelligence to legal informatics
• Applications of deep learning
• Applications of machine learning
• Collective intelligence#Applications
• List of artificial intelligence projects
• Progress in artificial intelligence
• Open data
• Timeline of computing 2020–present

Footnotes