Symbolic Artificial Intelligence and Numeric Artificial Neural Networks: Towards a Resolution of the Dichotomy SpringerLink

Quanta Magazine moderates comments to facilitate an informed, substantive, civil conversation. Abusive, profane, self-promotional, misleading, incoherent or off-topic comments will be rejected. Moderators are staffed during regular business hours (New York time) and can only accept comments written in English. Artificial intelligence software was used to enhance the grammar, flow, and readability of this article’s text. Qualitative simulation, such as Benjamin Kuipers’s QSIM,[88] approximates human reasoning about naive physics, such as what happens when we heat a liquid in a pot on the stove. We expect it to heat and possibly boil over, even though we may not know its temperature, its boiling point, or other details, such as atmospheric pressure.

Symbolic AI involves the explicit embedding of human knowledge and behavior rules into computer programs. But in recent years, as neural networks, also known as connectionist AI, gained traction, symbolic AI has fallen by the wayside. Researchers investigated a more data-driven strategy to address these problems, which gave rise to neural networks’ appeal. While symbolic AI requires constant information input, neural networks could train on their own given a large enough dataset. Although everything was functioning perfectly, as was already noted, a better system is required due to the difficulty in interpreting the model and the amount of data required to continue learning.

Once symbolic candidates are identified, use grid search and linear regression to fit parameters such that the symbolic function closely approximates the learned function. Essentially, this process ensures that the refined spline continues to accurately represent the data patterns learned by the coarse spline. By adding more grid points, the spline becomes more detailed and can capture finer patterns in the data.

Deep learning vs. machine learning

Watson’s programmers fed it thousands of question and answer pairs, as well as examples of correct responses. When given just an answer, the machine was programmed to come up with the matching question. This allowed Watson to modify its algorithms, or in a sense “learn” from its mistakes.

More importantly, this opens the door for efficient realization using analog in-memory computing. Maybe in the future, we’ll invent AI technologies that can both reason and learn. But for the moment, symbolic AI is the leading method to deal with problems that require logical thinking and knowledge representation.

The Future is Neuro-Symbolic: How AI Reasoning is Evolving

Many of the concepts and tools you find in computer science are the results of these efforts. Symbolic AI programs are based on creating explicit structures and behavior rules. Symbolic AI and Neural Networks are distinct approaches symbolic ai vs neural networks to artificial intelligence, each with its strengths and weaknesses. Qualcomm’s NPU, for instance, can perform an impressive 75 Tera operations per second, showcasing its capability in handling generative AI imagery.

In this view, deep learning best models the first kind of thinking while symbolic reasoning best models the second kind and both are needed. A key component of the system architecture for all expert systems is the knowledge base, which stores facts and rules for problem-solving.[51]

The simplest approach for an expert system knowledge base is simply a collection or network of production rules. Production rules connect symbols in a relationship similar to an If-Then statement. The expert system processes the rules to make deductions and to determine what additional information it needs, i.e. what questions to ask, using human-readable symbols.

It combines symbolic logic for understanding rules with neural networks for learning from data, creating a potent fusion of both approaches. This amalgamation enables AI to comprehend intricate patterns while also interpreting logical rules effectively. Google DeepMind, a prominent player in AI research, explores this approach to tackle challenging tasks. Moreover, neuro-symbolic AI isn’t confined to large-scale models; it can also be applied effectively with much smaller models.

They can be used for a variety of tasks, including anomaly detection, data augmentation, picture synthesis, and text-to-image and image-to-image translation. Next, the generated samples or images are fed into the discriminator along with actual data points from the original concept. After the generator and discriminator models have processed the data, optimization with backpropagation starts. The discriminator filters through the information and returns a probability between 0 and 1 to represent each image’s authenticity — 1 correlates with real images and 0 correlates with fake. These values are then manually checked for success and repeated until the desired outcome is reached.

For instance, frameworks like NSIL exemplify this integration, demonstrating its utility in tasks such as reasoning and knowledge base completion. Overall, neuro-symbolic AI holds promise for various applications, from understanding language nuances to facilitating decision-making processes. A. Deep learning is a subfield of neural AI that uses artificial neural networks with multiple layers to extract high-level features and learn representations directly from data.

Despite the results, the mathematician Roger Germundsson, who heads research and development at Wolfram, which makes Mathematica, took issue with the direct comparison. The Facebook researchers compared their method to only a few of Mathematica’s functions —“integrate” for integrals and “DSolve” for differential equations — but Mathematica users can access hundreds of other solving tools. Note the similarity to the use of background knowledge in the Inductive Logic Programming approach to Relational ML here.

They’re typically strict rule followers designed to perform a specific operation but unable to accommodate exceptions. For many symbolic problems, they produce numerical solutions that are close enough for engineering and physics applications. By translating symbolic math into tree-like structures, neural networks can finally begin to solve more abstract problems. However, this assumes the unbound relational information to be hidden in the unbound decimal fractions of the underlying real numbers, which is naturally completely impractical for any gradient-based learning.

Amongst the main advantages of this logic-based approach towards ML have been the transparency to humans, deductive reasoning, inclusion of expert knowledge, and structured generalization from small data. Critiques from outside of the field were primarily from philosophers, on intellectual grounds, but also from funding agencies, especially during the two AI winters. Multiple different approaches to represent knowledge and then reason with those representations have been investigated. Below is a quick overview of approaches to knowledge representation and automated reasoning. The logic clauses that describe programs are directly interpreted to run the programs specified.

For Deep Blue to improve at playing chess, programmers had to go in and add more features and possibilities. In broad terms, deep learning is a subset of machine learning, and machine learning is a subset of artificial intelligence. You can think of them as a series of overlapping concentric circles, with AI occupying https://chat.openai.com/ the largest, followed by machine learning, then deep learning. A group of academics coined the term in the late 1950s as they set out to build a machine that could do anything the human brain could do — skills like reasoning, problem-solving, learning new tasks and communicating using natural language.

Due to the shortcomings of these two methods, they have been combined to create neuro-symbolic AI, which is more effective than each alone. According to researchers, deep learning is expected to benefit from integrating domain knowledge and common sense reasoning provided by symbolic AI systems. For instance, a neuro-symbolic system would employ symbolic AI’s logic to grasp a shape better while detecting it and a neural network’s pattern recognition ability to identify items.

Approaches

A key challenge in computer science is to develop an effective AI system with a layer of reasoning, logic and learning capabilities. But today, current AI systems have either learning capabilities or reasoning capabilities —  rarely do they combine both. Now, a Symbolic approach offer good performances in reasoning, is able to give explanations and can manipulate complex data structures, but it has generally serious difficulties in anchoring their symbols in the perceptive world. While we cannot give the whole neuro-symbolic AI field due recognition in a brief overview, we have attempted to identify the major current research directions based on our survey of recent literature, and we present them below. Literature references within this text are limited to general overview articles, but a supplementary online document referenced at the end contains references to concrete examples from the recent literature.

This mechanism develops vectors representing relationships between symbols, eliminating the need for prior knowledge of abstract rules. Furthermore, the system significantly reduces computational costs by simplifying attention score matrix multiplication to binary operations. This offers a lightweight alternative to conventional attention mechanisms, enhancing efficiency and scalability. The average base pay for a machine learning engineer in the US is $127,712 as of March 2024 [1].

Below, we identify what we believe are the main general research directions the field is currently pursuing. It is of course impossible to give credit to all nuances or all important recent contributions in such a brief overview, but we believe that our literature pointers provide excellent starting points for a deeper engagement with neuro-symbolic AI topics. GANs are becoming a popular ML model for online retail sales because of their ability to understand and recreate visual content with increasingly remarkable accuracy.

Then it began playing against different versions of itself thousands of times, learning from its mistakes after each game. AlphaGo became so good that the best human players in the world are known to study its inventive moves. More options include IBM® watsonx.ai™ AI studio, which enables multiple options to craft model configurations that support a range of NLP tasks including question answering, content generation and summarization, text classification and extraction. For example, with watsonx and Hugging Face AI builders can use pretrained models to support a range of NLP tasks. A Data Scientist with a passion about recreating all the popular machine learning algorithm from scratch. KANs benefit from more favorable scaling laws due to their ability to decompose complex functions into simpler, univariate functions.

Deep learning algorithms can analyze and learn from transactional data to identify dangerous patterns that indicate possible fraudulent or criminal activity. Deep learning eliminates some of data pre-processing that is typically involved with machine learning. These algorithms can ingest and process unstructured data, like text and images, and it automates feature extraction, removing some of the dependency on human experts.

Symbolic AI has been criticized as disembodied, liable to the qualification problem, and poor in handling the perceptual problems where deep learning excels. In turn, connectionist AI has been criticized as poorly suited for deliberative step-by-step problem solving, incorporating knowledge, and handling planning. Finally, Nouvelle AI excels in reactive and real-world robotics domains but has been criticized for difficulties in incorporating learning and knowledge. This directed mapping helps the system to use high-dimensional algebraic operations for richer object manipulations, such as variable binding — an open problem in neural networks. When these “structured” mappings are stored in the AI’s memory (referred to as explicit memory), they help the system learn—and learn not only fast but also all the time. The ability to rapidly learn new objects from a few training examples of never-before-seen data is known as few-shot learning.

But then programmers must teach natural language-driven applications to recognize and understand irregularities so their applications can be accurate and useful. NLP research has enabled the era of generative AI, from the communication skills of large language models (LLMs) to the ability of image generation models to understand requests. NLP is already part of everyday life for many, powering search engines, prompting chatbots for customer service with spoken commands, voice-operated GPS systems and digital assistants on smartphones.

Whether it’s through faster video editing, advanced AI filters in applications, or efficient handling of AI tasks in smartphones, NPUs are paving the way for a smarter, more efficient computing experience. Smart home devices are also making use of NPUs to help process machine learning on edge devices for voice recognition or security information that many consumers won’t want to be sent to a cloud data server for processing due to its sensitive nature. At its most basic level, the field of artificial intelligence uses computer science and data to enable problem solving in machines. Human language is filled with many ambiguities that make it difficult for programmers to write software that accurately determines the intended meaning of text or voice data. Human language might take years for humans to learn—and many never stop learning.

But the benefits of deep learning and neural networks are not without tradeoffs. Deep learning has several deep challenges and disadvantages in comparison to symbolic AI. Notably, deep learning algorithms are opaque, and figuring out how they work perplexes even their creators.

It aims to bridge the gap between symbolic reasoning and statistical learning by integrating the strengths of both approaches. This hybrid approach enables machines to reason symbolically while also leveraging the powerful pattern recognition capabilities of neural networks. According to Will Jack, CEO of Remedy, a healthcare startup, there is a momentum towards hybridizing connectionism and symbolic approaches to AI to unlock potential opportunities of achieving an intelligent system that can make decisions.

You create a rule-based program that takes new images as inputs, compares the pixels to the original cat image, and responds by saying whether your cat is in those images. Using OOP, you can create extensive and complex symbolic AI programs that perform various tasks. Deep learning fails to extract compositional and causal structures from data, even though it excels in large-scale pattern recognition.

Despite the difference, they have both evolved to become standard approaches to AI and there is are fervent efforts by research community to combine the robustness of neural networks with the expressivity of symbolic knowledge representation. The traditional symbolic approach, introduced by Newell & Simon in 1976 describes AI as the development of models using symbolic manipulation. In the Symbolic approach, AI applications process strings of characters that represent real-world entities or concepts. Symbols can be arranged in structures such as lists, hierarchies, or networks and these structures show how symbols relate to each other. An early body of work in AI is purely focused on symbolic approaches with Symbolists pegged as the “prime movers of the field”.

Each edge in a KAN represents a univariate function parameterized as a spline, allowing for dynamic and fine-grained adjustments based on the data. By now, people treat neural networks as a kind of AI panacea, capable of solving tech challenges that can be restated as a problem of pattern recognition. Photo apps use them to recognize and categorize recurrent faces in your collection.

In the human brain, networks of billions of connected neurons make sense of sensory data, allowing us to learn from experience. Artificial neural networks can also filter huge amounts of data through connected layers to make predictions and recognize patterns, following rules they taught themselves. Parsing, tokenizing, spelling correction, part-of-speech tagging, noun and verb phrase chunking are all aspects of natural language processing long handled by symbolic AI, but since improved by deep learning approaches.

Neural networks use a vast network of interconnected nodes, called artificial neurons, to learn patterns in data and make predictions. Neural networks are good at dealing with complex and unstructured data, such as images and speech. They can learn to perform tasks such as image recognition and natural language processing with high accuracy. Symbolic AI, rooted in the earliest days of AI research, relies on the manipulation of symbols and rules to execute tasks. This form of AI, akin to human “System 2” thinking, is characterized by deliberate, logical reasoning, making it indispensable in environments where transparency and structured decision-making are paramount. Use cases include expert systems such as medical diagnosis and natural language processing that understand and generate human language.

You can foun additiona information about ai customer service and artificial intelligence and NLP. Unlike MLPs that use fixed activation functions at each node, KANs use univariate functions on the edges, making the network more flexible and capable of fine-tuning its learning process to the data. Understanding these systems helps explain how we think, decide and react, shedding light on the balance between intuition and rationality. In the realm of AI, drawing parallels to these cognitive processes can help us understand the strengths and limitations of different AI approaches, such as the intuitive, fast-reacting generative AI and the methodical, rule-based symbolic AI. François Charton (left) and Guillaume Lample, computer scientists at Facebook’s AI research group in Paris, came up with a way to translate symbolic math into a form that neural networks can understand. Knowledge-based systems have an explicit knowledge base, typically of rules, to enhance reusability across domains by separating procedural code and domain knowledge.

• These problems are known to often require sophisticated and non-trivial symbolic algorithms.
• In turn, connectionist AI has been criticized as poorly suited for deliberative step-by-step problem solving, incorporating knowledge, and handling planning.
• Deep learning has several deep challenges and disadvantages in comparison to symbolic AI.

And programs driven by neural nets have defeated the world’s best players at games including Go and chess. NSI has traditionally focused on emulating logic reasoning within neural networks, providing various perspectives into the correspondence between symbolic and sub-symbolic representations and computing. Historically, the community targeted mostly analysis of the correspondence and theoretical model expressiveness, rather than practical learning applications (which is probably why they have been marginalized by the mainstream research). The advantage of neural networks is that they can deal with messy and unstructured data. Instead of manually laboring through the rules of detecting cat pixels, you can train a deep learning algorithm on many pictures of cats.

Generative AI has taken the tech world by storm, creating content that ranges from convincing textual narratives to stunning visual artworks. New applications such as summarizing legal contracts and emulating human voices are providing new opportunities Chat GPT in the market. In fact, Bloomberg Intelligence estimates that “demand for generative AI products could add about $280 billion of new software revenue, driven by specialized assistants, new infrastructure products, and copilots that accelerate coding.”

Meanwhile, with the progress in computing power and amounts of available data, another approach to AI has begun to gain momentum. Statistical machine learning, originally targeting “narrow” problems, such as regression and classification, has begun to penetrate the AI field. In contrast, a multi-agent system consists of multiple agents that communicate amongst themselves with some inter-agent communication language such as Knowledge Query and Manipulation Language (KQML).

The complexity of blending these AI types poses significant challenges, particularly in integration and maintaining oversight over generative processes. There are more low-code and no-code solutions now available that are built for specific business applications. Using purpose-built AI can significantly accelerate digital transformation and ROI. Perhaps surprisingly, the correspondence between the neural and logical calculus has been well established throughout history, due to the discussed dominance of symbolic AI in the early days. Limitations were discovered in using simple first-order logic to reason about dynamic domains. Problems were discovered both with regards to enumerating the preconditions for an action to succeed and in providing axioms for what did not change after an action was performed.

• To enhance the interpretability of KANs, several simplification techniques can be employed, making the network easier to understand and visualize.
• And, the theory is being revisited by Murray Shanahan, Professor of Cognitive Robotics Imperial College London and a Senior Research Scientist at DeepMind.
• Think of this as using the same cooking technique for all ingredients, regardless of their nature.
• Its robust performance on a range of tasks highlights its potential for practical applications, while its resilience to weight-heavy quantization underscores its versatility.
• The input layer is where the deep learning model ingests the data for processing, and the output layer is where the final prediction or classification is made.

One promising approach towards this more general AI is in combining neural networks with symbolic AI. In our paper “Robust High-dimensional Memory-augmented Neural Networks” published in Nature Communications,1 we present a new idea linked to neuro-symbolic AI, based on vector-symbolic architectures. Symbolic artificial intelligence showed early progress at the dawn of AI and computing. You can easily visualize the logic of rule-based programs, communicate them, and troubleshoot them. Both convolutional neural networks (CNNs) and recurrent neural networks (RNNs) have played a big role in the advancement of AI. Learn how CNNs and RNNs differ from each other and explore their strengths and weaknesses.

Machine learning and deep learning models are capable of different types of learning as well, which are usually categorized as supervised learning, unsupervised learning, and reinforcement learning. Supervised learning utilizes labeled datasets to categorize or make predictions; this requires some kind of human intervention to label input data correctly. In contrast, unsupervised learning doesn’t require labeled datasets, and instead, it detects patterns in the data, clustering them by any distinguishing characteristics. Reinforcement learning is a process in which a model learns to become more accurate for performing an action in an environment based on feedback in order to maximize the reward.