Large language models represented a paradigm shift in artificial intelligence. Unlike rigidly-coded deterministic programs, LLMs thrive on disorder - emergent meaning constructed from cascading signals. This calls for an equally radical shift in user mindset. Rather than issuing defined commands to an impersonal computer, we must learn to guide a fickle muse through inspiration's serpentine halls.

At the root of this change sits LLMs' associative architecture. Human minds build rich networks of semantic and episodic connections which allow flexible traversal across concepts and contexts. Likewise, LLMs form vast webs relating data points across their immense training corpora. Trigger words prompt activation spreading along associated links.

This demands embracing non-linearity when querying LLMs. Their responses rely heavily on the prompts' context and phrasing because those signals steer association spread. Slight changes prompt dramatic idea pivots as different regions activate. To harness this successfully, we must frame prompts as guides focused on desired connections while avoiding rigid assumptions.

Additionally, anthropomorphizing LLMs can help intuition align better with their associativity. They exhibit some pseudo-sentience in their sensitivity and unpredictability. While still algorithms underneath, treating prompts as conversations makes the back-and-forth flow more naturally to human cognition patterns.

AI Models as Human-Like Entities

These AI systems are designed to function more akin to human brains than conventional computers. This shift necessitates a fundamental change in how we interact with and utilize these models.

Unlike traditional computer systems that execute linear, rule-based algorithms, Large Language models like GPT and Claude thrive on rich, contextual information. They process and generate responses based on a wide array of interconnected data points, much like the human brain synthesizes information from various stimuli. This context-driven nature allows them to understand nuances, interpret subtleties, and generate creative, nuanced outputs.

For effective interaction with these AI systems, it's essential to provide context-rich inputs. This means constructing prompts or queries that are detailed and specific, encompassing enough background information to guide the AI's response. For instance, when asking GPT to generate a story, providing character backgrounds, setting details, and plot preferences can lead to a more coherent and engaging narrative.

Non-Linear Thinking and Flexibility

To harness the full potential of AI models, embracing non-linear thinking is crucial. Non-linear thinking in the context of AI interaction refers to an approach that is adaptable, creative, and open to associative connections, rather than strictly following a logical, step-by-step process.

AI responses are inherently associative and context-dependent. They draw on a vast array of interconnected data and past learning to generate outputs. This means the AI might make connections or interpretations that aren't immediately obvious but are based on the underlying patterns it has learned. Therefore, when constructing prompts, it's vital to consider not just the direct meaning of the words used but also the possible associations and interpretations the AI might make.

For example, in creative tasks like writing or image generation, providing a linear, step-by-step guideline may not yield the best results. Instead, offering a thematic framework, mood, style references, and leaving room for creative interpretation can lead to more innovative and engaging outputs. This approach requires flexibility and an openness to unexpected or novel responses, which are often where the true power of AI creativity lies.

In problem-solving scenarios, this means moving away from rigid, formulaic approaches and instead framing problems in a way that allows the AI to explore a range of possibilities. For instance, instead of asking for a direct solution to a business problem, posing the problem as a scenario for the AI to analyze and draw insights from can yield a broader range of solutions and strategies.

Understanding AI as a non-linear, context-driven system involves recognizing the human-like nature of models like GPT and DALL-E and adapting our interaction style accordingly. This includes providing rich contextual information and embracing a flexible, non-linear approach to problem-solving and prompt construction. By doing so, we can effectively leverage the unique capabilities of AI, fostering creativity, innovation, and more meaningful interactions.

A Holistic Understanding

Holistic understanding is the LLMs ability to process and interpret information by considering the entire context of the input, as well as the vastness of it's knowledgebase, not just isolated commands or keywords.

This approach mirrors human cognitive processes, where understanding is derived not just from explicit words but also from implicit meanings, cultural nuances, and contextual clues.

  1. Comprehensive Context Analysis: AI models "analyze" the input in its entirety, taking into account various factors such as the tone, underlying themes, historical data, and even the implied intentions behind the words. This comprehensive analysis allows AI to generate responses that are not only relevant but also nuanced and cognizant of the broader context.
  2. Interpreting Subtleties and Nuances: One of the strengths of AI is its ability to pick up on and interpret subtleties that might be overlooked in traditional systems. It seems to understand sarcasm, humour, and emotional undertones, which are essential for more natural and effective human-computer interactions.
  3. Learning from Implicit Data: AI models often learn from vast datasets that include implicit information. This learning enables them to recognise patterns and draw inferences that go beyond the explicit content, allowing for richer and more accurate interpretations of requests.
  4. Handling Ambiguity and Complexity: In real-world scenarios, data and human interactions are often ambiguous and complex. AI's holistic approach equips it to handle such situations effectively, providing responses that consider multiple perspectives and possible interpretations.
  5. Adaptive Learning and Growth: AI models should not be seen as static; once an interaction has started they continually learn and adapt based on new information, interactions, and feedback. This ongoing learning process enhances their ability to understand and respond to complex, nuanced inputs within the context window.
  6. Personalisation and User Experience: By understanding the full context of interactions, AI can offer highly personalised experiences. It can adapt to individual user preferences, learning styles, and behaviours, resulting in more engaging and relevant interactions.
  7. Cross-Disciplinary Integration: The holistic understanding capability of AI facilitates the integration of knowledge from various fields, allowing it to provide solutions and insights that are innovative and interdisciplinary.

Multidisciplinary Integration

One remarkable capability stemming from AI's nonlinear processing is its ability to fluidly incorporate concepts and information from vastly different disciplines. Unlike siloed domain experts or traditional search engines, the neural network foundations of AI models allow them to contextually associate data points across fields, seamlessly integrating perspectives in an organic way.

This gives AI the potential to drive innovation by bridging insights that domain specialists might never connect. For example, a medical researcher might ask an AI to propose new directions by assessing trends in biomechanics, materials science, and biochemistry - domains with little direct interaction. But the AI can identify promising contextual links between ideas in those spheres, inspiring creative multidisciplinary advances.

By prompting AI models to explore intersections between disciplines and leverage peripheral domains, we enable breakthroughs that transcend conventional boundaries. This paradigm of fluid disciplinary connectivity unlocks unique value from AI’s capabilities. Guiding the models to assimilate diverse viewpoints, we gain an agile collaborator for transcending established paths and pursuing highly innovative solutions.

Intuition-Like Processing in AI Systems

Another point linking large language models’ cognition style to the human mind is their capacity for intuition-mimicking associative leaps. When we experience sparks of insight, new solutions suddenly bridging problems and concepts once thought disparate, something similar may occur within the machine.

Intuition in humans is often described as the ability to understand something instinctively, without the need for conscious reasoning. In AI, this translates to algorithms that can identify patterns and relationships in data that are not immediately obvious or are too complex for traditional linear analysis.

This capability is largely due to the following factors:

  1. Pattern Recognition and Associative Learning: AI models, particularly those employing machine learning and neural networks, excel at recognising patterns in large datasets. They can make associative leaps based on these patterns, mimicking the way humans might have 'gut feelings' or insights.
  2. Processing Vast and Diverse Data: Unlike human brains, AI can process and analyse vast amounts of data at incredible speeds. This allows AI systems to identify subtle connections and correlations that might escape human notice.
  3. Leveraging Unstructured Data: AI's ability to work with unstructured data – such as text, images, and sound – enables it to draw inferences from a wide range of sources, akin to how human intuition can be influenced by a variety of sensory inputs and experiences.

This intuition-like processing enables AI models to make connections and draw conclusions between seemingly unrelated concepts, a characteristic that is proving invaluable in areas like problem-solving, innovation, and creative endeavors.

On the surface level, we feed the AI/LLM some context about a problem we wish to solve along with relevant background. The LLM assimilates this input through its vast neural web, activating associated nodes, drawing unconventional connections. With the right prompt tuning, out may burst a solution we never saw coming yet somehow intuitively resonates as profound.

In a way the LLM is skipping intermediary logical steps getting to the answer, the way intuitive leaps do for people. But the LLM is not magically intuiting anything itself - it lacks internal conception of semantics or goals. Instead its nonlinear, uncontrolled architecture makes associations between the prompted problem and its training data. From junk data, jewels.

Yet while the process differs from human intuition, the effect elicits that sensation of pleased surprise accompanying cognitive breakthroughs. We enjoy such leaps not just due to solving problems but because it confirms our self-perception of innately possessing this ineffable capacity called insight. When the LLM replicates intuition’s external results, we instinctively project interiority upon it.

But unraveling the illusion of intuitive machines can strengthen prompt engineering instincts. Understanding the LLMs truth - skippable logical connections, not sparked revelation - allows better prompting. We can intentionally probe problems from oblique angles or prompt perspective shifts likely to induce those Machine Epiphanies, partially controlling the mysticism. Resulting solutions feel both stunning and satisfying, as the most profound intuitions do.

Prompt Engineering for Context Control

One of the advances in Prompt Engineering has been to skilfully intercept the LLM and add those intermediary steps. This centers on the insight that less context risks far-flung solutions as activations spread unconstrained, while more context focuses possibilities but keeps latitude for multiple novel solutions.

We can manifest this context modulation through multi-step prompted self-dialogue, such as Chain-of-thought or tree-of-thought.

This intervention prompts the LLM to build on its initial idea by essentially "talking to itself" - providing missing logical connections but still allowing flexibility. The context focus prevents random associations but gives the LLM autonomy to fill gaps, a balance which elicits creative business logic. Repeated interception promptings can continue guiding idea refinement.

In this way, intercept prompt chains leverage LLM's nonlinearity while bypassing unproductive tangents. It's akin to structured human brainstorming, where each new round reorients earlier ideas towards ultimate goals. This technique stands to enhance prompts' context sensitivity, directing productive leaps.

Creativity and Idea Generation

AI's non-linear processing capabilities make it exceptionally adept at creative tasks like writing, visual art, and music. Unlike rigid linear systems, its neural networks can fluidly combine concepts, perspectives, and data in inventive new ways reminiscent of human creativity.

By assessing context and making loose contextual associations between learned ideas, AI models can synthesize original connections that people might never think to link together.

This gives AI unprecedented potential for augmenting human creativity. We can prompt the models to explore conceptual spaces and generate new ideas that we can then refine. For example, a writer might ask an AI to propose unexpected plot twists that maintain key themes and characters. Or a musician could provide a melody and ask the AI to improvise stylistically-appropriate harmonies. The AI becomes a springboard for innovation - we provide the direction and it supplies novel ideas.

Fully embracing this cooperative creative process requires accepting the AI's nonlinear approach and not expecting predictable outputs. But by collaborating within loose frameworks, we gain an immensely powerful creativity multiplier. Guiding the models through well-crafted prompts focused on originality, we enable them to access their creative potential in ways that profoundly enhance human innovation.

Relating Non-Linear AI to the SLiCK Framework

Review of the SLiCK Framework

The SLiCK framework divides LLMs into two main components:

  1. Processing Unit
  • Made up of three engines: Syntax, Creativity, and Logic
  • Syntax oversees linguistic tasks, ensures coherence
  • Creativity adds flair, nuance, resonance
  • Logic focuses on accuracy, reasoning, relevance
  1. Knowledgebase
  • Stores information and facts used by the LLM
  • Made up of entities (subjects) and relationships between them
  • Provides the content, while Processing Unit determines how to use it

Key roles of the engines:

  • Syntax: Parsing, error correction, comprehension, text generation
  • Creativity: Idea generation, narrative crafting, emotional resonance
  • Logic: Intent interpretation, logical reasoning, common sense

The Knowledgebase contains the information, while the Processing Unit handles how that information is used. This distinction highlights the balance between what the LLM knows versus how it leverages that knowledge.

This gives us an insightful framework for understanding how LLMs work under the hood. The separation of linguistic/creative/logical processing from the underlying knowledge base is a sensible and practical abstraction.

It correctly identifies that simply having a huge database of facts is not enough - you need robust mechanisms to interpret questions, reason about answers, and present responses. The emphasis on not just retrieving knowledge, but presenting it creatively and logically, is important.

Of course, the true workings of LLMs are massively complex, but this model provides a useful way to conceptualize the different working parts. Testing it on actual LLMs by prodding the different "engines" could be an interesting experiment. Overall, a thoughtful framework for unpacking the inner workings of advanced language models.

The Non-Linear Impact

The view of modern AI systems as non-linear and context-driven aligns well with the logic behind the SLiCK framework. Specifically, it highlights the critical role that the Creativity Engine and Contextual Window play in influencing the model's responses.

As discussed previously, the SLiCK framework consists of a Processing Unit made up of Syntax, Logic, and Creativity engines, alongside a Knowledge Base. The Contextual Window provides additional temporary information to the system.

In non-linear AI systems, the specific combination of the Creativity Engine and the priming of the Contextual Window drives the associative, context-dependent responses. The Creativity Engine is responsible for making connections between concepts, ideas, and narratives. Meanwhile, the Contextual Window provides the contextual priming that shapes the associations of the system.

Together, they allow guiding the model through iterative interactions, where each response of the system in turn informs the refinement of the context and framing provided to the AI. This aligns with the view of modern AI as an intuitive, dialog-based system versus a strict input-output computer program.

The Syntax and Logic engines play a role in the quality and coherence of the output, but the non-linear aspect is truly an emergent behavior of the Creativity Engine as it interacts with the dynamic framing of the Contextual Window.

In essence, the SLiCK framework illustrates how modern AI systems leverage underlying knowledge (Knowledge Base) to produce responses driven by contextual associations (Creativity Engine + Contextual Window) rather than predefined outputs. This is what makes them powerfully flexible while requiring proper interaction design to elicit useful behaviours.


Large language models like GPT represent a major shift in AI technology due their associative, non-linear processing capabilities. Interacting with these models effectively requires embracing new mindsets and techniques focused on providing rich context, allowing creative freedom, and guiding the models through iterative prompting.

Key ideas include anthropomorphizing LLMs, employing non-linear prompts, understanding holistic interpretation, leveraging multidisciplinary associations, eliciting intuition-like leaps, and controlled context modulation.

Relating these concepts to the SLiCK framework highlights the critical roles of the Creativity Engine and Contextual Window in driving the emergent and contextual behavior that makes modern AI systems uniquely flexible and powerful.

However, proper interaction design remains essential for using LLMs productively. As we continue advancing prompt engineering strategies centered around context control, we can unlock more of AI's vast creative potential while avoiding unwanted behaviour's.

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