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Climate scientist Tapio Schneider is delighted that machine learning has taken the drudgery out of his day. When he first started modelling how clouds form, more than a decade ago, this mostly involved painstakingly tweaking equations that describe how water droplets, air flow and temperature interact. But since 2017, machine learning and artificial intelligence (AI) have transformed the way he works.

“Machine learning makes this science a lot more fun,” says Schneider, who works at the California Institute of Technology in Pasadena. “It’s vastly faster, more satisfying and you can get better solutions.”

Conventional climate models are built manually from scratch by scientists such as Schneider, who use mathematical equations to describe the physical processes by which the land, oceans and air interact and affect the climate. These models work well enough to make climate projections that guide global policy.

But the models rely on powerful supercomputers, take weeks to run and are energy-intensive. A typical model consumes up to 10 megawatt hours of energy to simulate a century of climate, says Schneider. On average, that is about the amount of electricity used annually by a US household. Moreover, such models struggle to simulate small-scale processes, such as how raindrops form, which often have an important role in large-scale weather and climate outcomes, says Schneider.

Think big and model small

The branch of AI called machine learning — in which computer programs learn by spotting patterns in data sets — has shown promise in weather forecasting and is now stepping in to help with these issues in climate modelling.

“The trajectory of machine learning for climate projections is looking really promising,” says computer scientist Aditya Grover at the University of California, Los Angeles. Similar to the early days of weather forecasting, he says, there is a flurry of innovation that promises to transform how scientists model the climate.

But there are still hurdles to overcome — including convincing everyone that models based on machine learning are getting their projections right.

Copy cats

Researchers are using AI for climate modelling in three main ways. The first approach involves developing machine-learning models called emulators, which produce the same results as conventional models without having to crank through all the mathematical calculations.

Think of a conventional climate model as a computer program that can calculate where a ball will land on the basis of physical factors, such as how hard the ball is thrown, where it is thrown from and how fast it is spinning. Emulators can be considered as equivalent to a sports player who learns the patterns in all those modelled outputs and is then able to predict, without crunching through all the maths, where the ball will land.

In a 2023 study, climate scientist Vassili Kitsios at the Commonwealth Scientific and Industrial Research Organisation in Melbourne, Australia, and his colleagues developed 15 machine-learning models that could emulate 15 physics-based models of the atmosphere¹. They trained their system, called QuickClim, using the physical models’ projections of surface air temperature up to the year 2100 for two atmospheric carbon concentration pathways: a low and a high carbon emission scenario. Training each model took about 30 minutes on a laptop, says Kitsios. Researchers then asked the QuickClim models to forecast temperatures under a medium carbon emission scenario, which the models had not seen during training. The results closely matched those of the conventional physics-based models (see ‘AI climate model works at speed’).

AI climate model works at speed. Graphic showing similarity between a physics-based climate model and the AI emulator. — Source: Ref. 1

Once trained with all three emissions scenarios, QuickClim could quickly predict how global surface temperatures would change during the century under many carbon emission scenarios — about one million times faster than the conventional model could, says Kitsios. “With traditional models, you have less than five or so carbon concentration pathways you can analyse. QuickClim now allows us to do many thousands of pathways — because it’s fast,” he says.

QuickClim could one day help policymakers by exploring multiple scenarios, which would take conventional approaches simply too long to simulate. Models such as QuickClim will not replace physics-based models, Kitsios says, but could work alongside them.

Another team of researchers, led by atmospheric scientist Christopher Bretherton at the Allen Institute for Artificial Intelligence in Seattle, Washington, developed a machine-learning emulator for one physics-based atmospheric model. In a 2023 preprint study², the team first created a training data set for the model, called ACE, by feeding ten sets of initial atmospheric conditions into a physics-based model. For each set, the physics-based model projected how 16 variables, including air temperature, water vapour and windspeed, would change over the next decade.

How machine learning could help to improve climate forecasts

After training, ACE was able to iteratively use estimates from 6 hours earlier in its projections to make forecasts 6 hours ahead, over a time span of up to a decade. And it performed well: better than a pared-down version of the physics-based model that runs at half the resolution to save on time and computing power. In that comparison, ACE more accurately predicted the state of 90% of the atmospheric variables, ran 100 times faster and was 100 times more energy-efficient.

Study author and climate scientist Oliver Watt-Meyer at the Allen Institute for Artificial Intelligence says he was surprised. “I was impressed by the result. These early findings suggest that we’ll be able to make these models that are very fast, accurate and able to probe a lot of different scenarios,” he says.

Firm foundations

In the second approach, researchers are using AI in a more fundamental way, to power the guts of climate models. These ‘foundation’ models can later be tweaked to perform a wide range of downstream climate- and weather-related tasks.

Foundation models hinge on the idea that there are fundamental, possibly unknown, patterns in the data that are predictive of the future climate, says Grover. By picking up on these hidden patterns, the hope is that foundation models might be able to churn out better climate and weather predictions than conventional approaches can, he says.

In a 2023 paper³, Grover and researchers at the tech giant Microsoft built the first such foundation model, called ClimaX. It was trained on the output from five physics-based climate models that simulated the global weather and climate from 1850 to 2015, including factors such as air temperature, air pressure and humidity, simulated on timescales from hours to years. Unlike emulator models, ClimaX was not trained towards the specific task of mimicking an existing climate model.

After this general training, the team fine-tuned ClimaX to perform a wide range of tasks. In one, the model predicted the average surface temperature, daily temperature range and rainfall worldwide from input variables of carbon dioxide, sulphur dioxide, black carbon and methane levels. This task was proposed in 2022 as a benchmark for comparing AI climate models, in a study by atmospheric physicist Duncan Watson-Parris at the University of California, San Diego, and his colleagues⁴. ClimaX predicted the state of temperature-related variables better than did three climate emulators built by Watson-Parris’s team³. However, it performed less well than the best of these three emulators in predicting rainfall, says Grover.

Science and the new age of AI: a Nature special

“I like the idea of foundation models,” says Watson-Parris. But these early findings don’t yet prove that ClimaX can outperform conventional climate models, or that foundation models are intrinsically superior to emulators, he adds.

In fact, it will be difficult to convince people that any machine-learning model can outperform conventional approaches, says Schneider. The true state of the future climate is unknown and we can’t wait for decades to see how well the models are performing, he says. Testing climate models against past climate behaviour is useful, but not a perfect measure of how well they can predict a future that’s likely to be vastly different from what humanity has seen before. Perhaps if models get better at seasonal weather prediction, they’ll be better at long-term climate predictions, too, says Schneider. “But to my knowledge, that’s not yet been demonstrated and that’s no guarantee,” he says.

Moreover, it is hard to interpret the way in which many of the AI models work, a problem known as the the black box of AI, which could make it hard to trust them. “With climate projections, you absolutely need to trust the model to extrapolate,” says Watson-Parris.

Best of both

A third approach is to embed machine-learning components inside physics-based models to produce hybrid models — a sort of compromise, says Schneider.

An aerial view of thick snow covering houses and trees — Snow cover is hard for conventional climate models to predict, but hybrid models that blend machine-learning and physics-based techniques have successfully simulated snow cover and other small-scale processes.Credit: Mario Tama/Getty

In this case, machine-learning models would replace only the parts of conventional models that work less well — typically the modelling of small-scale, complex and important processes such as cloud formation, snow cover and river flows. These are a “key sticking point” in standard climate modelling, says Schneider. “I think the holy grail really is to use machine learning or AI tools to learn how to represent small-scale processes,” he says. Such hybrid models could perform better than purely physics-based models, while being more trustworthy than models built entirely from AI, he says.

In this vein, Schneider and his colleagues have built physical models of Earth’s atmosphere and land that contain machine-learning representations of a handful of such small-scale processes. They perform well, he says, in tests of river-flow and snow-cover projections against historical observations⁵. “We’ve found machine-learning models can be more successful than physical models in simulating certain phenomena,” says Schneider. Watson-Parris agrees with that assessment.

By the end of the year, Schneider and his team hope to complete a hybrid model of the ocean that can be coupled to the atmosphere and land models, as part of their Climate Modeling Alliance (CliMA) project.

Similar efforts to create ‘digital twins’ of Earth are being developed by NASA and the European Commission. The European project, called Destination Earth (DestinE), is entering its second phase in June this year, in which machine learning will have a key role, says Florian Pappenberger, who leads the forecast department at the European Centre for Medium-Range Weather Forecasts in Reading, UK.

The ultimate goal, says Schneider, is to create digital models of Earth’s systems, partly powered by AI, that can simulate all aspects of the weather and climate down to kilometre scales, with great accuracy and at lightning speed. We’re not there yet, but advocates say this target is now in sight.

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Improving your Midjourney prompts for amazing AI art

In the ever-evolving world of digital art, artists and designers are constantly seeking new ways to push the boundaries of creativity. Midjourney AI stands at the forefront of this exploration, offering a powerful tool that blends artificial intelligence with artistic expression. By understanding and manipulating the various parameters of Midjourney AI, creatives can unlock a new realm of possibilities, crafting artwork that resonates with their unique vision. This guide offers further insight into writing Midjourney prompts to take your AI artwork to the next level.

To begin with, the “stylize” value is a critical setting that influences the balance between an abstract interpretation and a more literal representation of your ideas. If you’re aiming for a piece that exudes a strong artistic character, increasing the stylize value can infuse your work with an abstract touch. Conversely, a lower value keeps the AI’s output more faithful to your specific instructions, ensuring that the details you envision are accurately reflected in the final piece.

crafting Midjourney Prompts for AI art

Moving on, the “style raw” setting is another lever at your disposal. This feature allows you to steer the AI’s default output towards the artistic outcome you have in mind. By adjusting this setting, you can refine the AI’s interpretation of your prompt, aligning it more closely with your expectations.

A simple yet effective technique to guide the AI is to provide a rough sketch. Even a basic outline created in a program like Photoshop or Canva can significantly influence the AI’s creative trajectory. Your sketch acts as a navigational tool, directing the AI towards the artistic destination you’re aiming for.

Midjourney prompts writing take a step to a new level, when you upload a reference image to Discord and incorporate it into your prompt, you give the AI a clear visual target to aim for. This method can greatly improve the specificity and relevance of your artwork, ensuring that the final product aligns with your vision.

Writing Midjourney Prompts

Watch the video below kindly created by Future Tech Pilot on creating the best possible prompts to get fantastic results from Midjourney.

Here are some other articles you may find of interest on the subject of Midjourney Styles :

The “image weight” parameter offers you the ability to dictate how much your reference image should influence the AI’s output. A higher image weight means the AI will adhere more to your provided image, while a lower weight allows for more creative freedom and interpretation by the AI.

Keywords play a subtle yet powerful role in shaping the AI’s output. Including terms like “unsplash” can nudge the AI towards certain styles, such as cinematic or photorealistic, helping to capture the ambiance you desire for your artwork.

For those looking to maintain thematic consistency across multiple pieces, the “describe” feature is invaluable. It enables you to generate descriptive prompts from an existing image, ensuring that each piece in a series shares a common thread.

Another technique to influence the AI’s artistic direction is to use a style reference (D-SREF) with an image. This approach allows you to guide the AI towards a specific style without the need for explicit descriptions, fostering a more organic interpretation by the AI.

Finally, the “style weight” (D-SSW) adjustment is a fine-tuning tool that lets you control the extent to which your chosen style affects the final artwork. This is essential for achieving the precise level of stylistic influence you’re after.

Midjourney AI presents a rich toolkit for artists and designers to refine their AI art prompts. Through experimentation with settings like “stylize,” “style raw,” and various weight adjustments, you can exert considerable control over the artistic output. By using hints, the “describe” feature, and manipulating style references, you can further customize the creative process to your liking.

Exploring the Depths of Digital Art with Midjourney AI

The key to producing art that truly captures your vision is a willingness to explore and experiment with these tools. Each adjustment you make is a step toward mastering the art of AI-generated imagery, enabling you to create with both accuracy and creativity. As you continue to experiment with Midjourney AI, you’ll find that the power to shape your artistic creations is at your fingertips, ready to be harnessed and directed in ways that were once unimaginable.

The realm of digital art is a dynamic and ever-changing landscape where artists and designers leverage technology to express their creativity. Midjourney AI emerges as a cutting-edge tool that marries the capabilities of artificial intelligence with the nuances of human artistic expression. By mastering the various parameters within Midjourney AI, creatives can unlock a vast array of possibilities, allowing them to produce artwork that truly reflects their individual vision.

The “stylize” value is a pivotal setting within Midjourney AI that determines the balance between abstract and literal interpretations of a concept. For artwork that radiates a distinct artistic flair, increasing the stylize value can introduce an abstract quality to the piece. On the other hand, a lower value will result in the AI producing an output that is more aligned with the specific details of your vision, ensuring that the nuances you imagine are precisely captured in the final artwork.

Enhancing Artistic Direction with Midjourney AI’s Advanced Features

The “style raw” setting is another powerful tool at an artist’s disposal. This parameter allows you to influence the AI’s default creative process, guiding it towards the artistic outcome you envision. By fine-tuning this setting, you can adjust the AI’s interpretation of your instructions, ensuring that the output is more closely aligned with your expectations.

A straightforward yet impactful method to direct the AI is through the use of a rough sketch. Even a simple outline crafted in software like Photoshop or Canva can significantly shape the AI’s creative path. Your sketch serves as a compass, pointing the AI towards the artistic destination you seek.

Incorporating an image prompt by uploading a reference picture to Discord and using it in your prompt provides the AI with a clear visual benchmark. This technique can enhance the specificity and relevance of your artwork, guaranteeing that the end result is in harmony with your original concept.

The “image weight” parameter allows you to control how much your reference image influences the AI’s output. A higher image weight compels the AI to closely follow your provided image, whereas a lower weight permits the AI more creative leeway and interpretation.

Keywords have a subtle yet potent effect on the AI’s creative output. Including terms like “unsplash” can guide the AI towards specific styles, such as cinematic or photorealistic, aiding in capturing the atmosphere you wish to convey in your artwork.

For artists aiming to achieve a consistent theme across a series of works, the “describe” feature is incredibly useful. It enables the generation of descriptive prompts from an existing image, ensuring a cohesive aesthetic thread throughout the series.

Mastering AI Art with Midjourney AI’s Customizable Parameters

Utilizing a style reference (D-SREF) with an image is another strategy to steer the AI towards a particular artistic style without explicit descriptions. This method encourages a more natural interpretation by the AI, allowing for a unique artistic expression.

Finally, the “style weight” (D-SSW) adjustment is a precision tool that lets you dictate the degree to which your selected style influences the final piece. This fine-tuning is crucial for attaining the exact stylistic impact you desire.

Midjourney AI offers a comprehensive suite of tools for artists and designers to refine their AI art prompts. By experimenting with settings such as “stylize,” “style raw,” and various weight adjustments, you can exert significant influence over the artistic output. Employing strategies like the “describe” feature and manipulating style references allows for further customization of the creative process.

The secret to creating art that truly embodies your vision lies in the willingness to explore and experiment with these tools. Each modification is a step towards perfecting the craft of AI-generated imagery, empowering you to create with both precision and inventiveness. As you delve deeper into the capabilities of Midjourney AI, you’ll discover that the ability to shape your artistic creations is within reach, offering unprecedented opportunities to push the boundaries of digital art.

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