Category robots

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Humans are known to accumulate knowledge over time, which in turn allows them to continuously improve their abilities and skills. This capability, known as lifelong learning, has so far proved difficult to replicate in artificial intelligence (AI) and robotics systems.

Engineers have developed a versatile swimming robot that nimbly navigates cluttered water surfaces. Inspired by marine flatworms, the innovative device offers new possibilities for environmental monitoring and ecological research.

Swimming robots play a crucial role in mapping pollution, studying aquatic ecosystems, and monitoring water quality in sensitive areas such as coral reefs or lake shores. However, many devices rely on noisy propellers, which can disturb or harm wildlife. The natural clutter in these environments—including plants, animals, and debris—also poses a challenge to robotic swimmers.

Researchers find large language models process diverse types of data, like different languages, audio inputs, images, etc., similarly to how humans reason about complex problems. Like humans, LLMs integrate data inputs across modalities in a central hub that processes data in an input-type-agnostic fashion.

A recent breakthrough in photothermal actuator design has been achieved by a research team from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences, led by Prof. Tian Xingyou and Prof. Zhang Xian. The team developed a novel superstructure liquid metal/low expansion polyimide/polydimethylsiloxane (LM@PI/PDMS) actuator, which combines rapid movement with impressive load-carrying capacity—an achievement that has eluded previous actuator designs.

Researchers have unveiled a transformative framework for understanding complex systems. This pioneering study establishes the new field of higher-order topological dynamics, revealing how the hidden geometry of networks shapes everything from brain activity to the climate and artificial intelligence (AI).

Ballbots are versatile robotic systems with the ability to move around in all directions. This makes it tricky to control their movement. In a recent study, a team has proposed a novel proportional integral derivative controller that, in combination with radial basis function neural network, robustly controls ballbot motion. This technology is expected to find applications in service robots, assistive robots, and delivery robots.

The ballbot is a unique kind of robot with great mobility and possesses the ability to go in all directions. Obviously, controlling such a robotic device must be tricky. Indeed, ballbot systems pose unique challenges, particularly in the form of the difficulty of maintaining balance and stability in dynamic and uncertain environments.

Furniture manufacturer Enterijer Mesicki has created a cutting-edge robotic solution for automated furniture production using RoboDK software and FANUC technology.

Conventional drones use visual sensors for navigation. However, environmental conditions like dampness, low light, and dust can hinder their effectiveness, limiting their use in disaster-stricken areas. Researchers from Japan have developed a novel bio-hybrid drone by combining robotic elements with odor-sensing antennae from silkworm moths. Their innovation, which integrates the agility and precision of robots with biological sensory mechanisms, can enhance the applicability of drones in navigation, gas sensing, and disaster response.

An innovative circuit design could enable miniature devices, such as microdrones and other microrobotics, to be powered for longer periods of time while staying lightweight and compact. Researchers from the University of California San Diego and CEA-Leti developed a novel self-sustaining circuit configuration—featuring miniaturized solid-state batteries—that combines high energy density with an ultra lightweight design.

As you may have heard, DeepSeek-R1 is making waves. It’s all over the AI newsfeed, hailed as the first open-source reasoning model of its kind. 

The buzz? Well-deserved. 

The model? Powerful.

DeepSeek-R1 represents the current frontier in reasoning models, being the first open-source version of its kind. But here’s the part you won’t see in the headlines: working with it isn’t exactly straightforward. 

Prototyping can be clunky. Deploying to production? Even trickier.

That’s where DataRobot comes in. We make it easier to develop with and deploy DeepSeek-R1, so you can spend less time wrestling with complexity and more time building real, enterprise-ready solutions. 

Prototyping DeepSeek-R1 and bringing applications into production are critical to harnessing its full potential and delivering higher-quality generative AI experiences.  

So, what exactly makes DeepSeek-R1 so compelling — and why is it sparking all this attention? Let’s take a closer look at if all the hype is justified. 

Could this be the model that outperforms OpenAI’s latest and greatest? 

Beyond the hype: Why DeepSeek-R1 is worth your attention

DeepSeek-R1 isn’t just another generative AI model. It’s arguably the first open-source “reasoning” model — a generative text model specifically reinforced to generate text that approximates its reasoning and decision-making processes.

For AI practitioners, that opens up new possibilities for applications that require structured, logic-driven outputs.

What also stands out is its efficiency. Training DeepSeek-R1 reportedly cost a fraction of what it took to develop models like GPT-4o, thanks to reinforcement learning techniques published by DeepSeek AI. And because it’s fully open-source, it offers greater flexibility while allowing you to maintain control over your data.

Of course, working with an open-source model like DeepSeek-R1 comes with its own set of challenges, from integration hurdles to performance variability. But understanding its potential is the first step to making it work effectively in real-world applications and delivering more relevant and meaningful experience to end users. 

Using DeepSeek-R1 in DataRobot 

Of course, potential doesn’t always equal easy. That’s where DataRobot comes in. 

With DataRobot, you can host DeepSeek-R1 using NVIDIA GPUs for high-performance inference or access it through serverless predictions for fast, flexible prototyping, experimentation, and deployment. 

No matter where DeepSeek-R1 is hosted, you can integrate it seamlessly into your workflows.

In practice, this means you can: 

• Compare performance across models without the hassle, using built-in benchmarking tools to see how DeepSeek-R1 stacks up against others.
  
  
• Deploy DeepSeek-R1 in production with confidence, supported by enterprise-grade security, observability, and governance features.
  
  
• Build AI applications that deliver relevant, reliable outcomes, without getting bogged down by infrastructure complexity.
  

LLMs like DeepSeek-R1 are rarely used in isolation. In real-world production applications, they function as part of sophisticated workflows rather than standalone models. With this in mind, we evaluated DeepSeek-R1 within multiple retrieval-augmented generation (RAG) pipelines over the well-known FinanceBench dataset and compared its performance to GPT-4o mini.

So how does DeepSeek-R1 stack up in real-world AI workflows? Here’s what we found:

• Response time: Latency was notably lower for GPT-4o mini. The 80th percentile response time for the fastest pipelines was 5 seconds for GPT-4o mini and 21 seconds for DeepSeek-R1.
  
  
• Accuracy: The best generative AI pipeline using DeepSeek-R1 as the synthesizer LLM achieved 47% accuracy, outperforming the best pipeline using GPT-4o mini (43% accuracy).
  
  
• Cost: While DeepSeek-R1 delivered higher accuracy, its cost per call was significantly higher—about $1.73 per request compared to $0.03 for GPT-4o mini. Hosting choices impact these costs significantly.
  
  

While DeepSeek-R1 demonstrates impressive accuracy, its higher costs and slower response times may make GPT-4o mini the more efficient choice for many applications, especially when cost and latency are critical.

This analysis highlights the importance of evaluating models not just in isolation but within end-to-end AI workflows.

Raw performance metrics alone don’t tell the full story. Evaluating models within sophisticated agentic and non-agentic RAG pipelines offers a clearer picture of their real-world viability.

Using DeepSeek-R1’s reasoning in agents

DeepSeek-R1’s strength isn’t just in generating responses — it’s in how it reasons through complex scenarios. This makes it particularly valuable for agent-based systems that need to handle dynamic, multi-layered use cases.

For enterprises, this reasoning capability goes beyond simply answering questions. It can:

• Present a range of options rather than a single “best” response, helping users explore different outcomes.
  
  
• Proactively gather information ahead of user interactions, enabling more responsive, context-aware experiences.
  

Here’s an example:

When asked about the effects of a sudden drop in atmospheric pressure, DeepSeek-R1 doesn’t just deliver a textbook answer. It identifies multiple ways the question could be interpreted — considering impacts on wildlife, aviation, and population health. It even notes less obvious consequences, like the potential for outdoor event cancellations due to storms.

In an agent-based system, this kind of reasoning can be applied to real-world scenarios, such as proactively checking for flight delays or upcoming events that might be disrupted by weather changes. 

Interestingly, when the same question was posed to other leading LLMs, including Gemini and GPT-4o, none flagged event cancellations as a potential risk. 

DeepSeek-R1 stands out in agent-driven applications for its ability to anticipate, not just react.

Compare DeepSeek-R1 to GPT 4o-mini: What the data tells us

Too often, AI practitioners rely solely on an LLM’s answers to determine if it’s ready for deployment. If the responses sound convincing, it’s easy to assume the model is production-ready. But without deeper evaluation, that confidence can be misleading, as models that perform well in testing often struggle in real-world applications. 

That’s why combining expert review with quantitative assessments is critical. It’s not just about what the model says, but how it gets there—and whether that reasoning holds up under scrutiny.

To illustrate this, we ran a quick evaluation using the Google BoolQ reading comprehension dataset. This dataset presents short passages followed by yes/no questions to test a model’s comprehension. 

For GPT-4o-mini, we used the following system prompt:

Try to answer with a clear YES or NO. You may also say TRUE or FALSE but be clear in your response.

In addition to your answer, include your reasoning behind this answer. Enclose this reasoning with the tag <think>. 

For example, if the user asks “What color is a can of coke” you would say:

<think>A can of coke must refer to a coca-cola which I believe is always sold with a red can or label</think>

Answer: Red

Here’s what we found:

• Right: DeepSeek-R1’s output.
• On the far left: GPT-4o-mini answering with a simple Yes/No.
• Center: GPT-4o-mini with reasoning included.

We used DataRobot’s integration with LlamaIndex’s correctness evaluator to grade the responses. Interestingly, DeepSeek-R1 scored the lowest in this evaluation.

What stood out was how adding “reasoning” caused correctness scores to drop across the board. 

This highlights an important takeaway: while DeepSeek-R1 performs well in some benchmarks, it may not always be the best fit for every use case. That’s why it’s critical to compare models side-by-side to find the right tool for the job.

Hosting DeepSeek-R1 in DataRobot: A step-by-step guide  

Getting DeepSeek-R1 up and running doesn’t have to be complicated. Whether you’re working with one of the base models (over 600 billion parameters) or a distilled version fine-tuned on smaller models like LLaMA-70B or LLaMA-8B, the process is straightforward. You can host any of these variants on DataRobot with just a few setup steps.

1. Go to the Model Workshop:

• Navigate to the “Registry” and select the “Model Workshop” tab.

2. Add a new model:

• Name your model and choose “[GenAI] vLLM Inference Server” under the environment settings.
• Click “+ Add Model” to open the Custom Model Workshop.

3. Set up your model metadata:

• Click “Create” to add a model-metadata.yaml file.

4. Edit the metadata file:

• Save the file, and “Runtime Parameters” will appear.
• Paste the required values from our GitHub template, which includes all the parameters needed to launch the model from Hugging Face.

5. Configure model details:

• Select your Hugging Face token from the DataRobot Credential Store.
• Under “model,” enter the variant you’re using. For example: deepseek-ai/DeepSeek-R1-Distill-Llama-8B.

6. Launch and deploy:

• Once saved, your DeepSeek-R1 model will be running.
• From here, you can test the model, deploy it to an endpoint, or integrate it into playgrounds and applications.

From DeepSeek-R1 to enterprise-ready AI

Accessing cutting-edge generative AI tools is just the start. The real challenge is evaluating which models fit your specific use case—and safely bringing them into production to deliver real value to your end users.

DeepSeek-R1 is just one example of what’s achievable when you have the flexibility to work across models, compare their performance, and deploy them with confidence. 

The same tools and processes that simplify working with DeepSeek can help you get the most out of other models and power AI applications that deliver real impact.

See how DeepSeek-R1 compares to other AI models and deploy it in production with a free trial. 

The post How to use DeepSeek-R1 for enterprise-ready AI appeared first on DataRobot.

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