From ultra-dense 70-GPU AI servers with two-stage engineered liquid cooling to our BSD-hardened security architecture, JEA Labs manufactures the most powerful and efficient computers in the world, with capabilities 8-20 years ahead of current industry standards.
Offering 400-1000% higher compute capacity than standard servers. One rack equals the power of all NASA's current supercomputers combined.
Two-stage engineered liquid cooling slashes energy consumption by 50-99%, delivering the greenest compute systems in 30+ years. This innovation could reduce global CO2 emissions by quadrillions of tons annually as AI adoption grows.
Custom BSD-based OS with Mandatory Access Control, ZFS snapshots, and fault-tolerant distributed filesystems ensure enterprise-grade protection. Our OS supports Kerberos, PKI, LAPD, PAM, and military-grade security frameworks.
Our modular nodes deliver high returns over a 7–10-year lifecycle by enabling component-level upgrades—swap out CPUs, RAM, GPUs, DPUs, neuromorphic chips or PCIe/CXL boards as needed—so you stay at the cutting edge without replacing entire systems. This fine-grained refresh model not only maximizes ROI but also drastically cuts e-waste by extending the useful life of your core hardware.
We deliver 100% custom-engineered platform solutions, meticulously optimized and provisioned precisely to each client's unique requirements. This bespoke service includes fine-grained system tuning via precision frequency and voltage scaling (validated overclocking/underclocking), integration of specialized hardware components, and highly resilient connectivity options such as high-capacity 5G interfaces and multi-constellation satellite access.
Our System of Systems approach combines hardware, software, and services into a unified platform that eliminates silos, integrates workflows, and creates a seamless technological ecosystem.
Our premier AI platform, powered by our Software-Defined Architecture, achieves unprecedented compute density within a single system enclosure. This design unlocks immense processing capacity, far exceeding traditional systems. It integrates state-of-the-art engineered liquid cooling for optimal thermal management and sustained peak performance, while the Software-Defined approach concurrently drives dramatically superior power efficiency compared to conventional server deployments.
Real-world impact: Train large language models 8x faster than industry standard clusters while reducing carbon footprint by 28%.
Leveraging our Software-Defined Architecture, our storage-optimized node delivers immense capacity and supports enterprise-grade distributed file systems including ZFS, Gluster, Ceph, and Lustre. It integrates substantial high-speed system memory with ultra-low latency NVMe storage to achieve cutting-edge data throughput capabilities.
Real-world impact: Store and process entire genomic databases or satellite imagery archives with unprecedented speed and redundancy.
Our Software-Defined platform for advanced RF applications features sophisticated, reconfigurable SDR antenna arrays providing expansive and dynamic spectral coverage. It incorporates integrated atomic-level timing sources and robust multi-constellation GNSS support, delivering unparalleled precision and flexibility for complex radio frequency processing tasks
Real-world impact: Enable next-generation 5G/6G networks, advanced radar systems, and spectrum monitoring with unprecedented precision.
Built on cutting-edge principles inspired by architectures like Intel's Loihi2, our Software-Defined Neuromorphic platform delivers vastly scaled neural network capacity. Supported by our advanced thermal management infrastructure, this approach enables exceptionally dense and efficient brain-inspired computing solutions.
Real-world impact: Run human-like reasoning and pattern recognition at microsecond latencies with minimal power consumption.
Leveraging our Software-Defined Architecture, we deliver portable high-performance computing solutions for autonomous vehicles, drones, and robotics. These systems integrate massive parallel processing capacity within optimized mobile form factors, enabling ultra-low latency, real-time cognitive processing at immense speed for dynamic operational environments.
Real-world impact: Enable truly autonomous systems that operate independently of cloud connections, even in remote or contested environments.
Based on our Software-Defined Architecture, we offer space-optimized computing nodes specifically engineered for the rigorous environments of Low Earth Orbit (LEO) and Medium Earth Orbit (MEO). These nodes integrate our proprietary thermal management technology to enable significant processing capability per satellite node, delivering high-performance compute for demanding space applications.
Real-world impact: Process satellite imagery, climate data, and communications in orbit, drastically reducing the need for ground transmission.
Deploy complex multi-agent systems that coordinate to solve problems beyond single agent capabilities. Our infrastructure enables workflow orchestration, decision-making autonomy, and continuous learning.
Train trillion-parameter AI models in weeks instead of months. Our 70+ GPU systems with high-bandwidth fabric deliver near-linear scaling efficiency for distributed training of foundation models.
Handle thousands of simultaneous inference requests with sub-millisecond latency. Ideal for recommendation engines, fraud detection, and time-sensitive analytics at global scale.
Process vast user interaction datasets to deliver hyper-personalized experiences across digital touchpoints, adapting to individual preferences in real-time.
Accelerate pharmaceutical research through molecular simulation, protein folding, and drug-target interaction modeling. Our systems can analyze billions of compounds in days instead of years.
Transform production with real-time analytics, predictive maintenance, and AI-driven quality control. Our SCADA nodes combine industrial control with edge AI in a single system.
Run high-resolution climate simulations (1km² grid) in hours instead of days. Enable more accurate forecasting, disaster prediction, and climate change research.
Power next-generation self-driving vehicles, drones, and robotics with edge computing that can process sensor data and make decisions in microseconds without cloud dependency.
With a record-breaking PUE of 1.01-1.07 using our engineered liquid cooling (versus industry average 1.57), JEA Labs systems deliver:
If AI continues its exponential growth trajectory, our technology could deliver environmental impact comparable to electrifying the entire transportation sector.
Our systems deliver exceptional financial returns through:
Despite higher initial investment, total cost of ownership analysis shows 30-50% savings over conventional infrastructure for compute-intensive workloads.
| Metric | Standard HPC/Cloud Infrastructure | JEA Labs Solutions | Advantage |
|---|---|---|---|
| Power Efficiency | PUE 1.57-2.0 | PUE 1.01-1.20 | 50-99% improvement |
| Compute Density | 30-60 kW per rack | 150-300+ kW per rack | 400-1000% higher |
| Hardware Lifespan | 3-5 years | 7-10+ years | 100-200% longer |
| Space Requirements | 30-60 racks per MW | 5-7 racks per MW | 300-600% reduction |
| GPU Capacity | 8-16 GPUs per server | 16-70+ GPUs per server | 100-775% more GPUs |
JEA Labs systems aren't just incremental improvements—they represent generational leaps in computing capability, efficiency, and sustainability. Our technology integrates seamlessly with Neocloud environments while delivering performance that's 8-20 years ahead of current industry standards.
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