One physical pool for Arm cores, weights, activations, and KV-cache.
Headless inference hardware
blackbox. 512 GB unified. Inference only.
A sealed node for large open language models — private on your floor, efficient by design, ready from one unit to one hundred.
Design targets
More model. Less machine.
Wide LPDDR on package — the path models actually walk.
Aggregate theoretical per direction across four UALink x4 ports.
Sustained full inference budget. No graphics tax. No training tax.
Mandate
If it doesn’t emit tokens, it doesn’t ship.
Not a workstation. Not a training rack. A headless inference system — silicon, memory, and cooling aimed at language models alone.
DVC-1 architecture
One SoC. One memory pool. One job.
DVC-1 places Arm control cores, a large tensor fabric, SRAM, memory controllers, and cluster I/O on one silicon platform. CPU and accelerator share the same physical LPDDR — no shuttling between system RAM and separate VRAM.
Unified memory
512 GB where the model actually lives.
One pool.
No shuttle.
Arm cores and the inference accelerator share one physical address space. Weights, KV-cache, and runtime data live in a coherent local pool — not bounced between host memory and a separate accelerator heap.
Inference accelerator
Built for the next token.
Hardware that follows the transformer.
DVC-1 keeps weights in motion, cuts idle cycles, and fuses the ops that dominate modern language models. Primary KPIs: tokens per watt, time to first token, cost per million tokens.
Minimum for dense FP8 inference. Stretch goal 4 PF by process node, die area, and power envelope.
Quantized decode and batching first. No silicon reserved for graphics or training.
Power & cooling
Rack-class work. Desk-side power.
Every watt serves the model.
The compact enclosure uses a vapor chamber, two large low-RPM fans, and front-to-back airflow. An internal high-efficiency PSU absorbs short peaks without raising sustained draw.
Scale-up & scale-out
From 512 GB to 51.2 TB.
One node when enough. A hundred when not.
Each unit holds 512 GB of real local unified memory. Multiple nodes form a distributed model pool over UALink switches and RDMA. Memory is not physically local across the cluster — the runtime shards layers, experts, and KV-cache automatically.
Connectivity
Four fast ports. No waste.
x4
x4
x4
x4
RDMA A
RDMA B
MGMT
Service
Four UALink x4. Switch when the cluster grows.
Each x4 port targets up to 100 GB/s per direction at 200 Gbit/s per lane. Four ports yield a theoretical aggregate of 400 GB/s per direction. Five or more nodes use a switched fabric — not a chain.
Open software stack
Ubuntu in. Familiar API out.
A local AI service — not a new proprietary stack.
Standard tooling
Ubuntu LTS ARM64, containerd, Kubernetes support, Prometheus metrics, and an OpenAI-compatible REST and streaming API.
Open model formats
Runtime targets for safetensors, GGUF, and ONNX. Conversion and quantization as reproducible pipelines.
Automatic sharding
Runtime splits layers, experts, tensors, and KV-cache across nodes without the API client knowing the topology.
Planned system specification
davici blackbox 512.
Deliverables from ASIC partner
- Architecture model, PPA estimates, and memory bandwidth model.
- Arm, LPDDR, PCIe, UALink, Ethernet, and security IP integration.
- RTL, verification, emulation, DFT, physical design, and tapeout.
- Package, substrate, signal integrity, power integrity, and thermal model.
- Boot firmware, Linux BSP, kernel driver, runtime, and profiling tools.
Deliverables from ODM
- Motherboard, VRM, BMC, NVMe, networking, and cabling.
- Chassis, cooling, PSU, acoustics, and serviceability.
- EVT, DVT, and PVT units with complete test documentation.
- EMC, safety, CE, RoHS, WEEE, and production testing.
- Supply chain, second-source plan, and cost model for 1k, 10k, and 100k units.
Tokens.
Nothing else.
Large open models. Local. Scalable. Efficient. Under your control.