FOR EVALUATION DOC TORUS-BRIEF-001 REV 2026-07 CLASS UAGVIS / passive-defensive PacketFive
TORUS · Unattended Air-Ground-Visual Sensor

A passive sensing complex for mission-critical perimeters.

TORUS is an unattended, layered detection system (a UAGVIS, the modern successor to ground sensor fields) built to protect fixed assets and the people inside them. It senses across the ground, the sightline, and the airspace, classifies threats at the edge with on-device AI, and drives a cued, safety-interlocked response, from terrain with no mains power and no network.

Zero-missthreat pipeline
Layeredground / visual / air
Passivelow-signature sensing
Cued responsetransducer interlock
AI-enablededge to command
01 / OPERATIONAL NEED

The perimeter is the problem

Mission-critical sites (installations, infrastructure, research and forward positions) are compromised at the approaches, long before the fence. The approaches are exactly where power, network, and manpower are scarce. Fixed cameras see a cone; patrols see a moment; fences report only contact.

TORUS holds the approaches continuously and passively. It detects an intrusion in more than one physical domain, correlates the cues, and hands the operator a classified track with location and confidence, not a raw alarm.

Design goal

Not one event missed

Every threat event is captured, sequenced, and delivered. Coverage gaps are detected, not discovered after the fact.

Posture

Passive & low-signature

Sensing emits nothing to find. The only active element is a response node, and it fires only through an interlock.

Autonomy

Off-grid, unattended

Battery and solar operation, long-range radio, months between visits.

Assurance

Auditable by design

Every detection and every command is timestamped and logged for after-action review.

02 / LAYERED DEFENCE

Three sensing domains, one picture

TORUS covers an approach from below, at eye level, and overhead. Each domain matures on its own track, so the ground layer deploys today and the system extends without replacing what is already emplaced.

GROUND · FIELDED

Ground sensing

Seismic and acoustic detection on unattended battery nodes reporting over long-range radio. Pre-production hardware complete.

TORUS-SN · SEISMIC + ACOUSTIC + GNSS
VISUAL · IN DEVELOPMENT

Visual confirmation

Long-range thermal cores and LiDAR on a mast, cued by ground detections to identify and track at standoff, day or night.

THERMAL (LWIR) + LiDAR + LONG-RANGE OPTICS
AIR · EXPERIMENTAL

Airspace awareness

Radar-class RF detection of airborne targets at range. An active research track: long-range air detection demands higher transmit power and dedicated RF front ends.

HIGH-POWER RF · RESEARCH
03 / SENSOR NODE VARIANTS

One protocol, four node classes

A deployment mixes node classes to match cost, threat, and site constraints. All classes report on the same event contract, so the command layer treats a mixed field as one sensor network.

#ClassLink / RFMaturityRole & trade-off
1Fixed WirelessLoRa 433 MHz FIELDEDLowest cost per node; the default perimeter element for wide, dense rings.
2Programmable WirelessSDR (AD9371 / AD9363)
+ LoRa failsafe
R&DSoftware-defined RF for experimental, R&D, and mission-critical use. Ships with LoRa as a failsafe that can also serve as the main link; where LoRa alone suffices, class 1 is the cheaper choice.
3Wired OpticalOptical fibre R&DEmanation-quiet, tamper-resistant wired transport for the highest-assurance segments.
4Transducerper host node CONCEPTEffect node. On a validated cue it actuates a response through a mandatory safety interlock (activate, safety-validate, then trigger).
04 / GROUND SENSING PAYLOAD

What is on the node

Every sensing channel on the TORUS-SN ground node is a named, datasheet-backed component selected for low standby power and field serviceability.

Seismic

Geophone + adjustable AFE

4.5 Hz vertical geophone into a low-noise front end with 128-step digital gain and a hardware wake comparator that trips with the processor asleep. Signatures: footfall, vehicles, digging.

R.T. CLARK 4.5 Hz · OPA2134 · MCP4017 · LM393
Acoustic

Stereo MEMS array

Two 24-bit I2S microphones give a stereo field for on-device classification. Audio is classified at the node; raw audio never leaves it.

2× INMP441 I2S
Radio & position

Tri-function transceiver

LoRa 433 MHz uplink, GNSS scanning, and passive Wi-Fi-scan positioning from one device. A relocated node reports its own new position.

SEMTECH LR1110 · 32 MHz TCXO
Compute & autonomy

Edge processing + power

Dual-core edge MCU with on-device ML, temperature-compensated timekeeping, single-cell Li-ion with USB-C charging, and three independently gated sensing rails.

ESP32-S3 · DS3231 · TP4056 · 3× TPS22918
05 / THREAT PROCESSING

Zero-miss, priority-preemptive

The runtime guarantee is a reliability property, not a slogan: every event is captured, ordered, and delivered, and the most dangerous event is never queued behind noise.

CAPTURE

Sequence at source

Each node stamps every event with a monotonic sequence number.

DELIVER

At-least-once

Events are forwarded with de-duplication on identity; nothing is silently dropped.

DETECT GAPS

Miss = visible

A break in the sequence is flagged and replayed, so a missed event is detected, not discovered later.

PREEMPT

Severity first

Critical threats preempt lower-priority processing in the queue.

On complexity, stated correctly. The runtime is a hard-real-time, zero-miss pipeline. The genuinely NP-hard problem in TORUS is optimal sensor placement for complete coverage (a set-cover / art-gallery problem). That is why the deployment is rehearsed in simulation first: the coverage problem is approximated off-line, then zero-miss processing is guaranteed on-line.

06 / DEPLOYMENT & COVERAGE

A ring around what matters

A representative emplacement: ground nodes form the outer detection ring, visual masts cover the likely approaches, the experimental air layer watches the volume overhead, and every element reports to a single gateway at the asset.

AIR SURVEILLANCE VOLUME · EXPERIMENTAL VISUAL MAST THERMAL + LiDAR VISUAL MAST THERMAL + LiDAR TORUS-SN GROUND RING ×8 PROTECTED INSTALLATION TORUS-MEG GATEWAY CONTACT SEISMIC + ACOUSTIC
ground node + seismic footprint visual mast field of view LoRa 433 MHz uplink air surveillance volume gateway
07 / MISSION REHEARSAL

Rehearse the site before emplacement

Remote sites are expensive to survey twice. A deployment is rehearsed as a cyber-physical twin in NVIDIA Isaac Sim: terrain reconstructed from mapping data, the full system placed virtually, and intrusion scenarios run against it. The figure below is real output from the open-source planner.

t+49s SN-06 t+128s SN-05 t+400s SN-02 t+446s SN-01 TORUS deployment simulation · Rural perimeter - mountain installation rural · 8 nodes · ring 250 m · noise floor 0.05 · 4 detections
SCENARIO rural perimeter RING 8 nodes @ 250 m FIRST CONTACT t+49 s, node SN-06 OUTCOME 4 nodes triggered along track

In urban emplacements the twin earns its keep twice: the city noise floor is simulated first, so seismic thresholds and acoustic classifiers arrive on site pre-tuned against the local background instead of by trial and error.

08 / SYSTEM ARCHITECTURE

Sensor field, gateway, command

Edge

TORUS-SN nodes

Mixed node classes sense passively and classify at the edge, reporting compact events over LoRa, SDR, or optical.

AI AT THE EDGE
Aggregation

TORUS-MEG gateway

Receives the field, fuses and timestamps events on a Jetson-class edge computer, and forwards over flexible backhaul. Cluster-aware: gateways chain and federate across distances for high availability. Off-grid, rugged.

8-CH LoRa · JETSON ORIN · CLUSTER / HA
Command

TORUS-CCISRT

The operator layer: one live common operating picture for the room and the field, with the transducer response under interlock.

AI AT COMMAND & CONTROL
09 / COMMAND LAYER

TORUS-CCISRT: one picture, two vantage points

Command, Control, Intelligence, Surveillance, Reconnaissance, and Transducer. The operations room and the field operator share a single fused picture; each sees it in the form the job needs, and effect nodes fire only through the interlock.

Operations room

Common operating picture

Map wall with live node, gateway, and mast state; fused, prioritised alerts; triage and escalation; thermal/video cued from the masts; timeline replay; deployment planning with the Isaac rehearsal link.

Field operator

Rugged tasking app

Handheld map with own position and the node ring; prioritised alerts with bearing and distance; cue a sensor or mast; confirm or reclassify in the field; offline-tolerant sync over the gateway.

10 / ASSURANCE

Built to be trusted with the response

Interlock

No trigger without validation

A transducer walks arm, safety-validate, then trigger. The trigger is refused until validation passes.

Audit

Every command logged

Who armed, validated, or triggered what, and when, is recorded for after-action review.

Deployment

On-prem / air-gapped

The command layer runs on-premises, with a fully air-gapped option for high-security sites.

11 / DOCUMENTATION & SOURCE

Datasheets and repositories

TRADEMARKS & THIRD-PARTY NOTICE

TORUS is an independent platform. Company names and product model numbers referenced across this brief and its datasheets (including but not limited to Teledyne FLIR, Semtech (LR1110), R.T. Clark, InvenSense (INMP441), Texas Instruments, Microchip, Espressif (ESP32-S3), Analog Devices (DS3231, AD9371, AD9363), and NVIDIA Jetson and Isaac Sim) are used solely for engineering and bill-of-materials identification. Their use does not imply any affiliation with, sponsorship by, or endorsement by those companies. Supply of any such third-party product or component to the designers, manufacturers, integrators, or evaluators of the TORUS platform remains at the sole discretion of the respective owning company, organisation, or legal entity. "FOR EVALUATION" is a document-handling marking only and does not denote any government classification. All trademarks are the property of their respective owners.