— Act I · Prototype v1 · Today —
Live system simulation

From bench prototype to clinical reality.

EchoVest combines precision probe positioning, dual-sensor spatial tracking, and real-time AI processing into a single wearable platform. Below is a live simulation of the motion control and sensor fusion system running on Arduino GIGA R1 hardware.

EchoVest™ · GIGA Display Preview
v1 · Build 2026.04
ECHOVEST · EM-TECH GLOBAL HOLDINGS
SYSTEM READY ONLINE
Motion Control
EXTEND ▲
◄ LEFT
■ STOP
RIGHT ►
RETRACT ▼
STEP MODE
MOTIONSTOP
OWNER---
SPEED200
MODECOARSE
IMU #1 · PATIENT BODY ACTIVE
BMI270 · Wire1 · Internal · GIGA Display Shield
Ax+0.02
Gx+0.12
Ay−0.01
Gy−0.08
Az+0.98
Gz+0.03
IMU #2 · PROBE MOTION ACTIVE
External · Wire · I2C 0x68 · Attached to Probe
Ax+0.00
Gx+0.00
Ay+0.00
Gy+0.00
Az+0.00
Gz+0.00
CARDIAC COORDINATES
Cx+0.00mm
Cy+0.00mm
Cz0.00mm
Roll+0.00°
Pitch+0.00°
Yaw+0.00°
Echo Depth: 0.00 mm (pending) CONFIDENCE: 70%
Speed & System
SPEED
200
SET SPEED
PING
STATUS
FINE
EchoVest Motion Control v2 · Dual-IMU + Cardiac Coords · Arduino GIGA R1 + Display Shield T: 00000 ms
3.97" Display 800×480 Resolution Capacitive Touch Dual BMI270/MPU STM32H747XI MCU LVGL UI Stack
2026 2030
The same vest. Four years of intelligence.
Forward-Looking Concept Visualization Everything below this line represents EchoVest's 2030 product roadmap and engineering direction. The figures, displays, sensor fusion modalities, and performance characteristics shown are concept illustrations — not validated capabilities of the current Prototype v1 (shown above). All forward-looking statements are subject to research, regulatory clearance, and engineering validation.
EchoVest · Future-State Concept · 2030 Roadmap

Adaptive. Multi-spectral. AI-guided.

Where Prototype v1 stabilizes a probe, EchoVest 2030 fuses ultrasound with infrared thermography, LiDAR depth sensing, and real-time tissue heatmaps. Six independently controlled actuators move the probe array with sub-millimeter precision, guided by an on-board neural acquisition engine.

Concept
P1 P2 P3 P4 P5 P6 PARASTERNAL LONG P1 · 3.5 MHz SUBCOSTAL P5 · 2.5 MHz SUPRASTERNAL P6 · 4.0 MHz APICAL 4-CH / 2-CH P3-P4 · 3.5 MHz
Concept
EJECTION FRACTION
0%
Real-time AI estimate
CARDIAC OUTPUT
0 L/min
Doppler integration
SCAN CONFIDENCE
0%
6-probe consensus
ACQUISITION TIME
0s
Vest-to-report
Concept
— Multi-Spectral Imaging Modes —
ULTRASOUND
2.5–5 MHz · phased array · coherent beamforming
HEATMAP
Tissue perfusion · myocardial activity
INFRARED
Surface thermography · inflammation
LiDAR
Chest topology · 3-D probe routing
Concept
HEATMAP · MYOCARDIAL PERFUSION
SIMULATED
PEAK ΔT+2.4°C
ZONES17 / 17
FLOWNORMAL
FRAME0
INFRARED · TISSUE TEMP
SIMULATED
CORE37.1°C
MAX38.4°C
ANOMALIES0
FRAME0
LiDAR · CHEST TOPOLOGY
SIMULATED
POINTS8,400
DEPTH14.2 cm
SCANSTABLE
FRAME0
Concept
— Stewart Platform · 6-DOF Actuator Array —
● ALL SYSTEMS NOMINAL
Compute

Edge AI on the chest.

EchoVest 2030 carries an embedded NPU running a full echocardiographic interpretation engine on-device. No cloud round-trip required. Inference under 80ms.

Sensing

Five sensor modalities.

Phased-array ultrasound, thermal IR, LiDAR depth mapping, multi-channel EKG, and 9-axis IMU. Each stream is fused in real time with sub-millimeter spatial registration.

Power

Eight-hour ambulatory.

Solid-state battery delivers a full clinical day on a single charge. Wireless inductive recharging on a chest dock between scans.

The future is not arriving. We are building toward it.

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