Inertia-1

The big idea

Towards one general motion model

Motion is universal — but the models built for it weren't. Inertia-1 brings the whole landscape under one roof.

01A fragmented field

Datasets disagree on the basics — sampling rate, window length, sensor modality, body placement, even signal format — and every task gets its own bespoke model. Findings rarely carry from one setup to the next.

02One unified exploration

Inertia-1 studies the full lifecycle of motion models — data, sensing, objectives, and scale — inside a single, controlled space instead of isolated one-offs.

03A general representation

The payoff: one representation that adapts across placements, devices, and tasks — the same backbone, working far beyond the setting it was trained on.

Head Chest Back Arm Wrist Hand Hip Thigh Knee Shin Ankle Accelerometer Gyroscope Magnetometer Triaxial ENMO 0.2 Hz 1 Hz 5 Hz 20 Hz 10 s window 30 s window 60 s window 2 hr window Frequency domain Time domain Activity recognition Gait detection Longitudinal health Head Chest Back Arm Wrist Hand Hip Thigh Knee Shin Ankle Accelerometer Gyroscope Magnetometer Triaxial ENMO 0.2 Hz 1 Hz 5 Hz 20 Hz 10 s window 30 s window 60 s window 2 hr window Frequency domain Time domain Activity recognition Gait detection Longitudinal health
What we found

Beyond benchmarks, Inertia-1 surfaces the choices that decide whether a motion model actually works in the real world.

Learn it on the wrist. Use it anywhere on the body.

A wrist sensor pretrained on accelerometry transfers across the body — head, chest, hip, thigh, knee, shin, and ankle — each showing its own motion signal.

Pretrain once on the wrist, then point the model anywhere. It holds up on body placements — and even sensor types like gyroscope and magnetometer — that it never saw during training. No retraining for each new spot on the body.

Wrist-accelerometer pretraining transfers across sensors and placements.
Wrist accelerometer Other sensors · gyro, mag Other placements
Fused representation higher accuracy · cleaner motion clusters

Add more streams. Get more signal.

Multi-stream fusion improves representation geometry.

Stack on more streams — extra placements, gyroscope, magnetometer — and the learned representation gets both more accurate and cleaner, with activities separating into tighter clusters. The streams are complementary: each one catches something the others miss.

Also worth knowing

Sensing design is a first-order choice

How you capture motion shapes what a model can do with it. A few practical rules of thumb from the study.

How it works

One pipeline, from raw signal to real-world insight

The general representation comes together in three clean steps.

01
Pretrain at scale

Learn from planetary-scale accelerometry — over 18 million hours across global cohorts — with self-supervision, no labels required.

02
Transfer across settings

Adapt the same representation to new placements, devices, and sampling rates with light tuning — or none at all.

03
Deploy across tasks

Power activity, mobility, and health applications from one backbone — from fitness tracking to clinical screening.

Capabilities

From movement to meaning

The same representation spans the full spectrum of motion understanding.

One general model for human motion

Inertia-1 is a first step toward a unified motion foundation model — and an open invitation to collaborators with motion data, new tasks, or a shared interest in where the field is headed.