Datasets:

anthonytec2
/

OctoSense

	---
	pretty_name: OctoSense
	license: mit
	task_categories:
	- depth-estimation
	- image-segmentation
	- robotics
	tags:
	- autonomous-driving
	- multimodal
	- lidar
	- event-camera
	- stereo
	- optical-flow
	- ego-motion
	- sensor-fusion
	- infrared
	- gps
	- geospatial
	- robotics
	- 3d
	- timeseries
	size_categories:
	- n>1T
	configs:
	- config_name: default
	data_files: metadata.parquet
	---
	# Pre-Release State

	<p align="center">
	<img src="assets/banner_inline.png" alt="OctoSense" width="760"/>
	</p>

	<p align="center">
	<video autoplay loop muted playsinline width="100%" poster="https://huggingface.co/datasets/anthonytec2/OctoSense/resolve/main/assets/hero.gif">
	<source src="https://huggingface.co/datasets/anthonytec2/OctoSense/resolve/main/assets/hero.mp4" type="video/mp4"/>
	<img src="assets/hero.gif" alt="OctoSense — synchronized multi-sensor driving across day, night, and degraded conditions" width="100%"/>
	</video>
	</p>

	A time-synchronized, calibrated multi-sensor driving dataset: 371 sequences · 59 hrs · 2,474 km · 8.43 TB,
	spanning urban, suburban, and rural driving (highway / residential / city) on Long Island and in
	Philadelphia, across sunrise, daytime, sunset, and nighttime. Sequences carry synchronized stereo RGB, stereo event cameras, infrared, Ouster LiDAR, two IMUs, GPS and CAN data, plus ground truth (depth, ego-motion optical flow, semantic segmentation) and a fused GPS + LiDAR-inertial odometry trajectory.

	Upon release, we will provide code for using the dataset and deriving flow.


	> Canonical key for every sequence is its recording datetime, `rosbag2_YYYY_MM_DD-HH_MM_SS`.
	> Per-sequence attributes live in `metadata.parquet` (the viewer's table: a sensor-montage thumbnail, a GPS-track map, and all metadata columns per sequence).

	## Sensors

	\| Modality \| Sensor \| Info \| Rate \|
	\|---\|---\|---\|---\|
	\| RGB (stereo) \| 2× FLIR Blackfly S (Sony IMX421) \| 1920×1456 \| 100 Hz \|
	\| Event (stereo) \| 2× SilkyEV VGA (Prophesee) \| 640×480 \| ≈7 MEv/s avg \|
	\| Thermal \| FLIR A35 \| 320×256 \| 50 Hz \|
	\| LiDAR \| Ouster OS1-64 \| 64 beams × 2048 \| 10 Hz \|
	\| IMU \| VectorNav VN-100T \| Acc/Gyro/Mag/Baro/Temp \| 400 Hz \|
	\| IMU (in LiDAR) \| IAM-20680HT \| Acc/Gyro \| 100 Hz \|
	\| GNSS \| u-blox ZED-F9P \| RTK (NTRIP) \| 5 Hz \|
	\| Vehicle \| 2021 Mazda CX-5 \| CAN Signals \| 50–100 Hz \|


	## Coordinate frames & calibration

	![Per-sensor coordinate axes on the OctoSense rig (red = X, green = Y, blue = Z)](assets/cal_axis.png)

	All extrinsics are stored per-sequence under `/calib` in the bag h5, named `A_T_B` — a 4×4 matrix that
	maps a point from frame B into frame A (e.g. `imgl_T_ouster` takes LiDAR points into the
	left-RGB frame). Frame abbreviations:

	\| abbrev \| frame \| \| abbrev \| frame \|
	\|---\|---\|---\|---\|---\|
	\| `imgl` / `imgr` \| RGB left / right \| \| `ir` \| Infrared (FLIR A35) \|
	\| `evl` / `evr` \| Event left / right \| \| `ouster` \| LiDAR \|
	\| `imu` \| VectorNav IMU \| \| \| \|

	Provided extrinsics: `imgl_T_imgr`, `imgl_T_imu`, `imgl_T_ir`, `imgr_T_imu`, `ir_T_imgl`, the event-pair
	set (`evl_T_evr`, `evl_T_imgl`, …), `ouster/imgl_T_ouster` / `ouster/ir_T_ouster`, and
	`calib/lidar_T_lidarimu` (LiDAR IMU → LiDAR/sensor frame, from the Ouster factory
	`imu_to_sensor_transform`). Each drive records which calibration it used via `rgb_cal_id` /
	`imu_cal_id` / `lidar_cal_id` (in the metadata). RKO-LIO odometry (`ouster/odom/`) tracks the LiDAR pose in the Map frame*;
	the `fused_traj` trajectory tracks the same LiDAR pose in the UTM-relative world frame (see Ground truth). The depth
	GT is rendered in the rectified left-RGB camera image (OpenCV `stereoRectify`, R1 applied). Use the
	`/calib` extrinsics (e.g. `imgl_T_ouster`) to move between frames.

	> Per-session calibration is released alongside the data, in Kalibr format:
	> - Cameras (`calibration-camchain.yaml`) — a 4-camera Kalibr chain: `cam0` = RGB right
	> (`/flir_cam_right`), `cam1` = RGB left (`/flir_cam_left`), `cam2` = event right (`/event_camera_right`,
	> 640×480), `cam3` = event left (`/event_camera_left`, 640×480). Each entry has pinhole
	> `intrinsics [fx,fy,cx,cy]` + radtan `distortion_coeffs`; each cam after `cam0` carries `T_cn_cnm1`
	> (transform from the previous cam in the chain).
	> - Camera↔IMU (`calibration-camchain-imucam.yaml`, adds `T_img[l/r]_imu`) + the IMU noise model (`calibration-imu.yaml`).
	> - LiDAR↔camera (`lidar_calibration_results.yaml`) and IR intrinsics + extrinsics (`ir_calib_result.json`).
	>
	> The processed h5 renames `cam0`/`cam1` to the `left`/`right` RGB streams above (and `cam2`/`cam3` are the right/left event cameras).

	![Ground-truth modalities: depth · semantic segmentation · odometry · optical flow](assets/gt.png)

	## Ground truth

	- Odometry / ego-motion — [RKO-LIO](https://docs.ros.org/en/jazzy/p/rko_lio/) LiDAR-inertial odometry: SE(3) LiDAR pose in the Map frame with linear/angular velocity. The high-rate `hf_odom/*` is obtained by integrating the IMU between LiDAR keyframes.
	- Depth — sparse metric depth in the rectified left-RGB image (`depth_cm`, uint16 cm,
	`0 = invalid`). Built by accumulating 61 LiDAR scans (≈6 s), removing dynamic objects (YOLO26-medium
	on the nearest RGB frame), keeping the minimum depth per pixel, and then projecting into the camera image.
	- Optical flow — derived, not stored — the ego-motion-induced flow (accumulated points projected into a
	future RGB frame). Regenerate from `depth + poses` with `derive_flow.py`.
	- Semantic segmentation — 19-class Cityscapes pseudo-labels ([EoMT](https://github.com/tue-mps/eomt)), on the 303 daytime sequences
	(`has_seg = true`); night/degraded have no labels.
	- Fused reference trajectory — RKO-LIO odometry + GPS fused in a pose graph, under `fused_traj`
	(`T_world_lidar` (N,4,4) + `t`) in a UTM-relative world frame anchored at the first GPS fix.
	Geo-referencing + fusion quality live as `fused_traj` group attrs (`epsg`/`utm_zone`/`hemisphere`, `origin_{easting,northing,alt}_m`, `lever_xyz_lidar_m`, GPS residual
	RMS + p90, `confidence_tier`). `fused_traj/t` is non-uniformly sampled — poses are emitted at the union of the LiDAR-odom (≈10 Hz) and
	GPS (≈5 Hz) timestamps (≈13 Hz combined), so inter-pose intervals vary (≈0.02–0.1 s).

	## Per-sequence files (`<session>/<bag_id>/`)

	\| file \| contents \|
	\|---\|---\|
	\| `data.h5` \| timestamps, IMU, GPS, CAN, LiDAR (range [deskewed by RKO] / sig / nir / refl), RKO-LIO odom, `fused_traj` (fused GPS+LIO trajectory), `/calib` \|
	\| `events.h5` \| raw async event streams (`ev/left`, `ev/right`) — ≈78% of a sequence's bytes \|
	\| `img_{left,right,infrared}.mp4` \| per-camera H.265 encoded video \|
	\| `rgb_left_rect_depth.h5` \| sparse metric depth in the rectified left-RGB image (`depth_cm`); flow derived via `derive_flow.py` \|
	\| `rgb_left_rect_semantic.h5` \| 19-class Cityscapes pseudo-label seg in the rectified left-RGB image — day sequences only \|
	\| `captions.h5` \| per-window scene captions (Gemma-4-31B VLM) + 4096-d Qwen3-Embedding-8B caption vectors + window metadata \|

	Units/conventions: depth in cm (`0`=invalid); event timestamps in µs; all other h5 time arrays in seconds.

	> Experimental — `car/radar` (Mazda forward radar). Six object tracks decoded from the CAN data
	> with the [opendbc Mazda radar DBC](https://github.com/commaai/opendbc/blob/master/opendbc/dbc/mazda_radar.dbc) (CAN IDs 865–870 = `RADAR_TRACK_361..366`). Layout:
	> `car/radar/track_{1..6}/` with `t` (M,) float64 main-clock seconds, `dist` (M,) uint16, `ang` (M,) int16,
	> `vrel` (M,) int16. Values are stored raw (no scale/offset): `dist`=`DIST_OBJ` (sentinel `4095` = no track),
	> `ang`=`ANG_OBJ` (signed 12-bit), `vrel`=`RELV_OBJ` (signed 11-bit).

	## Data format

	All `/t` arrays are seconds on a common PPS-synced main clock* (Kalman-smoothed); event times are
	µs on that same clock (`t/1e6` → s). Align streams by timestamp — RGB runs
	≈100 Hz vs LiDAR ≈10 Hz. Camera frames are raw (un-rectified): rectify with the per-camera `intrinsics` +
	radtan `dist_coeffs` (stored in the h5 and the camchain); the depth GT is already in the rectified left-RGB frame.

	Main bag h5 (`data.h5`):

	\| key \| shape · dtype \| meaning \|
	\|---\|---\|---\|
	\| `ouster/range_pcl` \| (N,131072,3) int32 \| LiDAR XYZ in mm, 64×2048 destaggered (`[0,0,0]` = no return) \|
	\| `ouster/{sig,nir}_pcl` · `refl_pcl` \| (N,131072) uint16 · uint8 \| per-point signal / near-IR / reflectivity \|
	\| `ouster/odom/map_T_lidart` \| (N,4,4) f64 \| RKO-LIO LiDAR pose in the map frame (translation m) (+ `lin_vel` m/s, `ang_vel` rad/s, `t` s); `hf_odom/*` = high-rate \|
	\| `ouster/{accel,ang_vel}` \| (M,3) f32 \| in-LiDAR IMU (IAM-20680HT); extrinsic to sensor frame = `calib/lidar_T_lidarimu` \|
	\| `img/{left,right}/`, `infrared/` \| — \| `t` (≈100/100/50 Hz) · `intrinsics` (3,3) · `dist_coeffs` (4,) · `resolution` (2,) \|
	\| `vectornav/` \| (K,·) \| `accel` (m/s²), `ang_vel` (rad/s) — each + `_raw` (uncompensated); `magnetic` (Gauss), `pressure` (Pa), `temperature` (°C), `t` (s); 400 Hz \|
	\| `gps/data` \| (G,7) f64 \| `[lat°, lon°, alt_m, cov_xx, cov_yy, cov_zz, fix]`. `fix` = ROS `NavSatStatus.status`: −1 no-fix · 0 standard fix · 1 SBAS · 2 GBAS/RTK. \|
	\| `gps/velocity_enu` · `gps/heading` \| (G,3) · (G,2) f64 \| ENU velocity m/s · `[heading_rad, heading_acc]` \|
	\| `car/` \| (·,2+) f32 \| CAN (col 0 = time, s): `speed` (mph), `wheels` (4× wheel speed, mph), `steer` (deg), `steer_rate` (deg/s), `vcc` = `[acc_x, acc_y]` (≈m/s²), `brake_on` (0/1), `pedal` & `brake_press` (raw counts) + `radar/` (above). Experimental — decoded via a community Mazda DBC; units approximate/unverified. \|
	\| `fused_traj/T_world_lidar` \| (R,4,4) f64 \| fused RKO-LIO+GPS pose, UTM-relative world frame (+ `fused_traj/t`; geo-ref + quality in `fused_traj` attrs: `epsg`/`utm_zone`, `origin_*`, `confidence_tier`, residual RMS/p90) \|
	\| `calib/` \| — \| extrinsics `A_T_B` \|

	Events (`events.h5`) — flat arrays over all events, per side:

	\| key \| dtype \| meaning \|
	\|---\|---\|---\|
	\| `ev/{left,right}/t` \| uint64 \| event time µs (main clock) \|
	\| `ev/{left,right}/{x,y}` \| uint16 \| pixel col / row, raw 640×480 (un-rectified) \|
	\| `ev/{left,right}/p` \| uint8 \| polarity (0/1) \|
	\| `ev/{left,right}/ms_to_idx` \| uint64 \| millisecond → event index \|

	Depth GT (`rgb_left_rect_depth.h5`) — per-LiDAR-scan sparse depth in the rectified left-RGB image.
	`N` = `n_lidar_frames`; frame `k` ↔ LiDAR scan `k`. Carries its own `timestamps`
	(identical to `data.h5` `ouster/t`) and index arrays:

	\| key \| shape · dtype \| meaning \|
	\|---\|---\|---\|
	\| `depth_cm` \| (N,1456,1920) uint16 \| metric depth in cm (`m = depth_cm/100`), `0 = invalid` \|
	\| `timestamps` \| (N,) f64 \| main-clock seconds (= `data.h5` `ouster/t`) \|
	\| `lidar_indices` \| (N,) int64 \| LiDAR-scan index (`0..N−1`) \|
	\| `left_img_indices` \| (N,) int64 \| matching frame in `img_left.mp4`\|
	\| `poses` \| (N,4,4) f32 \| per-scan LiDAR pose used to accumulate the depth (input to `derive_flow.py`) \|
	\| `K_rect` · `R3` \| (3,3) f64 \| rectified left-RGB intrinsics · rectification rotation (`R1`) \|
	\| `imgl_T_ouster` \| (4,4) f64 \| LiDAR → raw (unrectified) left-RGB cam \|
	\| `raw_res` \| (2,) int32 \| source image resolution \|

	Root attrs: `depth_scale_cm`, `flow_{gap,scale,invalid}`, `flow_stored` (=`False` — flow is derived, not stored), `n_scans`.

	Semantic GT (`rgb_left_rect_semantic.h5`, day sequences only) — per-LiDAR-scan 19-class seg in the
	rectified left-RGB image, aligned 1:1 with `rgb_left_rect_depth.h5`:

	\| key \| shape · dtype \| meaning \|
	\|---\|---\|---\|
	\| `semantic` \| (N,1456,1920) uint8 \| Cityscapes class id `0..18` (see `classes` attr); `255` = ignore \|
	\| `lidar_indices` \| (N,) int64 \| LiDAR-scan index for each frame (`0..N−1`) \|
	\| `left_img_indices` \| (N,) int64 \| matching frame in `img_left.mp4` (RGB ≈100 Hz vs LiDAR ≈10 Hz) \|
	\| `timestamps` \| (N,) f64 \| main-clock seconds \|

	Root attrs: `classes` (19 names), `num_classes=19`, `model=EoMT-Cityscapes-DINOv2-L-1024`,
	`coordinate_frame=rectified_left`, `preprocessing=rectify+CLAHE`, `resolution=1920x1456`.
	So `semantic[k]` ↔ `depth_cm[k]` ↔ `img_left.mp4[left_img_indices[k]]` ↔ `ouster/t[k]`.

	Captions & semantic search (`captions.h5`) — each sequence is split into ≈5 s windows (`W` per
	sequence ≈ duration / 5 s); every window gets a natural-language scene caption (a Gemma-4-31B VLM) and a
	4096-d text embedding (Qwen3-Embedding-8B) for free-text retrieval:

	\| key \| shape · dtype \| meaning \|
	\|---\|---\|---\|
	\| `captions` \| (W,) str \| one scene caption per window \|
	\| `embeddings` \| (W,4096) f32 \| Qwen3-Embedding-8B vector for each caption \|
	\| `metadata` \| (W,) struct \| `window_id`, `frame_idx` (→ `img_left.mp4` frame), `timestamp` (main-clock s), `speed_mps`, `turn_deg`, `dist_m`, `is_night` \|

	Root attrs: `caption_model`, `embed_model`, `embed_dim` (4096), `num_windows`, `video_id`.

	## Splits

	`train` = 293 · `test` = 78 (bag-level; preserved across dataset versions). The dataset contains daytime, nighttime, and degraded sequences.

	## `metadata.parquet` fields (27)

	`bag_id, session, start_time, split, is_daytime, degraded, has_seg,
	duration_s, n_lidar_frames, n_rgb_frames, n_imu_samples, n_events_left, n_events_right,
	n_gps_fixes, n_gps_valid, gps_quality, gps_lat_min/max, gps_lon_min/max,
	mean_speed_mph, idle_fraction, distance_m, rgb_cal_id, imu_cal_id, lidar_cal_id, sensor_dropout`

	- `gps_quality` ∈ {`RTK_fixed_cm`, `float_dm`, `single_m`, `no_fix`, `absent`} — 67 / 62 / 239 / 2 / 1 (RTK-fixed ≈1–3 cm, float ≈0.1–0.5 m, single ≈0.5–3 m).
	- `sensor_dropout` — `null`, or `sensor:seconds[;sensor:seconds]`

	## Loading

	```python
	import h5py, hdf5plugin, numpy as np, pyarrow.parquet as pq
	meta = pq.read_table("metadata.parquet").to_pydict() # per-sequence table
	with h5py.File("<session>/<bag_id>/data.h5") as f:
	lidar = f["ouster/range_pcl"][:]; odom = f["ouster/odom/map_T_lidart"][:]

	# RGB / IR frames — native-res H.265 mp4 decoded with torchcodec.
	from torchcodec.decoders import VideoDecoder
	dec = VideoDecoder("<session>/<bag_id>/img_left.mp4") # 1920x1456; len(dec) == n_rgb_frames
	rgb_k = dec[k] # (3, H, W) uint8 tensor at frame k
	# RGB runs ≈100 Hz vs LiDAR ≈10 Hz — align by TIMESTAMP, not shared index:
	with h5py.File("<session>/<bag_id>/data.h5") as f:
	img_t = f["img/left/t"][:]; lid_t = f["ouster/t"][:] # seconds, same main clock
	k = int(np.argmin(np.abs(img_t - lid_t[j]))) # RGB frame nearest LiDAR frame j
	# img_right.mp4 / img_infrared.mp4 decode the same way (IR is grayscale-as-video, ≈50 Hz).

	# Depth + semantic GT — one frame per LiDAR scan, in the rectified left-RGB image:
	with h5py.File("<session>/<bag_id>/rgb_left_rect_depth.h5") as f:
	depth_m = f["depth_cm"][j] / 100.0 # (1456,1920); 0 = invalid (j = LiDAR scan)
	with h5py.File("<session>/<bag_id>/rgb_left_rect_semantic.h5") as f: # day sequences only
	seg = f["semantic"][j] # (1456,1920) uint8, class 0..18
	rgb_idx = f["left_img_indices"][j] # matching img_left.mp4 frame for scan j

	# flow is derived, not stored:
	from derive_flow import derive_flow_from_h5
	flow_uv = derive_flow_from_h5("<session>/<bag_id>/rgb_left_rect_depth.h5", frame_idx, poses=odom)
	```

	## Statistics

	371 sequences · 59 hrs · 2,474 km · 8.43 TB · 303 day / 68 night · 4 degraded · segmentation on 303 · GPS: 67 RTK / 62 float / 239 single / 2 no-fix / 1 absent.

	## Notes/Known limitations

	- Optical flow is derived solely from ego-motion — rigid camera-motion reprojection of LiDAR depth; it does not
	capture independent motion of dynamic objects.
	- Seg is day-only (303 sequences); night/degraded have no segmentation labels.
	- IMU compensated vs raw. VectorNav factory-calibrates each unit (bias/scale/axis-misalignment + temperature applied). In this dataset `accel` ≡ `accel_raw` (bit-identical); `ang_vel` additionally has the on-board EKF's real-time gyro-bias estimate removed.
	- 5 sequences have a >10 s sensor dropout (see `sensor_dropout`): 3 with the event camera off early
	(20–43 s), 1 GPS+CAN, 1 CAN. 3 sequences have no usable GPS (`no_fix`/`absent`), and 5 sequences have no `fused_traj` (GPS too sparse / low-quality for the pose-graph fusion).
	- IR & GPS are PPS-synced indirectly, through the IMU PPS-system clock calibration.
	- IR calibration is best-effort. The infrared intrinsics/extrinsics were calibrated from existing data without a heated target board. They are estimated from the markerboard's 4 corners alone, then manually refined. Treat the IR calibration as approximate.
	- LiDAR clock is PPS-stepped, not Kalman-aligned. Unlike the other streams, the Ouster clock is not
	actively Kalman-smoothed onto the main clock; its internal clock only advances its whole-second
	counter when the PPS edge arrives.
	- IMU is noisy from vehicle vibration. Both IMUs pick up road and engine vibration; the sensors are
	soft-mounted to dampen it, but residual vibration noise remains in the accelerometer / gyro signals.
	- IR frame rate occasionally dips below 50 Hz. The infrared camera is not run as a composable node, so
	under load it sometimes falls below its nominal 50 Hz capture rate (gaps visible in `infrared/t`).
	- RKO-LIO cold-start transient. The estimator's initial phase can occasionally be jerky — at the start of a
	sequence the LIO briefly reports ≈zero motion, then "catches up" with a jump once it converges →
	jerky roll/pitch (occasionally z) over the first few meters of motion (upstream RKO-LIO issue #139).
	- LiDAR deskew is a constant-motion approximation. Each ~100 ms sweep is
	[motion-compensated by RKO-LIO](https://github.com/PRBonn/rko_lio/blob/a67dd406caaa8229d3ff858f2f38519eb8097831/rko_lio/core/lio.cpp#L437)
	using the average body acceleration `a` and average angular velocity `ω` over the sweep — a point at offset
	`dt` from the scan reference time is warped by `exp([ v·dt + ½·a·dt², ω·dt ])` (constant-acceleration
	translation + constant-angular-velocity rotation). Because `a`/`ω` are held constant across the sweep,
	rapid intra-sweep motion (high jerk, sharp turns, potholes) leaves some residual skew; `a` is
	Kalman-filtered + jerk-bounded to limit this but cannot fully remove it.
	- LiDAR noise can leak into the depth GT. The depth ground truth is projected directly from the raw
	Ouster returns, so sensor noise (stray or spurious returns from rain, snow, fog, dust, retroreflectors
	(see [LiDAR ghosts & blooming](https://www.teachkidsrobotics.com/blog/what-are-lidar-ghosts-and-blooming/)),
	or specular/multi-path reflections) can survive into our depth ground truth as a small number of
	erroneous points.
	- Platform Bounce. On a few sequences the SeaSuckers loosened, resulting in vertical motion (bounce) of the platform.

	We have taken great care to perform data quality checks on this data. That said, some issues at this scale may slip through, so should you find any examples of gross desynchronization, please report them and we can take a look.

	## Citation
	```bibtex
	@misc{bisulco2026octosense,
	title = {{OctoSense}: Self-Supervised Learning for Multimodal Robot Perception},
	author = {Bisulco, Anthony and Wang, Jeremy and Daniilidis, Kostas and Balestriero, Randall and Chaudhari, Pratik},
	year = {2026},
	howpublished = {Preprint},
	}
	```

	## License

	Released under the MIT License — free to use, modify, and redistribute with attribution; provided "as is" without warranty. If you use OctoSense, please cite the paper (see Citation above).