Datasets:

neurips2026citympc
/

CityMPC

CityMPC is a large-scale synthetic dataset of multi-path wireless channels for 5 US cities (Austin TX, New York NY, Dallas TX, Fort Worth TX, Denver CO), generated via Sionna RT ray tracing on DeepMIMO v4 building geometries at 3.5 GHz.

Each sample pairs:

A full multi-path channel description — up to 25 paths per link with complex gains, delays, and angles of departure/arrival.
An environment-aware POV rendering of the propagation scene — RGB image, depth map, surface normals, RF material maps (per-channel permittivity, conductivity, roughness, scattering), and global building height map.

The dataset is intended for training and evaluating environment-aware channel-prediction models that replace ray tracing at inference time. It accompanies a NeurIPS 2026 Evaluations & Datasets Track submission. The full code release is at the citympc repository (link withheld for double-blind).

What's in this release (~700 GB)

Tier	Cities	Per-city contents	Total
Sionna scenes (all 20 DeepMIMO US cities)	20 cities	`<city>.tar.gz` (scene.xml + meshes/*.ply)	244 KB
Mini bundle (all 5)	Austin, NY, Dallas, Fort Worth, Denver	`train_2000.{npz,pt}`, `val_500.{npz,pt}`, `test_500.{npz,pt}`, `norm_stats.json`	~23 GB
Full bundle (all 5)	Austin, NY, Dallas, Fort Worth, Denver	`train.h5`, `val.h5`, `test.h5`, `train.npz`, `val.npz`, `test.npz`	~680 GB

Per-city full sizes: Austin ~127 GB, NY ~101 GB, Dallas ~156 GB, Fort Worth ~134 GB, Denver ~162 GB.

Sample for reviewers (small subset, ~4.6 GB)

Per NeurIPS Datasets-track guidance, large datasets should provide a smaller sample. The per-city mini bundle is exactly that: 2000 training links + 500 validation + 500 test, baked as PyTorch tensors with normalisation statistics — same schema as the full data, ~3,000× smaller per city.

# Smallest single download — Austin mini bundle, ~4.6 GB:
hf download neurips2026citympc/CityMPC \
  --repo-type dataset \
  --include "manifests/city_10_austin_3p5_s/{train_2000,val_500,test_500}.* manifests/city_10_austin_3p5_s/norm_stats.json" \
  --local-dir .

How the sample was created: deterministic seed-42 random subset of links from the filtered training/validation/test splits (size N=2000/500/500), then the same bake_dataset.py pipeline used for the full splits stacks normalised tensors into .pt files with the identical schema as train.h5 / val.h5 / test.h5. The same procedure is available for all 5 cities.

Quick start (full dataset)

pip install huggingface_hub
hf download neurips2026citympc/CityMPC --repo-type dataset --include "manifests/city_10_austin_3p5_s/*" --local-dir .

For a one-line download + verify experience, use the citympc scripts/download_hf.py helper (see the citympc repo).

Croissant metadata

A valid Croissant 1.1 metadata file is at the dataset repo root: croissant.json. It contains all FileObject SHA-256 hashes, the RecordSet schema (channel sample fields + norm-stats fields), Responsible AI properties, and provenance. Validated against mlcroissant (0 errors, 0 warnings).

Data schema

Each HDF5 file (train.h5, val.h5, test.h5) and each baked tensor file (*_2000.pt, *_500.pt) shares the same record schema. One record = one TX-RX link. Field shapes use N for the number of links in a split and 25 for the maximum number of multi-path components.

Field	Shape	Description
`excess_delay`	`(N, 25)`	Excess delay (seconds) of each path relative to first arrival τ₀. Zero-padded for inactive paths.
`path_presence`	`(N, 25)`	Binary indicator of active paths (0.0 or 1.0).
`path_coeff`	`(N, 25, 2)`	Complex path coefficient (real, imag) per path.
`path_dirs`	`(N, 25, 6)`	Departure + arrival 3D unit direction vectors `[AoD_x, AoD_y, AoD_z, AoA_x, AoA_y, AoA_z]`.
`path_loss_db`	`(N,)`	Total received path loss (dB) aggregated over all active paths.
`first_arrival`	`(N,)`	Absolute propagation delay (seconds) of the first-arriving path.
`rx_pov`	`(N, 12, 128, 128)`	Receiver POV image stack: RGB (3) + depth (1) + normals XYZ (3) + RF material props (5). Float32.
`tx_pov`	`(N, 12, 128, 128)`	Transmitter POV image stack — same 12-channel layout as `rx_pov`.
`global_map`	`(N, 1, 128, 128)`	Global building height map centred on the TX-RX midpoint.
`scalars`	`(N, 6)`	TX + RX 3D world coordinates `[tx_x, tx_y, tx_z, rx_x, rx_y, rx_z]` in metres.

norm_stats.json (per city) contains:

Key	Description
`first_arrival.mean_log_ns`	Mean of `log(first_arrival × 1e9)` across training-split links.
`first_arrival.std_log_ns`	Std of `log(first_arrival × 1e9)` across training-split links.
`path_loss_db.mean`	Mean of `path_loss_db` across training-split links.
`path_loss_db.std`	Std of `path_loss_db` across training-split links.
`n_links_valid`, `n_links_total`	Link counts.

Provenance

Geometry source: DeepMIMO v4 — building footprints (OpenStreetMap-derived) and TX/RX user grids for 20 US city scenarios at 3.5 GHz.
Ray tracing: Sionna RT — full TX-RX path enumeration with up to 25 paths per link, complex coefficients, delays, AoD/AoA, computed for all link pairs.
POV rendering: Mitsuba 3 — 12-channel image stacks rendered from both TX and RX viewpoints, plus a global height map per link.
Filtering & splits: link-level power filter + path-level prune + L_max truncation; 80/10/10 train/val/test split via deterministic seed; norm_stats.json recomputed on the filtered training set.
Full pipeline reproducibility: see PIPELINE.md in the citympc code release.

Responsible AI

Synthetic data

This dataset is fully synthetic. It contains only ray-traced wireless channel parameters and 3D environment renderings derived from publicly available building geometry models. No personal or sensitive information is present.

Limitations

Frequency: 3.5 GHz only. Results may not generalise to mmWave (28+ GHz), sub-GHz, or other bands without retraining.
Geography: 5 US cities. Other cities, non-US urban layouts, and rural/suburban environments are out of distribution.
Static environments: No dynamic objects (vehicles, pedestrians, foliage), no weather, no atmospheric effects.
Geometry fidelity: DeepMIMO v4 building footprints are extruded uniformly from OpenStreetMap data and may not match real building heights or shapes.
Source code: The generation pipeline is open-source; see the citympc repository for full reproducibility.

Biases

All cities are mid-to-large US urban centres with dense building layouts; receiver placements follow DeepMIMO v4 user grids and may oversample regular street patterns.
Material RF properties are assigned from a fixed per-material lookup; no spatial variation within a material class.

Intended uses

Training and benchmarking ML models for environment-aware multi-path channel prediction.
Channel charting, site-specific radio resource management, digital-twin radio simulation.
Evaluation of generative models that consume image/geometric scene representations.

Out-of-scope uses

Operational deployment of trained models without site-specific validation.
Generalisation claims beyond the cities, frequency, and conditions covered.

Social impact

Open release of the dataset and the generation toolchain reduces reliance on proprietary or computationally expensive ray tracers in 5G/6G research, and supports reproducibility in environment-aware wireless communications.

File integrity (SHA-256)

File	SHA-256
`manifests/city_10_austin_3p5_s/train.h5`	`89830838f697674d993390862e8ae99adf1ebc16de0a6db9ded898ae9b32245c`
`manifests/city_10_austin_3p5_s/val.h5`	`2a89a446355cebb5a347891a5a69b2cd8a67455e09c0efa53020638d9ef7ae60`
`manifests/city_10_austin_3p5_s/test.h5`	`551cffd696a7a259ac1f9b318479880f886b08722c8fcca535e1ec39d050dda6`
`manifests/city_10_austin_3p5_s/norm_stats.json`	`5a9f73b8692464b75f6fb54a228fb7fb51c58e837be0a7c4e01608c03ed8b8e1`
`manifests/city_10_austin_3p5_s/train_2000.pt`	`3c996049dc3ca61c90c20f72366f18ad1fbceca1b5717b754558f0af9af6dd45`
`manifests/city_0_newyork_3p5_s/train.h5`	`89d34d6d70b16eb226e5b0e7a0bc459115d03eb45112e246e742a957664f7035`
`manifests/city_0_newyork_3p5_s/val.h5`	`a75efb4d9e9c2a162750c6b35f6848639c8b4e1a33ff9bff3683d4ff5646d567`
`manifests/city_0_newyork_3p5_s/test.h5`	`00872e53d95895dba15dacfb6a675046db3b84166ee3a0c516eb668ac881fafe`
`manifests/city_0_newyork_3p5_s/norm_stats.json`	`f74a82ca84aa3cd5577bcb0f29f37c386268c787d7c3201e4e09b8154ea4a1b6`
`manifests/city_0_newyork_3p5_s/train_2000.pt`	`028e16a072ba6fe9589ce43ae8b02a4d084e3e125ab9371c6e9ef22dc2b8c7a6`
`manifests/city_8_dallas_3p5_s/train.h5`	`ec9ff0c5df4feb3549bff3ef6341a1949363c40ce624976d9b272db73db71ef5`
`manifests/city_8_dallas_3p5_s/val.h5`	`6981d2b15bb71a2ee8f74f11210f8d891efed1b177c2922c54d267fd9a0d4bad`
`manifests/city_8_dallas_3p5_s/test.h5`	`9876d5b8a65ee42f99b084a44f22f4e3be5be5aee6a4742c9783b144437daa33`
`manifests/city_8_dallas_3p5_s/norm_stats.json`	`f4bf3a71288e74d364f463ee85ef0377bd43b8faccfcf5b7fbda5afcc5fc7294`
`manifests/city_8_dallas_3p5_s/train_2000.pt`	`670b0266756b308e56991bb54f9581adbef7fec51525b74217fd0d4b4c7638ca`
`manifests/city_12_fortworth_3p5_s/train.h5`	`d7b0a591f60f10b0000a45c8d18320b78d0d8264cdb9d03401bfcab1288aaae4`
`manifests/city_12_fortworth_3p5_s/val.h5`	`d13e41ae0fe852e58a01f692c55b7c6a89e8143d82430a84c89b83657c9d4623`
`manifests/city_12_fortworth_3p5_s/test.h5`	`cde6c439f7ec918d8fa77ce524e8d096737b5b5824bcceb851919e1522ac5681`
`manifests/city_12_fortworth_3p5_s/norm_stats.json`	`d400be7f4fcc59cda63b0eafe88bd3330a8a3866c19a9ac6ae59c86c97fb3ef5`
`manifests/city_12_fortworth_3p5_s/train_2000.pt`	`ce7a01b737021521f215162d904cae70c6079b3951bbbf3bbffcdbb52e4fba7d`
`manifests/city_18_denver_3p5_s/train.h5`	`0de729b9165b97f67835c04745b5e604d495fcd3c1c3fa27e8203460905e58cd`
`manifests/city_18_denver_3p5_s/val.h5`	`d3eb526e35fe4c57eace7d4f8628c496f87ce7f8ae17f83d625458fb80daa8ca`
`manifests/city_18_denver_3p5_s/test.h5`	`e4cdd747079b0027bb44533395881fa3f931fa14182f0fe12e4567f95d925c2f`
`manifests/city_18_denver_3p5_s/norm_stats.json`	`6d9fd65de6bccb346b29204726392fd710276a6a2e763245c4c80794eb96cd7d`
`manifests/city_18_denver_3p5_s/train_2000.pt`	`a08371d2ccc1d8cc5a5494880bcb388db155ff7c5bf589fd163e74e94363325c`

Citation

@inproceedings{citympc2026,
  title     = {CityMPC: Environment-Aware Multi-Path Channel Prediction via Conditional Generation},
  booktitle = {Advances in Neural Information Processing Systems (NeurIPS)},
  year      = {2026},
  note      = {Evaluations \& Datasets Track}
}

License

Apache 2.0.

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