Spatiotemporal Filling and Multistep Smoothing for satellite time series reconstruction
Project description
🌿 STMS: Spatiotemporal and Multistep Smoothing for Time-Series Reconstruction
STMS is a Python package for reconstructing and smoothing cloud-affected or noisy time-series data, particularly from satellite-derived vegetation indices (VI) such as NDVI, EVI, MSAVI, NIRv, and other time-series environmental indicators
Although originally designed for Sentinel-2 data, STMS is data-agnostic and works with any temporal signal measured at geolocated sampling units.
✨ What STMS Does
STMS performs two complementary steps:
1️⃣ Spatiotemporal Filling
Reconstructs missing or low-quality values by:
- Detecting consecutive unreliable observations
- Searching for spatially nearby or structurally similar time series
- Selecting candidates based on correlation, distance, and/or grouping (nested IDs)
- Predicting values through polynomial regression and weighted aggregation
2️⃣ Multistep Smoothing
Applies iterative smoothing with increasing quality thresholds to:
- Smooth noisy observations
- Preserve phenological or seasonal shapes
- Adaptively reweight low-confidence points
- Produce a final smooth, continuous time-series signal
STMS is suitable for:
- Consecutive cloud or incomplete satellite vegetation indices
- Remote sensing environmental monitoring
- Agricultural time-series
- Ecological and climate data
- Any geotemporal dataset with consecutive missing or noisy values
📦 Installation
From PyPI:
pip install stms
⚙️ Basic Usage
from stms import stms
model = stms()
vi_filled = model.spatiotemporal_filling(
id_sample=id_array,
days_data=day_of_year,
vi_data=vi_raw,
long_data=longitude,
lati_data=latitude,
cloud_data=cloudscore
)
vi_smoothed = model.multistep_smoothing(
id_sample=id_array,
days_data=day_of_year,
vi_data=vi_filled,
cloud_data=cloudscore
)
Required Inputs
| Name | Description |
|---|---|
id_sample |
ID for each time-series (one ID per pixel/plot/station) |
days_data |
Time axis as day-of-year or numeric timestamp |
vi_data |
Raw VI values (cloudy allowed) |
long_data, lati_data |
Spatial coordinates (used for candidate search) |
cloud_data |
CloudScore+ or quality weights |
🔧 Parameter Overview
You can customize the STMS behavior when constructing the model:
model = stms(
n_consecutive=5,
threshold_cloudy=0.1,
threshold_corr=0.9,
n_candidate=10,
n_tail=24,
id_nested=None,
n_candidate_nested=None,
max_candidate_pool=None,
candidate_sampling="distance"
)
| Parameter | Description |
|---|---|
n_consecutive |
Minimum consecutive low-quality points considered a gap |
n_tail |
Padding before/after a gap |
threshold_cloudy |
Quality threshold to classify an observation as “cloudy” |
threshold_corr |
Minimum correlation required to accept a candidate |
n_candidate |
Maximum global number of candidate series used |
id_nested |
Optional grouping (e.g., pixel → field, station → region) |
n_candidate_nested |
Limit candidates per group |
max_candidate_pool |
Maximum groups selected |
candidate_sampling |
"distance" or "random" group sampling |
🧪 Example with Simulated Data
import numpy as np
from stms import stms
# simulate VI curve
def sine_curve(t):
return 0.3*np.sin(2*np.pi/100 * (t - 90)) + 0.5
x = np.arange(0, 365, 5)
vi = sine_curve(x) + np.random.normal(0, 0.02, len(x))
cloud = np.ones_like(vi)
# introduce synthetic cloud contamination
cloud[40:55] = 0.01
vi[40:55] = np.random.uniform(0.05, 0.1, 15)
model = stms()
vi_filled = model.spatiotemporal_filling(
id_sample=np.array(["A"]*len(x)),
days_data=x,
vi_data=vi,
long_data=np.repeat(110.0, len(x)),
lati_data=np.repeat(-7.0, len(x)),
cloud_data=cloud
)
vi_smooth = model.multistep_smoothing(
id_sample=np.array(["A"]*len(x)),
days_data=x,
vi_data=vi_filled,
cloud_data=cloud
)
📚 Citation
If STMS contributes to your research, please cite:
Suseno, B., Brunel, G., Wijayanto, H., Sadik, K., Afendi, F. M., & Tisseyre, B. (2025). Reconstructing satellite temporal series data under cloudy conditions: Application in predicting rice growth phases. Smart Agricultural Technology, 12, 101378. https://doi.org/10.1016/j.atech.2025.101378
📄 License
MIT License © Bayu Suseno
🤝 Contributing
Pull requests, bug reports, and feature suggestions are welcome! Please open an issue if you encounter any problem.
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