TCARI/OSAVI705 — TCARI/OSAVI 705,750 | Spectral Index Calculator

3 * (750nm - 705nm) - 0.2 * (750nm - 550nm) * (750nm / 705nm) / ((1 + 0.16) * (750nm - 705nm) / (750nm + 705nm + 0.16))

Bands: 550, 705, 750
Range: -1 to 1
Typical: Most vegetation 0.2 to 0.8

Used in crop monitoring.

When to use

Time-series monitoring of crop health, growth stages, and stress detection
Land cover classification and vegetation type discrimination
Biomass estimation and net primary productivity studies
Drought impact assessment over agricultural and forest areas
Phenology tracking — green-up, peak season, and senescence
robust leaf chlorophyll estimation
vegetation health monitoring

Limitations

Saturates in dense canopies (LAI > 3) — values plateau and lose discrimination ability
Sensitive to atmospheric scattering, especially blue-band haze
Soil background contaminates measurements in sparsely vegetated areas
Sun-sensor geometry (BRDF effects) introduces variability across acquisitions
Cloud cover and shadows produce invalid pixels that need masking

What the values mean

-1 Water / Snow

-0.1 Bare ground / Built-up

0.1 Sparse / Stressed

0.3 Moderate vegetation

0.5 Healthy vegetation

0.7 Dense canopy

Surface type	Typical TCARI/OSAVI705
Open water, snow	-0.3 to -0.1
Bare soil, urban	-0.1 to 0.2
Sparse or stressed crops	0.2 to 0.4
Healthy crops, grassland	0.4 to 0.7
Dense forest, peak season	0.7 to 0.9

General Formula

550 550

705 705

750 750

Sensor-Specific Formulas

Most-used sensors — click to show code below

Sensor	Provider	Formula	Band Mapping
Dragonette-1	Wyvern	`3 * (Band 20 - Band 16) - 0.2 * (Band 20 - Band 5) * (Band 20 / Band 16) / ((1 + 0.16) * (Band 20 - Band 16) / (Band 20 + Band 16 + 0.16))`	550→Band 5, 705→Band 16, 750→Band 20
Sentinel-2	ESA	`3 * (B6 - B5) - 0.2 * (B6 - B3) * (B6 / B5) / ((1 + 0.16) * (B6 - B5) / (B6 + B5 + 0.16))`	550→B3, 705→B5, 750→B6

Spectral Band Visualization — Dragonette-1

Code Examples

Adapted for Dragonette-1 bands —

tcari_osavi705_dragonette-001.py

Frequently Asked Questions

What is the TCARI/OSAVI705 (TCARI/OSAVI 705,750) and when should I use it?

TCARI/OSAVI 705,750 is a modified version of the TCARI/OSAVI index that uses the red-edge bands at 705nm and 750nm instead of traditional red and NIR bands. This modification improves sensitivity to chlorophyll content estimation while reducing the influence of leaf area index and soil background. Vegetation indices quantify plant health, biomass, and photosynthetic activity by exploiting the contrast between how plants absorb visible light for photosynthesis and reflect near-infrared radiation from their cellular structure. TCARI/OSAVI705 is particularly suited for robust leaf chlorophyll estimation, vegetation health monitoring, precision agriculture. The general formula is 3 * (750nm - 705nm) - 0.2 * (750nm - 550nm) * (750nm / 705nm) / ((1 + 0.16) * (750nm - 705nm) / (750nm + 705nm + 0.16)), which requires 550 and 705 and 750 spectral bands.

Which satellite sensors can I use to calculate TCARI/OSAVI705?

TCARI/OSAVI705 is supported by 4 satellite sensors in our database, including Dragonette-1, Dragonette-2/3, GeoEye-1, Sentinel-2. Each sensor uses different band designations — for example, Dragonette-1 uses the formula 3 * (Band 20 - Band 16) - 0.2 * (Band 20 - Band 5) * (Band 20 / Band 16) / ((1 + 0.16) * (Band 20 - Band 16) / (Band 20 + Band 16 + 0.16)), while Dragonette-2/3 uses 3 * (Band24 - Band20) - 0.2 * (Band24 - Band9) * (Band24 / Band20) / ((1 + 0.16) * (Band24 - Band20) / (Band24 + Band20 + 0.16)). Select a sensor above to see its specific band mapping.

What spectral bands does TCARI/OSAVI705 require and why?

TCARI/OSAVI705 requires 550 (550), 705 (705), 750 (750). Vegetation strongly absorbs red light for photosynthesis while reflecting near-infrared light from its mesophyll cell structure, making this contrast a reliable indicator of plant vigour.

How do I calculate TCARI/OSAVI705 in Python or R?

Both Python and R code samples are provided above. In Python, use rasterio to load individual band GeoTIFF files and numpy for the arithmetic. In R, the terra package handles raster operations efficiently. The key is to load bands as floating-point arrays to avoid integer division, and to handle division-by-zero cases where the denominator equals zero. For production use, consider applying a valid data mask to exclude no-data pixels before calculation.

How does TCARI/OSAVI705 compare to NDVI and other vegetation indices?

While NDVI is the most common vegetation index, TCARI/OSAVI705 provides complementary information that NDVI cannot capture on its own. The choice of index depends on your application, sensor availability, and atmospheric conditions.

TCARI/OSAVI705 vs other vegetation indices

Index	Name	How it differs
ARI	Anthocyanin Reflectance Index	Alternative vegetation index — different band combination
mARI	Modified Anthocyanin Reflectance Index	Refined formulation for specific conditions
ARVI	Atmospherically Resistant Vegetation Index	Atmospherically corrected version
ARVI2	Atmospherically Resistant Vegetation Index 2	Atmospherically corrected version

Related Vegetation Indices

References

Main et al. (2011) - An investigation into robust spectral indices for leaf chlorophyll estimation

Wu et al. (2008) - Estimating chlorophyll content from hyperspectral vegetation indices

Need help choosing?

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