Apan, Armando; ... - Formulation and assessment of ...

Basic information

Author	Apan, Armando; Held, Alex; Phinn, Stuart; Markley, John
Title	Formulation and assessment of narrow-band vegetation indices from EO-1 hyperion imagery for discriminating sugarcane disease
Journal	2003 Spatial Sciences Institute Conference: Spatial Knowledge Without Boundaries (SSC2003)
DOI
Link	http://eprints.usq.edu.au/8061/
Date/Year	2003
Location	Canberra, Australia
Publisher	Spatial Sciences Institute
Volume
Issue
Pages	1-13
Keywords	hyperspectral remote sensing, spectral vegetation indices, sugarcane disease, Hyperion
Comment

Indices

Nr.	Name	General Formula
1	Average reflectance 750 to 850	$Averagereflectancebetween750nmand850nm$
2	Disease-Water Stress Index 5	$\frac{800nm - 550nm}{1660nm + 680nm}$
3	Modified Chlorophyll Absorption in Reflectance Index	$((700nm - 670nm) - 0.2 (700nm - 550nm)) (\frac{700nm}{670nm})$
4	Modified Normalised Difference 750/705	$\frac{750nm - 705nm}{750nm + 705nm - 2 445nm}$
5	Modified Simple Ratio 705/445	$\frac{750nm - 445nm}{705nm - 445nm}$
6	Normalized Difference 1070/1200	$\frac{1070nm - 1200nm}{1070nm + 1200nm}$
7	Normalized Difference 750/660	$\frac{750nm?660nm}{750nm + 660nm}$
8	Normalized Difference 750/705	$\frac{750nm - 705nm}{750nm + 705nm}$
9	Normalized Difference 800/680	$\frac{800nm - 680nm}{800nm + 680nm}$
10	Normalized Difference 860/1240	$\frac{860nm - 1240nm}{860nm + 1240nm}$
11	Optimized Soil Adjusted Vegetation Index	$(1 + Y) \frac{800nm - 670nm}{800nm + 670nm + Y}$
12	Plant Senescence Reflectance Index	$\frac{678nm - 500nm}{750nm}$
13	Ratio of WI and Normalised Difference 750/660	$\frac{\frac{900nm}{970nm}}{\frac{750nm?705nm}{750nm + 705nm}}$
14	Simple Ratio 1600/820	$\frac{1600nm}{820nm}$
15	Simple Ratio 1660/550	$\frac{1660nm}{550nm}$
16	Simple Ratio 1660/680	$\frac{1660nm}{680nm}$
17	Simple Ratio 550/680	$\frac{550nm}{680nm}$
18	Simple Ratio 695/420	$\frac{695nm}{420nm}$
19	Simple Ratio 695/760	$\frac{695nm}{760nm}$
20	Simple Ratio 750/550	$\frac{750nm}{550nm}$
21	Simple Ratio 750/705	$\frac{750nm}{705nm}$
22	Simple Ratio 800/1660	$\frac{800nm}{1660nm}$
23	Simple Ratio 800/550	$\frac{800nm}{550nm}$
24	Simple Ratio 800/635	$\frac{800nm}{635nm}$
25	Simple Ratio 800/680	$\frac{800nm}{680nm}$
26	Simple Ratio 970/900	$\frac{970nm}{900nm}$
27	Structure Intensive Pigment Index 1	$\frac{800nm - 445nm}{800nm - 680nm}$
28	TCARI/OSAVI	$\frac{3 (700nm - 670nm) - 0.2 (700nm - 550nm) \frac{700nm}{670nm}}{(1 + 0.16) \frac{800nm - 670nm}{800nm + 670nm + 0.16}}$
29	Transformed Chlorophyll Absorbtion Ratio	$3 ((700nm - 670nm) - 0.2 (700nm - 550nm) (\frac{700nm}{670nm}))$

Sensors

Nr.	Name	Spectral Range	Bands	Calculated	Comment
1	Hyperion	349.896-2582.28	242

Applications

Nr.	Name	Comment
1	Hyperspectral remote sensing
2	Vegetation

List of References