Specim Hyperspectral Vision Systems
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What is hyerspectral imaging?
Hyperspectral imaging reveals the invisible and generates an in-depth
understanding of phenomena and objects studied.
The human eye, like a normal colour camera, acquires light in three bands,
red, green and blue. Spectral imaging divides the spectrum into many more
bands where hyperspectral sensors look at objects using a vast portion
of the electromagnetic specrtum. The term "hyper" in a hyperspectral
camera means "over" as in very many and this type of camera
provides ample spectral information to identify and distinguigh spectrally-unique
materials.
A hyperspectral camera captures the object or scene line-by-line and
this line is split into its spectral components before reaching the sensor.
In general, hyperspectral sensors measure bands at 10 ot 20 nm intervals.
The resultant image consists of dozens to hundreds of narrow, adjacent
and data-rich spectral bands, every pixel of which can then be used to
characterise the objects under review with great precision and detail.
Consequently, hyperspectral imaging leads to a greatly improved ability
to classify the objects based on their spectral signatures as well as
enabling proccess control capabilities beyond what has been traditionally
possible.
Applications for hyperspectral imaging
Hyperspectral cameras are designed for applications that require a high
resolution and distortion-free image on the detector and this type of
capture is valuable in applications where there is a need to distinguish
between spectrally similar materials. Uses for hyperspectral cameras include:
• Monitoring crop vigor and
disease treatment |
• Land cover classification
and fire management |
• Environmental impact of disasters |
• High speed drill core analysis |
• Colour-quality control in textile manufacturing |
• Separating crime scene details |
• Mineral mapping |
• Species detection |
• National intelligence |
• Chemical imaging |
• Scientific research |
• Material classification |
Hyperspectral
systems |
Model |
Spectral
Range |
Spectral
resolution |
Spatial
pixels/line |
Pixel
size on sample |
Maximum sample size |
SisuCHEMA - chemical
imaging |
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Chemical imaging is one of
the most powerful non-destructive technologies, enabling advanced
machine vision solutions for production, recycling, and quality control.
Hyperspectral imaging provides consistent and reliable methods for
all colour management applications with absolute precision. |
SisuCHEMA VNIR |
400 - 1 000 nm |
2.8 nm |
1312 |
38 - 152 µm |
200 x 300 x 45 mm (WxLxT) |
SisuCHEMA NIR |
900 - 1 700 nm |
6 nm |
320 |
Scalable from 30 to 600 microns |
SisuCHEMA SWIR |
1 000 - 2 500 nm |
10 nm |
320 |
Scalable from 30 to 600 microns |
Model |
Spectral
Range |
Spectral
resolution |
Spatial
pixels/line |
Pixel
size on sample |
Maximum sample size |
SisuRock - core imaging |
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Geological samples, such as
drill cores, can rapidly be mapped for nearly all minerals of commercial
interest with hyperspectral imaging. sisuROCK generates an image where
each pixel contains a full spectrum, unique to each mineral of interest.
High speed, automated computer algorithms identify the minerals and
convert the data into mineral maps of the samples depictured. |
SisuRock
- SWIR |
970 – 2 500 nm |
10 nm |
320 |
HR*: 0.2 mm; HS: 2.0
mm |
1 500 x 640 x 200 mm (L x W x H), 50 kg |
SisuRock - VNIR |
400 - 1 000 nm |
2.8 nm |
1 000 |
HR*: 0.09 mm; HS:
0.64 mm |
SisuRock - RGB |
N/A |
N/A |
4 000 |
HR*: 0.016 mm; HS:
0.16 mm |
* HR - High Resolution
mode for single core measurement. HS - High Speed mode for single
core box measurement. |
Model |
Spectral
Range |
Spectral
sampling |
Spectral
bands |
Pixel
size on target |
Maximum sample size |
SisuSCS - Single core
scanner |
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SCS is developed for high
resolution measurements of drill core type samples like lake sediment
cores or oil sands. This unit is ideal when annual core production
is lower than in traditional mining and exploration. |
SisuSCS-
SWIR |
1000 - 2500 nm |
6.3 nm / pixel |
256 |
0.16 - 0.38 mm (320 pixels) |
130 x 1 500 x 75 mm (L x W x H) |
SisuSCS-
VNIR |
400 - 1000 nm |
0.78 - 6.27 nm / pixel |
96 - 768 (adjustable by binning) |
0.04 - 0.09 mm (1 312 pixels) |
130 x 1 500 x 75 mm (L x W x H) |
Model |
Spectral
Range |
Spectral
resolution |
Sensor |
Frame
rate per second |
Number of spectral bands |
Aisa Series - Airborne |
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AISA systems are ruggedised
spectral imaging solutions dedicated to airborne and defence usage,
covering VNIR (380-1 000 nm,), SWIR (1 000-2 500 nm) and thermal LWIR
(7.6 – 12.4 um) spectral ranges. The combination of the reliability
and performance with least size and weight have made AISA sensors
the tools of choice for demanding remote sensing applications. SPECIM
provides complete systems ready to be installed and operated onboard
all types of fixed- or rotary wing as well as manned or unmanned airborne
platforms. |
AisaEAGLET |
400-1000 nm |
3.3 nm |
Progressive CCD |
up to 125 |
410; 205; 102 depending on binning |
AisaEAGLE |
400-970 nm |
3.3 nm |
Progressive CCD |
up to 160 |
488, 244, 122, 60 depending on binning |
AisaHAWK |
970 - 2500 nm |
12 nm |
MCT |
Up to 100 |
254 |
AisaDUAL |
Total 400-2500 nm |
VNIR - 3.3 nm; SWIR 12 nm |
VNIR - CCD; SWIR - MCT |
up to 100 |
VNIR - 244, 122, 60. SWIR - 254, 227, 63 |
AisaFENIX |
VNIR: 380 - 970 nm
SWIR: 970 - 2 500 nm |
VNIR: 3.5 nm
SWIR: 10 nm |
VNIR: CMOS
SWIR: Stirling-cooled MCT |
Up to 130 |
VNIR: 344, 172, 86
SWIR: 275 |
AisaOWL |
7.6 - 12.5 µm |
100 nm (diffraction limited) |
Stirling-cooled MCT |
up to 100 |
100 |
Accessories
for Aisa series |
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