Pete Watt & Nelson Gapare: Indufor Asia Pacific

pete.watt@indufor-ap.com

nelson.gapare@indufor-ap.com

Forest Resource Assessment

Reducing the cost and effort using remote sensing

Looking back

10-15 years ago remote sensing and GIS were treated as specialist stand alone

tools only used for specific tasks. Today, you simply can’t do that, the

boundaries between spatial analytics and decision making are too intertwined to

look at these tools separately.

And now..

From land use, land cover, change detection/monitoring, to compliance

assessment, valuation and due diligence, remote sensing/geospatial technology

are fundamental. More so, the cost of data has dropped significantly while the

resolution has improved to sub-meter levels.

The increasing demand for historical data to set baselines and reference levels

– yes, think REDD+, ETSs, VCS and so on means we do need to smarten up in

pre-processing, classification. That’s just what we have been doing with the

likes of RapidEye, SPOT5, Landsat to name a few. Have a look at some of the

work we have been doing.

….remote sensing and GIS as business as usual services

Resource Monitoring & Strategic Planning

• Strategic planning & project screening

• Resource Due Diligence

• Long-term tracking and monitoring of plantation performance

• Resource Monitoring, wood theft, fire, wind damage & disease

• Compliance monitoring (FSC)

• Resource Classification

• National-level & VCS mapping for climate change

• LiDAR Applications

Selected Applications

What are the challenges?

• Illegal activities can be sporadic and varying

• Activities can be located in isolated areas

• Compliance monitoring can be difficult

• Resource classification can be complicated

• Shortage of human capacity for ground monitoring

and assessment

• Costs of monitoring and enforcement can be high

• Strategic planning can be difficult without

reasonable ground intelligence

Multi-faceted challenges – e.g. regulatory compliance

Remote sensing – a multi -faceted solution

• Remote sensing eliminates key challenges such as

• Isolation of locations and accessibility

• Identification of temporal changes

• Detection of unsanctioned activities

• Cost

2010 Reference

2011 Normalised

2011 Uncorrected

What are the costs?

Imagery Costs

• Imagery from the archive 0.95

euro/km2 or EUR 950 for 100,000

ha (approx USD1300)

• Tasking images – new collections

minimum 20% cloud cover is 0.95

euro/km2 but order area is 250,000

ha. (approx. 3100 USD)

Indufor’s Detection Cost and

Reporting Solution

Indufor has developed routines that

allow detection and mapping of forest

change i.e. roads or clearance (at 0.5

ha scale).

If suitable imagery are available this

service is priced at about USD30 to 40

cents/ha based on a minimum coverage

area of 100,000 ha.

Detected Encroachment

For example…..Monitoring Compliance?

Location: South America

Application:

Monitoring of harvesting

and roading operation in

forest concessions

Solution:

5 m satellite imagery used

to automatically detect &

record harvesting and

roading areas.

Further examples - Mining Operations

Location: South America

Application:

Detection of mining

encroachment in forest

Concessions

Solution:

5 m satellite imagery used

to automatically detect &

record mining areas.

And you can link the log….to a location

Selective harvest monitoring

A tool for rapid intelligence gathering

Fire detection - China

Mapping non-sanctioned logging- Brazil

Disease detection - Australia

Resources Identification and Verification

Location: Global

Application:

Area verification is an integral part of the

valuation and the due diligence process.

Solution:

Indufor routinely use satellite images and

other spatial datasets to verify the extent

and status of resources.

The process applied uses in-house

routines that assess the quality of the

resource and area.

Pine

Detection of Harvesting using Satellite Imagery

Location: China, 2012

Species : Eucalyptus

Application:

Due to airborne data collection restrictions no

information is available to update the progress of

harvesting or land clearance operations

Solution:

Cost-effective 5 m satellite imagery used to

automatically detect harvested and cleared

areas. These outputs are provided in a GIS

format and allow the calculation and tracking of

harvesting

Satellite Image

GIS output

On-going Detection of Harvesting Operations

Location: Australia

Species : Pine

Application:

Due to the cost of aerial

image collection only

infrequent information is

available to update the

progress of harvesting

and thinning operations

Solution:

Cost-effective 5 m

satellite imagery used to

automatically detect &

record harvest areas.

Forest Carbon Projects

Location: Papua New Guinea & Laos, 2012

Application:

Establishment of forest reference levels and

reference carbon emissions levels, and

projection of future land use change for

Voluntary Carbon Markets (VCS Standard)

Solution:

• Using satellite imagery to determine historical

land use and land cover change

• Projecting future deforestation by modelling

relationships between historical trends and

drivers of deforestation

Satellite imagery

2006 Satellite imagery

2010

2009

2059

2019

Projected forest cover loss (purple)

Mapping Plantation Performance

Location: New Zealand

Species : Pine

Application:

Monitoring plantation

status by detecting

gaps, areas of poor

growth or incorrectly

attributed areas in the

GIS.

Solution:

Using satellite imagery a

prediction model is

applied that colour

codes anomalies to

allow targeted

intervention 5 m Satellite image Variation Map (green ok – red issues)

Science References

• Watt, P.J., & Watt M.S., Meredith A.W, 2011. Forest planning applications using RapidEye satellite data. New Zealand

Journal of Forestry

• Watt, P.J., & Watt M.S (2011). Applying satellite imagery for forest planning. New Zealand Journal of Forestry (56) 1

• Watt, P.J. 2005. An evaluation of LiDAR and optical satellite data for the measurement of structural attributes in British

upland conifer plantation forestry. Doctoral thesis. Department of Geography, University of Durham, England

• Watt, P.J. & Watt M.S 2012 (in review) Development of a national model of tree volume from LiDAR metrics for New

Zealand. International Journal of Remote Sensing

• Donoghue, D.N.M., Watt, P.J., Cox, N.J., Dunford, R.W., Wilson, J., Stables, S. and Smith, S. 2004. An evaluation of the

use of satellite data for monitoring early development of young Sitka spruce plantation forest growth, Forestry, 77, 383-396.

• Donoghue, D.N.M., Watt, P.J., Cox, N.J, Wilson, J. 2007 .Remote sensing of species mixtures in conifer plantations using

LiDAR height and intensity data. Remote Sensing of Environment.

• Donoghue, D.N.M. & Watt, P.J. 2006. Using LiDAR to compare forest height estimates from IKONOS and Landsat ETM+

data in Sitka spruce plantation forests, International Journal Of Remote Sensing 27 (11): 2161-2175.

• Dymond, J.R. , Gapare, N., Burgess, D.W., Shepherd, J.D., Newsome, P.F., Watt, P.J. (2012). Environmental Science &

Policy (16)1-8. Remote sensing of land-use change for Kyoto Protocol reporting: the New Zealand Case

Resource Mapping

Indufor Asia Pacific Ltd

Auckland City

New Zealand

www.indufor-ap.com

Indufor OY

Helsinki

Finland

www.indufor.fi