FEM TIPS F - PowerPoint PPT Presentation

1 / 32

About This Presentation

Title:

FEM TIPS F

Description:

2111 2005 NORWEGIAN UNIVERSITY OF LIFE SCIENCES Department of Ecology and Natural Resource Management www.umb.no REDD in Tanzania NORWEGIAN UNIVERSITY OF LIFE ... – PowerPoint PPT presentation

Number of Views:117

Avg rating:3.0/5.0

Slides: 33

Provided by: jus99

Category:

more less

Transcript and Presenter's Notes

Title: FEM TIPS F

1
(No Transcript)
2
Climate change mitigation related to Tanzanian
forests Key factors for analysis and research
prioritizing
Ole Hofstad
3
Organisation of the presentation

Mitigating climate change through REDD
Monitoring
Carbon accounting
PES mechanisms
Land-use change modelling
Policy measures within the forest sector
Other policies

4
Carbon stocks
5
GHG emissions
6
The importance of degradation
7
Monitoring forest ecosystems

area and density
technologies
sampling
accuracy
frequency
costs

8
The monitoring problem may be considered as two
separate components

estimating areas of different vegetation types
(e.g. forest, woodland, savannah, cropland,
etc.), and
estimating the average biomass density (tons/ha)
in each vegetation type.

Cropland and burned bush in Northern
Mozambique (Photo E. H. Hansen)
9
Area estimates

Areas may be measured on the ground, either by
triangulation using surveying equipment, or GPS.
These methods are both time consuming and
expensive and best suited for small areas with
very high precision requirements.
Areas may be measured on aerial photographs. This
is expensive if aerial photography is ordered for
this particular use alone.
Areas may be measured on satellite images based
on reflected sunlight. Classification of
vegetation types may be assisted by competent
personnel, or be made unassisted by computer.
Using satellite images is the preferred method in
most modern applications for large areas of low
unit value.

10
(No Transcript)
11
Biomass measurements

Biomass density may be measured on temporary or
permanent sample plots in the field. Trees (and
bushes) are measured in various ways, e.g. stem
diameter, height, crown diameter, etc. These
measurements are transformed by allometric
functions into estimates of volume or weight of
individual trees or bushes.
Biomass density may be estimated on the basis of
crown cover measured on aerial photos.
Biomass estimates may be based on data collected
by the use of light emitted from an airborne or
satellite laser, or
from an airborne or satellite radar.

The three latter methods (photo, laser, radar)
require some sample plots on the ground where
trees are measured manually. Such data is
necessary in order to calibrate the remote
sensing data.
12
Combining area estimates with estiamated biomass
density
13
Air-borne laser
14
Remote sensing of biomass density in forests
Points of reflection distributed in space
15
Sampling

Stratified sampling
Sampling percentage
Permanent plots
Temporary plots

Stratification
Forest types rain forest (flooded or not),
montane forest, seasonal green forest, open
forest, shrub, savanna, etc., cropland, grazing
land
Agro-ecological zones, regions, districts
Biomass density
The smaller the reporting unit, the larger
sampling percentage is required to give precise
estimates

16
Proposed laser project

1. If FRA2010/NFI decides to measure ground plots
either from FRA2010 tiles or along the lines
formed by FRA2010 tiles (see map), we should
consider offering to fly LiDAR along these lines
of FRA2010 tiles in all, or parts of, Tanzania.
If we fly all over Tanzania, it will imply flying
a total distance of ca 9000 stripe-km, which will
give a systematic sample of laser data for all of
Tanzania. Calibrated with field data from below
the flight corridors, one would be able to give a
national biomass estimate for the whole of
Tanzania in less than one year (given that field
data are measured during the same period). We may
even be able to break the estimate down into
regional partial estimates.
2. In addition we should select one of the three
"ecosystems" as an object for detailed studies,
where we either fly wall-to-wall with LiDAR or
fly stripes very close (as proposed in Brazil) in
an area of 5-10,000 km2. In this area we must
establish a set of separate sample plots on the
ground. Observations from these plots will be
used to calibrate LiDAR measurements of biomass.
This set of data will serve two purposes
2a GEO/FCT sites
2b detailed studies of design of laser-mapping
of biomass through sampling
2c ground validation of SAR-study. If we
choose tropical rain forest as a case, this will
be complementary to Brazil since we may find
higher biomass density than in Amazonia.

17
Precision
Relationship between accuracy (Sm) and number of
plots (n) according to different patterns of
spatial variation Sm Standard error CV
Coefficient of variation

For the REDD-activities in Tanzania, where a lot
of different inventories will be performed, it
will be of crucial importance to gain basic
knowledge on patterns of spatial variation for
biomass ha-1 (or volume or basal area ha-1) under
different forest conditions and plot designs. A
research project to approach these challenges
could be performed along the following lines
Systematic review of previously performed
inventories with respect to spatial variation
Undertake inventories in selected study areas
covering important vegetation types and inventory
designs
Perform theoretical inventory simulations in
order to select optimal inventory strategies
under different conditions and requirements

18
Frequency

How often will new area estimates be presented?
How often shall biomass estimates be updated?
Rotation on permanent sample plots
Repeated flights airplane or satellite (with
camera, laser, or radar)
Higher frequency, higher costs

19
CARBON IN FOREST

IPCC Guidelines
Three hierarchical tiers of methods that range
from
default data
simple equations
to the use of country-specific data and models to
accommodate national circumstances.
It is good practice to use methods that provide
the highest levels of certainty, while using
available resources as efficiently as possible.
Combination of tiers can be used.

Living biomass
Trees, bushes, herbs and grass
Above ground
Roots
Ded wood
Logging residues
Ded branches, roots and more
Soil

20
LIVING BIOMASS

Biomass expansion factor (BEF/BF)
E.g. IPCC default value 0.44 tons Dry Matter /
m3 fresh volume
Biomass equation
Allometric functions for whole trees or fractions
like stem, branches and roots.
E.g. Biomass above ground
B 0.3623 dbh1.382 h0.64
B - 4.22412 0.56 dbh2
Field measurements and laboratory measurement of
wood density are required.

21
Land-use changes to achieve REDD
22
Leakage
23
Global trade in forest products
Main trade flows of tropical roundwood 2007.
(million m3) Buongiorno, J., D. Tomberlin, J.
Turner, D. Zhang, S. Zhu 2003. The Global Forest
Products Model Structure, Estimation, and
Applications.
24
Source Jayant Sathaye, Lawrence Berkeley
National Laboratory, California
25
(No Transcript)
26
(No Transcript)
27
Land-use model
28
Land-use models at village or watershed level

Namaalwa, J., P. L. Sankhayan O. Hofstad 2007.
A dynamic bio-economic model for analyzing
deforestation and degradation An application to
woodlands in Uganda. Forest Policy and Economics,
9 (5)479-95.
Sankhayan, P. L., M. Gera O. Hofstad. 2007.
Analysis of vegetative degradation at a village
level in the Indian Himalayan state of Uttarkhand
a systems approach by using dynamic linear
programming bio-economic model. Int. J. Ecology
and Environmental Sciences 33(2-3) 183-95.
Hofstad, O. 2005. Review of biomass and volume
functions for individual trees and shrubs in
southeast Africa. J. Tropical Forest Science,
17(1)413-8.
Namaalwa, J., W. Gombya-Ssembajjwe O. Hofstad
2001. The profitability of deforestation of
private forests in Uganda. International Forestry
Review 3 299-306.
Sankhayan, P. L. O. Hofstad 2001. A
village-level economic model of land clearing,
grazing, and wood harvesting for sub-Saharan
Africa with a case study in southern Senegal.
Ecological Economics 38 423-40.
Hofstad, O. P. L. Sankhayan 1999. Prices of
charcoal at various distances from Kampala and
Dar es Salaam 1994 - 1999. Southern African
Forestry Journal, 18615-18.
Hofstad, O. 1997. Woodland deforestation by
charcoal supply to Dar es Salaam. J.of
Environmental Economics and Management, 3317-32.

29
Tanzanian land-use and forest sector trade models

Kaoneka, A.R.S. 1993. Land use Planning and
quantitative modelling in Tanzania with
particular reference to agriculture and
deforestation some theoretical aspects and a
case study from the West Usambara mountains.
Dr.Scient. Thesis, Agriculture University of
Norway, Aas.
Monela, G. S. 1995. Tropical rainforest
deforestation, biodiversity benefits and
sustainable land use Analytical of economic and
ecological aspects related to the Nguru
Mountains, Tanzania. Dr. Scient. Thesis,
Department of Forestry, Agricultural University
of Norway.
Ngaga, Y.M. 1998 Analysis of production and trade
in forestry products of Tanzania. Dr.Scient.
Thesis, Agriculture University of Norway, Aas.
Makundi, W. R. 2001. Potential and Cost of Carbon
Sequestration in the Tanzanian Forest Sector.
Mitigation and Adaptation Strategies for Global
Change, 6(3-4)335-53.
Ngaga, Y. M. B. Solberg 2007. Assessing the
Suitability of Partial Equilibrium Modelling in
Analyzing the Forest Sector of Developing
Countries Methodological Aspects with Reference
to Tanzania. Tanzania Journal of Forestry and
Nature Conservation, 7611-27.
Monela, G. C. J. M. Abdallah 2007. External
policy impacts on Miombo forest development in
Tanzania. In Dubé, Y. C. F. Schmithüsen
(eds.) Cross-sectoral policy developments in
forestry.
Monela, G. C. B. Solberg 2008. Deforestation
and agricultural expansion in Mhonda area,
Tanzania. In Palo, M. H. Vanhanen (eds.)
World forests from deforestation to transition?