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REDD+ readiness: early insights on monitoring, reporting and verification systems of project
developers
View the table of contents for this issue, or go to the journal homepage for more
2013 Environ. Res. Lett. 8 034038
(http://iopscience.iop.org/1748-9326/8/3/034038)
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IOP PUBLISHING ENVIRONMENTAL RESEARCH LETTERS
Environ. Res. Lett. 8 (2013) 034038 (15pp) doi:10.1088/1748-9326/8/3/034038
REDD+ readiness: early insights onmonitoring, reporting and verificationsystems of project developers
Shijo Joseph1, Martin Herold2, William D Sunderlin1 andLouis V Verchot1
1 Center for International Forestry Research, Jalan CIFOR, Bogor 16115, Indonesia2 Center for Geoinformation, Department of Environmental Science, Wageningen University,The Netherlands
E-mail: [email protected] and [email protected]
Received 23 March 2013Accepted for publication 17 September 2013Published 30 September 2013Online at stacks.iop.org/ERL/8/034038
AbstractA functional measuring, monitoring, reporting and verification (MRV) system is essential toassess the additionality and impact on forest carbon in REDD+ (reducing emissions fromdeforestation and degradation) projects. This study assesses the MRV capacity and readinessof project developers at 20 REDD+ projects in Brazil, Peru, Cameroon, Tanzania, Indonesiaand Vietnam, using a questionnaire survey and field visits. Nineteen performance criteria with76 indicators were formulated in three categories, and capacity was measured with respect toeach category. Of the 20 projects, 11 were found to have very high or high overall MRVcapacity and readiness. At the regional level, capacity and readiness tended to be highest in theprojects in Brazil and Peru and somewhat lower in Cameroon, Tanzania, Indonesia andVietnam. Although the MRV capacities of half the projects are high, there are capacitydeficiencies in other projects that are a source of concern. These are not only due to limitationsin technical expertise, but can also be attributed to the slowness of internationalREDD+ policy formulation and the unclear path of development of the forest carbon market.Based on the study results, priorities for MRV development and increased investment inreadiness are proposed.
Keywords: deforestation, carbon pool, climate change mitigation, remote sensing, REDD+
1. Introduction
Reducing emissions from deforestation and degradation andenhancing the carbon stock (REDD+) is a key strategy formitigating climate change. The United Nations FrameworkConvention on Climate Change (UNFCCC) takes a leadrole in formulating the strategy through consultation witha range of agencies including other international bodies,
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national and subnational governments, non-governmentalorganizations and the private sector. Formulated at the 13thConference of the Parties (COPs), known as the Bali ActionPlan, REDD+ comprises local, subnational, national andglobal actions whose primary aim is to reduce emissionsfrom deforestation and forest degradation and enhance forestcarbon stocks (increase removals) in developing countries(UNFCCC 2007, Angelsen et al 2012). UNFCCC (2011) hascalled for a three-phase approach to REDD+ implementationwhere ‘Phase 1 is the REDD+ readiness to establishREDD+ strategies, policies and accounting frameworks;Phase 2 is implementation of REDD+ policies and measures,and possibly payments based on their implementation; and
11748-9326/13/034038+15$33.00 c© 2013 IOP Publishing Ltd Printed in the UK
Environ. Res. Lett. 8 (2013) 034038 S Joseph et al
Phase 3 is the results-based payments for REDD+ (i.e. foremissions and removals)’.
REDD+ adopts several funding streams and models forits implementation that operate simultaneously at variouslevels (van der Eynden 2012, Lotsch 2012). The firstmodel involves developed countries contributing to theGreen Climate Fund or Forest Carbon Partnership Facility(FCPF), which are administered by the UNFCCC and theWorld Bank, respectively. These funds are allocated tonational governments, which administer and distribute themto subnational governments and individual REDD+ projects.A second model involves international aid agencies support-ing national governments and individual REDD+ projectsthrough bilateral agreements. For example, Norway supportsthe Brazilian and Indonesian governments in the implemen-tation of REDD+, and also independent REDD+ projectsin Tanzania. A third model involves development of thevoluntary carbon market (which could be later changed intoa compliance market) for selling carbon credits generatedby the REDD+ projects. This funding stream is exclusivelyfor the REDD+ projects and therefore needs to follow strictguidelines issued by the certifiers such as the verified carbonstandard (VCS) and Plan Vivo.
As of 2009, about 100 local REDD+ projects hadbeen initiated in 40 developing countries (Cerbu et al 2011,Obersteiner et al 2009). A 2012 count of both REDD+ andnon-REDD+ forest carbon projects found 340 sites in52 countries (Kshatriya et al 2012). Unlike many otherconservation initiatives, the key goal of REDD+ projects is toimplement performance-based rewards for increase of forestcarbon stocks (additionality) against a baseline, while alsoachieving social and environmental co-benefits. REDD+ aimsto ensure that activities to generate additionality in oneplace should not cause emissions in neighbouring areas(leakage), and should also satisfy permanence criteria (i.e., noreversibility of sequestered carbon).
The economic and political dimensions of REDD+ andits performance-based criteria require highly precise mea-suring/monitoring, reporting and verification (MRV) ofemissions and removals from forests (Herold and Skutsch2011). Establishing an effective MRV system is a majorstep towards REDD+ readiness. UNFCCC has called forthe development of ‘modalities for measuring, reporting andverifying anthropogenic forest-related emissions by sourcesand removals by sinks, forest carbon stocks, and forestcarbon stock and forest-area changes resulting from theimplementation of the activities’ (UNFCCC 2011). Keyadditional references refer to activity data and emissionfactors as the essential building blocks of an MRV system(IPCC 2003, 2006, Shoch et al 2011, GOFC-GOLD 2012).Activity data reflect the extent of the area in which carbonchanges occur over time, while emission factors reflect theamount of carbon per unit area. The Intergovernmental Panelon Climate Change (IPCC) proposed a tiered approach formeasurements: Tier 1, the simplest to use, is based on globallyavailable activity data and default emissions values, Tier 2is based on country- or region-specific data, and Tier 3 useshigher-order, spatially explicit data to obtain greater certainty(IPCC 2006).
Several studies have analysed MRV systems at thenational scale using data from the Food and AgricultureOrganization’s Forest Resources Assessment, national com-munications to UNFCCC and other online compilations toreview existing capacity and identify gap areas (Herold 2009,Romijn et al 2012, Hosonuma et al 2012). A number ofconcept papers on MRV requirements at different scaleshave primarily looked at data availability (Gibbs et al 2007,Joseph et al 2011, Goetz and Dubayah 2011, De Sy et al2012) and the associated cost (Bottcher et al 2009). Fry(2011), Larrazabal et al (2012) and Pratihast et al (2013)highlighted the need to develop community MRV protocolsto maximize community participation and reduce costs. Noneof the above publications focused on MRV systems perse or the operational design of MRV systems required forREDD+ projects. The only exception to this trend wasbaseline modelling and monitoring readiness with respect tointernationally recognized carbon certification standards andmethods (Estrada and Joseph 2012).
2. Data and methods
2.1. Data
Assessing MRV capacity and readiness at project sitesrequires a complete understanding of project developers’MRV systems, the drivers of deforestation at the sites, andthe planned mitigation activity. After careful examination ofthe national context and subnational initiatives (for the fullselection criteria, see Sunderlin et al 2010, pp 17–20), 20REDD+ project developers were selected for this assessment:seven in Latin America (five in Brazil and two in Peru),seven in Africa (five in Tanzania and two in Cameroon)and six in Southeast Asia (five in Indonesia and one inVietnam). Table 1 summarizes key project characteristics, andfigure 1 shows their geographical distribution. The projectdevelopers have varied characteristics ranging from local andnational NGOs (e.g.: MCDI—Tanzania, CED—Cameroon,IPAM—Brazil), international conservation organizations (FFIand TNC), government organizations (States of Acre—Braziland Aceh—Indonesia), and private organizations (MazarsStarling Resources—Indonesia and Bosques Amazonicos—Peru). One key criterion for the selection of these projects inour sample was that they have sufficient funding to operate forseveral years. This was important because we are conducting alongitudinal survey, and we need to be assured we can collecta second round of data.
The assessment was carried out from October 2011 toSeptember 2012. The first step was to carry out an MRVquestionnaire survey to assess the status and progress ofMRV systems of the principal project developers. The surveywas divided into three sections, namely: remote sensingand GIS; ground measurements; and reference level andmonitoring plans. The survey was done by communicatingdirectly with the key MRV expert in the respective projectdevelopment organizations. Furthermore, a field-based surveywas conducted at each project site that collected informationon the overall condition of the project area, the drivers of
2
Environ. Res. Lett. 8 (2013) 034038 S Joseph et alTa
ble
1.D
etai
lsof
part
icip
atin
gR
ED
D+
proj
ects
ites
and
proj
ectd
evel
oper
s.
Cou
ntry
Stat
e/pr
ovin
cePr
ojec
tnam
ePr
inci
palp
roje
ctde
velo
per
Maj
orde
fore
stat
ion
and
degr
adat
ion
driv
ers
Miti
gatio
nac
tivity
plan
neda
12
34
5
Bra
zil
Mat
oG
ross
oN
orth
wes
tMat
oG
ross
oPi
lotR
ED
D+
Proj
ect
Inst
ituto
Cen
tro
deV
ida
(IC
V)
Cat
tlera
nchi
ngan
dbe
efpr
oduc
tion,
subs
iste
nce
farm
ing,
illeg
allo
ggin
g
YY
YY
N
Para
Avo
ided
defo
rest
atio
nin
smal
lrur
alpr
oper
ties
inth
ere
gion
ofth
eT
rans
amaz
onH
ighw
ay
Am
azon
Env
iron
men
tal
Res
earc
hIn
stitu
te(I
PAM
)C
attle
ranc
hing
and
beef
prod
uctio
n,su
bsis
tenc
efa
rmin
g,ill
egal
logg
ing
YY
YY
Y
Para
RE
DD+
Pilo
tPro
gram
inSa
oFe
lixdo
Xin
guT
heN
atur
eC
onse
rvan
cy(T
NC
)B
razi
lC
attle
ranc
hing
and
beef
prod
uctio
n,su
bsis
tenc
efa
rmin
g,ill
egal
logg
ing
YY
YY
N
Am
azon
asB
losa
Flor
esta
Prog
ram
Fund
acao
Am
azon
asSu
sten
tave
l(FA
S)Il
lega
llog
ging
,min
ing,
infr
astr
uctu
rede
velo
pmen
t,su
bsis
tenc
efa
rmin
g
YY
YY
N
Am
apa
Bio
fılic
aIn
vest
imen
tos
Am
bien
tais
and
Fund
acao
Ors
a,A
map
a
Bio
filic
aSu
bsis
tenc
efa
rmin
g,ill
egal
logg
ing,
infr
astr
uctu
rede
velo
pmen
t
YY
YY
N
Peru
Mad
rede
Dio
sB
razi
lNut
Con
cess
ions
RE
DD+
Proj
ect
Bos
ques
Am
azon
icos
(BA
M)
Cat
tlera
nchi
ngan
dbe
efpr
oduc
tion,
subs
iste
nce
farm
ing,
min
ing,
illeg
allo
ggin
g
YY
YY
N
San
Mar
tinA
ltoM
ayo
RE
DD+
Initi
ativ
eC
onse
rvat
ion
Inte
rnat
iona
lC
omm
erci
alpl
anta
tions
(cof
fee)
,cat
tlera
nchi
ngan
dbe
efpr
oduc
tion,
subs
iste
nce
farm
ing
YN
NN
N
Cam
eroo
nSo
uth
and
east
regi
onPa
ymen
tfor
Eco
syst
emSe
rvic
es(P
ES)
proj
ect
Cen
tre
pour
l’E
nvir
onne
men
tetl
eD
evel
oppe
men
t(C
ED
)
Subs
iste
nce
farm
ing,
logg
ing,
extr
actio
nof
non-
timbe
rfo
rest
prod
ucts
YY
YY
Y
Sout
hw
estr
egio
nM
t.C
amer
oon
RE
DD
Proj
ect
GFA
-Env
est
Com
mer
cial
plan
tatio
ns(o
ilpa
lm,r
ubbe
ran
dte
a),
subs
iste
nce
farm
ing,
illeg
allo
ggin
g
YY
YY
N
Tanz
ania
Shin
yang
aC
omm
unity
Bas
edR
ED
DM
echa
nism
sfo
rSu
stai
nabl
eFo
rest
Man
agem
enti
nSe
mi-
Ari
dA
reas
Tanz
ania
Tra
ditio
nal
Ene
rgy
Dev
elop
men
tand
Env
iron
men
tal
Org
aniz
atio
n(T
aTE
DO
)
Subs
iste
nce
farm
ing,
fuel
woo
dan
dch
arco
alpr
oduc
tion,
over
graz
ing
YY
YY
N
Mor
ogor
oM
akin
gR
ED
Dw
ork
for
Com
mun
ities
and
Fore
stC
onse
rvat
ion
inTa
nzan
ia–K
ilosa
Tanz
ania
Fore
stC
onse
rvat
ion
Gro
up(T
FCG
)
Subs
iste
nce
farm
ing,
fuel
woo
dan
dch
arco
alpr
oduc
tion,
fire
YY
YY
N
3
Environ. Res. Lett. 8 (2013) 034038 S Joseph et al
Tabl
e1.
(Con
tinue
d.)
Cou
ntry
Stat
e/pr
ovin
cePr
ojec
tnam
ePr
inci
palp
roje
ctde
velo
per
Maj
orde
fore
stat
ion
and
degr
adat
ion
driv
ers
Miti
gatio
nac
tivity
plan
neda
12
34
5
Lin
diM
akin
gR
ED
Dw
ork
for
Com
mun
ities
and
Fore
stC
onse
rvat
ion
inTa
nzan
ia–L
indi
Tanz
ania
Fore
stC
onse
rvat
ion
Gro
up(T
FCG
)
Subs
iste
nce
farm
ing,
fuel
woo
dan
dch
arco
alpr
oduc
tion,
fire
YY
YY
N
Ung
uja/
Zan
ziba
rH
IMA
—Pi
lotin
gR
ED
Din
Zan
ziba
rth
roug
hC
omm
unity
Fore
stM
anag
emen
t
CA
RE
Inte
rnat
iona
lin
Tanz
ania
Fuel
woo
dan
dch
arco
alpr
oduc
tion,
subs
iste
nce
farm
ing,
infr
astr
uctu
rede
velo
pmen
t
YY
NN
N
Lin
diM
ping
oC
onse
rvat
ion
Proj
ect
Mpi
ngo
Con
serv
atio
nan
dD
evel
opm
entI
nitia
tive
(MC
DI)
Fire
,sub
sist
ence
farm
ing,
fuel
woo
dan
dch
arco
alpr
oduc
tion
YY
NN
N
Indo
nesi
aA
ceh
Red
ucin
gC
arbo
nE
mis
sion
sfr
omD
efor
esta
tion
inth
eU
luM
asen
Eco
syst
em
Gov
ernm
ento
fA
ceh
(Tas
kFo
rce
RE
DD
Ace
h)Su
bsis
tenc
efa
rmin
g,lo
ggin
gY
YY
YN
Wes
tKal
iman
tan
RE
DD
Pilo
tPro
ject
Dev
elop
men
t,C
omm
unity
Car
bon
Pool
s
Faun
aan
dFl
ora
Inte
rnat
iona
lInd
ones
ia(F
FI-I
ndon
esia
)
Com
mer
cial
plan
tatio
ns(o
ilpa
lm),
subs
iste
nce
farm
ing,
illeg
allo
ggin
g,m
inin
g
YY
YY
Y
Cen
tral
Kal
iman
tan
The
Rim
baR
aya
Bio
dive
rsity
Res
erve
Proj
ect
Infin
iteE
arth
PT.R
imba
Ray
aC
onse
rvat
ion
Com
mer
cial
plan
tatio
ns(o
ilpa
lm),
subs
iste
nce
farm
ing,
illeg
allo
ggin
g,pe
atfir
es
YN
NN
N
Cen
tral
Kal
iman
tan
Kat
inga
nC
onse
rvat
ion
Are
a:A
Glo
balP
eatla
ndC
apst
one
Proj
ect
Star
ling
Res
ourc
es/P
T.R
imba
Mak
mur
Uta
ma
(RM
U)
Ille
gall
oggi
ng,c
omm
erci
alpl
anta
tions
(oil
palm
and
rubb
er)
YN
NN
N
Eas
tKal
iman
tan
Ber
auFo
rest
Car
bon
Prog
ram
The
Nat
ure
Con
serv
ancy
(TN
C)
Com
mer
cial
plan
tatio
ns(o
ilpa
lm),
logg
ing,
subs
iste
nce
farm
ing,
min
ing
YN
NN
N
Vie
tnam
Lam
Don
gSN
VSi
te,C
atT
ien
The
Net
herl
ands
Dev
elop
men
tOrg
aniz
atio
n(S
NV
)
Subs
iste
nce
farm
ing,
logg
ing,
infr
astr
uctu
rede
velo
pmen
t
YY
YY
N
aM
itiga
tion
activ
ities
:1=
redu
cing
emis
sion
sfr
omde
fore
stat
ion,
2=
redu
cing
emis
sion
sfr
omfo
rest
degr
adat
ion,
3=
cons
erva
tion
offo
rest
carb
onst
ocks
,4=
sust
aina
ble
man
agem
ent
offo
rest
s,5=
enha
ncem
ento
ffo
rest
carb
onst
ocks
.
4
Environ. Res. Lett. 8 (2013) 034038 S Joseph et al
Figure 1. Location of participating project sites.
deforestation and degradation, and the context of REDD+ atthe project site. Subsequently, three regional workshops werecarried out to discuss the operationalization of MRV atthe project sites (a workshop was held in Dar es Salaam,Tanzania, for the Tanzania and Cameroon project developers;in Petropolis, Brazil, for the Brazil and Peru projectdevelopers; and in Jakarta, Indonesia, for the Indonesia andVietnam project developers). About 20–25 people attendedeach workshop, including one to two participants from eachproject development organization, and also international MRVexperts.
2.2. Methods
Three broad categories were developed to assess the capacityand readiness of the project developers. Each category wasdivided into three subcategories, and criteria were formulatedto measure each after careful examination of the internationalstandards of carbon certification (such as VCS and Plan Vivo),IPCC and UNFCCC guidelines, and other reference guidessuch as GOFC-GOLD REDD Sourcebook (GOFC-GOLD2012).
(1) Remote sensing and GIS capacity and readiness—thisincludes data coverage at the project sites and the capacityof the developer to produce derivatives from the rawimage data. It is important because the spatial datainfrastructure and availability of remote sensing dataare fundamental to producing estimates of the baseline,and to developing meaningful monitoring plans forlong-term performance assessment of REDD+ projects.This category was subdivided into three subcategories:data, tools and methods, and implementation capacity.Data criteria were availability of medium- and high-resolution datasets; access to other higher-end monitoring
tools such as LiDAR, aerial, SAR and hyperspectraldatasets; and availability of ancillary spatial data layers atdifferent jurisdictional scales. Tools and methods criteriawere availability of data processing software, and thealgorithms used for image classification and changedetection. Implementation capacity indicates the projectdevelopers’ in-house expertise to analyse data.
(2) Carbon pool inventorying capacity and readiness—thisanalyses developers’ plans to measure various carbonpools with respect to IPCC tiers (IPCC 2006), andthe availability of existing emission factor data at theproject sites. The same three subcategories were used.Data criteria were the availability of allometric equations,carbon fraction coefficients and other emission factordatasets. Tools and methods criteria were the samplingscheme and the methods used for the measurement ofvarious carbon pools with respect to IPCC’s AFOLU(agriculture, forestry and other land use) guidelines.Implementation capacity was defined as the professionalexpertise available within the organization to carry outfield inventorying.
(3) Baseline, intervention and monitoring readiness—thiscategory assesses developers’ ability to understandthe drivers of deforestation and incorporate them inbaseline modelling, develop effective intervention plans,and develop monitoring strategies. The criteria weremethods used for baseline modelling, understanding ofthe proximate and underlying drivers of deforestation,intervention plans, and long-term monitoring strategies toevaluate the success of REDD+ interventions.
Figure 2 summarizes the three main categories and theirsubdivisions.
Performance indicators were assigned to each criterion,and an indicator value and score were given to each
5
Environ. Res. Lett. 8 (2013) 034038 S Joseph et al
Figure 2. Categories used to assess monitoring, reporting and verification readiness.
indicator. For example, the first criterion, availability ofmedium-resolution remote sensing data, was divided intofour performance indicators. If 100% spatial data coveragewas available for more than three points in time (which isimportant for reliable estimation of the deforestation rate andlinear projection of the baseline), that indicator received thehighest score, 3. A score of 2 was awarded for 100% datacoverage in two to three time points, and 1 for those with onetime point.
Similar guidelines were formulated for each indicator,and scores were assigned (see table 2). A total of 19 criteriawith 76 performance indicators under nine subcategories wereassessed. Each subcategory received a score of 0–3, for 9possible points in each major category and 27 possible pointsoverall. Capacity was assessed as very high for a score greaterthan 20, high for a score of 16–20, medium for 11–15, and lowfor 10 or less. This arbitrary scale was defined after analysingthe relative distribution of scores and the performance ofdeveloper organizations with respect to individual criteria.
Further analyses were carried out to check whether theslowness in readiness could be attributed to limitations in thepersonnel expertise and technical capacity available with theproject developer organizations. Firstly, the scores of in-housecapacity (a measure of expertise) for remote sensing and GISwork was compared with the scores of in-house capacity forthe field inventorying (i.e., remote sensing and GIS in-houseexpertise versus carbon pool inventorying in-house expertise)across projects. Second comparison was carried out with theaggregated scores for remote sensing and GIS with respect toaggregated scores for baseline, intervention and monitoring.The former comparison intend for attributing expertise whilethe latter for technical capacity.
3. Results
3.1. Deforestation drivers and mitigation activities
Deforestation and degradation drivers at the REDD+ demon-stration sites involved a complex interplay of commercial
and subsistence activities (table 1). The primary threats inBrazil and Peru were commercial activities such as cattleranching and beef production and mechanized illegal logging;in Tanzania and Cameroon, they were subsistence activitiessuch as farming and charcoal production (which is partiallycommercial); and in Indonesia and Vietnam, they were a mixof commercial and subsistence activities such as oil palmplantations and subsistence farming. Reducing emission fromdeforestation was the primary mitigation activity planned bythe project developers in all three regions. Forest degradationwas reported as a major problem at sixteen project sites.Conservation of carbon stock and sustainable managementof forests have been taken up by 14 project developers.Enhancement of carbon stock was not a major objective formost of the project developers, and only 3 out of 20 wereengaged in this activity.
3.2. Remote sensing and GIS capacity and readiness
Eleven of 20 project developers (55%) showed high orvery high remote sensing and GIS capacity and readiness(figure 3(a)), seven (35%) were ranked medium, and two(10%) were ranked low. Most project developers wereequipped with medium-resolution satellite data, primarilyLandsat series data available free of cost. The other majorsensors included SPOT series, IRS-LISS series, and CBERS.About half of the developers had high-resolution (>10 m)satellite data, in most cases with spatial coverage of morethan 50% of the study area. Eleven used at least one type ofhigher-end remote sensing technology (such as LiDAR, aerialphotos and SAR). SAR data were primarily PALSAR, whichwere freely available. All these organizations have manyyears of experience at their respective sites, and therefore theavailability of ancillary GIS layers at the project, provincialand national scales was not a problem.
Five organizations were well equipped with processingsoftware. Nine had some limitations with respect tocommercial software, but relied on open-source software
6
Environ. Res. Lett. 8 (2013) 034038 S Joseph et al
Table 2. Detailed breakdown of assessment categories, criteria and indicators.
Category Subcategory Criterion Performance indicatorIndicatorvalue Score
Remote sensing andGIS capacity andreadiness
Data Availability ofmedium-resolution remotesensing data with 100% spatialcoverage of project site at aspecific number of time points
>3 time points Very high 3
2–3 time points High 21 time point Medium 10 time points Low 0
Availability of high-resolutionremote sensing data (<10 m) inat least one time point withpercentage cover
>50% Very high 320–50% High 2<20% Medium 1None Low 0
Access to other higher-endmonitoring tools such as LiDAR,aerial, hyperspectral and SAR
3 or more tools Very high 32 tools High 21 tool Medium 1None Low 0
Availability of GIS data atnational, provincial and projectscales
All 3 scales Very high 32 scales High 21 scale Medium 1None Low 0
Tools andmethods
Availability of remote sensingand GIS processing software(ERDAS, ENVI, ArcGIS,IDRISI and open source)
3 or more programs Very high 32 programs High 21 program Medium 1None Low 0
Use of higher-end techniques forclassification and changeanalysis
Multivariate iterative algorithms,decision tree and otherhigher-end techniques.
Very high 3
Supervised/unsupervisedtechniques andpost-classification changedetection
High 2
Visual Medium 1None/yet to start Low 0
Implementationcapacity
Internal capacity for remotesensing and GIS work
In-house expertise within themain project implementationoffice
Very high 3
In-house expertise atheadquarters with assistancefrom the field office
High 2
such as R and QGIS for spatial analysis. Fourteenorganizations used decision tree or multivariate iterativealgorithms for image classification and change analysis.Eleven organizations showed very good in-house expertisewith the main project implementation office, five partiallyoutsourced their work, and the rest carried out the work atheadquarters with inputs from the regional project office.
Remote sensing and GIS capacity and readiness variedby region (figure 4(a)). Six out of seven projects in Brazil andPeru showed high or very high capacity and readiness, andone was in the medium category. The projects in Tanzaniaand Cameroon showed more variability: two of seven (29%)were rated very high, and the remaining five (71%) were ratedmedium to low. None of the projects in Indonesia and Vietnamshowed very high capacity and readiness in this category;three were rated high, two medium, and one low. Withrespect to high-resolution satellite data and other higher-endmonitoring tools such as LiDAR, aerial photos and SAR, allthree regions experienced limitations; these limitations weresevere in Tanzania and Cameroon. African project capacity
was further weakened by insufficient expertise and lack ofsoftware and processing infrastructure. In contrast, Indonesiaexperienced rapid progress in the acquisition of LiDAR inrecent years together with improvement in data processingalgorithms and facilities.
3.3. Carbon pools inventorying capacity and readiness
Eight (40%) project developers showed high or very highcapacity and readiness, while seven (35%) showed low(figure 3(b)) in this area. Eleven of the sites had site-specificallometric equations, while only five had specific carbonfraction coefficients. The rest of the sites followed globaldefault values available from the IPCC’s AFOLU guidelines.The other emission factor databases such as wood density,biomass expansion factor and root–shoot ratio were alsolimitedly available for most of the sites. Only two projectdevelopers had plans for monitoring all five carbon pools;eight focused on three carbon pools; five measured onlyabove-ground biomass, and the rest had not started carbon
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Table 2. (Continued.)
Category Subcategory Criterion Performance indicatorIndicatorvalue Score
Partial outsourcing Medium 1Complete outsourcing Low 0
Ground carbon poolinventoryingcapacity andreadiness
Data Availability of allometricequations
Site specific for most of the landcover types in the project area
Very high 3
Site specific for certain landcover types, global defaultequations for the rest
High 2
Only global default equationsfrom literature
Medium 1
None Low 0Availability of carbon fractioncoefficients
Site specific for most of the landcover types in the project area
Very high 3
Site specific for certain landcover types, global defaultequations for the rest
High 2
Only global default equationsfrom literature
Medium 1
None Low 0Availability of other emissionfactor databases such asroot–shoot ratio, biomassexpansion factor and wooddensity
Site specific for most of the landcover types in the project area
Very high 3
Site specific for certain landcover types, global defaultvalues for the rest
High 2
Only global default values fromliterature
Medium 1
None Low 0Tools andmethods
Monitoring of all five carbonpools (above-ground,below-ground, deadwood, litterand soil organic carbon)
All carbon pools Very high 3
At least 3 carbon pools High 2At least above-ground biomass Medium 1No plans/yet to start Low 0
Sampling scheme and methods Well defined with configurationsof permanent and temporarysampling units
Very high 3
Well defined with onlypermanent sampling unit
High 2
Loosely defined temporarysampling unit
Medium 1
No sampling scheme/yet to start Low 0
Implementationcapacity
Internal capacity for fieldinventorying
In-house expertise within themain project implementationoffice
Very high 3
In-house expertise atheadquarters with assistancefrom the field office
High 2
pool measurements. The AFOLU recommendation to usea mix of permanent and temporary sampling units formonitoring additionality was not followed by any projectdevelopers. Eleven focused only on permanent sampling units,while six had a vague sampling plan that was just enough todevelop a rough estimate of biomass. However, in terms ofin-house expertise, 90% of the project developers showed highor very high capacity to take up the inventorying program withthe main project implementation office.
Region-wise, three projects in Indonesia and Vietnamshowed high or very high capacity and readiness, and theremaining three showed low capacity (figure 4(b)). Theprojects in Brazil and Peru were more or less evenly
distributed among classification categories, while the projectsin Tanzania and Cameroon were predominantly in the mediumcategory. Distribution of allometric equations was similar inall regions: at least 50% of the project areas had site-specificallometric equations. However, the availability of otheremission factor coefficients such as carbon fraction and wooddensity was higher in Latin America, followed by SoutheastAsia and Africa. The number of carbon pools monitored byTanzania project developers was higher than in the othertwo regions. This is probably due to the fact that manyproject sites are less carbon rich, as they are located indry forest areas, and thus more pools must be counted tomake the project economically viable. Projects in Indonesia
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Table 2. (Continued.)
Category Subcategory Criterion Performance indicatorIndicatorvalue Score
Partial outsourcing Medium 1Complete outsourcing Low 0
Baseline,intervention andmonitoringreadiness
Baselinemodelling
Methods used for baselineestimate
GIS-based modelling withcovariates of deforestationagents
Very high 3
Simple historic average and/orlinear projection
High 2
Assumption based on expertknowledge
Medium 1
No specific plans/yet to start Low 0Deforestationdrivers andinterventionplans
Understanding of the proximatedrivers of deforestation
Very high degree ofunderstanding established overseveral years
Very high 3
Good degree of understanding High 2Limited experience with the site Medium 1No experience with the site Low 0
REDD+ intervention plans forproximate drivers
Well-defined one-to-oneintervention plans
Very high 3
Reasonably defined interventionplans
High 2
Loosely defined interventionplans
Medium 1
No definite plans Low 0Understanding of the underlyingdrivers of deforestation
Very high degree ofunderstanding established overseveral years
Very high 3
Good degree of understanding High 2Limited experience with the site Medium 1No experience with the site Low 0
REDD+ intervention plans forunderlying drivers
Well-defined one-to-oneintervention plans
Very high 3
Reasonably defined interventionplans
High 2
Loosely defined interventionplans
Medium 1
No definite plans Low 0Monitoringplans
Long-term monitoring plans toevaluate theREDD+ interventions
Well-defined monitoring plans Very high 3
Reasonably defined monitoringplans
High 2
Loosely defined monitoringplans
Medium 1
No definite plans Low 0
for which the assessment is already in the advanced stagesincluded soil organic carbon, since peat land carbon is amajor contributor to the total carbon dynamics of the area. Incontrast, project developers in Brazil and Peru mostly focusedon above-ground biomass alone, as this itself contributes alarge share of the carbon pool and can generate adequatecredits.
3.4. Baseline, intervention and monitoring readiness
None of the projects showed very high readiness for baselinemodelling, intervention plans and monitoring. Nine projects(45%) showed high, five (25%) medium, and six (30%)low readiness (figure 3(c)). Seven project developers used
historical averages and linear projection to develop baselineestimates, while six used GIS-based modelling incorporatingdeforestation agents. One relied on expert knowledge forestimating a baseline.
All project developers had very good understanding ofthe proximate drivers of deforestation at the site, since theyhad worked in the same area for multiple years. However,their intervention strategies varied. Only three organizationshad a well-defined strategy to slow and halt deforestationagents. About half of the organizations defined their strategyreasonably well, while two organizations defined theirstrategy loosely, and five did not have specific strategies oractivities at the time of the survey. Project developers seemedto have a reasonable understanding of underlying drivers of
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Figure 3. The MRV capacity and readiness of project developers at a sample of REDD+ projects in Brazil, Peru, Cameroon, Tanzania,Indonesia and Vietnam. (a) Remote sensing and GIS; (b) ground carbon pool inventorying; (c) baseline, intervention and monitoring; and(d) overall MRV readiness. The total number of projects in the sample is 20, and the values in the diagram represent number of projectdevelopers with percentage in parentheses.
deforestation, but they expressed limitations in their abilityto address these drivers, since many originate outside theproject boundary. In such cases, project developers outlinedtheir plans to work with local or regional government bodiesto develop intervention plans.
With respect to monitoring, only 20% of the projectdevelopers had reasonable monitoring plans, while the resthad loosely defined monitoring plans or no plan at all. Thiswas probably due to the fact that the projects are still in theplanning or verification stage and are not yet at the stage ofestablishing a fully functioning MRV system.
Although no project in any region was classified ashaving very high readiness, the projects in Brazil and Perutended to have better in this category than the other fourcountries (figure 4(c)). The lowest readiness was observedamong Southeast Asian projects, while most African projectsranked either high or low with a negligible percentagein the medium category. A higher-end future deforestationmodelling capacity (five out of seven) was clearly visibleamong Latin American projects for developing baselinemodelling; whereas the modelling capacity was largelylimited in the other regions (none in Africa, and one outof six in Southeast Asia). Progress with intervention planswas greater in Brazil and Peru, followed by Tanzania andCameroon and then Indonesia and Vietnam. This implies thatAfrica project developers have good understanding of theground conditions and can make well-defined intervention
plans although they have limited technical capacity. Withrespect to monitoring plans, projects in Brazil and Peru didnot show a clear difference although these countries were inthe forefront for many of the other activities.
3.5. Overall MRV capacity and readiness
In an aggregation of the three main categories, onlytwo projects (10%) had very high capacity and readiness(figure 3(d)). Nine (45%) had high, six (30%) medium, andthree (15%) low capacity. Considered by region, six out ofseven Latin American projects showed high or very highcapacity; no project in Africa or Southeast Asia had veryhigh capacity (figure 4(d)). Two out of seven African projectshad low capacity; three out of six Southeast Asian projectshad medium capacity. In general, the projects in Braziland Peru showed the highest capacity and readiness. Thosein Cameroon, Tanzania, Indonesia, and Vietnam showedcapacity that is on average lower than the two Latin Americancountries.
The comparative analysis of in-house capacities forremote sensing, GIS and field inventorying, and technicalcapacities for baseline, intervention and monitoring acrossprojects indicate that expertise and technical limitationswere not the primary reasons for the slow progress towardsreadiness. In-house capacities to carry out both remote sensingand GIS works, and carbon pools inventorying ranked high
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Figure 4. Region-wise capacity and readiness of project developers at a sample of REDD+ projects in Brazil, Peru, Cameroon, Tanzania,Indonesia and Vietnam. (a) Remote sensing and GIS; (b) ground carbon pool inventorying; (c) baseline, intervention and monitoring; and(d) overall MRV readiness. (The values within the column represent number of projects.)
or very high in 14 of the 20 projects (70%) (table 3).Four projects (20%) (two each in Africa and SoutheastAsia) had very high field inventorying expertise but partiallyoutsourced their remote sensing and GIS work. One projecthad high remote sensing and GIS capacity but low carbonpool inventorying capacity, and one was ranked mediumfor both categories. With respect to technical capacities forbaseline, intervention and monitoring readiness, five projectsshowed very high remote sensing and GIS capacity whilenone showed very high baseline, intervention and monitoringreadiness, suggesting that slow progress in the latter categorywas not solely due to limitations in the former category(table 4).
4. Discussion and recommendations
Performance indicators need to be identified at each phaseof REDD+ implementation to measure its success (Wertz-Kanounnikoff and McNeill 2012). The present study, whichaddresses the accounting framework of REDD+ projects inthe readiness phase, developed 19 performance criteria and 76indicators to measure MRV capacity and readiness. The studyfound that many projects are still working towards variouscategories of MRV capacity and need additional momentumto move forward to the next phases. The critical issues inthe accounting framework could be sorted into the followingcategories.
Table 3. Comparison of in-house project personnel expertise tocarry out remote sensing, GIS and carbon pool inventorying worksat a sample of REDD+ projects in Brazil, Peru, Cameroon,Tanzania, Indonesia and Vietnam. The upper left columns indicatehigh degree of expertise (70%) within the organizations.
Carbon pool inventoryingin-house expertise
Veryhigh High Medium Low Sum
Remote sensing andGIS in-houseexpertise
Veryhigh
6 5 0 0 11
High 2 1 0 1 4Medium 4 0 1 0 5Low 0 0 0 0 0
Sum 12 6 1 1 20
Data availability and methodological guidelines—theREDD+ projects are located in the tropical belt wherea number of prevalent atmospheric and ground conditionssuch as cloud cover, haze and uneven topography oftendisrupts a satellite sensor’s capacity to image good qualityground data (Joseph et al 2013). The access to time seriesremote sensing data was serious problem in most of theprojects in our study. This data limitation problem havebeen reported widely; including the world’s first verifiedREDD project, Noel Kempff Mercado Climate Action Project
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Table 4. Comparison of remote sensing and GIS capacity withbaseline, intervention and monitoring readiness at a sample ofREDD+ projects in Brazil, Peru, Cameroon, Tanzania, Indonesiaand Vietnam.
Baseline, intervention andmonitoring readiness
Veryhigh High Medium Low Sum
Remote sensingand GIScapacity
Veryhigh
0 4 1 0 5
High 0 2 3 1 6Medium 0 2 2 3 7Low 0 0 0 2 2
Sum 0 8 6 6 20
in Bolivia, where lack of time series data at the rightscale was a major constraint in generating the accurate andprecise estimates of deforestation and spatial modelling ofbaseline (Brown 2005). Although operational monitoring ofdeforestation is reasonably possible with the coarse resolutionremote sensing data as evident from INPE’s PRODESprogram (INPE 2011), establishing such a scheme usingmedium-resolution data still underway. Recent initiatives suchas mapping of annual deforestation rate using Landsat datain the Congo basin (Potapov et al 2012) and Sumatra Island(Margono et al 2012) are notable in this context. Moreimportantly, such system should make use of the pixel-basedtime series data compositing to remove the noises fromcloud, haze and other atmospheric impurities. This involvesthe implementation of number of higher-end computationalgorithms; for example: LEDAPS (Landsat EcosystemDisturbance Adaptive Processing System) for atmosphericcorrection (Masek et al 2006), Fmask (Function of mask)for cloud and cloud shadow masking (Zhu and Woodcock2012), and change break detection using BFAST (breaks foradditive seasonal and trend) (Verbesselt et al 2010a, 2010b).The spatial infrastructure and technical expertise are criticalcomponents in the implementation of such algorithms (Josephet al 2013).
Similarly ambiguity exists in methodological guidelineson how to set reference emission level in REDD+ projects(Angelsen and Verchot 2009, Dutschke 2013). The commonand easiest method is simple linear regression based onhistorical deforestation rate. Verified Carbon Standard alsorecommend the use logistical regression to overcome theproblems of linear regression (Shoch et al 2011). Other thanthese two, complex GIS-based predictive land cover modelsare also suggested for estimating the REL. Cortez et al(2010) proposed a double set of RELs at the project level;an absolute REL and a proportional REL to the respectivereference region; both could be independently validated. Thisis important for upscaling the REL to the subnational andnational scales through a nested approach (Pedroni et al2009), ensuring no displacement in the emission, and alsoto avoid the potential double counting issues. The overallchallenge is to make sure that the sum of all projects andsubnational emission reductions does not exceed the totalclaimed at national scale (Dutschke 2013).
Monitoring cost and choices—the earlier studies that focusedat the national scale observed critical gaps forest monitoringcapacities (Romijn et al 2012), largely attributed to the lackof technical capacity and expertise. The results of this study,which was focused at the project rather than national scale,indicate that technical and expertise limitations are not thesole reasons for the slow progress towards readiness. Of the20 projects, 18 had high or very high in-house expertise forcarbon pool inventorying, but only 15 reached these levelsfor remote sensing and GIS (table 3). The difference isinteresting, although not large, because at the country scalethese values are commonly reversed (Herold 2009, Romijnet al 2012). This implies that projects are better at producinglocal measurements of carbon stocks but rely more on externaltechnological expertise for remote sensing and GIS.
A national nesting protocol may be needed to addressthe monitoring choices (Cortez et al 2010). Monitoringchoices should be decided based on a cost-benefit analysiswhich is dependent on the size of the project and theemission reductions and removals expected. Bottcher et al(2009) compile the monitoring cost of different techniqueswhich ranges from $0.5 to $550 km−2 depending on therequired precision of carbon stock and area change detection.The cost of medium-resolution satellite data ranges from$0.001 to $0.5 km−2 (except for Landsat and CBERS)while high-resolution data are in the range of $2–30 km−2
(GOFC-GOLD 2012). Bottcher et al (2009) also argue thatsingle country or project solutions will face relatively highermonitoring costs and recommend an international cooperationto overcome initialization costs and unequal access tomonitoring technologies. Hardcastle and Baird (2008) studiedthe monitoring cost in 25 tropical countries and recommendedthe establishment of shared regional capacity, as mostnon-data costs are largely independent of the geographicalextent of the monitored area. Other advantages of such sharedsystem would include standardization of methodologies forcarbon accounting and reporting, facilitating a regional ratherthan national integration with carbon markets, and perhapsreducing transaction costs (Hardcastle and Baird 2008).
International policy dialogues—perhaps the single mostprominent factor determining the progress of the projects isthe pace of the international REDD+ negotiation progressingat the UNFCCC. Although REDD+ started with ambitiousplans and a fast pace in 2007, the momentum has slowednoticeably after the Copenhagen Summit. The economicdownturn in 2008 led many countries to withdraw fromtheir original ambitious funding plans (Angelsen and McNeill2012). The announcement of a Green Climate Fund inDurban stimulated enthusiasm, but the time frame put forthfor operationalizing market mechanisms (by 2020) was notpromising. This created a vacuum and an unclear path ofdevelopment in the forest carbon market. The projectedgrowth of the forest carbon market has shown a considerabledecrease in the last three years (Peters-Stanley and Hamilton2012). In addition, market fluctuations and the price collapseof clean development mechanism (CDM) credits—anotherUNFCCC initiative for emission reduction—made investorsdoubtful about the voluntary carbon market. Perhaps, these
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uncertainties together with the deficiency in the human andtechnical expertise might have resulted a general slowness inthe prospects of MRV development in the REDD+ projects.Although this was the case in private and multilateral funding,bilateral investment has increased in recent years, especiallyfrom the development assistance fund (Wertz-Kanounnikoffand McNeill 2012, Streck 2012).
RecommendationsFurther research and investment are needed to enable
REDD+ to move forward to the operational (‘results-basedaction’) phase. Although the sample is too small to allowdefinitive conclusions, some tentative recommendations canbe made.
• Improve remote sensing data access. Landsat seriesdata are the primary source of information for theproject developers. However, the availability of timeseries data was a limitation for many of the projectsites (especially African sites). This limitation is moresevere for high-resolution satellite data and other high-endmonitoring tools like LiDAR and aerial photos. Possibleways to address this would be the establishment of anEarth Observation Data Directory for REDD+ projectsby international donors, and other key stakeholderorganizations.
• Develop emission factor data. Although allometricequations are well developed in the Amazon, there is littleunderstanding of the carbon content of living biomass inthese areas. Data on wood density, the biomass expansionfactor and the root–shoot ratio were also limited at theAmazon project sites. Indonesia is a unique case inwhich peatland carbon plays an important role in the totalcarbon dynamics (Hergoualc’h and Verchot 2011). Datadeficiency, unless addressed with a substantial investment,will make it difficult for Indonesia to progress to theoperational phase of REDD+ (Verchot et al 2012). Thisdata deficiency problem is particularly severe in theinitial stages of REDD+ implementation. Once allometricequations are developed for each bioclimatic region andhave precise biomass values for each stratum, this problemwould be less important for future REDD+ projects.
• Account all relevant carbon pools. The dry forestproject sites in Tanzania are less carbon rich comparedto tropical wet forest sites and need to combine allsignificant carbon pools to make the project attractive forinvestors. Methodologically, projects focusing on avoideddeforestation might not attract large investment becauserates of deforestation is low in these landscapes. In suchsituations, mitigation activity focused reducing emissionsand increasing removals might be more suitable (Skutschet al 2009, Skutsch and Ba 2010). The forest enhancementactivities could also generate additional job opportunitiesand income for local communities and ensure more activeparticipation in the participatory MRV process. It is alsoimportant to combine bilateral, multilateral and otherinternational funds in addition to the carbon market tomake projects economically viable.
• Advance method development. Although degradation wasreported as an issue at 16 of the sites, its monitoringreceived less attention, largely attributed to methodologicaland technical limitations. The spatial and temporal scaleof various data products and their integration was anotherchallenging task in larger projects.
• Collaborate to build capacity. The software and dataprocessing capacity of project developers varies con-siderably. The level of technical expertise is a sourceof concern in many projects. Capacity developmentthrough collaboration should be encouraged within regionsand complemented by south–south cooperation technicalexchange. Also, it is important to organize more capacitybuilding training for development of expertise in dataprocessing.
• Coordinate efforts to slow, halt and reverse deforestationat the jurisdictional scale. Focusing on REDD+ creditingwithin project boundaries alone may shift deforestationactivities to neighbouring areas outside the project, makingnet change negligible. Project developers said some ofthe underlying drivers originate from outside their projectboundaries and are therefore under the purview of local,provincial or national governments. Therefore, the nextstep in the investment process should focus on nestingREDD+ projects and other efforts to slow and haltdeforestation within broader efforts to stop deforestationand degradation at higher jurisdictional scales.
• Ensure continued funding. Many project developersexpressed concern about continued availability of fundingafter the present project period. Assured project funding,or the establishment of a fund to support the efforts ofREDD+ projects might be necessary.
5. Conclusion
This study found that capacity and readiness tended to behighest in the projects in Brazil and Peru and somewhat lowerin Cameroon, Tanzania, Indonesia and Vietnam. Capacityand readiness also varied with respect to different MRVcategories. Remote sensing and GIS capacity was highestin Brazilian and Peruvian projects. With respect to carbonpool inventorying, the projects in Brazil and Peru focusedmostly on above-ground biomass; Tanzania combined asmany carbon pools as possible; and Indonesia focusedprimarily on above-ground, below-ground and peat carbon.On baseline modelling, intervention and monitoring, none ofthe projects showed very high capacity. Although the overallMRV capacity and readiness of half the projects is high,there are capacity deficiencies in other projects. This couldbe attributed not only to technical and expertise limitationsbut also to the general slowness of REDD+ progress ininternational negotiations and the unclear path of developmentof the forest carbon market. Substantial investment is requiredto make REDD+ operational at the project scale, and morechallenges are likely for monitoring, reporting and verificationat larger scales including jurisdictional counting.
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Acknowledgments
This study is part of a larger initiative, the Global ComparativeStudy on REDD+, undertaken by the Center for InternationalForestry Research with funding support from NORAD(Grant Agreement no. QZA-10/0468) and AusAID (GrantAgreement no. 46167). The authors would like to thankthe national coordinators of this study, Abdon Awono, AmyDuchelle, Daju Pradnja Resosudarmo, Demetrius Kweka,and Thu Ba Huynh, and other field researchers who helpedwith the survey and fieldwork. The study also drew oninsights developed during three regional workshops, and thecontribution of each participant is duly acknowledged. Theauthors also wish to thank Manuel Estrada, who played anindispensable role in organizing the workshops. Commentsby two anonymous reviewers and the editorial board memberhave substantially enhanced the quality of the paper.
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