Employment Sector Employment Working Paper No. 88 2011

Dynamic Social Accounting Matrix (DySAM ): Concept, Methodology and Simulation Outcomes

The case of Indonesia and Mozambique

Jorge Alarcón, Christoph Ernst, Bazlul Khondker, PD Sharma

Employment Intensive Investment Programme

Copyright © International Labour Organization 2011

First published 2011

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ILO Cataloguing in Publication Data

Alarcón, Jorge; Ernst, Christoph; Khondker, Bazlul; Sharma, P. D.

Dynamic social accounting matrix (DySAM) : concept, methodology and simulation outcomes : the case of Indonesia and Mozambique / Jorge Alarcón, Christoph Ernst, Bazlul Khondker, PD Sharma ; International Labour Office, Employment Sector, Employment Intensive

Investment Programme. - Geneva: ILO, 2011

1 v. (Employment working paper, No.88 )

ISBN: 9789221250418;9789221250425 (web pdf)

International Labour Office; Employment Sector

promotion of employment / employment / data base / data collecting / methodology / Indonesia / Mozambique

13.01.3>

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iii

Preface

The primary goal of the ILO is to contribute, with member States, to achieve full and

productive employment and decent work for all, including women and young people, a goal

embedded in the ILO Declaration 2008 on Social Justice for a Fair Globalization, 1

and

which has now been widely adopted by the international community.

In order to support member States and the social partners to reach the goal, the ILO

pursues a Decent Work Agenda which comprises four interrelated areas: Respect for

fundamental worker‘s rights and international labour standards, employment promotion,

social protection and social dialogue. Explanations of this integrated approach and related

challenges are contained in a number of key documents: in those explaining and elaborating

the concept of decent work2, in the Employment Policy Convention, 1964 (No. 122), and in

the Global Employment Agenda.

The Global Employment Agenda was developed by the ILO through tripartite

consensus of its Governing Body‘s Employment and Social Policy Committee. Since its

adoption in 2003 it has been further articulated and made more operational and today it

constitutes the basic framework through which the ILO pursues the objective of placing

employment at the centre of economic and social policies.3

The Employment Sector is fully engaged in the implementation of the Global

Employment Agenda, and is doing so through a large range of technical support and

capacity building activities, advisory services and policy research. As part of its research

and publications programme, the Employment Sector promotes knowledge-generation

around key policy issues and topics conforming to the core elements of the Global

Employment Agenda and the Decent Work Agenda. The Sector‘s publications consist of

books, monographs, working papers, employment reports and policy briefs.4

The Employment Working Papers series is designed to disseminate the main findings

of research initiatives undertaken by the various departments and programmes of the

Sector. The working papers are intended to encourage exchange of ideas and to stimulate

debate. The views expressed are the responsibility of the author(s) and do not necessarily

represent those of the ILO.

1 See http://www.ilo.org/public/english/bureau/dgo/download/dg_announce_en.pdf

2 See the successive Reports of the Director-General to the International Labour Conference: Decent

work (1999); Reducing the decent work deficit: A global challenge (2001); Working out of poverty

(2003).

3 See http://www.ilo.org/gea. And in particular: Implementing the Global Employment Agenda:

Employment strategies in support of decent work, “Vision” document, ILO, 2006.

4 See http://www.ilo.org/employment.

José Manuel Salazar-Xirinachs

Executive Director

Employment Sector

iv

Foreword

The Employment Intensive Investment Branch (EMP/INVEST) of the ILO has a long

tradition in the development and use of employment impact assessment methodologies.

They have been developed with the purpose to compare the cost-effectiveness and

employment dimension of different technologies applied in the implementation of

infrastructure investment. Another objective of these methodologies has been to evaluate

the effectiveness of already implemented infrastructure investment with regard to

employment and general economic variables. The Dynamic Social Accounting Matrix

described in this paper is a logical development of these assessment tools by

EMP/INVEST. For many decades, ILO has been using Input-Output Tables around the

world. Static Social Accounting Matrices have been introduced more recently, which

expands Input-Output Tables by introducing social transfers of enterprises, households and

the Government. Indonesia and Mozambique have been the first two countries where

EMP/INVEST assisted the Governments in the construction of a DySAM. The particularity

of a DySAM is a) the inclusion of a satellite account with disaggregated employment data

by activity, b) the inclusion of technology choices (labour-based, capital based), and c) the

possibility to up-date data for years, where input-output tables are not available (relaxing

some assumptions).

This working paper should help technicians and modelers gain a basic understanding

of the functioning of the DySAM and its potential for applications in concrete situations,

not only for infrastructure investment but also in respect of various other government

spending and public policies. Its strength is its multi-sectoral approach and it has already

been applied in the analysis of trade policies and fiscal stimulus packages, including

infrastructure investment and other measures applied to the whole economy, e.g. tax cuts or

sectors and subsidies. Satellite accounts facilitate the inclusion of real data, not just on

employment but also on the environment by generating an analysis of environmental

shocks and policies. Another strength is that it allows a better understanding of the impact

of policies and programmes on specific target groups. In this context, it has been used to

look specifically at female and young workers, and also on rural and urban workers. The

DySAM allows not only the evaluation of the effectiveness of past programmes or the

simulation and comparison of the possible outcome of future policies or policy mix but also

the evaluation of external shocks such as an economic crisis, a natural disaster or a trade

opening.

Terje Tessem

Chief, Employment Intensive

Investment Programme

Azita Berar Awad

Director

Employment Policy Department

v

Contents

Page

Preface ...................................................................................................................................................... iii

Foreword .................................................................................................................................................. iv

Abbreviations ......................................................................................................................................... viii

Glossary .................................................................................................................................................... ix

Introduction ............................................................................................................................................... 1

Preamble: In search of tools to promote employment centred development .................................. 1

Social Accounting Matrix ............................................................................................................... 2

Guide to the Report ......................................................................................................................... 4

1 Dynamic Sam Methodology ................................................................................................................... 5

1.1 Overview ................................................................................................................................... 5

1.2 Database and data handling ....................................................................................................... 6

1.2.1 Consistency verification ............................................................................................... 6

1.2.2 Derivation of consistent macro data series ................................................................. 6

1.2.3 Source data compilation and building consistency...................................................... 7

2 Dynamic SAM and satellite modules ................................................................................................... 10

2.1 Derivation of Dynamic Macro SAMs ..................................................................................... 10

2.2 SAM Transformation Methodology ........................................................................................ 11

2.3 Derivation of Dynamic Sectoral SAM .................................................................................... 11

2.3.1 DySAM Algorithm ...................................................................................................... 12

2.3.2 DySAM Algorithm Comparison for Indonesia and Mozambique .............................. 13

3 Derivation of dynamic SAM model for impact analysis ...................................................................... 18

4 Simulation Design and Impact Analysis .............................................................................................. 20

4.1 Introduction ............................................................................................................................. 20

4.2 Total backward linkages ......................................................................................................... 20

4.2.1 Dynamic backward linkages ...................................................................................... 21

4.2.2 Total backward linkage comparison .......................................................................... 21

4.3 Dynamic SAMs multipliers and linkages (total) ..................................................................... 23

4.4 Summary observations of the policy indicators – the case of Indonesia ................................. 25

5. Satellite accounts and transformation and employment ...................................................................... 27

5.1 Introduction ............................................................................................................................. 27

5.2 The Employment Satellite Module ......................................................................................... 28

5.2.1 General ...................................................................................................................... 28

5.2.2 Employment Methodology and Modelling ................................................................. 29

vi

5.3 Employment summary results: the case of Indonesia ............................................................. 30

6 Simulation the Case of Indonesia: Fiscal Stimulus Package Infrastructure ......................................... 33

6.1 Simulation Scenario: the case of Indonesia ............................................................................. 33

REFERENCES ........................................................................................................................................ 39

APPENDIX ............................................................................................................................................. 41

1 Backward linkages: Evolution over time for a selected number of endogenous accounts ......... 41

Glossary of Symbols: .......................................................................................................... 41

2 Dynamic Macro SAMs [s3]: The Case of Mozambique ...................................................................... 49

Table

Page

Table 1: Data development steps ............................................................................................................... 8

Table 2: DySAM Algorithm Comparisons – Step 1 ................................................................................ 13

Table 3: DySAM Algorithm Comparisons – Step 2 ................................................................................ 14

Table 4: DySAM Algorithm Comparisons – Step 3 ................................................................................ 14

Table 5: Matrices for accounts of the Indonesian DySAM (2000 – 2008) ............................................. 15

Table 6: DySAM Algorithm Comparisons – Step 4 ................................................................................ 15

Table 7: Endogenous and exogenous accounts of a SAM ....................................................................... 18

Table 8: Indonesia: Comparison of selected Commodity and Activity total backward linkages ............ 23

Table 9: Summary of the impact of injections by account type (The information in this table is very

similar to the information in the last para of section 4.) ......................................................... 25

Table 10: Indonesia DySAM 2008 Correlation Matrix ........................................................................... 26

Table 11: Indonesia DySAM 2008 Average partial backward linkages ................................................. 27

Table 12: DySAM summary labour multipliers by accounts for 2008 (Unit Persons) ........................... 31

Table 13: DySAM Total Labour Multipliers by Construction Type for 2008 (persons) ........................ 32

Table 14: DySAM partial activity multipliers by construction type for 2008 (billion IDR) ................... 32

Table 15: Stimulus Package by Items and Delivery Levels .................................................................... 33

Table 16: Economy-wide Impacts of FSPC Injection of 10,665.0 billion rupiahs in 2009 (billion rupiahs)

................................................................................................................................................ 34

Table 17: Net Cost of the Construction Fiscal Stimulus Package in 2009 (billions of rupiahs) ............. 34

Table 18: Total Impact on Job creation 2009: Economy Wide, Construction by Type and Crops ......... 35

vii

Table 19: Intra Account Impact on Job creation 2009: Economy Wide, Construction by Type and Crops

................................................................................................................................................ 36

Table 20: Share of new employment by location and gender, 2008 (percentage) .................................. 36

Table 21: Macro SAMs for selected years .............................................................................................. 49

Figures

Page

Figure 1: Principal circular ‗closed‘ economic flow ................................................................................. 3

Figure 2: Derivation procedure of a dynamic macro SAM ..................................................................... 10

Figure 3: Dynamic SAM Flow Chart: Indonesia .................................................................................... 13

Figure 4: The dynamic SAM for Indonesia (2000-2008) ........................................................................ 16

Figure 5: The dynamic SAM for Mozambique (2000-2008) .................................................................. 17

Figure 6: Indonesia: Over time trend of total backward linkages for selected economic Activities ....... 24

Figure 7: Relations between the SAM and satellite accounts; Extended SAM (ESAM) ........................ 28

Figure 8: Commodity Account and Activity Account ............................................................................ 41

Figure 9: Total Backward Linkage of Factor Accounts (1-14) ............................................................... 44

Figure 10: Total Backward Linkage of Household Accounts (1-14) ...................................................... 46

Figure 11: Total Backward Linkage of Household Accounts (15-28) .................................................... 47

Figure 12: Total Backward Linkage of Household Accounts (29-35) .................................................... 48

Figure 13: Behaviours of Activity and Commodity Accounts of the Dynamic SAMs ........................... 51

Figure 14: Behaviours of Household and Government Accounts of the Dynamic SAMs ...................... 52

viii

Abbreviations

APS Average Propensity to Spend (An)

CM or Co Commodities

CMEA Coordinating Ministry for Foreign Affairs (Indonesia)

DySAM Dynamic Social Accounting Matrix

EPI Export Promotion Industrialization Strategy

ESAM Extended Social Accounting Matrix

FD Final Demand

FDOI or iE Final Demand Other Institutions

FoF Flow of Funds

FP or Fp Factors of production

FSPC Fiscal Stimulus Package Construction

GOI Government of Indonesia

HH or iH Households

ILO International Labour Office

iG, iTx and iSu Institution Government, Taxes and Subsidies

ISI Import Substitution Industrialization Strategy

MCM Matrix of Imported Commodities by Demand Type

MDGs Millennium Development Goals

ME Manpower equivalence

MTCs Meticals (currency in Mozambique)

PA or A Production Activities

PRSP Poverty Reduction Strategy Paper

RoWor wCu Rest of World Current Account

SAM Social Accounting Matrix

SNA System of National Accounts (UNSD 1993 Recommendations)

TM Trade Margins

UN United Nations

UNSD United Nations Statistical Division

ix

Glossary

Backward linkage = an exogenous injection into the system increases the income of the

corresponding account and then cascades on the incomes of all other endogenous

accounts, the column-wise sum of all these effects constitutes its total backward

linkage. The column-wise sum within each account is the total partial linkage.

Forward linkage = effect read row-wise represents the amounts of expenditures per

account that are made ‗available‘ for the expansion in other accounts; can be

interpreted as market potential availability.

Data module = specially developed data set, where time series and SAM data are made

consistent; forms the basis of the DySAM.

Endogenous account = a set of economic variables that are determined within a model.

The set is therefore not subject to direct manipulation by the modeller since that would

override the model. In SAM models, production and incomes are almost always

endogenous.

Endogenous variable = economic variable that is part of the endogenous account. It is

therefore not subject to direct manipulation by the modeller since that would override

the model. In trade models, the quantity of trade itself is almost always endogenous.

Exogenous account = a set of economic variables that are taken as given within an

economic model. The set is, therefore, subject to direct manipulation by the modeller.

Exogenous variable = variable that is part of an exogenous account. It is, therefore, subject

to direct manipulation by the modeller.

Intra-account effects = intra-account effects measure impacts within the account where

the injection enters. In DySAM modelling defined as the sum of the injection (I) and

transfer (T) effects (M1). Only exists for accounts with intra-account transactions.

Induced effects = induced effects measure impact outside the account where the injection

enters, e.g. household expenditures, from the income earned in a directly or indirectly

affected activity. In DySAM modelling defined as the sum of open loop (O) and close

(C) loop effects (OC). It exists for all accounts.

Injections = autonomous effects on exogenous accounts/variables; for example, increase in

investment expenditures, government purchases, and/or exports.

Leakages = are exogenous expenditures accounts/variables in the model; for example,

saving, taxes, remittances and imports. In SAM modelling these transactions are

defined as a B Matrix.

Macro control totals = consistent macro values derived from the process crossing over

time series with the SAM. The overtime values are used to anchor the building process

of the DySAM by applying stepwise iterative and RAS methods.

Manpower equivalence = correcting the number of persons employed with a factor that

uses a norm reflecting ―actual‖ working days.

Placeholder value = proxy values used when ―true‖ data is absent, scarce or inaccurate; the

proxy values can be replaced once the ―true‖ values are available.

Note: Glossary is self-defined or taken and adjusted from: Deardorff‘s Glossary of

International Economics (http://www-personal.umich.edu/~alandear/glossary/ , and

http://www.amosweb.com/cgi- in/awb_nav.pl?s=wpd&c=dsp&k=injections-

x

leakages+model , extracted on28 July 2010) and other sources (e.g. from Indonesian

Data and DySAM reports).

1

Introduction

Preamble: In search of tools to promote employment centred development

Employment generation is an accepted and effective strategy for reducing

poverty and progressing development in many developing nations. The strategy in

developing countries is based on the recognition that a wage income is a primary

source of income for poor household groups. Therefore, creating additional

employment opportunities and/or raising the wage income of the existing employed

population are central themes in most poverty reduction strategies.

A typical Poverty Reduction Strategy Paper (PRSP; or similar goal-based

policy agenda) will often promote investment projects that are geared to achieving

an agreed level of poverty reduction by increasing (or enhancing) ‗returns‘ to

labour. Since investment is a proximate determinant of employment generation, a

natural question in the mind of development planners pertains to the efficiency of

such investments to total employment generation (direct, indirect and induced over

short- medium- and long-term time horizons). Infrastructure investment is a major

element of analysis and requires special attention, as: i) it represents an important

share of public spending; ii) it represents the ―flexible part of public spending,

which can be more easily adjusted in good or bad times; iii) it has a multiplier effect

on the private sector and private companies mostly implementing that type of

investment.

Various types of analytical tools may be adopted to assess the impact of investment on

employment. However, since investment is a component of the national aggregate demand,5

a ‗Keynesian‘ type of demand driven (multiplier) approach may prove to be the most

suitable choice for understanding such questions. The Social Accounting Matrix (SAM) is

an accounting platform that offers such an approach.

A workshop hosted by the Employment Intensive Investment Branch (Emp/INVEST)

of the ILO on employment impact assessment methodologies in March 2008 clearly

demonstrated the common interest of different branches, programmes and external partners

for the development and use of appropriate tools and methodologies to assess the

employment impacts of public policies and investments, particularly those related to

infrastructure. There was a strong consensus that a social accounting matrix (SAM), which

is based on input-output methodology, would be the most suitable tool and should,

therefore, be developed further.

It allows a better understanding of the impact and transmission channels of external

shocks, e.g. a financial crisis or a trade opening, or macro and sectoral policies through the

various sectors towards the target groups at the micro level, meaning different types of

workers or households. It can also be used for the analysis of public infrastructure

5 The relationship can be expressed as: F = C + I + G + (E-M).

2

investment, public spending in general, and also other sectoral policies and trade policies,

etc. The SAM not only permits the evaluation of the effectiveness of past programmes and

the simulation and comparison of the possible outcome of future policies or policy mix but

also allows the evaluation of external shocks.

Social Accounting Matrix

A SAM can be considered to be an extension of input-output tables, which have been

used extensively by the ILO over recent decades to measure,6 among other things, the

direct and indirect employment effects of public investment through a multiplier analysis.

The major deficit encountered with input-output tables is that they do not include detailed

data about the distributional side of economic processes. That is, they do not contain data

on the expenditure pattern of the economic actors (government, enterprises, and

households). A SAM brings together, in a coherent way, data on income creation and

production as national accounts and input-output tables do, and also includes information

on incomes received by different institutions and related spending.7

As a result, the ILO started using a static SAM to analyze the impact of trade on

employment, as in the case of Costa Rica, India and South Africa (see Kucera, Roncolato,

2011, Ernst, Sánchez-Aconchea, 2008). An employment satellite account was introduced

with real employment data that was disaggregated by sector, which allowed a detailed

analysis of the employment impact of trade strategies and policies.8 As SAM methodology

covers a single and non-current period of data, there was a need to develop a dynamic SAM

(DySAM). More concretely, a DySAM has to be able to deal with the four main problems

of a static SAM, including:

A SAM model is static with fixed coefficients;

data in the SAM refers to one single period (normally a year);

the year of the SAM is normally not current; and

A SAM lacks behavior.

Comparisons between the ‗traditional‘ static SAM modelling and DySAM modelling

can be summarized as follows:

1. Dynamic SAM‘ (DySAM) describes an instrument based on an existing ‗static‘ Social

Accounting Matrix (SAM) for the economy of a country and the available data from

national accounts, BoP, budget and financial statistics.

2. The static SAM gives a snapshot of the economy, while a DySAM shows the consistent

evolution of the economic structure over time, for periods covering the years before and

after the static SAM.

6 SAM as a planning policy instrument was proposed by G. Paytt and E.Thorbeke in 1976, as part of

the ILO World Employment Programme.

7 A SAM, therefore, displays the following elements: 1. Inputs, 2. Outputs, 3. Factor incomes created

in domestic production, 4. Distribution of these factor incomes, 5. Redistribution of these factor

incomes over these institutions, 6. Expenditure of the institutions on consumption, investment, 7.

Savings made by them. For more information, see van Heemst, Ch. 1, in Alarcon (1991) et al.

8 See Ernst, Sánchez-Aconchea on Costa Rica (2008) and Kucera, Roncolato on India and South

Africa (2010).

3

3. DySAM thus helps to identify cross section and time series data problems and enhances

data gathering processes.

4. Several sequential SAMs over time imply dynamics.

5. Over time shifts reflect technology choices.

6. A DySAM lessens the need to calculate expenditure income elasticities, in order to

introduce behaviour, i.e. SAM fixed-price model (see Pyatt and Round, 1979).

7. There will always be one DySAM period that matches surveys (e.g. labour, household

expenditure, population, etc), which eliminates the need to introduce time-bound

assumptions.

8. An employment satellite account for one or several years with disaggregated labour

market data can be added and coupled with the DySAM, and matched with the exact

year of the particular survey.

9. Allows the use of place holders when information is scarce, missing or not fully

reliable, this can done via satellites, for instance, to dynamize the sectoral

disaggregation of the construction sector.

10. The use of place holder values eliminates the need to hold up programming before

‗final‘ data are provided.

11. The DySAM can be updated when new data become available or when a more current

SAM and/or System of National Accounts (SNA) time series data comes on-stream.

The Dynamic SAM can be used to support and strengthen the process of developing

coherent national strategies by, inter alia, analysing the effects of investment planning on

the economy. It can be used to specifically explore the relationship between intensive

employment strategies, job creation, and poverty reduction.

Figure 1: Principal circular ‘closed’ economic flow

Source: Adapted from Fig. 1 (pp. 12) in Alarcon (2007), see also DySAM Reports (2010)

The Dynamic SAM may be used for: (i) Counterfactual simulation analysis (e.g.

magnitude of exogenous injections) at any year within the period for which it is computed.

This helps to validate valuable experiences such as analysis of completed public

policies/programmes; and (ii) Short-run policy simulations from the terminal year and after.

Using the DySAM approach may be viewed as a ‗full-information‘ data model, which

4

mitigates exclusive use of a dated static SAM or a SNA, the latter of which typically has

low resolution to capture the circular flow operating in the economy (c.f. Flow Chart 1).

It can clearly be seen that a time-consistent and reliable database9 is paramount.

Although, consistency is a shared characteristic of all serious modelling efforts, it does

require added importance when deriving dynamic SAM multiplier sequences. In addition, it

is clear that the base year SAM structure, the number of accounts, the types of

classifications and the account openings will limit or enrich the quality of analysis that may

be envisaged.

While modelling with a dynamic SAM, similar to static SAM modelling, satellite

accounts can be used to introduce a wider range of analysis. Satellites can be of the

‗expanding‘ or ‗extending‘ types. The former refers to the use of information to ‗blow out‘

existing entries in the SAM. For instance, the original SAM household and labour factor

classifications can be increased or altered. Similarly, the construction sector can be

separated into various types of activities or commodities (i.e. infrastructure, roads,

irrigation, etc.). The latter refers to the extension of certain accounts with directly linked

physical information. Such information types can be as varied as employment,

environmental aspects, types of housing, demographic information and morbidity satellite

tables, to name a few.

The DySAM multiplier analysis, using the SAM framework, helps us to gain a better

understanding of the dynamic-interdependent linkages between the different sectors of the

economy and the institutional agents at work within the society, namely households,

enterprises and the government.

Guide to the Report

The purpose of the paper is to provide an overview and a general understanding of the

DySAM and its potential for use. The paper starts by explaining various data issues, and

then describes the methodology in general and the new elements that DySAM introduces,

particularly its dynamic nature and the employment satellite account. Indonesia and

Mozambique are the first two cases for which a DySAM methodology has been developed

that take ILO‘s specific needs into account. These two countries serve as illustrations. The

last chapter focuses on simulation and impact analysis. This is followed by a conclusion on

the major findings.

9 Firstly, the degree of effectiveness of the DySAM depends on the quality, quantity and consistency

of the data used for it. This is not exclusive to DySAM, it is a shared condition, since, any serious

policy decisions should be based on, even though limited, empirical analysis. Secondly, it is

unacceptable and self-defeating to shy away from dealing with data problems (see point one)

because data do not improve themselves. The best approach is to start working with the existing data

to expose the kind of problems they have, since data refer to different periods, and times series need

to be crossed over with survey data; this would be the best way to improve existing data quality and

consistency. Hence, examining/testing the SAM and crossing it over with other data (SNA, LFS) can

provide good insights and thus make a significant contribution to finding objective ways to improve

it; e.g. the SAM helps to create a consistency between survey data and financial flows and even

physical data (employment). And thirdly, since most developing countries already have SAMs, there

is a basis to upon which to build.

5

1 Dynamic Sam Methodology

1.1 Overview

The term ‗Dynamic SAM‘ (DySAM) describes an instrument based on an existing

‗static‘ Social Accounting Matrix (SAM) for any economy and the available up-to-date

time series of national accounts (SNA). The methodology of building a Dynamic SAM

entails the following elements:

Re-verification of the existing static SAM: The starting point for deriving a dynamic

SAM is the availability of a balanced static SAM. In line with convention, all desirable

properties (including balances of the SAM accounts) of the static SAM are assessed. The

base static SAM is referred to as [s0]. If required, the static SAM is thoroughly adjusted to

conform to the desirable properties for subsequent dynamic transformation.

Constructing a time series of macro control totals: This is done for each block of

accounts of the static macro SAM (e.g. Commodity-Activity,10

Factors-Institution,

Institution-Institution, etc.) using the available SNA time series for the economy and using

the static macro SAM shares to interpolate for those accounts not available in the SNA.

This is entitled the ‗Dynamic Macro SAM‘ and labeled as [d0]. This resembles the concept

of a National Accounting Matrix or aggregated macro SAM.

Constructing the dynamic sectoral SAM (DySAM): The DySAM algorithm uses the

structures derived from the original base static SAM [s0] (intermediate use, factorial and

institutional income distributions, etc) and constrains them to the control totals derived in

[d0]. Since the controls totals are different from year to year, the algorithm proceeds to

generate interior structures for each block, which are compatible and consistent throughout

the economic system as typified by the SAM. This year-by-year iterating, consistency

seeking, circular process can be characterized as a step-by-step loop process for

generating/updating the SAM and making structural adjustments. The process:

1. Provides the necessary information for all subsequent years up until the last year for

which the consistent data are available in the database [d0]. The DySAM algorithm also

performs/imposes ‗reality checks,‘ which requires that the input data sets (historical

SNA data and the SAM) and the estimated DySAM follow the recommended

accounting practices (the 1993 UNSD SNA recommended conventions).11

2. Computes the sequence of multipliers (forward/backward/decompositions): to gain

insight into the evolution of the dynamic and interdependent processes that generates

the observed economic time series.

10 The commodity activity dichotomy does not appear in the SNA and is not common in I-O, it was first introduced in the I-O framework by Alarcon (see Alarcon et.al. 1984 and Chapter 4 in Alarcon et.al. 1991). It was formalized for the SAM framework by Pyatt, he states “activities have to be understood as a process, while a commodity is a good or service” and is in-bedded in industry technology vs. commodity argument. See Pyatt Sec. 2 (1994). 11 Among the most important aspects is the non-negativity of the values for input use, final consumption or exports.

6

1.2 Database and data handling

This subsection summarises the process and methods for deriving consistent time

series of SNA control totals and features of the static SAM. Illustrations will refer to either

the Indonesia 2005 SAM or the Mozambique 2001 SAM and will be indicated as

appropriate.

1.2.1 Consistency verification

Although, consistency is a shared characteristic of all serious modelling efforts, it

acquires added importance when deriving the dynamic SAM multipliers sequences. For

example, all the data made available from the Governments of Indonesia (GOI) and

Mozambique (GOM) for DySAM implementation has been checked against the consistency

framework requirements. Two iterative rounds of data refinement have been performed.

Each successive round of iteration refocused the investigation and allowed new data

anomalies to be identified. Reconciliation iterations are very fruitful exercises, and the

reconciliation process serves two important ‗goals'.

1.2.2 Derivation of consistent macro data series

The dynamic SNA macro SAMs for a time series (t=1...n) are derived using the

information provided mainly by the SNA of a country. More specifically, the following

accounts are required to generate the macro data sets for any economy:

The real side (supply, production and demand).

Government budget.

Money and credit.

Balance of payments.

Population, and

Sectoral data: real and nominal GDP and employment.

The numerical specifications of accounting frameworks (SNA, I-O, SAM) are needed,

in order to accurately represent the economy of a given country and this depends on the

availability of consistent and balanced data sets. Experience demonstrates that even when

extensive data are available, there are barriers due to inconsistencies and failure to find a

balance across different components of the data. It is thus essential to assess the consistency

features of a country‘s data before embarking on constructing a DySAM. Derivation of

consistent macro data sets should be conducted in accordance with the following three

steps:

1. data collection activities of all relevant data, SNA, I-O and SAM;

2. completeness and consistency assessment of the available data sets; and

3. derive consistent data sets using the DySAM data module

Subsequently, the relevant macroeconomic data needs to be compiled in a Macro

Social Accounting Matrix framework (macro-SAM) and Flow-of-Funds framework (FoF),

in order to assess the intra and inter-accounts consistency of all the official data sets.

7

Macroeconomic data sets are generally of two types, namely flows and stocks. All

values of the variables on the real side (i.e. production (activity/commodity); institutions,

government budget; and balance of payment accounts are flow variables. All monetary

variables are reported as stock variables.12

1.2.3 Source data compilation and building consistency

The activities of data review and consistency building are crucial for the successful

numeric calibration of the DySAM. All the data made available and provided by

governments for the DySAM construction need to be checked against the consistency

framework requirements (see below). As part of the process, two iterative rounds of data

refinement are usually performed. Each successive round of iteration refocuses the

investigation and allows new data anomalies to be identified. Reconciliation iterations are

necessary and are very fruitful exercises, and the reconciliation process serves two

important goals, namely:

1. Upon completion, the government will have an improved and solid base of reliable and

consistent country data upon which to build quantification systems. These data will be

balanced across all macroeconomic accounts and, importantly, will retain the economic

character of the original country‘s ‗source data‘.

2. The reconciliation exercise helps the government to identify specific targets for future

data strengthening activities.

Each new cycle of data changes requires a re-working of the ‗data module,‘ including

reality checks (e.g. non-negativity restrictions and compliance with SNA and other

accounting recommended practices) and balance checks across all accounts. The data are

processed series-by-series to locate any new data anomalies or reconciliation needs.

Compilation and building of DySAM data set for a DySAM model proceeds according

to the following iterative steps outlined in the table below. Each of the iterations requires an

12

a. Barring a few exceptions, almost all the flow variables should, in principle, depict either a positive value or a zero value (i.e. +, 0). Stock Change, although a flow variable, is an exception that may depict any one of these values (i.e. ─, +, 0). b. Almost all the monetary stock variables should, in principle, depict a positive value (i.e. +). Flow values derived from the monetary stock values may, however, depict any one of these values (i.e. ─, +, 0). c. Any deviation from the above two conditions needs careful attention during the compilation process of data sets.

Box 1: The advantages of using a macro-SAM /FoF framework for handling data

1. It assesses data consistency using a single-entry system (maximising the efficiency of a ‘SAM accounting’ approach).

2. It examines overall data consistency by linking the real side information of current institutions (macro-SAM) to the financial flows of the institutions (FoF).

3. It measures resource gaps of current institutions and subsequent gap financing by resources drawn from institutions within the purview of an integrated framework.

4. It is scalable. The resolution of the consistent data structures, embedded in the SAM/FoF frameworks, may be increased to be commensurate with specific country data sets. This creates a reliable data baseline for policy modelling efforts.

8

intensive review of the specific changes and checks that have to be imposed on the entire

data set.

Table 1: Data development steps

Step Description

Data collection

A data collection template is designed, which contains six accounts. The six templates include the following information: The real side (supply, production and demand) Government Budget Money and Credit Balance of Payments Population Sectoral Data-Real and Nominal GDP and Employment The government/national institutions provide ‘official’ data sets covering a requested period and data gaps are identified.

Compilation and building – First iteration

The DySAM team compiles the macro data sets and includes complement placeholder values (i.e. proxies for missing and obvious erroneous values, such as deficit financing information), which can be drawn from various sources such as the International Monetary Fund, World Bank, UNSD. The intra block (e.g. budget and BOP) and inter-block inconsistencies are corrected in the DySAM data module in a way that the differences between the original values of the variables and the revised (adjusted) values are kept to a minimum. Major characteristics of the first complied data set are assessed and reported to the government counterparts for their consideration and feedback.

Compilation and building: Iteration 2

A second iteration is conducted when the team incorporates new information and revises placeholder values (i.e. after discussing with the data producing agencies) into the data module through direct contacts with data providers. The second round of iteration generates a significantly improved data set that is used for constructing the DySAM.

It should be noted that good communication between the DySAM team and the

national institutions can help reduce the overall number of data issues in the given country.

This process of the elimination and refinement of the original ‗source data‘ is quite

common and is necessary, in order to acquire reliable and consistent country data that can

be used to build important and useful quantification systems.

Most of the time, SAMs require some reworking, such as the re-ordering of accounts,

adjusting valuation by allocating trade margins (TM) and grouping the institutional

accounts and converting valuation into producer‘s prices. Re-ordering refers to organizing

the accounts to follow the circular economic flow (see figure 1). This is mainly done for

analytical reasons, as is easier to follow the cascading flow of income throughout the

economy. The consolidated Macro SAM, which is re-ordered, fully balanced and valued at

purchaser‘s prices, is used to benchmark the DySAM. The example below further illustrates

the process.

9

Box 2: Re-ordering, adjustment and conversion of SAM 2001: The case of Mozambique

The first task was to re-order the Mozambican SAM accounts in a way that follows the circular economic flow. Then the separation into endogenous and exogenous for the modelling process is made.

The Mozambique SAM was valued at purchaser prices and, contrary to convention, the TM were placed in three rows in the intersection of the commodity-activity mapping and without keeping the zero balance (i.e. double counting). Therefore, the three TM rows were collapsed into a single row and transferred to the trade row entry in the commodity-commodity mapping. Furthermore, the row sum was placed with a negative, in order to maintain the zero row wise balance, in the trade-trade diagonal entry. These meant that the commodity entries were reduced to 27 and the double counting was thus eliminated.

Elements of the institutional account, which were previously dispersed, were grouped together in a single account. Following the most conventional presentations of SAMs, the capital account was placed after the domestic current accounts and before the consolidated rest of the world account. Again following convention, the entry that accounts for the closure of the economic systems—the ‘Rest of the World’ (foreign) savings—was kept at the intersection of the Savings-Investment account row and Rest of the World column.

The next step was to convert the SAM to producers’ prices. When all commodities carry the same trade margin, the TM collapsed row entry is used to derive the TM matrices for intermediate, final household consumption and enterprises to match the 27 SAM commodity input entries and the 167 using activities and final demand. Since all the remaining elements of the final demand were presented in single column vectors, e.g. government, gross capital formation and exports, the application of the mentioned assumption presented fewer problems.

The fact that some SAM breakdowns are not homogeneous is problematic for DySAM modelling. For example, the Mozambique SAM presented some activities broken into a combination of sub-classifications, namely urban, rural, north, south and Maputo; this resulted in some activities presenting seven sub-classifications while others presented only four. If the SAM was used at such full disaggregation, for intermediate and household demand, the TM row would have to be blown out into 27 by 167 and 27 by 35 entries, correspondingly. Instead, classifications were streamlined, with the main purpose being to make it simpler and easier to understand. With that in mind, and for the purposes of the DySAM, economic activities were collapsed into three main regions (Rural - North, Centre and South; Urban - North, Centre and South; and Maputo). A larger number of sub-classifications did not necessarily add any value or clarity to the analysis and the data behind it became very shaky.

The final SAM of Mozambique has six main accounts. As a result of the conversion to producers’ prices, the macro values and totals for commodity accounts, production activities and MCM cannot coincide with the original entries valued at purchaser’s prices. Furthermore, the original separate TM entries were deleted because they became redundant. For reasons that are not clear discrepancies between the row totals (incomings) and the expenditure totals (outgoings) were found and these had to be addressed before the SAM could be made consistent.

The adjustments and conversions made throughout the source data compilation and

consistency process reflect recommendations found in SNA conventions and the

requirements of the DySAM. Additionally, the SAM had to undergo a series of reality

checks. These reality checks are associated with a stricter and more specific observance of

the SNA and other recommendations and conventions. Furthermore, SAM modelling,

maths and programming restrictions related to the DySAM‘s dynamic algorithm need to be

taken into consideration as well.

The SAM modelling reality check is meant to indicate whether empty intra-account

intersections in the base SAM are the result of design, default or definition. Default

concerns those entries that could be booked differently, for instance negative net taxes,

indicating that subsidies greater than taxes appear as zero in the subsidy cells; they are zero

by design. In contraposition, there are accounts which do not have transactions, but in a

cascading direction the zero block intersection has to be empty; they are zero by definition.

The importance of such distinctions lies in the fact that no simulations are possible via

those intersections that are zero by definition.

There are other entries to which reality checks must be applied. These reality checks

are made to confirm adherence to more specific SNA conventions. In the case of fixed

capital formation, reality checks need to make sure that only those that are indicated in the

UNSD SNA 1993 recommendations (agriculture (sheds, silos, drainage, etc. when built by

famers themselves), the planting of fruit trees, livestock, machinery, equipment and

10

transport equipment production and construction) should show positive entries. Exceptions

to this convention are cases in which the government defence sector builds its own

complexes and barracks or when education and health sectors build their own physical

facilities. The forestry account can also be counted as part of fixed capital formation when

re-forestation programmes are operating. As a result of balancing efforts, the account can

show entries in other commodities and/or activities, and some of the entries may be

negative. Finally, there are accounts or single entries that are placed simply for accounting

reasons: among the former, there may be full import matrices by demand type, primary,

secondary and disposable income modules; among the latter, negative entries in main

diagonal cells. Since, they do not add analytical value, they are collapsed and/or deleted.

2 Dynamic SAM and satellite modules

2.1 Derivation of Dynamic Macro SAMs

The DySAM algorithm requires a time series (t = 1... n) of macro SAMs that are

consistent with SNA macro-meso control totals. It also requires using the structure of the

latest available static SAM (s0). This dynamic macro SAM is referred to as [s3 (t)] and it

contains all the macro controls that are necessary to build the DySAM. However, as all the

macro controls required for module [s3 (t)] are typically not available in the SNA dataset,

the construction of [s3 (t)] is undertaken in two steps, namely:

First - build the consistent macro data set based on the available SNA information. This is

referred to as the SNA macro SAM [d0 (t)].

Second - merge [d0 (t)] with the static SAM for the base period [s0] to generate [s3 (t)].

The derivation procedure of the dynamic macro SAM is diagrammed below.

Figure 2: Derivation procedure of a dynamic macro SAM

SNA SAM (Derived)

d0ij(t)

Non-zero entries Y <

X

Dynamic SAM (Derived)

s3ij(t)

Where ij denote dimension

It contains X number of

non-zero entries

Base Static SAM (Given)

s0ij

Where ij denote

dimension

It has X number of non-

zero entries

Static SAM Structure

share s0ij

11

T

h

i

s

m

e

t

h

o

T

h

i

s method has been used for all the other elements where no direct one-to-one

correspondence could be found between SNA-SAM elements and elements of the dynamic

SAM. For instance, savings of institutions, which are derived as the residual between total

receipts and total payments, have been used to close the accounts. Finally, the identity

between savings (i.e. derived from the savings of four institutions) and investment has been

enforced, in order to ensure the overall balance of the dynamic SAMs for each year of the

reference period. The estimated dynamic macro SAMs for Mozambique for selected years

are reported in the Appendix I.

2.2 SAM Transformation Methodology

Once the dynamic macro SAM has been derived and adjustments to the static SAM

have been completed, the adjusted static SAM is transformed into a dynamic SAM by

linking it to a dynamic macro-meso control framework, the ‗DySAM Data Module‘. The

DySAM Data Module is specially designed to generate the macro-meso controls for the

static SAM.

As the control flows are incorporated into the static SAM it becomes dynamic and

moves forward in time (2001-2008). This ensures that the DySAM has the following

attributes:

Establishment of the dynamic flows across each account over the time period.

Establishment of consistency for each year of the time period.

Separation of DySAM accounts into ‗endogenous‘ and ‗exogenous‘ categories.

Generation of dynamic SAM multipliers decompositions to estimate direct/intra-account

transmission effects within the same account (e.g. injection in commodities and impact

on commodities) and indirect/induced effects among accounts (e.g. higher wages

stimulating higher consumption and thus tax collection). Quantification of these

dynamic transmission chains (intra-account and induced) allows SAM-based dynamic

models to be constructed.

2.3 Derivation of Dynamic Sectoral SAM

In the context of the issues above, once the static SAM is thoroughly adjusted and the

dynamic macro SAM has been constructed, all necessary inputs are ready for building the

dynamic sectoral SAM with the same resolution as the baseline static SAM.

Box 3: The relationship between SNA and SAM: Case of Mozambique

In the case of Mozambique, the non-zero elements of static 2001 SAM [s0] number 37 (after adjustment), while the elements of SNA macro SAMs [d0 (t)] for the period 2000-2008 period number just 15. The one-to-one correspondence between the dynamic SNA-SAMs and the static 2001 SAM is established for these 15 common elements only. The estimates of the remaining 22 elements—which along with the already defined 15 elements would constitute the entire set of non-zero elements of the dynamic macro SAMs—have been derived using the structural information of the static 2001 SAM and the controls of the dynamic SNA-SAMs [d0(t)].

For instance, value additions are defined as capital, labour and land value added in the static 2001 SAM of Mozambique. However, this breakdown of value added is not reported in the SNA. Value added is reported as a consolidated figure. Thus, the shares of these three types of value added in total value added as observed in 2001 are used to derive the three types of value added for each year of the reference period, i.e. 2000-2008.

12

2.3.1 DySAM Algorithm

The algorithm is designed to generate full SAMs for each year. The process entails

four main steps, namely: 1) build the data inputs13

for the DySAM as described above; 2)

raise the static SAM with the corresponding dynamic macro14

controls, which generates a

sequence of SAMs that are balanced at the macro level but are unbalanced15

at the interior

sectoral account levels nesting within the corresponding macros; 3) the balancing16

of

accounts at the sectoral level, which starts with the commodity-activity blocks by

initializing an iterative sequence of demand-side adjustments with supply anchors, a key

assumption being that supply is more robustly estimated than demand; and lastly, 4) matrix

rebalancing, which ensures the balance of components sub-matrices using the RAS

technique17

, thereby reducing sectoral imbalances, over-time, to the infinitesimal.

To illustrate the DySAM process the algorithm flow chart referring to Indonesia is

used; this shows the steps of DySAM construction.

13The two principal data inputs are (1) the static baseline SAM and (2) the dynamic Macro SAM (s3

(t)) both of which have identical non-null transaction blocks.

14The macro controls are of three types: 1) the sum of a matrix, such as input use; 2) the sum of a

vector, such as fixed capital formation; or 3) a scalar value such as foreign savings.

15 This imbalance is because the observed structural dynamics of the economy displayed in the

macro control time series diverges from that inherent in the baseline static SAM. However, this is

the ―best/least discrepant initial estimate‖ of the DySAM based on current data. To also be a

―feasible estimate‖ all sectoral accounts must also balance. This task is accomplished in steps (3) and

(4), which are sequential and convergent iterative steps in estimating the (balanced) DySAM.

16It follows directly that the sum of sectoral imbalance in the initial DySAM estimate will be zero by

design since they are balanced (that is zero) at the macro level. This property of the magnitude of

sectoral imbalances is also preserved in the sequence of all balancing iterations. It is crucial to ensure

that the sequential iterative steps are convergent and find closure for all sectoral accounts of the time

series of SAMs which comprise the estimated DySAM.

17This step is invoked for accounts whose components are matrices, such as input use or household

final demand.

13

Figure 3: Dynamic SAM Flow Chart: Indonesia

2.3.2 DySAM Algorithm Comparison for Indonesia and Mozambique

The algorithm to build a DySAM has been used successfully for Indonesia and

Mozambique. This section compares the four steps of the DySAM building process for

these two countries18

.

Step 1: Build Input Datasets. The sectoral static SAM for Indonesia refers to the

year 2005 and its dimensions are 84x84 whereas for Mozambique it refers to year 2001 and

its dimensions are 183x183. The dimensions of the consistent dynamic macro SAMs for

both countries are 11x11 and refer to the period 2000 to 2008.

Salient features of building the DySAM for Indonesia and Mozambique follow.

Table 2: DySAM Algorithm Comparisons – Step 1

Country Base Year Static SAM

SAM Dimension Time Series of Macro SAMs

Macro SAM Dimensions

Mozambique 2001 183 x 183 2000-2008 11 x 11

Indonesia 2005 84 x 84 2000-2008 11 x 11

18Recently, a DySAM for Venezuela has also been completed.

Dynamic Macro

SAM (2000-2008)

Baseline Static

SAM 2005

x1: 11x11 s3: 84x84

Build Input Datasets1

Initial DySAM

(Sector Imbalance)

x2: 84x84

Raise the Static SAM

using Dynamic Macro

Controls

2

Initalise Demand

Side Iterating

Adjustment with

Supply Anchor

(Co+A)

3

j0 (51x84) j16 [51x84]Iterations (16)

Imbalance Range

(1% to 28%)

Imbalance Range

(< 0.02% )

Reduce imbalance to

infinitessimal using

the RAS

4RAS Matrices

(Co A), (iH FL),

(Co iH) Error Range

(<1.0E(-14) %)

Balanced DySAM

(x4)(84x84)

Flow Chart: Dynamic SAM Algorithm

14

Step 2: Raise the Static SAM using Dynamic Macro Controls. This step generates

the initial DySAM sequence for 2000 to 2008, which balance at the macro level but are

unbalanced at the sectoral level. Essentially, in this step all prior information that is to be

preserved in the DySAM is loaded. For instance, most countries, including Indonesia, have

more disaggregated information on the supply side, such as value added, taxes and imports.

This supply-side information may be incorporated19

in the initial DySAM by using, as

raising factors, vector controls that sum up to the corresponding macro controls.

On the demand-side, the accounts implicated span the commodity and activity space,

and for Indonesia20

have the dimensions 51x84. Correspondingly, on the supply-side in the

matrix layout these accounts have the dimensions 84x51. The relative discrepancy between

demand and supply at the sectoral level in step 2 ranges over 1 per cent to 28 per cent.

Table 3: DySAM Algorithm Comparisons – Step 2

Country Initial DySAM Demand Side Dimension

Supply Side Dimension

Demand/Supply Imbalance

Mozambique 2000-2008 104 x 183 183 x 104 -26% to 29%

Indonesia 2000-2008 51 x 84 84 x 51 1% to 28%

Step 3: Balance commodity-activity accounts. This is done by initializing an

iterative sequence of demand-side adjustments with supply anchors. The demand vectors

implicated in step 3 iterations are the intermediate demand vector (Co A) and the final

demand block of column vectors (Co iH), (Co iG) (Co Cc) and (Co wC). These are the

component demand vectors that are balanced with respect to the supply vectors (Total Row

Commodity) and (Total Row Activity).

For Indonesia, 16 iterations reduced the initial relative discrepancy between demand

and supply from a maximum of 28 per cent to less than 0.02 per cent - a 1,400-fold

reduction.

Table 4: DySAM Algorithm Comparisons – Step 3

Country Initial DySAM Demand/Supply Imbalance

Number of Iterations Imbalance at final iterate

Mozambique 2000-2008 -26% to 29% 32 <|4.8 e-03|%

Indonesia 2000-2008 1% to 28% 16 <0.02%

19Preserving additional supply-side information on value-added, imports and taxes overtime in the

DySAM requires that adjustments of sectoral imbalances in the commodity-activity accounts take

place on the demand-side. This is done in step 3 of the algorithm.

20 Please see

Figure 4: The dynamic SAM for Indonesia (2000-2008)

15

Step 4: Ensure the balance of components sub-matrices using the RAS21

technique and

reduce sectoral level imbalances to infinitesimal. The matrices entering the accounts of the

Indonesian DySAM are given in the table below.

Table 5: Matrices for accounts of the Indonesian DySAM (2000 – 2008)

Account Matrix description Code Matrix size RAS Iterations

Commodity Commodity - activity intermediate inputs table Co A 24 x 27 40

Household final consumption matrix Co iH 24 x 10 80

Activity Activity - commodity domestic supply table A Co 27 x 24

Factor incomes Factor incomes the factor labour matrix FL A 16 x 27

Household labour income Household income from labour iH FL 10 x 16 80

Intra household transfers Intra household transfers iH iH 10 x 10

Source: Part I: Data Report: Indonesia (091202): Indonesia Dynamic SAM Data Report; Derivation of Consistent Data Set.

Three of these six matrices namely, the supply table (A Co), the labour value added

(FL A) matrix, and the inter-household transfer matrix (iH iH) are not implicated in the

RAS iterative adjustments. The matrices implicated in RAS balancing are (Co A) the

intermediate input table, (Co iH) the household final consumption matrix and (iH FL) the

matrix of household income from labour requiring, respectively, 40, 80 and 80 iterations to

achieve convergence in all accounts over the period 2000-2008.

Table 6: DySAM Algorithm Comparisons – Step 4

Country Rebalanced Matrices(RAS)

Dimension Number of RAS Iterations

Convergence at final iterate

Mozambique ( Co A) 27 x 77 40 <|5.0 e-05|%

( Co iH) 27 x 35 40

Indonesia ( Co A) 24 x 27 40 <|1.0 e-14|%

( Co iH) 24 x 10 80

( iH FL) 10 x 16 80

The verification that balance is achieved for all accounts for each year (2000-2008) is

reported in the mentioned reports; see Appendix under 3.

In general, there is a connection between the accuracy of baseline country data, the

number of iterative sequences and the number of blocks requiring RAS balancing. The

21RAS refers to a bi-proportional iterative method used to estimate non negative matrices on the

basis of limited information, the acronym reflect the right-hand-side of the original equation or (ri

aijsj).r and s are row and column multipliers respectively.It was originally proposed by Bacharach

(1970) as part of the Cambridge Growth Project lead by R. A. Stone during the 60s. Extensive and

exhaustive reviews of this technique can be found in Lahr and Mesnard (2004) and Kratena and

Zacharias (2004). Since then, there have been innumerable ‗improvements‘, those interested may

please refer to Oosterhaven (2005) or Fofana et al. (2002) with the generalized RAS (GRAS) for

updating I-O. In order to update SAMs, other explicit methods have been developed by, among

others, Robinson and El-Said (2000) and Robinson et. al. (2001).

16

character of these connections will differ across countries, as well as within countries when

estimation procedures are revised.

Figure 4: The dynamic SAM for Indonesia (2000-2008)

(TC-TR) A

(iG iG)

(A iSu)

(wCu iH)(wCu A) (wCu FL) (wCu Fk) (wCu Cc)(wCu iSu)(wCu iCr) (wCu iG) 0

(Co Cc)) (Co TC)

(iG TC)

(A TC)

(FL TC)

(Fk TC)

(iH TC)

(iCr TC)

(iTx TC)

(iSu TC)

(cC TC)

TC

(TR wCu)

(TC-TR) wCu

1

Commodity

Activity

ACCOUNT

Factor Labor

Factor Capital

Corporate

Household

Government

Subsidy

Tax

Capital A/C

Total Row/Col

Balance

Dimension

iH

Co

FK

iCr

iG

Cc

iTx

iSu

FL

Label

TR

Bal

A

(iTx Co)

0

0

0

0

Co

(TR Co)

(TC-TR) Co

24

0

(A Co)

0

0

0

0

0

0

0

0

A

(TR A)

27

(Co A)

0

(FL A)

(Fk A)

0

0

0

(iH FL)

0

0

FL

(TR FL)

(TC-TR) FL

16

0

0

0

0

0

0

0

(iH Fk)

(iCr Fk)

0

FK

(TR Fk)

(TC-TR) Fk

1

0

0

0

0

0

0

(iG iH)

(iH iH)

(iCr iH)

0

iH

(TR iH)

(TC-TR) iH

10

(Co iH)

0

0

0

(cC iH)

0

(iG iCr)

(iH iCr)

(iCr iCr)

0

iCr

(TR iCr)

(TC-TR) iCr

1

0

0

0

0

(cC iCr)

0

(iH iG)

(iCr iG)

(iSu iG)

iG

(TR iG)

(TC-TR) iG

1

(Co iG)

0

0

0

(cC iG)

0

(iG iTx)

0

0

0

iTx

(TR iTx)

(TC-TR) iTx

1

0

0

0

0

0

0

0

0

0

0

iSu

(TR iSu)

(TC-TR) iSu

1

0

0

0

0

0

0

0

0

0

Cc

(TR Cc)

(TC-TR) Cc

1

0

0

0

0

Factor (F) Institutions (i)

WorldCosolidatedCurrent A/C

wCu 0 (wCu TC)

(Co wCu)

(iTx wCu)

(iG wCu)

(iH wCu)

(iCr wCu)

0

wCu

1

0

(FL wCu)

(Fk wCu)

(cC wCu)

0

17 14

1 2 3 4 5 6 7 8 9 10 11 12#

1

2

3

4

5

7

8

9

10

6

11

12

#

84

24

27

16

1

10

1

1

1

1

1

1

1

1

84

17

Figure 5: The dynamic SAM for Mozambique (2000-2008)

0

0

0

(wC iC)0 0 0 (wC Cc)0 0 0

(Co Cc) (Co TC)

(iG TC)

(A TC)

(FL TC)

(Fk TC)

(iC TC)

(iH TC)

(iT TC)

(cC TC)

TC

(TR wC)

(TC-TR) wC

1

Commodity

Activ ity

ACCOUNT

Factor Labor

Factor Capital

Household

Corporate

Government

Tax

Capital A/C

Total Row/Col

Balance

Dimension

iC

Co

Fk

iH

iG

Cc

iT

FL

Label

TR

Bal

A

(iT Co)

0

0

0

Co

(TR Co)

(TC-TR) Co

27

0

(A Co)

0

0

0

(iT A)

0

0

0

A

(TR A)

(TC-TR) A

77

(Co A)

0

(FL A)

(Fk A)

0

0

0

0

(iH FL)

FL

(TR FL)

(TC-TR) FL

23

0

0

0

0

0

0

0

(iC Fk)

0

Fk

(TR Fk)

(TC-TR) Fk

3

0

0

0

0

0

(iT iC)

(iG iC)

0

(iH iC)

iC

(TR iC)

(TC-TR) iC

3

0

0

0

0

(cC iC)

(iT iH)

0

0

0

iH

(TR iH)

(TC-TR) iH

35

(Co iH)

(A iH)

0

0

(cC iH)

0

0

(iC iG)

(iH iG)

iG

(TR iG)

(TC-TR) iG

1

(Co iG)

0

0

0

(cC iG)

0

(iG iT)

0

0

iT

(TR iT)

(TC-TR) iT

4

0

0

0

0

0

0

0

0

0

Cc

(TR Cc)

(TC-TR) Cc

2

0

0

0

(cC cC)

Static SAM for Mozambique 2001 (Producer Prices/National)

02/08

Factor (F) Institutions (i)

World Current

A/CwC (wC Co) (wC TC)

(Co wC)

0

0

0

(iH wC)

wC

1

0

(FL wC)

0

(cC wC)

0

33 43

1 2 3 4 6 7 8 9 10 11 12#

1

2

3

4

6

8

9

10

7

11

12

#

27

77

23

3

3

1

4

2

35

1

1

183

Layout & Dimensions

0

0

0

(iH Fn)

Fn

(TR Fn)

(TC-TR) Fn

7

0

0

0

5

(Fn TC)Factor Land Fn 0 (Fn A) 0 0 0 0 (Fn iG) 0 0 05 7 0

<x1 ( Co A) Co

r 1 A c1>

<x1 ( Co iH) Co

r 1 iH c1><x1

( Co iG)

Co r 1 iG

c1>

<x1 ( Co Cc) Co

r 1 A Cc c1> <x1

( Co

wC) Co

r 1 A wC

c1>

<x1

( Co

TC) Co

r 1>

Set: x1 (r1, c1)

<x1 ( A Co) A r 1

Co c1>

<x1 ( A iH) A r 1 iH

c1>

<x1 ( A

TC) A

r 1>

<x1 ( FL A) FL

r 1 A c1><x1

( FL

wC) FL

r 1 wC

c1>

<x1

( FL

TC) FL

r 1>

<x1 ( Fk A) Fk

r 1 A c1>

<x1

( Fk

TC) Fk

r 1>

<x1 ( Fn A) Fn

r 1 A c1>

<x1

( Fn

TC) Fn

r 1>

<x1

( Fn iG)

Fn r 1 iG

c1>

<x1 ( iC Fk) iC r 1

Fk c1>

<x1 ( iC

iG) iC r 1

iG c1>

<x1 ( iC

TC) iC

r 1>

<x1 ( iH FL) iH r 1

FL c1>

<x1 ( iH Fn) iH r 1

Fn c1>

<x1 ( iH iC) iH r 1 iC

c1>

<x1 ( iH

iG) iH r 1

iG c1>

<x1 ( iH

wC) iH

r 1 wC

c1>

<x1 ( iH

TC) iH

r 1>

<x1 ( Tr iG) iG

c1><x1 ( iG iC) iG r 1 iC c1> <x1 ( iG iT) iG r 1 iT c1>

<x1 ( iT Co) iT r 1

Co c1>

<x1 ( iT A) iT r 1 A

c1>

<x1 ( iT iC) iT r 1 iC

c1>

<x1 ( iT iH) iT r 1 iH

c1>

<x1 ( iT

TC) iT

r 1>

<x1 ( cC iC) cC

r 1 iC c1>

<x1 ( cC iH) cC

r 1 iH c1>

<x1

( cC iG)

cC r 1 iG

c1>

<x1

( cC

wC) cC

r 1 wC

c1>

<x1 ( cC cC) cC

r 1 cC c1>

<x1

( cC

TC) cC

r 1>

<x1 ( wC Co) wC r 1 Co c1> <x1 ( wC iC) wC r 1 iC c1> <x1 ( wC cC) wC r 1 cC c1>

<x1 ( wC TC)

wC r 1>

<x1 ( Tr iG) iG

c1><x1 ( Tr iC) iC c1> <x1 ( Tr iH) iH c1> <x1 ( Tr iT) iT c1> <x1 ( Tr cC) cC c1>

<x1 ( Tr wC)

wC c1><x1 ( Tr Co) Co c1> <x1 ( Tr A) A c1> <x1 ( Tr FL) FL c1> <x1 ( Tr Fk) Fk c1> <x1 ( Tr Fn) Fn c1>

<x1 ( TC- TR) iC r 1> <x1 ( TC- TR) iH r 1>

<x1

( TC- TR) iG

r 1><x1 ( TC- TR) iT r 1> <x1 ( TC- TR) cC r 1>

<x1

( TC- TR) wC

r 1><x1 ( TC- TR) Co c1> <x1 ( TC- TR) A r 1> <x1 ( TC- TR) FL r 1> <x1 ( TC- TR) Fk r 1> <x1 ( TC- TR) Fn r 1>

18

3 Derivation of dynamic SAM model for impact analysis

The move from a SAM data framework to a SAM model or multiplier framework

requires a specification of the SAM accounts as ‗exogenous‘ and ‗endogenous‘. Generally,

accounts intended to be used as policy instruments are made exogenous and accounts a

priori specified as objectives or targets must be made endogenous.

For any given injection into the exogenous accounts (i.e. instruments) of the SAM,

influence is transmitted through the interdependent SAM system among the endogenous

accounts. The interwoven nature of the system implies that the incomes of factors,

institutions and production are all derived from exogenous injections into the economy via

a multiplier process. The multiplier process is developed on the assumption that when an

endogenous income account receives an exogenous expenditure injection, it spends it in the

same proportions as shown in the matrix of average propensities to spend (APS). The

elements of the APS matrix are calculated by dividing each cell by its corresponding

column sum total and are referred as direct effects.

Table 7: Endogenous and exogenous accounts of a SAM

Co

mm

od

itie

s

Pro

du

cti

on

ac

tiv

itie

s

Fa

cto

r la

bo

ur

Fa

cto

r c

ap

ita

l

Ho

us

eh

old

s

Co

rpo

rate

Go

ve

rnm

en

t

Ind

ire

ct

tax

Su

bs

idy

Ca

pit

al

ac

co

un

t

Re

st

of

Wo

rld

Commodities

Production

activities

Factor labour

Factor capital

Households

Corporate

Government

Indirect tax

Subsidy

Capital account

Rest of World

Social Accounting Matrix

Endogenous Exogenous

En

do

ge

no

us

E

xo

ge

no

us

The multiplier analysis using the SAM framework helps to understand the linkages

between the different sectors and the institutional agents at work within the economy.

The economy-wide impacts of the exogenous shocks are examined by changing the

growth targets of exogenous vectors. More specifically, the differential ‗growth‘ targets can

be set under different ‗simulations‘ for various sectors, in order to estimate their effects on

output, value-added or GDP, consumption expenditure or basic needs and household

income.

19

If an exogenous shock is injected into the SAM system (e.g. rise in expenditure of

infrastructure programmes injected through the capital account), the first effect will be to

increase the income of the corresponding account (i.e. commodity or activity). The increase

will trigger effects, in a cascading manner, on all other endogenous accounts: factors,

households and basic-needs. Furthermore, those effects will spill over onto the exogenous

leaks block.

Therefore, the DySAM Multiplier Framework or DySAM Model provides a major

insight into the following issues:

1 Examination of the expenditure and technological structure of the sectors oriented

towards the production of basic intermediate and final goods and services (An).

2 Examination of the expenditure structures of factors of production, institutions and

the demand for goods and services of domestic and foreign origin (An).

3 Assessment of the impacts on the endogenous SAM accounts caused by exogenous

shocks in a clear and differentiated manner via the multipliers matrix Ma.22

4 Identification of key sectors, commodities, factors of production and institutional

accounts in the economy and quantifies the main linkages (total and partial backward

and forward).

5 Display of the dynamics of the production structure, factorial and institutional

income formation via the dynamic multipliers DyMa (yearly sequence of Ma

matrices).

6 Assessment of the effects of incomes of households and their impact on production

via their corresponding demand.

7 Evaluation of the effects of the government budget and its impact on production via

corresponding demand/supply variations.

8 Assessment of the effects on deficit/surplus of the government budget and of the

balance of payments resulting from government budget policy outlays and on the

external sector (BxMa).

9 Analysis of the direct and indirect impacts via An and (Ma-An), respectively.

10 Assessment of the intra-transfer (M1) as well as induced effects (O+C).23

11 Assessment of employment impacts by activities and across labour types and regions

using the Employment Satellite Module.

22 The Ma = (I - An)

-1 which is the matrix of cumulative production multipliers/technology

coefficients or the Generalized Leontief inverse, provides a numerical assessment of the direct and

indirect effects arising out exogenous injections on the output of each activity or commodity.

23 M1 = (I - A0)

-1 which are the intra-group or intra transfer effects. O = (M2 - I). M1 = M2 M1 –

M1 or open-loop multiplier measures the net extra-group effects or net cross-effects arising out of

an initial injection when it has completed a tour outside the original accounts without returning to it.

For instance, if the initial injection takes place into households it measures the effects into factor

incomes via demand expenditures WANTS, commodities and activities. C = (M3 - I). M2 . M1 = M3

M2 M1 – M2M1 or closed-loop multiplier, which measures the net contribution of circular effects or

net inter-group effects that arise after the original injection has completed a tour through all groups

of accounts and returned to the one where it originally started. It measures the effect of an injection

on household income after going through expenditures, commodities, activities and factor incomes.

For details on decomposition, please refer to Pyatt & Round (1979) and Defourny & Thorbecke

(1985).

20

12 Design of simulations in alternative scenarios and analysis on the simulations.

13 Basis for the development of computable general equilibrium models.

4 Simulation Design and Impact Analysis

4.1 Introduction

In this section the major characteristics of the dynamic multipliers are discussed. This

is required to understand the transmission mechanism at work in the country and is a pre-

requisite to designing, analysing and interpreting simulation scenarios. This analysis can be

used to formulate evidence-based policy stances and to prioritize specific exogenous stimuli

that support the policy stance.

The characteristics of an economy (Mozambique or Indonesia) are embedded in the

country SAM structure. These characteristics and the relative strength of various

transmission chains are revealed in an analysis of the ‗backward‘ and ‗forward‘ linkages

computed in the SAM multiplier module. The DySAM also provides insight into the

evolution of these characteristics.

The total backward linkages are the column sums of the multiplier matrix Ma.

Although grossly overestimated (see Sec. 200), they do provide valuable information about

the degree of integration within an account and with the other economic accounts of the

DySAM. This indicator, when employed with insight, can be used to determine which

activities contribute most to growth as a result of an exogenous increase in final demand.

Total forward linkages are the row sums of the multiplier matrix Ma. These indicators,

taking into account their caveats, can help to understand the importance of a commodity for

the rest of the economy in terms of intermediate demand and can be used as an indicator of

market availability. For example, a commodity that exhibits high forward linkages is said to

be important in the process of expansion or high growth. Its identification is, therefore,

pivotal in the economic management of potential bottlenecks.

The analysis presented will focus first on total backward linkage temporal

comparisons and account-wise partial backward linkages for the end year. This analysis

will be framed in the context of two stylised policy stances: one that would prioritise

growth and another that would prioritise income distribution.

4.2 Total backward linkages

In this section the estimated total backward linkages of the endogenous accounts are

reviewed. Two points need to be taken into consideration. Firstly, total backward linkages

are only the first of a series of indicators providing pointers for policy formulation. While

interpreting total backward linkages, it should be remembered that the aggregation of the

four account impacts into a total magnitude involves double, in this case in two instances,

counting.24

Secondly, the static backward linkages differ from the corresponding dynamic

24 This ―double counting‖ inherent in total backward linkages is not present in the account-wise

partial backward linkages. In the cases of Indonesia and Mozambique, the Commodity-Activity and

Factor Incomes-Institutional Incomes mean twice double counting.

21

backward linkage, by a scale factor reflecting the discrepancy between the SNA macro

estimates and the corresponding baseline SAM estimates.25

4.2.1 Dynamic backward linkages

The dynamic profiles of the backward linkages for Indonesia and Mozambique share

some salient features, namely the values of backward linkages of the endogenous accounts

reveal, on the whole, a decreasing trend from 2000 to 2004 or 2005 and a slightly

increasing behaviour in 2007 and 2008. From 2004/2005 onwards, some of these changing

behaviours may reflect, among other things, the growing/declining importance of the

imports, savings and government revenue and expenditure, which are treated as exogenous

accounts of the dynamic SAM model. It is known that the higher the values of exogenous

(or leak) accounts, the lower the degree of endogeneity and hence backward linkages.

The extent of changes in the value of backward linkages is significantly different for

each element of the endogenous account for each year of the reference period. This reflects

changes over time and strength of integration. The time evolution is not smooth, attesting to

the non-manipulative methodology used. The varying results are also a consequence of

supply constraints and the interplay of the domestic and foreign economic factors and

actors, as well as their response to changes in the general economic environment, including

changes in price relatives.

This observation further illustrates that the dynamic SAM captures the behaviour of

actors, entrepreneurs and households, among others. It shows that changes from year to

year to reflect changes in average propensities to spend (matrix An). This characteristic of

the DySAM lessens the need to introduce expenditure elasticities as a way to parameterise

the move from a ‗behaviour less‘ (static) accounting multiplier SAM model to the fixed-

price SAM model. This is because an equivalence exists between income elasticities

adjustments and changes over time captured in the DySAM.

4.2.2 Total backward linkage comparison

Dynamic multiplier estimates (Ma) are available for the period 2000-2008 and the

corresponding static multipliers estimates refer to the 2005 ‗baseline‘ SAM for Indonesia.

To analyse changes over time in the Indonesian economy, it is necessary to start with a

snapshot comparison of the total backward linkages for 200826

with the static backward

linkages for 2005. These are presented in the bar graphs (see Figure 7-11, ILO, 2010b).

These charts display the total backward linkages for the component elements of each block

of endogenous accounts, namely commodity (Co), activity (A), factor (Fp), household (iH)

and company (iC). The entries in each of these bar graphs displays the magnitude of the

total multiplier for each element of the respective block and they are sorted in ascending

order27

on the values for 2008.

25 Please see the corresponding countries‘ data reports. Clearly, if the SAM for 2005 or 2001 had

been used, correspondingly for Indonesia and Mozambique, to benchmark their SNA estimations

this scale discrepancy would not have been present and the two estimates would have coincided.

26 These estimates are computed in the dynamic multiplier module. Please also see Appendix, 2.

27 This presentation mode permits convenient visual detection of shifts in ordering between 2001 and

2008 pointing to differences in the overtime evolution of components elements. This may, in turn,

22

Static 2005

Dynamic 2008

Compare Total Commodity Backward Linkage

Ma(Tr Co): Ascending Order

4 6 8 10 12

c CoalMetalPetrol c5

c ChemFertClayCement c5

c PaperPrintTranspMetal c5

c RealEstate BusinessSrv c5

c AirWaterTrp Communicatn c5

c OthIndivHHSrv c5

c ForestHunt c5

c ElecGasWater c5

c BankInsuranceSrv c5

c WeaveTextileGarmentLeather c5

c HotelAffairs c5

c Construction c5

c Fishery c5

c FoodDrinkTobacco c5

c Storage OthTrpSrv c5

c Wood c5

c TradeSrv c5

c LandTrpSrv c5

c MiningQuarry c5

c Livestock c5

c GovDefEduHlthFilm OthSocSrv c5

c OthAg c5

c Restaurant c5

c Crops c5

For example, for Indonesia (see Figure 6: Indonesia Total Backward Linkage of

Commodity Account Figure ), a feature of all the 2005 linkages is that they are higher than

the 2008 estimates in all account blocks. This is a result of the noted discrepancy between

the SNA macro estimates and the corresponding baseline SAM estimates, resulting in a

pervasive upward bias in the (static) 2005 linkage estimates. The magnitude of the bias is

not similar in all estimates and is, on the whole, lower for Mozambique. It is reported that

for both countries, the linkages are higher for the commodity and activity blocks and lower

for the factor and institution blocks.

Figure 6: Indonesia Total Backward Linkage of Commodity Account

The sizes of commodity

backward linkages for 2005 static

SAM (red bar) were all lower

than those for generated by the

DySAM for 2008 (blue bar). The

lowest 2008 is 3.8 and for 2005

4.09, at the other end the highest

for 2008 is 7.36 and for 2005

7.65. For both years the values of

the backward linkages of the top

six activities (i.e. crops,

Restaurant, Other Agriculture

Mining-Quarry, Government etc,

Livestock and Trade) are above 6

both under the static and dynamic

simulations. Given their high

potential these commodities

should be targeted if growth

enhancement is the strategy of the

government.

Lowest 5 commodity

backward linkages ranged

between 3.8 and close to 4.71. In

decreasing order these are: Air-

water transport, Weave Textile,

Coal-metal petroleum, Electricity

Gas Water Chemical-fertilizer and

Paper-printing and metal.

The backward linkages of

the remaining 13 commodities

which ranged between 4.6 and

6.37 can be categorised as the

middle group.

Largest decreases in backward linkage values in the year 2008 compared to 2005, in

decreasing order, are found for Food industry (16%), Hotels Affairs (10%) Restaurant (9%)

and Mining and Quarry (8%), most are found among the top commodities. On the other

hand, smallest decreases in backward linkage values in the year 2008 compared to 2005 are

trigger another round of investigation (not attempted in this report) into the determinants of these

differences.

23

found for Other Agri. and Crops (4%), Fishery, Government etc and Bank (3%), some are

top other not. The first set of activities thus appears to be relatively more dynamic than the

second set.

Additionally, for Indonesia the SNA and SAM discrepancies are illustrated in the table

below, where the total backward linkages ratios, reflecting the comparison of the

Indonesian static 2005 SAM with the Indonesian dynamic 2008 SAM, are presented. The

linkages for 2005 are consistently higher; this is reflected by the fact that the ratios are all

over unity; in some cases the upward bias is 7 per cent (Restaurants), while in other cases it

is as low as 2 per cent (Crops).

Table 8: Indonesia: Comparison of selected Commodity and Activity total backward linkages

Indo

nesi

a

c C

rops

c O

thA

g

c T

rade

Ser

vice

s

c R

esta

uran

t

a C

rops

a O

ther

Agr

icul

ture

a Li

vest

ock

a R

oad

Labo

ur In

tens

ive

a R

oad

Cap

ital

Inte

nsiv

e

a Ir

rigat

ion

2005 Static 10.14 9.74 9.37 10.19 9.24 8.85 8.93 8.72 7.16 7.66

2008 DySAM 9.82 9.40 8.86 9.51 9.06 8.66 8.55 8.42 6.88 7.33

Ratio 1.03 1.04 1.06 1.07 1.02 1.02 1.04 1.04 1.04 1.04

4.3 Dynamic SAMs multipliers and linkages (total)

The figure presented below can clearly show that although most accounts appear to

follow a pattern over time, rising from below the values of the static SAM (see blue line)

from 2000 to 2004, falling thereafter, and rising but remaining below the 2005 levels.

Whereas, in the case of Mozambique there is not a clearly distinguishable pattern (see

Mozambique DySAM Report, April 2010, sec. 4.1).

24

Figure 6: Indonesia: Over time trend of total backward linkages for selected economic Activities

s_ST_Ma

s5_IRsCL_0324_Dy

"s5 Ma (Tr A) A c5"[a Storage OthTrpSrv c5] : Sum All Backward Linkage (Tr A) (1x27)

10

8

6

"s5 Ma (Tr A) A c5"[a BankInsuranceSrv c5] : Sum All Backward Linkage (Tr A) (1x27)

10

8

6

"s5 Ma (Tr A) A c5"[a RealEstate BusinessSrv c5] : Sum All Backward Linkage (Tr A) (1x27)

8

7

6

"s5 Ma (Tr A) A c5"[a GovDefEduHlthFilm OthSocSrv c5] : Sum All Backward Linkage (Tr A) (1x27)

20

13

6

"s5 Ma (Tr A) A c5"[a OthIndivHHSrv c5] : Sum All Backward Linkage (Tr A) (1x27)

10

8

62000 2003 2006 2009

Time (Year)

The main reasons for the varying results have been indicated above but it is useful to

remember that changes over time can be equated with income elasticities shifts as a way to

move from the ‗behaviour less‘ accounting multiplier SAM model to the fixed-price SAM

model.

The importance of backward linkages for the ranking according to importance, i.e. the

potential contribution to the expansion of the economy, is presented by the block diagonal

backward linkages as shown in Appendix 1.28

Dynamic multiplier estimates (Ma) are available for the period 2000-2008 and the

corresponding static multipliers estimates refer to the 2005 ‗baseline‘ SAM for Indonesia.

To analyse changes over time in the Indonesian economy, a snapshot comparison of the

total backward linkages of 2008 with the static backward linkages for 2005 were presented

in the report indicated above.

The major observations are:

A feature of all the 2005 linkages is that they are higher than the 2008 estimates in

all account blocks. This is a result of the noted discrepancy between the SNA macro

estimates and the corresponding baseline SAM.29

28It is pertinent to recall the two caveats relevant to the total backward linkage comparisons. Firstly,

total backward linkages are only the first in a series of indicators providing pointers for policy

formulation. While interpreting total backward linkages it

25

Playing a role is the growing importance of imports, savings and government revenue

and expenditure, which are treated as exogenous accounts of the dynamic SAM model.

All account blocks, with the exception of household (iH) and company (iC), evidence

structural shifts between 2005 and 2008. This suggests that household income groups seem

to be more evenly inserted in the income streams, when compared to factor labour income,

which have a bias towards urban areas.

This analysis can be used to guide the formulation of evidence-based policy and can

help determine the growth model that best suits the particular economy. In general, high

backward linkages, especially partial backward linkages, can be used to design policy

packages with the highest linkages in one account or, if policy priorities so indicate, a mix

of partial linkages of different sizes within each main account block. It can also help design

a policy mix by combining desired backward linkages across selected accounts, e.g. growth

combined with incomes policies. The most common basis for designing policy packages is

outlined in Table 4.2, below.

4.4 Summary observations of the policy indicators – the case of Indonesia

A full and detailed presentation of the Indonesian impact analysis in each of the four

endogenous blocks was presented in the corresponding report. In this document, only

highlights of the most relevant findings are presented. The total impact and partial impacts

are reported. Furthermore, the impact analysis presents a decomposition by type - intra-

account transfer impacts (M1) and induced impacts (O+C). As these impacts are a sequence

of a unitary injection into each of the endogenous accounts they may be compared. The

policy indicators based on this analysis of impact are collated below.

Table 9: Summary of the impact of injections by account type (The information in this table is very similar to the information in the last para of section 4.)

Account

Description

Commodity and activity accounts

A policy package that can potentially generate the highest possible growth in commodities should be considered, and commodity groups that have the highest partial backward linkages should be targeted. Differences in the degree of endogeneity focus attention on the role of imports (and other leaks). Factor and institutional income formation stand to benefit little in a growth strategy, e.g., when injections take place via the commodity account.

Factor account

Labour types benefit almost equally from induced effects, notwithstanding the fact that urban based labour categories occupy the top four ranks. A factor incomes policy favoring a specific category of workers is non-distorting. It will not bias commodity growth, activity growth or institutional income formation.

Household account

The induced impacts are more potent than the direct impact component. A direct income policy is distribution-neutral, as the induced transmission to other households is as large as the intra account transmission. Therefore, income distribution will largely remain unchanged.

29 The magnitude of the bias is not similar in all estimates. They are higher for the commodity and

activity blocks and lower for the factor and institution blocks. This is also reflective of the interplay

of the economic factors and the constraint imposed by economic events, domestic and external

26

For the year 2008 (see Table below), in the case of Indonesia, when an injection is

made into the commodity or activity account, the correlations between these two accounts

(Co, A; A, Co) are close to unity. This implies that injections in either the commodity or

activity account will greatly benefit each other. This is because there is a unique

relationship between these accounts, in that they are both are domestic in nature.

However, correlations of commodity and activity account with the rest of the accounts

are low. For instance, the correlations with factor incomes (Fp) and institutional incomes

(iE) are low (below 0.6). This implies that injection in commodities or activities will not

benefit factor incomes or institutional incomes greatly. This means that growth policies are

not compatible with incomes polices.

Alternatively, factor incomes and institutional incomes have correlations with

commodities and activities that are close to unity. The implication is that injections into

factor or institutional accounts will benefit one another and also significantly impact the

growth of production accounts. This means that income policies (income distribution and

poverty alleviation strategies) are complementary with growth policies.

Table 10: Indonesia DySAM 2008 Correlation Matrix

Indonesia DySAM 2008 Correlation Matrix

Co A Fp iE

Co 1.0 0.999 1.000 0.998

A 0.993 1.0 1.000 0.998

Fp 0.595 0.527 1.0 0.999

iE 0.563 0.506 0.999 1.0

To further illustrate the injection effects, see Table 11, an injection of IDR 1 billion

(approximately USD 100,000) into the commodity account (Co) generates an average

increase of IDR 2.74 billion in itself, meaning in the commodity account (Co), and IDR

2.60 billion in the activity account (A). The incomes of institutions (iE) will increase by

IDR 1.50 billion but factor incomes (Fp) will grow only by IDR 1.40 billion.

An injection of IDR 1 billion into the activity account (A) generates IDR 2.74 billion

in itself and only IDR 1.83 billion in the commodity account (Co). Furthermore, the growth

impact on account factor incomes (Fp) will be IDR 1.45 billion and institutional incomes

(iE) IDR 1.55 billion (see Table 8 below).

The indication is that policies that tend to stimulate commodities (Co) (via exports,

household or government demand) are to be preferred to those stimulating activity accounts

(A). The reason is that the multipliers are weaker since there are leaks into imports when

the activity account expands.

An injection of IDR 1 billion into the factors of production (Fp) account will generate

IDR 2 billion within itself, namely factors of production account, and IDR 2.11 billion in

the institutional income account (iE). Moreover, the impact on growth will be IDR 2.06

billion for the commodity account (Co) and IDR 1.94 billion for the activity account (A).

An injection of IDR 1 billion into the institutional incomes account (iE) will generate

IDR 2.06 within itself and IDR 0.96 billion in the factors of production account (Fp).

Furthermore, the impact on growth will be IDR 1.95 billion in the commodity account (Co)

and IDR 1.85 billion in the activity account (A).

27

Table 11: Indonesia DySAM 2008 Average partial backward linkages

Indonesia DySAM 2008 Average Partial

Backward Linkages

Main

Accounts Co A Fp iE

Co 2.74 1.83 2.06 1.95

A 2.60 2.74 1.94 1.85

Fp 1.40 1.45 2.00 0.96

iE 1.50 1.55 2.11 2.06

The broad indication is that income policies oriented towards increasing factor

incomes will be more balanced and may render the highest income gains. A second choice

may be the expansion of commodities promoting the highest economic growth. These

comparisons deepen the understanding of the impact that is formed through the circular

transmission.

5. Satellite accounts and transformation and employment

5.1 Introduction

In principle there are two types of satellites, the expansion and the extension type. The

shift from an ‗expanded data‘ SAM structure to an ‗expanded‘ SAM Multiplier Model, to

derive the ‗extended‘ Employment Multiplier Module is analogous to the general SAM

Multiplier Module.

One of the main aims of the DySAMs created for Indonesia and Mozambique was to

assess the impact of infrastructural investments in general and labour-intensive versus

capital-intensive road construction in particular.

Therefore, the information required to build the employment satellite must be

compatible with the entries and accounts as presented in the SAM and must be separated by

the location and must disaggregate the construction sector. In most cases it is important to

separate construction by type. For Indonesia, the four types are road labour intensive, road

capital intensive, irrigation and construction rest. For Mozambique, the types are rural and

urban roads, rural and urban infrastructure, irrigation, highways and buildings, houses and

construction rest. The activities were correspondingly allocated to three regions (rural,

urban and Maputo), hence there are a total of nine sub-sectors for the case of Mozambique.

A reference table to expand the construction sector with corresponding input

structures could be derived after some research and data probing. Subsequently, the capital

formation column (labelled as capital balance in the SAM) and the government

consumption column were separated by the same types of construction. Household

consumption did not require expansion because the corresponding entries were zero, in

conformity with SNA 1993.

The calculations with the increased construction resolution show the impacts of

injection of government infrastructural (types of road, irrigation, etc) investments, and thus

assesses the largest total potential contribution to growth arising out of each construction

type by region.

28

5.2 The Employment Satellite Module30

5.2.1 General

One of the main purposes for building a DySAM in Indonesia and Mozambique was

to evaluate the employment impact of policy shocks. The methodology for such an

assessment is further elaborated here.

A SAM is money-metric. However, labour by economic activity can be used to build a

‗bridge‘ between the SAM and information on employment. It is possible to extend a SAM

in many ways and a SAM can be connected with demographic (labour and, households),

housing, education, health and capital stock information. Inclusion of such information can

extend the analysis to include capital and labour output ratios, as well as per head and per

household requirements in terms of food nutrition intake (calories, vitamins, and proteins),

households housing, education and health. Information on emissions or pollutants into the

environment, whether they are related to production, consumption by household and

unwanted can also be included.

The figure below is a graphical representation showing that the SAM is at the core and

that other satellite matrices can be coupled to the SAM and thus that their impact can be

measured and accounted for.

Figure 7: Relations between the SAM and satellite accounts; Extended SAM (ESAM)

Source: Adapted from Fig 4. Alarcon (Revision 2007).

30 This section is based on Sec. 4.2; for Construction-Employment Analysis on Sec. 4.3, see Part II,

ILO, 2010b.

29

Such an extension can be accomplished by coupling satellite modules with the

money metric SAM.31

Some well-known satellite modules are the following:

1. Social module (well-being, education, health and housing)

2. Demographic module (population, labour and households)

3. Labour and/or Employment Equivalent by Activity

4. Green Jobs and Environmental module (green employment, natural resources and

emissions)

5. Institutional uses of financial resources (flow of funds)

At the outset, it should be noted that the satellite account for each of the above

modules should be built after the entries in the SAM have been agreed. The relations with

the money metric SAM should be made explicit by extending the SAM itself with the

appropriate systems in rows and columns.

The modelling can be achieved by using formulae that are analogous to those used in

input-output/SAM modelling. For an employment satellite account, the technical concepts

of average labour-output and capital-output relations need to be introduced. Both ratios

reflect the inverse level of labour and investment average productivity and can, therefore,

help to illustrate the level of employment and investment demand that can be expected

when injections are applied into the system.

The analysis that can be undertaken is similar to the SAM multiplier analysis. Labour

multipliers will show how an external injection will generate labour places in all economic

activities. Introducing employment, investments and households as a vector(s) of ratios, in

a manner similar to the matrix of leakages, and pre-multiplying the matrix of multipliers

(Ma) by the ratios, the performed calculations and results will be analogous to the

multipliers of the matrix of leaks. However, as these variables differ in nature and have

different dimensions, the interpretation of impacts is in physical terms, e.g. the ratios are

not based on propensities to spend but on the labour and investment ratios. Henceforth, in

the case of injections, the interpretation of the corresponding multipliers will show the

levels of employment and volume of investments that are compatible with the expansion or

contraction of the economy.

5.2.2 Employment Methodology and Modelling

The modelling of employment can be achieved by using formulae that are analogous

to those used in input-output/SAM modelling. The technical concepts of average labour-

output and capital-output relations are introduced. From economic theory and input-output

modelling perspectives, we know that both ratios show, by implication, the level of labour

and investment productivity; therefore, the analytical validity of this treatment is not

symbolic and can help to illustrate the level of employment and investment demand that

can be expected when injections are applied into the system. In the present case, the labour

figures per economic activity have been used to this effect. The interpretation and ensuing

analysis presented is similar to the SAM multiplier. Capital stock figures per economic

activity usually suffer from lack of information. Labour multipliers will show how an

external injection will generate labour places in all economic activities.

31

One such example can be found in Alarcon et al (2000).

30

Concretely, introducing employment levels as a vector(s) below the matrix of leakages

(L), all performed calculations and results will be similar to the matrix of leaks with caveats

regarding the nature and dimensions.

The formal methodological explanation about how the satellites can be understood by

re-interpreting the so-called leak multipliers or exogenous SAM multiplier, which can be

derived simply by pre multiplying the Ma by the B matrix.

Defining L (the employment satellite variables) as:

L (t) = λ Y(t)

Furthermore, the SAM model solution is:

Y = Ma X

Replacing Y with Ma X in the labour equation:

L (t) = λ Ma X(t)

Where:

L is a matrix/vector of employment

Y is a vector of incomes of endogenous variables

X is a vector of expenditures of exogenous variables

A is the matrix of average expenditure propensities for endogenous accounts

λ is the matrix/vector of labour-output ratios

t is time

Ma = (I – A) –1

is a matrix of aggregate accounting multipliers (generalized Leontief

inverse)

λ Ma = B (I – A) –1

is a vector/matrix of aggregate labour multipliers.

5.3 Employment summary results: the case of Indonesia

One of the main aims of the DySAM is to assess the employment impact of

infrastructure investments in general and labour intensive versus capital intensive

road construction in particular.32

In this section, we present a brief analysis of the link to

employment generation as a stimulus originating in construction and how it propagates

through the transmission chains. In the concluding section, we focus more specifically on

the construction-employment connection. The following panels in the table provide a

summary the employment impacts for all endogenous accounts by type of impacted

account.

32

For details, please refer to Part II: Indonesia DySAM Report (ILO; 2010a), Section 4.

31

Table 12: DySAM summary labour multipliers by accounts for 2008 (Unit Persons)

Labour Multipliers Activities (Lm A) Labour Multipliers Commodities (Lm Co)

2008 Total Intra-account Induced 2008 Total Intra-account Induced Top 5 Average 81 58 24 Top 5 Average 78 55 23

Bottom 5 Average 18 5 13 Bottom 5 Average 18 5 13

Total Average 41 23 18 Total Average 40 22 18

The four panels of the above table (Table 12) summarize the labour multipliers—total

and decomposition in intra-account and induced—for all four endogenous accounts. It is

clear that the two highest labour multipliers belong to the activity and commodity accounts.

A unit injection (1 billion rupiahs) in the activity account generates, on average, 41 labour

places (one labour place is one employee/worker) and 40 if the injection is via the

commodity account. This reflects the unique relationship between commodities and

activities.

Although activities are the agencies hiring labour, the above results pinpoint

where the stimulus for this hiring originates. The circular process equilibrates and

the employment attributable to intra-account transfer (M1) and induced (OC)33

impacts can be determined.

In Table 12 it can be seen that in the activity and commodity account, the intra transfer

impact (M1) is more than twice the induced impact (OC) for the top five accounts in these

sets. For the bottom 5 accounts the induced impacts are larger, approximately 55 per cent of

the total impact The table also shows that the impacts derived from institution and factor

accounts are lower than those of the activity and commodity accounts, and are also entirely

induced impacts.

The table below shows the employment multipliers and their decomposition for the

four construction activities for 2008. For convenient reference the 2005 Static SAM

estimates are also reported.

33

In SAM modelling, the multipliers Ma can be decomposed into M1 or the effect within (intra group) the account in which the injection takes place (in this case within the production accounts Co and A), O the effect when the injection moves to the other accounts (in this case Fp and iE) and C when the effects comes back to the account where the injection took place. For our purpose, O+C is defined as induced (extra group) effect. More details on decomposition are found in Footnote 14.

Labour Multipliers Factor of Production (Lm Fp) Labour Multiplier Institutions (Lm iE)

2008 Total Intra-

account Induced 2008 Total Intra-

account Induced Top 5 Average 34 0 34 Top 5 Average 35 0 35

Bottom 5 Average 25 0 25 Bottom 5 Average 22 0 22 Total Average 30 0 30 Total Average 29 0 29

Top 5 Average (exc. Capital) 28 0 28

Top 5 Average (exc. Enterprises) 27 0 27

32

Table 13: DySAM Total Labour Multipliers by Construction Type for 2008 (persons)

Construction: Road Labour Intensive

Construction: Road Capital Intensive

Construction: Irrigation Construction: Rest

DySAM intra-account

30.9 8.6 8.6 13.7

DySAM induced 18.4 14.9 15.3 16.7

DySAM Total 49.3 23.5 23.9 30.4

Static SAM 2005 50.7 24.8 25.4 31.8

Table 13 shows that labour intensive road construction has the highest labour

multiplier, mainly as result of it having the highest integration with the rest of the

production and distribution, as reflected by the intra-transfer effect. This is because it uses

only domestically produced inputs and the leakage is zero. The other three-construction

activities show that the induced effect is dominant, indicating that the main propagation

arises via extra group accounts impacts. The static SAM 2005 multipliers show the same

pattern and are only slightly higher than their corresponding labour multipliers per

construction activity. This is because of the scale shift between the SNA and dynamic

macro SAM estimates for 2005.

The results in Table 13 are in line with the partial multiplier estimates for construction

activity given in Table 12

Table 14: DySAM partial activity multipliers by construction type for 2008 (billion IDR)

Construction: Road Labour Intensive

Construction: Road Capital Intensive

Construction: Irrigations Construction: Rest

DySAM intra-account 1.94 1.64 1.82 1.62

DySAM induced 1.21 0.98 1.01 1.09

Total 3.15 2.62 2.83 2.71

Intra-account share of total 61.5% 62.5% 64.3% 59.7%

Labour-intensive road construction has the highest activity multiplier (see Table12on

accounts, intra-account and induced effect), while Table 13 confirms that this construction

type also has the highest labour multipliers. Clearly, for policy purposes, if the main

objective is to generate employment regardless of skill levels, promoting labour intensive

road construction will generate twice the number of jobs compared to capital-intensive road

construction and irrigation.

33

6 Simulation the Case of Indonesia: Fiscal Stimulus Package Infrastructure

Indonesia‘s response to the crisis was designed to maintain purchasing power by

offering price subsidies on education, palm oil conversion, as well as on generic medicine

and wage income transfer. A second strategy was to cushion companies operations and

raise their competitiveness. The major means of achieving this were the reduction of

electricity tariffs for the industry, including a decrease of solar pricing, tax allowance,

expansion of the financing for the SMEs and export simplification procedures and

guarantees. A major contribution of the package was for infrastructure, e.g. 12.2 trillion

(see Budget in Table 15), the amount was earmarked to incentivise the economy via

construction-related production (FSPC).34

These investments include the rehabilitation of

roads, airports, seaports, railways, housing, traditional markets, rice warehouses and

strengthening training institutions.

Table 15: Stimulus Package by Items and Delivery Levels

Fiscal Stimulus in trillion IDR Budget IDR trillion

Realisation IDR trillion

Realization Per cent

Tax cut for companies, workers and individuals 43.0 43 100 %

Tax subsidies and import duties exemption 13.3 21.4 %

Infrastructure expenditure 12.2 10,815 88.7 %

Diesel and electricity subsidies +PNPM 4.7 86.8 %

Total 73.3 82.7 %

Source: CMEA: Total package 73.2 trillion IDR (1.4% of GDP and IDR 9,100 = USD 1)

6.1 Simulation Scenario: the case of Indonesia

To lessen the impact of the 2008 global economic crisis, in the fiscal year 2009 the

government provided a fiscal stimulus amounting to IDR 12.2 trillion. The total realization

rate in 2009 reached a reasonably high level of 88.7 per cent. The missing part is mostly

due to inefficiencies in the infrastructure component and the lack of demand for subsidies

from businesses. Therefore, the realized amounts, e.g. IDR 10,815 billion infrastructure, is

simulated here as injection via capital formation ‗cC capital‘ account ( see table 16).The

main purpose of the scenario is to calculate the different economic and labour growth

impacts using the Indonesia DySAM model the impact of the FSPC policy on the economy,

including:

Commodity Account

Activity Account

Labour Factor Account

Institutional Account

Job Creation

34

Capital formation of infrastructure expenditure increases by an average of 18.47 per cent annually.

The stimulus was added on top of it.

34

Of the 10.815 IDR trillion to construction, the GOI allocated 10.665 trillion rupiahs

directly to infrastructure works and 150 billion rupiahs to build public school and public

health facilities, e.g. facilities directly undertaken by the government in 2008; see Table 15.

Considering that the volume of capital formation in construction was, on average over the

2000-2008 period, about IDR 416,549.23 billion, the executed/injection amount

represented 3 per cent.

Table 16: Economy-wide Impacts of FSPC Injection of 10,665.0 billion rupiahs in 2009 (billion rupiahs)

Impacted Accounts A: Forecast 2009 + injection

B: Forecast 2009 Base Injection Effect (A-B) Growth Effect

Commodity Output 10,117,070.7 10,086,525.3 30,545.4 0.303%

Activity Output 9,717,032.2 9,687,837.2 29,195.0 0.301%

Factor Income Value Added or GDP (factor cost) 4,904,091.1 4,890,629.3 13,461.8 0.275%

Institution Income 5,663,943.4 5,649,536.3 14,407.1 0.255%

Government Income 860,800.03 858,511.45 2,288.58 0.27%

Source: DySAM Output and own calculations.

The impact of the FSPC programme on each of the main four accounts can be found in

Table 16, where in column (A) the forecast for 2009 plus the impact of the injection is

presented, while in column (B) the forecast for 2009 is shown without the injection. The

difference between the two is the net injection impact, these values by main account are

presented in column (A-B), and the FSPC impacts vary from 14,407 billion IDR for

institutional incomes to 30,545 billion IDR for commodity output. The total effect of the

FSPC is close to 2.3 trillion rupiahs for the government budget.

In terms of growth, the impact on production (commodity and activity output)

translates into growth rates slightly over 0.3 per cent. In contrast, income generation growth

reaches 0.27 per cent for factor income (GDP at factor cost in table 16) and 0.255 per cent

for institution income, (see table 16 last column). Put into perspective, the 10.8 trillion

IDRs amounts to 0.15 of GDP and generates 0.275 per cent GDP growth.

Since the government receives income back via taxes, calculated at about 2.3 trillion,

the net cost to the government amounts to 8.6 trillion rupiahs (see Table 17).

Table 17: Net Cost of the Construction Fiscal Stimulus Package in 2009 (billions of rupiahs)

Injection Fiscal Stimulus Package Effect on Government Income Net Cost Fiscal Stimulus Package

10,815.00 2,288.58 8,526.42

In terms of the impact on employment, the almost 11 trillion rupiahs FSPC via

construction generate 287,000 thousand jobs (see Table 18). Looking at construction by

type, 9 per cent of these jobs are generated in road labour intensive building and only 1.7

per cent in irrigation.

It is interesting to see that the job creation impact on the largest economic activity,

namely Crops, stands to create close to 90 thousand labour places or 28.5 per cent of all the

additional employment, which is much higher than its share in overall employment

(19.6%).

35

Table 18: Total Impact on Job creation 2009: Economy Wide, Construction by Type and Crops

JOB CREATION by activities

Employment Increase (Growth)

Share ME Factor(*) ME Persons (*) ME Share

Total Economy Wide 287,060 (0.26%) 100% 1.02 292,801 100.0%

Road LabourIntens. 25,722 (9%) 9.0% 1.16 29,791 10.2%

Road CapitalIntens. 8,539 (9%) 3.0% 1.16 9,890 3.4%

Irrigation 4,851 (9%) 1.7% 1.16 5,619 1.9%

Construction Rest 11,125 (9%) 3.9% 1.16 12,884 4.4%

Crops 81,951 (0.22) 28.5% 0.80 65,204

22.3%

(*) Source: Total Manpower, Manpower Equivalence (ME) and Average Work Hours Per Week, by Business Classification: BPS SAM Indonesia, 2005.

The results need to be corrected for over- or underemployment, using the provided

data, which have been derived from manpower equivalence (ME) factors of the 2005 SAM.

For the entire labour force, the factor is 1.02 (same table, fourth column), thus the actual

employment level is close to 293,000 labour equivalent places. For Construction and Crops,

the ME factor is 1.16, one of the highest among all reported economic activities. The

employment equivalent shares are now considerably higher for construction activities but

lower for crops activities by as much as 6.2 percentage points, an activity with high

underemployment. Labour-intensive road construction now creates 29,800 full-time jobs

instead of 25,700 jobs without correction for ME.35

For policy purposes, it is also important to understand how the total effect is formed.

decomposing the employment effects into induced (O+C, meaning open and closed

loop)and intra-account effect M1 (which is similar to a production coefficient). The Intra-

Account Effect arises out of intra-account transactions only and shows how much an

activity is integrated with the production structure. Table 19 shows that the Intra Account

Effect, the effect that dominates for all construction activities, which is not surprising given

that construction is the objective of the injection thus showing 99.5 per cent of the total

impact. However, the share contribution varies to the extent that now Labour-Intensive

Road Construction contributes 22.5 per cent of the total Intra-Account Effect (it was only

9%; see Table 13). In addition, the other construction activity shares have gone up

considerably.

For Crops (see Table 19), this effect is only 2.8 per cent, since most of the effect arises

as induced via the ‗workings of the economy‘ or via the cascading effect throughout the

economy (through other accounts such as factor income, institutions, etc.). At the economy-

wide level, there is also a dominance of the induced effect (60.4% compared with 39.6% of

the Intra-Account Effect).

35 Other national studies came up with other figures, which can be explained by differences in

assumptions when applying their models, mainly on: 1. Economic growth forecasts, 2. definition of a

job, 3. definition of multipliers, 4. application of economic versus engineering methods of

calculating multipliers, 5. time span.

36

Table 19: Intra Account Impact on Job creation 2009: Economy Wide, Construction by Type and Crops

JOB CREATION by Activities

Employment Increase

Share ME Persons (*) Share Total

Total Economy Wide 113,803 100.0% 116,079 39.6%

Road Labour Intensive 25,602 22.5% 29,652 99.5%

Road Capital Intensive 8,499 7.5% 9,859 99.5%

Irrigation 4,829 4.2% 5,602 99.5%

Construction Rest 11,073 9.7% 12,845 99.5%

Crops 2,314 2.0% 1,841 2.8%

To conclude, Table 20 shows that most of the employment will take place in rural

areas (59%) and will be male employment (62.3% urban + rural male). Looking at

construction, the figures show a lower share of urban workers (48.4%) as compared with

the total economy and a very strong domination of male workers, with over 97.6 per cent.

Table 20: Share of new employment by location and gender, 2008 (percentage)

7. Conclusions and Recommendations

To sum up, the DySAM Model with expanded construction activity accounts and an

extended employment satellite module has operational utility for the following purposes:

In addition to using an accounting framework it also provides a simple economic

modeling: Based on an accounting framework, some static SAM Model assumptions

are relaxed: technology/behaviour is not fixed: price relatives change; dynamics

generating the interdependent evolution of the economy evolution of backward and

forward linkages; it exhibits behaviour and lessens the need to calculate

expenditure/income elasticities.

It is a guiding tool for sectoral policy making: An assessment of the employment

generating potential across the activity set or sectors, as well as any activity subset or

sub-sectors such as construction.

It facilitates targeting: An assessment of the employment impacts of activities across

labour types by gender, location and age cohorts or income or skill levels using

simple variants of the extended employment satellite module.

It allows the evaluation of the effectiveness of past programmes and policies and the

simulation of future ones: A quantitative assessment of how injections into

exogenous accounts transmit through the interdependent endogenous accounts to the

impact on economic growth and employment generation.

Urban Male

Urban Female

Rural Male

Rural Female

Total Urban

Total Rural

Total 2008

Economy wide 25.4% 15.6% 36.9% 22.1% 41.0% 59.0% 100.0%

Construction 46.9% 1.6% 50.8% 0.8% 48.4% 51.6% 100.0%

37

It helps in choosing between different policy options or policy mixes: Inform the

design of policy packages consistent with alternative policy priorities (employment

first, growth first, etc.) via comparative scenario analysis.

It includes technology choice, as a change in the technological composition of

activities will lead to different employment outcomes in the future.

Various effects can be decomposed: A decomposition of the total impacts into intra-

account (including direct and indirect) and induced impacts, backward and forward

linkages.

Data requirement may be a serious issue. The major challenge is to incorporate and

reconcile information from various social and economic sources, including data from

previous years. Nevertheless, most developing countries already have a SAM that can be

updated. Moreover, good policy advice should be evidence-based. Macro data also need to

be underpinned by micro data competence at the sectoral level.

From the data side, one reason to use the DySAM model is that it harmonizes and

reconciles various datasets, it helps identify and resolve data inconsistencies and errors. The

platform is user-friendly with regard to simulations and also with regard to up-dating by

technical specialists.

Simulations on the Indonesian fiscal stimulus package on construction (FSPC) have

shown not only the high employment impact on measures economy-wide (almost 300,000

jobs) and in particular in the construction sector, especially in labour-intensive road

construction (almost 30,000 jobs) but also, the positive reflow of funds via tax income (IDR

2.3 trillion out of IDR 10.815 trillion). Furthermore, the FSPC package benefits more rural

than urban workers, these figures are more mitigated looking only at the construction

sector.

There are various areas for extension and expansion of the DySAM in the future.

Special groups of workers (women, the youth) and households can be analyzed by the use

of satellite accounts (extension); these are people who often benefit from targeted support

programmes. Environmental issues can be discussed through the expansion of the SAM

(opening for green sub-sectors) or expansion via an environmental satellite account (e.g.

showing real carbon emissions by activity, or water use, etc.). It can be used to analyze the

external sector (capital, FDI, flows, exports, imports and special tariff arrangements), the

national financial sector (e.g. microfinance and employment), poverty reduction strategies

(e.g. MDG, PRSPs) looking at the right policy mix between social protection and

employment, industrial policies or the general budgeting process.

To bring things to a conclusion, we want to indicate that the DySAM with an

employment satellite account has the potential to be an effective tool for undertaking

impact analysis on exogenous injections such as public investment on employment (e.g. the

fiscal stimulus package in Indonesia) and its employment generating potential. This can be

done by activity and across labour types by gender, location and other types using simple

variants of the extended employment satellite module. It combines various levels of

analysis, including macro, meso, and micro levels. It also includes technology choices and

allows the decomposition of the total impacts into intra-account and induced impacts. It

thus provides useful consistent numerical information for decision-makers in the design of

policy packages, as well as the basis for comparative scenario analysis that can consider the

best way to achieve policy priorities (employment first, growth first, labour or capital-

intensive methods, Co2 emissions by economic sector, etc.).

38

39

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Pyatt, G, J.I. Round (eds), (1985), ―Social Accounting Matrices: A Basis for Planning‖.

Washington DC: World Bank.

Round, J., (2003), ―Social Accounting Matrices and SAM-based Multiplier Analysis‖, in:

Bourgignon, F. and L. Pereira da Silva (eds), The Impact of Economic Policies on

Poverty and Income Distribution: Evaluation Techniques and Tools, The World Bank,

Washington D.C. pp. 269-287.

Robinson, S. and El-Said, M. (2000) ‗GAMS Code for Estimating A Social Accounting Matrix

(SAM) Using Cross Entropy (CE) Methods’. TMD Discussion paper No. 64.

Washington, DC, International Food Policy Institute (IFPRI).

Robinson, S., Cattaneo. A. and El-Said. M. (2001) ‗Updating and Estimating a Social

Accounting matrix Using Cross Entropy Methods’. Economic Systems Research 13 (1):

47-64

Van Heemst, J.J.P.: ―Introduction‖ in: The Social Accounting Framework for Development,

in Alarcon et al., 1991. The Social Accounting Framework for Development, Avebury:

Gower House, England.

UNSD (1993) ―Integrated Environmental and Economic Accounting, Studies in Methods”, Ser.

F. Nr 61, NY.

41

APPENDIX

1 Backward linkages: Evolution over time for a selected number of endogenous accounts

Glossary of Symbols:

s_ST_Ma: Static SAM 2005 matrix of multipliers

s_Dy_Ma: Dynamic SAM 2000-2008 matrices of multipliers

Note: for the interpretation of the codes and symbols please refer to Figure 4, see

Total Row/Col, where: (Tr Co) total of the Commodity (Co) and Tr A Total of the Activity

(A).

Figure 8: Commodity Account and Activity Account

Backward Linkage of Commodity Accounts (1-14)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Co) Co c5"[c Maize c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Rice c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Wheat c5] : Sum All Backward Linkage (Tr Co) (1x24)

1

0.9

0.8"s5 Ma (Tr Co) Co c5"[c OthGrain c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Cassava c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Bean c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c OthBasicFood c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Co) Co c5"[c Cashew c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Cotton c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c OthExportCrop c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c OthCrops c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Livestock c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Forestry c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

10"s5 Ma (Tr Co) Co c5"[c Fish c5] : Sum All Backward Linkage (Tr Co) (1x24)

20

15

102000 2002 2004 2006 2008

Time (Year)

42

Activity Account

Total Backward Linkage of Activity Accounts (1-16)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr A) A c5"[aR Maize c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Maize c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM Maize c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Rice c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Rice c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR OthGrain c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU OthGrain c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Cassava c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr A) A c5"[aU Cassava c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM Cassava c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Bean c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Bean c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM Bean c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR OthBasicFood c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU OthBasicFood c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM OthBasicFood c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

102000 2002 2004 2006 2008

Time (Year)

43

Total Backward Linkage of Activity Accounts (17-32)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr A) A c5"[aR Cashew c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Cashew c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Cotton c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Cotton c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR OthExportCrop c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU OthExportCrop c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM OthExportCrop c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR OthCrops c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr A) A c5"[aU OthCrops c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM OthCrops c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Livestock c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Livestock c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aR Forestry c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aU Forestry c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

10"s5 Ma (Tr A) A c5"[aM Forestry c5] : Sum All Backward Linkage (Tr A) (1x27)

20

14

8"s5 Ma (Tr A) A c5"[aR Fish c5] : Sum All Backward Linkage (Tr A) (1x27)

20

15

102000 2002 2004 2006 2008

Time (Year)

44

Factor Account

Note: Sum total backward linkages. The interpretation of the codes and symbols can

be found in Figure 4; see Total Row/Col, where: (Tr Fp) and (Tr iH) are Total Row of the

Factors (Fp) and institutions (iE).

Figure 9: Total Backward Linkage of Factor Accounts (1-14)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Fp) Fp c5"[fn RuC c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17.5

15

12.5

10"s5 Ma (Tr Fp) Fp c5"[fn RuS c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17.5

15

12.5

10"s5 Ma (Tr Fp) Fp c5"[fn UrN c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17.5

15

12.5

10"s5 Ma (Tr Fp) Fp c5"[fn UrC c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

8"s5 Ma (Tr Fp) Fp c5"[fn UrS c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

8"s5 Ma (Tr Fp) Fp c5"[fn UrM c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

82000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Fp) Fp c5"[fL Skill Inf M c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

8"s5 Ma (Tr Fp) Fp c5"[fL SemiSk Inf M c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

8"s5 Ma (Tr Fp) Fp c5"[fK Rural c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17

14

11

8"s5 Ma (Tr Fp) Fp c5"[fK Urban c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

16.5

13

9.5

6"s5 Ma (Tr Fp) Fp c5"[fK Project c5] : Sum All Backward Linkage (Tr Fp) (1x17)

2

1.75

1.5

1.25

1"s5 Ma (Tr Fp) Fp c5"[fn RuN c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

17.5

15

12.5

102000 2002 2004 2006 2008

Time (Year)

45

Backward Linkage of Factor

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Fp) Fp c5"[fL HiSkl For c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL Skill For N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL SemiSk For N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL UnSkl For N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

10"s5 Ma (Tr Fp) Fp c5"[fL Skill Inf N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

10"s5 Ma (Tr Fp) Fp c5"[fL SemiSk Inf N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

10"s5 Ma (Tr Fp) Fp c5"[fL UnSkl Inf N c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr Fp) Fp c5"[fL Skill For C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL SemiSk For C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL UnSkl For C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

10"s5 Ma (Tr Fp) Fp c5"[fL Skill Inf C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL SemiSk Inf C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

8"s5 Ma (Tr Fp) Fp c5"[fL UnSkl Inf C c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

15

10"s5 Ma (Tr Fp) Fp c5"[fL Skill For S c5] : Sum All Backward Linkage (Tr Fp) (1x17)

20

14

82000 2002 2004 2006 2008

Time (Year)

46

Institution Accounts

Figure 10: Total Backward Linkage of Household Accounts (1-14)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih RuN q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuN q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuN q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuN q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuN q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrN q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih UrN q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih RuC q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

13

6"s5 Ma (Tr iE) iE c5"[ih RuS q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

102000 2002 2004 2006 2008

Time (Year)

47

Institution Accounts

Figure 11: Total Backward Linkage of Household Accounts (15-28)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih RuC q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrC q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

13

6"s5 Ma (Tr iE) iE c5"[ih RuS q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

102000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih UrN q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih UrN q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrN q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih RuC q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

102000 2002 2004 2006 2008

Time (Year)

48

Institution Accounts

Figure 12: Total Backward Linkage of Household Accounts (29-35)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih RuS q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuS q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuS q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuS q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrS q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrS q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrS q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

13

62000 2002 2004 2006 2008

Time (Year)

s_ST_Ma

s_Dy_Ma

"s5 Ma (Tr iE) iE c5"[ih UrN q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih UrN q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih UrN q5 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

14

8"s5 Ma (Tr iE) iE c5"[ih RuC q1 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q2 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q3 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

10"s5 Ma (Tr iE) iE c5"[ih RuC q4 c5] : Sum All Backward Linkage (Tr iE) (1x11)

20

15

102000 2002 2004 2006 2008

Time (Year)

49

2 Dynamic Macro SAMs [s3]: The Case of Mozambique

Even though, dynamic Macro SAMs have been derived for the years 2000 to 2008, the

structures of some selected SAMs are presented here for illustration. In particular, SAMs

derived for 2000, and from 2005 to 2008, are presented below.

Table 21: Macro SAMs for selected years

Year 2000 Com Act FacLab

FacCap

FacLand Ent HH

ig Govt

ig YTax

ig CoTax ig Atax

ig Mduty

cC Cap

cC StkChg

w Cur AC

Total Demand

Commodity 49000.76 38167.5

2 7438.32 19487.34 825.78 5542.7

2 120462.43

Activity 97982.1

0 10021.1

5 108003.25

FacLab 42303.5 0.97 42304.55

FacCap 15655.26 15655.26

FacLand 1120.89 0.14 1121.03

Ent 15655.

26 69.62 15724.88

HH 42304

.55 1121.0

3 10332.

62 160.20 227.44 54145.83

ig Govt 94.56 985.30 3558.22 -77.23 2992.88 7553.73

ig IncomeTax 362.59 622.71 985.30

ig CoTaxNet 3558.22 3558.22

ig ATaxNet -77.23 -77.23

ig Mduty 2992.88 2992.88

cC Capital 1771.1

0 5334.46 -114.55 13322.

11 20313.12

cC StkChg 825.78 825.78

w Current AC

15929.23

3164.01 19093.24

Total Supply

120462.43 108003.25

42304.55

15655.26

1121.03

15724.88

54145.84 7553.73 985.30 3558.22 -77.23 2992.88 20313.12 825.78

19093.24

Year 2005 Com Act FacLab

FacCap

FacLand Ent HH

ig Govt

ig YTax

ig CoTax ig Atax

ig Mduty

cC Cap

cC StkChg

w Cur AC

Total Demand

Commodity 111497.26 92346.61

19440.77 27207.75 1152.93

40248.30 291893.61

Activity 222908.25

22798.00 245706.25

FacLab 96258.38 7.85 96266.23

FacCap 35622.27 35622.27

FacLand 2550.49 0.38 2550.87

Ent 35622.27 198.89 35821.16

HH 96266.23 2550.87

23511.03 457.62

1837.03 124622.78

ig Govt 215.17 4401.40 9945.84 -222.15

7329.93 21670.18

ig IncomeTax

1784.91

2616.49 4401.40

ig CoTaxNet 9945.84 9945.84

ig ATaxNet -222.15 -222.15

ig Mduty 7329.93 7329.93

cC Capital 3110.59

6861.67 1572.52

16815.88 28360.68

cC StkChg 1152.93 1152.93

w Current AC

51709.60

7199.46 58909.06

Total Supply

291893.62 245706.25

96266.23

35622.27 2550.87

35821.16

124622.77

21670.18

4401.40 9945.84 -222.15

7329.93 28360.67 1152.93

58909.06

Year 2007 Com Act FacLab

FacCap

FacLand Ent HH

ig Govt

ig YTax

ig CoTax ig Atax

ig Mduty cC Cap

cC StkChg

w Cur AC

Total Demand

Commodity

151277.84

126381.74

24384.71 34279.41

1452.59 61269.22 399045.51

50

Activity 302391.56

30927.18 333318.74

FacLab 130601.96 10.06 130612.03

FacCap 48331.78 48331.78

FacLand 3460.47 0.47 3460.94

Ent 48331.78 356.06 48687.84

HH 130612.02

3460.94

31899.42 819.27 2354.75 169146.40

ig Govt 291.93

9224.00

14717.00 -353.30

10532.80 34412.44

ig IncomeTax

3728.97

5495.03 9224.00

ig CoTaxNet

14717.00 14717.00

ig ATaxNet -353.30 -353.30

ig Mduty 10532.80 10532.80

cC Capital 2999.39

6342.45

8851.93 17538.22 35731.99

cC StkChg 1452.59 1452.59

w Current AC

71404.13

9768.12 81172.25

Total Supply

399045.49

333318.75

130612.02

48331.78

3460.94

48687.84

169146.40

34412.44

9224.00

14717.00 -353.30

10532.80 35732.00

1452.59 81172.25

Year 2008 Com Act FacLab

FacCap

FacLand Ent HH

ig Govt

ig YTax

ig CoTax ig Atax

ig Mduty cC Cap

cC StkChg

w Cur AC

Total Demand

Commodity

176051.63

151912.13

27592.37 42509.65

1801.35 67395.89 467263.01

Activity 351920.91

35992.80 387913.71

FacLab 151989.78 10.40 152000.18

FacCap 56246.75 56246.75

FacLand 4027.16 0.54 4027.70

Ent 56246.75 408.07 56654.82

HH 152000.19

4027.70

37123.38 938.94 2433.16 196523.36

ig Govt 339.74

11678.70

16576.00 -401.63

10935.30 39128.12

ig IncomeTax

4721.32

6957.38 11678.70

ig CoTaxNet

16576.00 16576.00

ig ATaxNet -401.63 -401.63

ig Mduty 10935.30 10935.30

cC Capital 3102.60

1661.06

10188.20 29359.15 44311.00

cC StkChg 1801.35 1801.35

w Current AC

87830.81

11367.78 99198.59

Total Supply

467263.02

387913.70

152000.19

56246.75

4027.70

56654.82

196523.36

39128.12

11678.70

16576.00 -401.63

10935.30 44311.00

1801.35 99198.59

51

s3_Mz_0217

"s3 (Tr A)" : Macro control. Total (A) payments

400,000

320,000

240,000

160,000

80,000

0

"s3 (Co A)" : Macro control. (Co) receipts from (A). (Input use)

200,000

160,000

120,000

80,000

40,000

0

"s3 (Fk A)" : Macro control. (Fk) receipts from (A).

60,000

48,000

36,000

24,000

12,000

0

"s3 (FL A)" : Macro control. (FL) receipts from (A).

200,000

160,000

120,000

80,000

40,000

0

"s3 (Fn A)" : Macro control. (Fn) receipts from (A).

6,000

4,800

3,600

2,400

1,200

0

"s3 (iT A )" : Macro control. (iT) receipts from (A).

0

-120

-240

-360

-480

-6002000 2002 2004 2006 2008

Time (Year)

s3_Mz_0217

"s3 (Tr Co)" : Total (Co) payments. Supply

600,000

480,000

360,000

240,000

120,000

0

"s3 (A Co)" : Macro control. (A) receipts from (Co). (Domestic Supply)

400,000

320,000

240,000

160,000

80,000

0

"s3 (iT Co)" : Macro control. (iT) receipts from (Co).

20,000

16,000

12,000

8,000

4,000

0

"s3 (iT Du)" : Macro control. (iT) receipts from (wC). (Duty)

20,000

16,000

12,000

8,000

4,000

0

"s3 (wC Co)" : Macro control. (wC) receipts from (Co). (Import)

100,000

80,000

60,000

40,000

20,000

02000 2002 2004 2006 2008

Time (Year)

3 Behaviours of Selective Accounts of the Dynamic SAM: The Case of Mozambique

Figure 13: Behaviours of Activity and Commodity Accounts of the Dynamic SAMs

52

s3_Mz_0217

"s3 (Tr iH)" : Macro control. Total (iH) payments

200,000

160,000

120,000

80,000

40,000

0

"s3 (A iH)" : Macro control. (A) receipts from (iH). (Home Production)

40,000

32,000

24,000

16,000

8,000

0

"s3 (Cc iH)" : Macro control. (Cc) receipts from (iH)

20,000

16,000

12,000

8,000

4,000

0

"s3 (Co iH)" : Macro control. (Co) receipts from (iH).

200,000

160,000

120,000

80,000

40,000

0

"s3 (iT iH)" : Macro control. (iT) receipts from (iH)

8,000

6,400

4,800

3,200

1,600

02000 2002 2004 2006 2008

Time (Year)

s3_Mz_0217

"s3 (Tr iG)" : Macro control. Total (iG) payments

40,000

32,000

24,000

16,000

8,000

0

"s3 (Cc iG)" : Macro control. (cC) receipts from (iG).

20,000

15,200

10,400

5,600

800

-4,000

"s3 (Co iG)" : Macro control. (Co) receipts from (iG). Cg

40,000

32,000

24,000

16,000

8,000

0

"s3 (Fn iG)" : Macro control. (Fn) receipts from (iG).

0.6

0.48

0.36

0.24

0.12

0

"s3 (iC iG)" : Macro control. (iC) receipts from (iG)

600

480

360

240

120

0

"s3 (iH iG)" : Macro control. (iH) receipts from (iG)

1,000

800

600

400

200

02000 2002 2004 2006 2008

Time (Year)

Figure 14: To illustrate their dynamic evolution reflecting the policy stances of the

government on revenue, expenditure, transfer programmes and savings instruments please

see Error! Reference source not found.XXXX for the SAM Layout and labelling

conventions used in the figures.

For instance, a sharp rise in revenue mobilization from the indirect sources (iT Co)

and direct sources (iT iH) is recorded from 2004 onward, perhaps capturing either reforms

in tax administration, increases in the tax rate or a combination of these two instruments.

The rise suggests that the country had embarked on a new and improved tax regime from

2004 onward.

Figure 14: Behaviours of Household and Government Accounts of the Dynamic SAMs

The savings behaviours (Cc iH) of households do not display systematic patterns. Such behaviours are expected as they are derived residually incorporating the total receipts and payments of their respective accounts. Similar behaviours have also been observed for the elements of other accounts of the dynamic SAMs (not reported here). The dynamic behaviours of the macro SAMs will also influence behaviours of the dynamic sectoral SAMs, multipliers and linkages.

53

Employment Working Papers

2008

1 Challenging the myths about learning and training in small and medium-sized

enterprises: Implications for public policy;

ISBN 978-92-2-120555-5 (print); 978-92-2-120556-2 (web pdf)

David Ashton, Johnny Sung, Arwen Raddon, Trevor Riordan

2 Integrating mass media in small enterprise development: Current knowledge and good

practices;

ISBN 978-92-2-121142-6 (print); 978-92-2-121143-3 (web pdf)

Gavin Anderson. Edited by Karl-Oskar Olming, Nicolas MacFarquhar

3 Recognizing ability: The skills and productivity of persons with disabilities.

A literature review;

ISBN 978-92-2-121271-3 (print); 978-92-2-121272-0 (web pdf)

Tony Powers

4 Offshoring and employment in the developing world: The case of Costa Rica;

ISBN 978-92-2-121259-1 (print); 978-92-2-121260-7 (web pdf)

Christoph Ernst, Diego Sanchez-Ancochea

5 Skills and productivity in the informal economy;

ISBN 978-92-2-121273-7 (print); 978-92-2-121274-4 (web pdf)

Robert Palmer

6 Challenges and approaches to connect skills development to productivity and

employment growth: India;

unpublished

C. S. Venkata Ratnam, Arvind Chaturvedi

7 Improving skills and productivity of disadvantaged youth;

ISBN 978-92-2-121277-5 (print); 978-92-2-121278-2 (web pdf)

David H. Freedman

8 Skills development for industrial clusters: A preliminary review;

ISBN 978-92-2-121279-9 (print); 978-92-2-121280-5 (web pdf)

Marco Marchese, Akiko Sakamoto

9 The impact of globalization and macroeconomic change on employment in Mauritius:

What next in the post-MFA era?;

ISBN 978-92-2-120235-6 (print); 978-92-2-120236-3 (web pdf)

Naoko Otobe

10 School-to-work transition: Evidence from Nepal;

ISBN 978-92-2-121354-3 (print); 978-92-2-121355-0 (web pdf)

New Era

54

11 A perspective from the MNE Declaration to the present: Mistakes, surprises and newly

important policy implications;

ISBN 978-92-2-120606-4 (print); 978-92-2-120607-1 (web pdf)

Theodore H. Moran

12 Gobiernos locales, turismo comunitario y sus redes:

Memoria: V Encuentro consultivo regional (REDTURS);

ISBN 978-92-2-321430-2 (print); 978-92-2-321431-9 (web pdf)

13 Assessing vulnerable employment: The role of status and sector indicators in Pakistan,

Namibia and Brazil;

ISBN 978-92-2-121283-6 (print); 978-92-2-121284-3 (web pdf)

Theo Sparreboom, Michael P.F. de Gier

14 School-to-work transitions in Mongolia;

ISBN 978-92-2-121524-0 (print); 978-92-2-121525-7 (web pdf)

Francesco Pastore

15 Are there optimal global configurations of labour market flexibility and security?

Tackling the ―flexicurity‖ oxymoron;

ISBN 978-92-2-121536-3 (print); 978-92-2-121537-0 (web pdf)

Miriam Abu Sharkh

16 The impact of macroeconomic change on employment in the retail sector in India:

Policy implications for growth, sectoral change and employment;

ISBN 978-92-2-120736-8 (print); 978-92-2-120727-6 (web pdf)

Jayati Ghosh, Amitayu Sengupta, Anamitra Roychoudhury

17 From corporate-centred security to flexicurity in Japan;

ISBN 978-92-2-121776-3 (print); 978-92-2-121777-0 (web pdf)

Kazutoshi Chatani

18 A view on international labour standards, labour law and MSEs;

ISBN 978-92-2-121753-4 (print);978-92-2-121754-1(web pdf)

Julio Faundez

19 Economic growth, employment and poverty in the Middle East and North Africa;

ISBN 978-92-2-121782-4 (print); 978-92-2-121783-1 (web pdf)

Mahmood Messkoub

20 Global agri-food chains: Employment and social issues in fresh fruit and vegetables;

ISBN 978-92-2-121941-5(print); 978-92-2-121942-2 (web pdf)

Sarah Best, Ivanka Mamic

55

21 Trade agreements and employment: Chile 1996-2003;

ISBN 978-92-121962-0 (print); 978-92-121963-7 (web pdf)

22 The employment effects of North-South trade and technological change;

ISBN 978-92-2-121964-4 (print); 978-92-2-121965-1 (web pdf)

Nomaan Majid

23 Voluntary social initiatives in fresh fruit and vegetable value chains;

ISBN 978-92-2-122007-7 (print); 978-92-2-122008-4 (web pdf)

Sarah Best, Ivanka Mamic

24 Crecimiento económico y empleo de jóvenes en Chile: Análisis sectorial y

proyecciones;

ISBN 978-92-2-321599-6 (print); 978-92-2-321600-9 (web pdf)

Mario D. Velásquez Pinto

25 The impact of codes and standards on investment flows to developing countries;

ISBN 978-92-2-122114-2 (print); 978-92-2-122115-9 (web pdf)

Dirk Willem te Velde

26 The promotion of respect for workers‘ rights in the banking sector:

Current practice and future prospects;

ISBN 978-92-2-122116-6 (print); 978-2-122117-3 (web pdf)

Emily Sims

2009

27 Labour market information and analysis for skills development;

ISBN 978-92-2-122151-7 (print); 978-92-2-122152-4 (web pdf)

Theo Sparreboom, Marcus Powell

28 Global reach - Local relationships: Corporate social responsibility, worker‘s rights and

local development;

ISBN 978-92-2-122222-4 (print); 978-92-2-122212-5 (web pdf)

Anne Posthuma, Emily Sims

29 Investing in the workforce: Social investors and international labour standards;

ISBN 978-92-2-122288-0 (print); 978-92-2-122289-7 (web pdf)

Elizabeth Umlas

30 Rising food prices and their implications for employment, decent work and

poverty reduction;

ISBN 978-92-2-122331-3 (print); 978-92-2-122332-0 (web pdf)

Rizwanul Islam, Graeme Buckley

56

31 Economic implications of labour and labour-related laws on MSEs: A quick review of

the Latin American experience;

ISBN 978-92-2-122368-9 (print); 978-92-2-122369-6 (web pdf)

Juan Chacaltana

32 Understanding informal apprenticeship – Findings from empirical research in

Tanzania;

ISBN 978-92-2-122351-1 (print); 978-92-2-122352-8 (web pdf)

Irmgard Nübler, Christine Hofmann, Clemens Greiner

33 Partnerships for youth employment. A review of selected community-based initiatives;

ISBN 978-92-2-122468-6 (print); 978-92-2-122469-3 (web pdf)

Peter Kenyon

34 The effects of fiscal stimulus packages on employment;

ISBN 978-92-2-122489-1 (print); 978-92-2-122490-7 (web pdf)

Veena Jha

35 Labour market policies in times of crisis;

ISBN 978-92-2-122510-2 (print); 978-92-2-122511-9 (web pdf)

Sandrine Cazes, Sher Verick, Caroline Heuer

36 The global economic crisis and developing countries: Transmission channels, fiscal

and policy space and the design of national responses;

ISBN 978-92-2-122544-7 (print); 978-92-2-122545-4 (web pdf)

Iyanatul Islam

37 Rethinking monetary and financial policy:

Practical suggestions for monitoring financial stability while generating employment

and poverty reduction;

ISBN 978-92-2-122514-0 (print); 978-92-2-122515-7 (web pdf) Gerald Epstein

38 Promoting employment-intensive growth in Bangladesh: Policy analysis of the

manufacturing and service sectors;

ISBN 978-92-2-122540-9 (print); 978-92-2-122541-6 (web pdf)

Nazneen Ahmed, Mohammad Yunus, Harunur Rashid Bhuyan

39 The well-being of labour in contemporary Indian economy: What‘s active labour

market policy got to do with it?;

ISBN 978-92-2-122622-2 (print); 978-92-2-122623-9 (web pdf)

Praveen Jha

40 The global recession and developing countries;

ISBN 978-92-2-122847-9 (print); 978-92-2-122848-6 (web pdf)

Nomaan Majid

57

41 Offshoring and employment in the developing world: Business process outsourcing in

the Philippines;

ISBN 978-92-2-122845-5 (print); 978-92-2-122846-2 (web pdf)

Miriam Bird, Christoph Ernst

42 A survey of the Great Depression as recorded in the International Labour Review,

1931-1939;

ISBN 978-92-2-122843-1 (print); 978-92-2-122844-8 (web pdf)

Rod Mamudi

43 The price of exclusion: The economic consequences of excluding people with

disabilities from the world or work;

ISBN 978-92-2-122921-6 (print); 978-92-2-122922-3 (web pdf)

Sebastian Buckup

44 Researching NQFs: Some conceptual issues;

ISBN 978-92-2-123066-3 (print), 978-92-2-123067-0 (web pdf)

Stephanie Allais, David Raffe, Michael Young

45 Learning from the first qualifications frameworks;

ISBN 978-92-2-123068-7 (print), 978-92-2-123069-4 (web pdf)

Stephanie Allais, David Raffe, Rob Strathdee, Leesa Wheelahan, Michael Young

46 International framework agreements and global social dialogue:

Lessons from the Daimler case;

ISBN 978-92-2-122353-5 (print); 978-92-2-122354-2 (web pdf)

Dimitris Stevis

2010

47 International framework agreements and global social dialogue:

Parameters and prospects;

ISBN 978-92-2-123298-8 (print); 978-92-2-122299-5 (web pdf)

Dimitris Stevis

48 Unravelling the impact of the global financial crisis on the South African labour

market;

ISBN 978-92-2-123296-4 (print); 978-92-2-123297-1 (web pdf)

Sher Verick

49 Guiding structural change: The role of government in development;

ISBN 978-92-2-123340-4 (print); 978-92-2-123341-1 (web pdf)

Matthew Carson

50 Les politiques du marché du travail et de l'emploi au Burkina Faso;

ISBN 978-92-2-223394-6 (print); 978-92-2-223395-3 (web pdf)

Lassané Ouedraogo, Adama Zerbo

58

51 Characterizing the school-to-work transitions of young men and women:

Evidence from the ILO school-to-work transition surveys;

ISBN 978-92-2-122990-2 (print); 978-92-2-122991-9 (web pdf)

Makiko Matsumoto, Sara Elder

52 Exploring the linkages between investment and employment in Moldova:

A time-series analysis

ISBN 978-92-2-122990-2 (print); 978-92-2-122991-9 (web pdf)

Stefania Villa

53 The crisis of orthodox macroeconomic policy: The case for a renewed commitment to

full employment;

ISBN 978-92-2-123512-5 (print); 978-92-2-123513-2 (web pdf)

Muhammed Muqtada

54 Trade contraction in the global crisis: Employment and inequality effects in India and

South Africa;

ISBN 978-92-2124037-2 (print); 978-92-2124038-9 (web pdf)

David Kucera, Leanne Roncolato, Erik von Uexkull

55 The impact of crisis-related changes in trade flows on employment: Incomes, regional

and sectoral development in Brazil;

Forthcoming

Scott McDonald, Marion Janse, Erik von Uexkull

56 Envejecimiento y Empleo en América Latina y el Caribe;

ISBN 978-92-2-323631-1 (print); 978-92-2-323632-8 (web pdf)

Jorge A. Paz

57 Demographic ageing and employment in China;

ISBN 978-92-2-123580-4 (print); 978-92-2-123581-1 (web pdf)

Du Yang, Wrang Meiyan

58 Employment, poverty and economic development in Madagascar: A macroeconomic

framework;

ISBN 978-92-2-123398-5 (print); 978-92-2-123399-2 (web pdf)

Gerald Epstein, James Heintz, Léonce Ndikumana, Grace Chang

59 The Korean labour market: Some historical macroeconomic perspectives;

ISBN 978-92-2-123675-7 (print); 978-92-2-123676-4 (web pdf)

Anne Zooyob

60 Les Accords de Partenariat Economique et le travail décent:

Quels enjeux pour l‘Afrique de l‘ouest et l‘Afrique centrale?;

ISBN 978-92-2-223727-2 (print); 978-92-2-223728-9 (web pdf)

Eléonore d’Achon; Nicolas Gérard

59

61 The great recession of 2008-2009: Causes, consequences and policy responses;

ISBN 978-92-2-123729-7 (print); 978-92-2-123730-3 (web pdf)

Iyanatul Islam, Sher Verick

62 Rwanda forging ahead: The challenge of getting everybody on board;

ISBN 978-92-2-123771-6 (print); 978-92-2-123772-3 (web pdf)

Per Ronnås (ILO), Karl Backéus (Sida); Elina Scheja (Sida)

63 Growth, economic policies and employment linkages in Mediterranean countries:

The cases of Egypt, Israel, Morocco and Turkey;

ISBN 978-92-2-123779-2 (print); 978-92-2-123780-8 (web pdf)

Gouda Abdel-Khalek

64 Labour market policies and institutions with a focus on inclusion, equal opportunities

and the informal economy;

ISBN 978-92-2-123787-7 (print); 978-92-2-123788-4 (web pdf)

Mariangels Fortuny, Jalal Al Husseini

65 Les institutions du marché du travail face aux défis du développement:

Le cas du Mali;

ISBN 978-92-2- 223833-0 (print); 978-92-2-223834-7 (web pdf)

Modibo Traore, Youssouf Sissoko

66 Les institutions du marché du travail face aux défis du développement:

Le cas du Bénin;

ISBN 978-92-2-223913-9 (print); 978-92-2-223914-6 (web pdf)

Albert Honlonkou, Dominique Odjo Ogoudele

67 What role for labour market policies and institutions in development?Enhancing

security in developing countries and emerging economies;

ISBN 978-92-2-124033-4 (print); 978-92-2-124034-1 (web pdf)

Sandrine Cazes, Sher Verick

68 The role of openness and labour market institutions for employment dynamics during

economic crises;

Forthcoming

Elisa Gameroni, Erik von Uexkull, Sebastian Weber

69 Towards the right to work:

Innovations in Public Employment programmes (IPEP);

ISBN 978-92-2-124236-9 (print); 978-92-2-1244237-6 (web pdf)

Maikel Lieuw-Kie-Song, Kate Philip, Mito Tsukamoto, Marc van Imschoot

70 The impact of the economic and financial crisis on youth employment: Measures for

labour market recovery in the European Union, Canada and the United States;

ISBN 978-92-2-124378-6 (print); 978-92-2-124379-3 (web pdf)

Niall O’Higgins

60

71 El impacto de la crisis económica y financiera sobre el empleo juvenil en América

Latina: Medidas des mercado laboral para promover la recuperación del empleo

juvenil;

ISBN 978-92-2-324384-5 (print); 978-92-2-324385-2 (web pdf)

Federio Tong

72 On the income dimension of employment in developing countries;

ISBN: 978-92-2-124429-5 (print);978-92-2-124430-1 (web pdf)

Nomaan Majid

73 Employment diagnostic analysis: Malawi;

ISBN 978-92-2-123101-0 (print); 978-92-2-124102-7 (web pdf)

Per Ronnas

74 Global economic crisis, gender and employment:

The impact and policy response;

ISBN 978-92-2-14169-0 (print); 978-92-2-124170-6 (web pdf)

Naoko Otobe

2011

75 Mainstreaming environmental issues in sustainable enterprises: An exploration of

issues, experiences and options;

ISBN 978-92-2-124557-5 (print); 978-92-2-124558-2 (web pdf)

Maria Sabrina De Gobbi

76 The dynamics of employment, the labour market and the economy in Nepal

ISBN 978-92-2-123605-3 (print); 978-92-2-124606-0 (web pdf)

Shagun Khare , Anja Slany

77 Industrial policies and capabilities for catching-up:

Frameworks and paradigms

Irmgard Nuebler

78 Economic growth, employment and poverty reduction:

A comparative analysis of Chile and Mexico

ISBN 978-92-2-124783-8 (print); 978-92-2-124784-5 (web pdf)

Alicia Puyana

79 Macroeconomy for decent work in Latin America and the Caribbean

ISBN 978-92-2-024821-8 (print); 978-92-2-024822-5 (web pdf)

Ricardo Ffrench-Davis

A complete list of previous working papers can be found on: htt:// www.ilo.org/employment

61

Employment Sector For more information visit our site: http://www.ilo.org/employment

International Labour Office Employment Sector 4, route des Morillons CH-1211 Geneva 22 Email: edempdoc@ilo.org