1. WP 10 Comparative policy analysis Universidade Atlântica - Portugal
UATLA - SMART Workshop Grenoble January 2005

2. UATLA - SMART Workshop Grenoble January 2005
Comparative Analysis
Report: Main Topics
Water renewable and withdrawal (trends) Socioeconomic indicators and water resources Population and water scarcity Water scarcity and sustainable development Comparative water policies
Socioeconomic Dimensions and Water Resources Water in SMART case studies Water and Socioeconomic Aspects Water availability imbalances Water Uses Population and Water Scarcity Trends in Water renewable and withdrawal Water Use in agriculture Water use for domestic purposes Water use for industry Water Scarcity and Sustainable Development Comparative Water Policy Dymensions
UATLA - SMART Workshop Grenoble January 2005

3. National Water Indicators Water Policies Analysis
UATLA - SMART Workshop Grenoble January 2005

4. Comparative Complex Water Resources Indicators: National Level
UATLA - SMART Workshop Grenoble January 2005

5. HDI – Human development Index WPI – Water Poverty Index
Comparative Water Resources Indicators
HDI – Human development Index
WPI – Water Poverty Index
Resources Index
Access to safe drinking water Index
Capacity Index
Use of Water Index
Environmental Index
WSI - Water Stress Index
SWSI - Social Water Stress Index
UATLA - SMART Workshop Grenoble January 2005

6. Human Development Index
Comparative Water Resources Indicators
Human Development Index
Components of HDI
life expectancy
educational attainment
income
The HDI sets shows where each country stands in relation to these scales – expressed as a value between 0 and 1
The scores for the three dimensions are then averaged in an overall index
It is here taken as the best available approach to the adaptive capacity of a society facing scarcity of water
The HDI facilitates the determination of priorities for policy intervention and the evaluation of progress over time
UATLA - SMART Workshop Grenoble January 2005
Source: UN Human Development Report

7. Human Development Index
Comparative Water Resources Indicators
Human Development Index
UN World Development Report
UATLA - SMART Workshop Grenoble January 2005

8. Human Development Index - 2000
Comparative Water Resources Indicators
Human Development Index
Egypt
0.635
Jordan
0.714
Lebanon
0.758
Tunisia
Turkey
0.735
UATLA - SMART Workshop Grenoble January 2005
Source: World Development Report (UNDP), 2000

9. Comparative Water Resources Indicators
Water Poverty Index (Lawrence, et al 2002)
Combining water scarcity issues and socio-economic aspects
5 aspects considered:
Resources, Access, Use, Capacity and Environment
The idea of WPI is to combine measures of water availability and access with measures of people’s capacity to access water
Water Availability Index
Meigh et al. (1999) took in their GWAVA (Global Water AVailability Assessment) model the temporal variability of water availability into account. The index includes surface water as well as groundwater resources, and compares the total amount to the demands of all sectors, i.e. domestic, industrial and agricultural demands. The month with the maximum deficit or minimum surplus respectively is decisive. The index is normalised to the range –1 to +1.
When the index is zero, availability and demands are equal.
Environmental Sustainability Index
Index of water scarcity - An indicator that combines information about water abstractions and water availability is the index of water scarcity. It is defined by the intensity of use of water resources, i.e. the gross freshwater abstractions as percentage of the total renewable water resources or as percentage of internal water resources.
Human Needs Index
Recently, the Water Poverty Index (WPI) (Sullivan, 2002, Lawrence et al., 2002), developed by the Centre for Ecology and Hydrology (CEH) in Wallingford, has been intensively discussed. This index tries to show the connection between water scarcity issues and socio-economic aspects. It ranks countries according to the provision of water, combining five components which are:
Resources
Access
Use
Capacity and
Environment
Each of these components is derived from two to five indicators which are normalised to a scale from 0 to 1.
In case of an equal weighting, the subindex and component values are then calculated as a simple average of the corresponding indicators, and this value is multiplied by 20. The overall index is generated as a sum of the component values so that the value is between 0 and 100. A value of 100 is only possible if a country ranks best in all of the five components.
Ex:
People can be ‘water poor’ in the sense of not having sufficient water for their basic needs because it is not available
People can also be “water poor” because they are “income poor”; although water is available
UATLA - SMART Workshop Grenoble January 2005

10. Comparative Water Resources Indicators
Water Poverty Index
UATLA - SMART Workshop Grenoble January 2005

11. Comparative Water Resources Indicators
Water Poverty Index - Conceptual Framework
The basic calculation, of a 5 components, is based on the following formula:
x i – x min / x max – x min
where xi , xmax and xmin are the original values for country i, the highest value country, and the lowest value country respectively.
The indices therefore show a country’s relative position and for any one indicator this lies between 0 and 1.
Within each of the five components, sub-component indices are 5 averaged to get the component index. Each of the five component indices is multiplied by 20 and then added together to get the final index score for the WPI, which is in the range 0 to 100.
The conceptual framework for the index can be illustrated in the four quadrant
diagram in Figure 1. Quadrant A indicates a country or community which scores
relatively highly on capacity and use, but has a low score on availability and
access. Quadrant B shows relatively high scores on both sets of factors. Quadrant
C indicates both water and income poverty, while quadrant D covers relatively low
capacity and use but high availability and access1. However, this is not a complete
description of the framework because the fifth factor, environment, should also be
included, but has been omitted here for presentational simplicity.
Water Poverty Index
[Resources] + [Access]+ [Use] + [Capacity] + [Environment]
UATLA - SMART Workshop Grenoble January 2005

12. National Values for the Water Poverty Index
Comparative Water Resources Indicators
National Values for the Water Poverty Index
71. Egypt
78. Turkey
86. Lebanon
The resulting Water Poverty Index is presented in rank score order with the highest
scoring country first (see Figure 2 and Appendix 1). The results show few
surprises. Of the 147 countries with relatively complete data, most of the countries
in the top half are either developed or richer developing. There are a few notable
exceptions: Guyana scores highly on resources, access and use to get into fifth
position, while Belgium is 56th in the list, having scored low on resources and on
environment. The US and New Zealand, though they score relatively highly on
Environment score very low on use. South Africa, low on the resources index, is
relatively high on the other sub-indices reflecting its progressive policies on access
and management. The index as presented does suggest areas of current future
policy concentration with the overall performance. Data are also provided in
Appendix 1 on the Falkenmark index measure: that is, water resources per capita
per year. The correlation between the Falkenmark index of water stress and our
Water Poverty Index is only 0.35 which suggests that the WPI does add to the
information available in assessing progress towards sustainable water provision7.
Table 2 below shows the correlation matrix for the five indices and the WPI. There
is very little correlation between the different sub-indices, with the exception of
access and capacity. Although intuitively, a strong association between these two
indicators is to be expected, we might have expected a stronger negative
correlation between resources and use (the more scarce the resources, the better
use is made of them), and a negative association between resources and
environment (the more scarce the resources, the more attention is paid to
conservation generally).
107. Tunisia
118. Jordan
UATLA - SMART Workshop Grenoble January 2005

13. 5 components (with ranks)
Comparative Water Resources Indicators
Water Poverty Index
5 components (with ranks)
Resources
Rank
Access
Capacity
Use
Environment
Egypt
3.4
136
18.3 34
13.3 86
12.5
127
10.5
101
Jordan
0.4
144 13 82
14.9 63
10.8 97
7.3
143
Lebanon
6.1
117
15.7 56
15.8 45 88
7.7
140
Tunisia
3.2
137
12.4 85
15.3 55
12.2
123
7.8
Turkey 87
14.8 62
13.1 91
10.7 93
10.1
110
UATLA - SMART Workshop Grenoble January 2005

14. UATLA - SMART Workshop Grenoble January 2005
Water Poverty Index
Resources Index
This index combines two separate indices: one of internal water resources and the
second of external water inflows. Both are calculated on a log scale to reduce the
distortion caused by high values, and expressed on a per capita basis. External
water inflow amounts are reduced by 50%; this is an arbitrary factor, but it is an
attempt to give reduced weight to external water inflows because these resources
are less secure than those generated internally within a country. The resources
index is a basic indicator of water availability. A significant additional factor that
affects availability is the reliability or variability of the resource; it should be
included because the more variable the resource, the smaller is the proportion of
the total resource that can actually be used. However, we were unable to find an
indicator of variability that is available at the national scale, and this factor had to
be omitted. Finally, water quality is also an important factor influencing the
availability of the resource. Data on this were found, but have been included under
the environment component (see below). To avoid duplication, it was not also
considered as part of the resources component.
UATLA - SMART Workshop Grenoble January 2005
Sources: World Resources Institute, 2000; Gleick, 2000

15. UATLA - SMART Workshop Grenoble January 2005
Water Poverty Index
Access to Water
There are three components to this index:
• percentage of the population with access to safe water
• percentage of the population with access to sanitation
• an index which relates irrigated land, as a proportion of arable land, to internal
water resources. This is calculated by taking the percentage of irrigated land
relative to the internal water resource index and then calculating the index of
the result. The idea behind this method of calculation is that countries with a
high proportion of irrigated land relative to low internal available water
resources are rated more highly than countries with a high proportion of
irrigated land relatively to high available internal water resources.
This index tries to take into account basic water and sanitation needs for relatively
poor agriculturally-based countries, recognising that water availability for growing
food is as important as for domestic and human consumption.
UATLA - SMART Workshop Grenoble January 2005
Sources: World Resources Institute, 2000; and HDR 2000

16. UATLA - SMART Workshop Grenoble January 2005
Water Poverty Index
Capacity – 2000/01
There are four components to this index.
• Log GDP per capita (PPP) (US$). This is the average income per head of
population adjusted for the purchasing power of the currency. This is
considered to be a much more accurate measure of the average standard of
living across countries. These data are presented in log form in order to reduce
the impact of very high values.
under-5 mortality rate (per 1000 live births). This is a well-established health
indicator, and it is one that is closely related to access to clean water.
• UNDP education index from the Human Development Report 2001.
• the Gini coefficient. This is a well known measure of inequality based on the
Lorenz curve which gives the distribution of income across the population.3
Where the Gini coefficient is not reported, the Capacity index is based only on
the first three sub-indices.
This index tries to capture those socio-economic variables which can impact on
access to water or are a reflection of water access and quality. Introducing the Gini
coefficient here is an attempt to adjust capacity to enjoy access to clean water by a
measure of the unequal distribution of income.
Sources: GDP - HDR 2001; Under-5 mortality - World Resources Institute, 2000; Education - HDR 2001
UATLA - SMART Workshop Grenoble January 2005

17. UATLA - SMART Workshop Grenoble January 2005
Water Poverty Index
Use – 2000/01
This index has three components:
• domestic water use per capita (m3/cap/yr). This index takes 50 litres per
person per day as a reasonable target for developing countries.4 We then
construct a two-way index such that countries at 50 litres = 1. Countries below
the minimum have an index calculated such that the lower the value the more
they are below the minimum. Countries above the minimum have a lower value
on the index the higher they are above 50 litres.5 This gives some measure of
‘excessive’ use.
• industrial water use per capita (m3/cap/yr). Here the proportion of GDP derived
from industry is divided by the proportion of water used by industry. The index
is derived in the usual way: the higher the ratio of industrial value added share
to industrial water use share, the higher the score on the index. This gives a
crude measure of water use efficiency.
• agricultural water use per capita (m3/cap/yr). The index is calculated in the
same way as for industrial water use.
UATLA - SMART Workshop Grenoble January 2005
Sources: Gleick, 2000; World Resources Institute, 2000; World Bank, 2001

18. UATLA - SMART Workshop Grenoble January 2005
Water Poverty Index
Environment
This index tries to capture a number of environmental indicators which reflect on
water provision and management and which are included in the Environmental
Sustainability Index (ESI) (World Economic Forum et al, 2001). These indicators
not only cover water quality and ‘stress’, but also the degree to which water and the
environment generally, and related information, are given importance in a country’s
strategic and regulatory framework.
This index is calculated on the basis of an average of five component indices.
These are:
• an index of water quality based on measures of
• dissolved oxygen concentration,
• phosphorus concentration,
• suspended solids
• electrical conductivity;
• an index of water stress6 based on indices of
• fertilizer consumption per hectare of arable land,
• pesticide use per hectare of crop land,
• industrial organic pollutants per available fresh water
• the percentage of country's territory under severe water stress (again the
ESI’s terminology)
• an index of regulation and management capacity based on measures of
• environmental regulatory stringency,
• environmental regulatory innovation,
• percent of land area under protected status
• the number of sectoral EIA guidelines;
• an index of informational capacity based on measures of availability of
sustainable development information at the national level, environmental
strategies and action plans, and the percentage of ESI variables missing from
public global data sets;
• an index of biodiversity based on the percentage of threatened mammals and
birds.
• Table 1 provides a summary of the structure of the index and the data used to
build it.
UATLA - SMART Workshop Grenoble January 2005
Sources: World Economic Forum, Yale Centre for Environmental Law and Policy, 2001

19. Comparative Water Resources Indicators
Water Poverty Index – 2000/01
Egypt 58
Jordan
46.3
Lebanon
55.8
Tunisia
50.9
Turkey
56.5
UATLA - SMART Workshop Grenoble January 2005

20. Water Stress Index (Falkenmark)
Comparative Water Resources Indicators
Water Stress Index (Falkenmark)
Water availability per person, calculated as an average according both temporal and spatial scale and thereby omits water shortages in dry seasons or in certain regions within special characteristics
It is the number of hundreds of people who has to share m³ annually available renewable water
UATLA - SMART Workshop Grenoble January 2005

21. Water Stress Index (Falkenmark, 1989)
Comparative Water Resources Indicators
Water Stress Index (Falkenmark, 1989)
Originally, the indicator based on the estimation that a flow unit of 1,000,000 m³ of water can support 2,000 people in a society with a high level of development.
Water availability of more than 1,700m³/capita/year is defined as the threshold above which water shortage occurs only irregularly or locally. Below this level, water scarcity arises in different levels of severity.
It does not take the water quality into account at all or does it give information about a country’s ability to use the resources. Even if a country has sufficient water according to the WSI, these water resources possibly cannot be used because of pollution or insufficient access to them.
UATLA - SMART Workshop Grenoble January 2005

22. Comparative Water Resources Indicators
Water Stress Index
Egypt 11
Jordan 31
Lebanon 5
Tunisia 23
Turkey 3
Unit - Hundreds of persons per flow unit. (One flow unit is one million m³ of renewable water)
Sources: World Resources Institute, 2000; and HDR 2000; World Development Report (UNDP), 2000
UATLA - SMART Workshop Grenoble January 2005

23. Social Water Stress Index (Ohlsson, Leif 1999)
Comparative Water Resources Indicators
Social Water Stress Index (Ohlsson, Leif 1999)
Social Water Stress Index represents a society’s social adaptive capacity in facing the challenges of physical water scarcity
Dividing the Water Stress Index by the Human Development Index for each country
A higher value indicates a greater degree of social water stress
UATLA - SMART Workshop Grenoble January 2005

24. Social Water Stress Index
Comparative Water Resources Indicators
Social Water Stress Index
Egypt 17
Jordan 43
Lebanon 8
Tunisia 31
Turkey 4
Unit - hundreds of persons per flow unit; divided by HDI
Sources: World Resources Institute, 2000; and HDR 2000; World Development Report (UNDP), 2000
UATLA - SMART Workshop Grenoble January 2005

25. Correlation Matrix - world countries
Comparative Water Resources Indicators
Correlation Matrix - world countries
Resources
Access
Capacity
Use
Environment
HDI
WPI
WSI
SWSI
0,054
-0,057
0,822
-0,012
-0,056
-0,110
0,276
0,271
0,280
-0,276
0,029
0,868
0,941
-0,119
0,467
0,456
0,853
0,767
0,122
0,809
0,584
0,145
0,109
-0,038
0,055
0,108
0,345
0,628
0,073
0,014
-0,026
0,027
0,016
0,291
0,974
UATLA - SMART Workshop Grenoble January 2005

26. Correlation Matrix - SMART countries
Comparative Water Resources Indicators
Correlation Matrix - SMART countries
Resources
Access
Capacity
Use
Environment
HDI
WPI
WSI
SWSI
0,304
-0,284
-0,497
-0,341
0,252
-0,246
0,463
0,717
-0,922
0,360
0,420
-0,543
0,544
-0,821
-0,566
0,753
0,817
-0,494
0,167
0,776
-0,214
-0,930
-0,628
0,366
0,215
-0,606
-0,171
-0,917
-0,949
-0,584
0,361
0,228
-0,594
-0,205
-0,903
0,998
UATLA - SMART Workshop Grenoble January 2005

27. Water Policies Analysis
UATLA - SMART Workshop Grenoble January 2005

28. UATLA - SMART Workshop Grenoble January 2005
Comparative Analysis
Objectives
To compare water policies and practices between five countries (case studies) Typifying each case study departing from a common list of indicators Compare the policies adopted by each case study region with EU-WFD Description of the main causes and effects of water scarcity
UATLA - SMART Workshop Grenoble January 2005

29. Key Institutional Framework
Water Policies Analysis
Key Institutional Framework
Egypt: There is a shortage of institutional capabilities for monitoring and land use changes. The main characteristics of water regulations are set by Law 4/1994. This law deals with marine pollution in general and land based sources which require treatment before disposal. It sets limits on possible discharge in the marine environment.
Lebanon: In general, water related legislation is out of date. Legislation concerned with land use and specific sectoral water management is lacking, as are laws concerned with the preservation and protection of natural resources and pollution control. Institutional capabilities for monitoring and implementing laws are poor.
Recently a reorganisation of water management has lead to the fusion of 21 institutions into 4 main bodies responsible for drinking water, irrigation and waste water treatment. Along with this institutional reform, a French company has been employed to fill management gaps with personnel and know-how for the next four years The new re-organisation should lead to better control of water prices, quality & allocation.
UATLA - SMART Workshop Grenoble January 2005

30. Key Institutional Framework
Water Policies Analysis
Key Institutional Framework
Jordan: The establishment of the Aqaba Special Economic Zone Authority will probably increase tourist activity and therefore water demand. No more data available about water legal framework
Tunisia: Since the beginning of the 60’s, a vast program to access alternative water sources, or non conventional water, has been applied. No more data available about water legal framework
Turkey : There are serious institutional, legal, social and economic drawbacks, which enhance water allocation and environmental pollution problems. There are constraints to achieving basin management objectives. Institutional evolution is slow in comparison to rapid evolution in water management problems. Legislation used in current management practices is too old and can not meet current demands.
UATLA - SMART Workshop Grenoble January 2005

31. Water Policies Analysis
Water Price
Egypt: Legislation doesn’t establish water price for irrigation as yet
Lebanon: Legislation that regulates water prices is out of date
Jordan: The main legislation on water price was established in 1997 and updated in 2003, the price of water is regulated for all uses
UATLA - SMART Workshop Grenoble January 2005

32. Water Policies Analysis
Water Price
Tunisia: Water cost is calculated by consumption ranges. This system is implemented Nationally. Water cost is proportional to the specific use and the different set quantities used every term. Unique prices are set for tourism and agriculture.
Turkey: There is no specific regulation to determine the price of surface water or groundwater. If consumers use water for irrigation from the water distribution systems installed by government, they pay for water considering the cost of the maintenance and operation of the system. Domestic and industrial water prices are determined by local municipalities if the consumers use the public water distribution systems.
Water cost is calculated by consumption brackets:
m3 = €/m3 / term; m3 = 0.136€/ m3 / term;
41 – 70 m3 = 0.273€/ m3 / term; m3 = 0.414€/ m3 / term;
150 m3 = €/ m3 / term. This system is implemented Nationally. Water cost is proportional to the specific use and the different set quantities used every term. Unique prices are set for tourism (0.506€/ m3) and agriculture (0.041€/ m3).
UATLA - SMART Workshop Grenoble January 2005

33. Water Rights and Water Allocation
Water Policies Analysis
Water Rights and Water Allocation
Egypt: Traditional water rights for irrigation are ensured by law.
Lebanon: Legislation affecting water rights does not take a global or environmental approach.
Jordan: There is a lack of legislation concerning water rights. Domestic use is given priority to followed by tourism and industry. The remaining water is allocated to agriculture.
UATLA - SMART Workshop Grenoble January 2005

34. Water Rights and Water Allocation
Water Policies Analysis
Water Rights and Water Allocation
Tunisia: There are no groups that are given priority. Water demand is satisfied in every case.
Turkey: The law that governs surface water use rights in Turkey foresees that water is a public good which everyone is entitled to use, subject to the rights of prior users. There is no registration system for surface water rights or water use. Each landowner has the right to use groundwater on the condition that it is used for meeting personal needs and after getting permission from DSI.
UATLA - SMART Workshop Grenoble January 2005

35. Water Policies Analysis
Water Quality
Egypt: In general, legislation for water quality is weak. There are requirements for the treatment of land based pollution sources before disposal and limits on possible discharge in the marine environment.
Lebanon: Quality standards and controls are lacking as part of an integrated overall watershed approach.
Jordan: Existing regulation about water quality is very restricted
Tunisia: Work in progress to identify water quality standards
Turkey: There is a surplus of regulations concerning water quality
UATLA - SMART Workshop Grenoble January 2005

36. Water Policies Analysis
Comparative Analysis
Problems related to international comparative analysis
differences in implementation policies
goal differences
differences in steering systems
At the theoretical point of view, the international scale of analysis is more difficult to obtain the optimal preconditions for comparative analysis
optimal preconditions for comparative analysis,
and for the formation of the required indicators and criteria, occur when the
objects of evaluation are as similar as possible.
This situation is impossible to consider when we work at international level of comparative analysis
UATLA - SMART Workshop Grenoble January 2005

37. Detailed task WP 10 - Comparative Policy Analysis 4 2005 Jan Feb Mar
Task Name
% Comp
Nº Months
2005
Jan
Feb
Mar
Apr
May
Jun
National Water Indicators: Comparative Analysis 4
Completing the Analysis
90% 2
Writing the Report
20%
Water Policies Analysis
Data inputs (Improvement)
75%
Compiled and format WP10 deliverable (Report) 0%
optimal preconditions for comparative analysis,
and for the formation of the required indicators and criteria, occur when the
objects of evaluation are as similar as possible.
This situation is impossible to consider when we work at international level of comparative analysis
UATLA - SMART Workshop Grenoble January 2005