Content uploaded by Alemayehu Seyoum Taffesse
Author content
All content in this area was uploaded by Alemayehu Seyoum Taffesse on Apr 20, 2017
Content may be subject to copyright.
Crop Production in Ethiopia: Regional Patterns and Trends
Alemayehu Seyoum Taffesse, Paul Dorosh and Sinafikeh Asrat
Development Strategy and Governance Division, International Food Policy Research
Institute, Ethiopia Strategy Support Program II, Ethiopia
IFPRI -ADDIS ABABA
P.O. Box 5689
Addis Ababa, Ethiopia
Tel: +251-11-646-2921
Fax: +251-11-646-2318
E-mail: ifpri-addis@cgiar.org
IFPRI HEADQU ARTERS
International Food Policy Research Institute
2033 K Street, NW • Washington, DC 20006-1002
USA
Tel: +1-202-862-5600
Skype: IFPRIhomeoffice
Fax: +1-202-467-4439
E-mail: ifpri@cgiar.org
www.ifpri.org
Ethiopia Strategy Support Program II (ESSP II)
ESSP II Working Paper No. 0016
March 2011
ESSP II Working Paper 16
ii
THE ETHIOPIA STRATEGY SUPPORT PROGRAM II (ESSP II)
WORKING PAPERS
ABOUT ESSP II
The Ethiopia Strategy Support Program II is an initiative to strengthen evidence-based policymaking
in Ethiopia in the areas of rural and agricultural development. Facilitated by the International Food
Policy Research Institute (IFPRI), ESSP II works closely with the government of Ethiopia, the
Ethiopian Development Research Institute (EDRI), and other development partners to provide
information relevant for the design and implementation of Ethiopia’s agricultural and rural
development strategies. For more information, see http://www.ifpri.org/book-
757/ourwork/program/ethiopia-strategy-support-program or http://www.edri.org.et/.
.
ABOUT THESE WORKING PAPERS
The Ethiopia Strategy Support Program II (ESSP II) Working Papers contain preliminary material and
research results from IFPRI and/or its partners in Ethiopia. The papers are not subject to a formal
peer review. They are circulated in order to stimulate discussion and critical comment. The opinions
are those of the authors and do not necessarily reflect those of their home institutions or supporting
organizations.
About the Author(s)
Alemayehu Seyoum Taffesse Research Fellow, Development Strategy and Governance
Division, Ethiopia Strategy Support Program II, IFPRI
Paul Dorosh Deputy Division Director, Development Strategy and Governance Division,
IFPRI
Sinafikeh Asrat MSc. Student at the Kennedy School of Government, Harvard University
(formerly with Ethiopia Strategy Support Program II, IFPRI)
iii
Crop Production in Ethiopia: Regional Patterns and Trends
Alemayehu Seyoum Taffesse, Paul Dorosh and Sinafikeh Asrat
Development Strategy and Governance Division, International Food Policy Research
Institute, Ethiopia Strategy Support Program II, Ethiopia
Copyright © 2010 International Food Policy Research Institute. All rights reserved. Sections of this material may be reproduced for personal and not-
for-profit use without the express written permission of but with acknowledgment to IFPRI. To reproduce the material contained herein for profit or
commercial use requires express written permission. To obtain permission, contact the Communications Division at ifpri-copyright@cgiar.org.
iv
Table of Contents
1.Introduction ............................................................................................................................ 1
2.Overview of agricultural crop area and production ................................................................ 1
2.1.Importance of crop categories ......................................................................................... 1
2.2.Distribution of cultivated land by farm size ...................................................................... 3
2.3.Crop area and production by farm size ............................................................................ 5
2.4.Seasonal variation ........................................................................................................... 8
3.Cereal production trends ....................................................................................................... 9
3.1.Trends in total cereal production ..................................................................................... 9
3.2.Trends in the production of the major cereals ............................................................... 12
4.Decomposition Analysis of Cereal Production ..................................................................... 13
4.1.Methodology .................................................................................................................. 13
4.2.Decomposition of changes in total cereal revenue ........................................................ 14
5.Other crop agriculture .......................................................................................................... 19
5.1.Pulses ............................................................................................................................ 19
5.2.Oilseeds ......................................................................................................................... 19
5.3.Coffee ............................................................................................................................ 20
5.4.Enset ............................................................................................................................. 21
5.5.Other crops .................................................................................................................... 21
6.Constraints and opportunities in crop agriculture ................................................................ 22
7.Summary and Conclusions .................................................................................................. 25
References ............................................................................................................................... 26
v
List of Tables
Table 2.1. Crop area and production (Smallholder farms, Meher season), 2004/05-2007/08 ... 2
Table 2.2. Ethiopia: Total area cultivated by farm size and agro-ecology ................................. 4
Table 2.3. Crop area by season and size of farm, 2007/08 ....................................................... 6
Table 2.4. Crop production by season and size of farm, 2007/08 ............................................. 7
Table 2.5. Crop yields by season and size of farm, 2007/08 ..................................................... 8
Table 3.1. Ethiopia: Cereal area, yield and production, decade averages and growth rates ... 11
Table 3.2. Cereal production by crop, 2004/05-2007/08 (1997-2000 E.C.) ............................. 11
Table 3.3. Ethiopia: Cereal area cultivated, decade averages ................................................ 12
Table 4.1. Median contributions to changes in quantity of cereal output by crop and year,
1998/99 – 2007/08 ................................................................................................. 15
Table 4.2. Median contributions to changes in cereal revenue by crop and development
domain, all periods, 1998/99 – 2007/08 ................................................................. 16
Table 4.3. Median contributions to changes in cereal revenue by crop and period ................. 17
Table 4.4. Median contributions to changes in cereal revenue by development domain and
period, 1998/99 – 2007/08 ..................................................................................... 18
Table 5.1. Ethiopia: Area cultivated of all crops (smallholder meher season), 1994/95 to
2008/09 .................................................................................................................. 20
Table 6.1. Fertilizer application by crop, private holdings; 1997/98, 2001/02, 2007/08 ........... 22
Table 6.2. Area under improved farm management practices by crop, private holdings,
1997/98, 2001/02, 2007/08 .................................................................................... 23
Table 6.3. Cereal yield by country and by year, 2006-2008 .................................................... 24
Table 6.4. Yields (Kg/Ha) of maize, wheat and sorghum by country and by year, 2006-2008 24
List of Figures
Figure 2.1. Shares of area cultivated by farm size and agro-ecology, 2007/08 ......................... 4
Figure 3.1. Ethiopia: Per capita cereal consumption and imports, 1961/62 to 2008/09 ........... 10
1
1. Introduction
Ethiopia’s crop agriculture is complex, involving substantial variation in crops grown across
the country’s different regions and ecologies. Five major cereals (teff, wheat, maize, sorghum
and barley) are the core of Ethiopia’s agriculture and food economy, accounting for about
three-quarters of total area cultivated, 29 percent of agricultural GDP in 2005/06 (14 percent
of total GDP) and 64 percent of calories consumed.1 There has been substantial growth in
cereals, in terms of area cultivated, yields and production since 2000, but yields are low by
international standards and overall production is highly susceptible to weather shocks,
particularly droughts. Thus, both raising production levels and reducing its variability are
essential aspects of improving food security in Ethiopia, both to help ensure adequate food
availability, as well as to increase household incomes.
Ethiopia’s crop agriculture in general, and the cereals sub-sector in particular, face serious
challenges. We show in this paper that much of the increase in production in the past decade
has been due to increases in area cultivated. However, little suitable uncultivated land
remains in the highlands, apart from pasture land. Soil degradation from erosion and soil
compaction also threatens crop yields (Hamza and Anderson 2005; Taddesse 2001).
Furthermore, uncertain rainfall and very low levels of irrigation make intensive cultivation with
improved seeds and fertilizer risky (McCann 1995).
This paper presents an overview of crop agriculture, focusing mainly on cereal production.
The next section describes area and production levels of the main agricultural crops,
distribution of cultivated area by farm size and the importance of seasonal differentiation.
Section three presents area, yield, production, growth and variability for cereals in general as
well as for each major cereal crop separately. The results of a decomposition analysis of
cereal production changes are discussed in section four. An overview of production of other
major agricultural crops, including enset, oilseeds, pulses and export crops (coffee and chat)
is presented in section five. Section six discusses major constraints to increasing agricultural
production, providing some international productivity data to compare with Ethiopia’s
agricultural productivity. Section seven summarizes the chapter and presents concluding
observations.
2. Overview of agricultural crop area and production
2.1. Importance of crop categories
Cultivated crop area (13 million hectares in 2007/08) accounts for a relatively small share of
the total area of Ethiopia as most land is not suited for cultivation. Table 2.1 shows average
area and production levels of the main crops cultivated for the period 2004/05-2007/08.
Cereals dominate Ethiopian crop production. Cereals were grown on 73.4 percent of the total
area cultivated, by a total of 11.2 million farmers. Together, these holders produce a yearly
1 Source: Food Balance Sheets database at http://faostat.fao.org/.
2
average of 12 million ton of cereals, which is 68 percent of total agricultural production. The
five major cereals are teff, wheat, maize, sorghum and barley. Teff accounts for 28 percent of
total cereal area, while maize stands for 27 percent of total annual cereal production.
Table 2.1. Crop area and production (Smallholder farms, Meher season), 2004/05-
2007/082
Crop
Average – 2004/2005 – 2007/08
Number of
holders
Area Cultivated in
hectares Production in quintals
Level
Share in
total area
cultivated
Level
Share in
total
production
(%) (%)
Grain 11,519,148 10,382,365 92.7 140,902,733 79.8
Cereals 11,156,837 8,230,211 73.4 120,629,724 68.3
Teff 5,462,782 2,337,850 20.9 24,079,480 13.6
Barley 3,842,462 1,024,390 9.1 13,264,217 7.5
Wheat 4,118,164 1,439,098 12.8 22,933,077 13
Maize 7,287,931 1,595,238 14.2 33,142,865 18.8
Sorghum 4,253,534 1,429,886 12.8 22,161,808 12.5
Pulses 6,377,027 1,384,499 12.4 14,955,466 8.5
Oilseeds 3,127,131 767,655 6.9 5,317,543 3.0
Vegetables 4,936,741 106,585 1.0 4,248,252 2.4
Root crops 4,757,733 174,826 1.6 14,732,919 8.3
Fruit crops 2,658,415 51,078 0.5 4,034,590 2.3
Chat 2,068,262 141,881 1.3 1,264,269 0.7
Coffee 3,049,120 305,940 2.7 2,106,711 1.2
Hops 1,685,422 23,457 0.2 263,111 0.1
Source: Author’s computation using CSA data
After cereals, the second most important crop group (in terms of acreage) is pulses. In
2004/05-2007/08 6.4 million holders grew pulses on 12.4 percent of total area cultivated.
Total pulse production averaged 1.5 million tons per year, which is 8.5 percent of total crop
production. Oilseeds form the third most important crop group. It is cultivated on 6.9 percent
of total area cultivated, by 3.1 million holders. They produce an average of 0.5 million ton of
oilseeds yearly, i.e. 3 percent of total annual production. Coffee is a major cash crop,
accounting for 3.8 percent of GDP (and 19 and 35 percent of the quantity and value of
exports respectively in that period), but occupying only 2.7 percent of total area cultivated
(i.e. 306 thousand hectares). Chat, another stimulant crop, is cultivated by 2 million farmers
2 CSA defines a holder as:
“... a person who exercises management control over the operation of the agricultural holding and makes the major decision
regarding the utilization of the available resources. He/she has primary technical and economic responsibility for the holding.
He/she may operate the holding directly as an owner or a manager. Under conditions of traditional agricultural holding the
holder may be regarded as the person, who with or without the help of others, operates land and/or raises livestock in his/ her
own right, i.e. the person who decides on which, where, when, and how to grow crops or raise livestock or both and has the
right to determine the utilization of the products.”
3
on 1.3 percent of total area cultivated, and accounts for 5 percent of total export earnings.
Vegetables and root crops together are cultivated on 281 thousand hectares, 2.6 percent of
total area cultivated.
2.2. Distribution of cultivated land by farm size
The Central Statistical Agency (CSA) classifies Ethiopian farms into two major groups:
smallholder “peasant” farms and large commercial farms. Smallholders and larger farms are
defined as those that cultivate less and more than 25.2 hectares respectively. The majority of
farmers in Ethiopia are smallholder farms. These farms, though small, are often fragmented,
produce mostly for own consumption and generate only a small marketed surplus. Large
farms (averaging 323 hectares per farm) can be state property or private and they sell
agricultural products at local markets and/or abroad. These larger farms usually use more
modern farm management practices and inputs than smaller farms do (e.g. machinery,
irrigation, fertilizers, pesticides and improved seeds). Large farms are not widely spread in
Ethiopia and the contribution of these farms to total agricultural output is limited. It is
estimated that they make up less than 4% of total production in the country (CSA January
2009, report 443).
Table 2.2 shows area cultivated by farm size for the smallholder farms only. Each farm size
interval contains 20 percent of Ethiopia’s smallholder farms. Sixty percent of smallholders
(called “small farms” further on) in Ethiopia cultivate less that 0.90 hectares of land. While 40
percent of the farmers cultivate less than 0.52 hectares, they manage only 11 percent of total
area cultivated. On the other hand, medium-size farms, defined as those cultivating 0.90
hectares or more, account for 75 percent of the total land cultivated.
Table 2.2 further shows how agricultural production is spread over different agro-ecological
regions. We distinguish five categories, i.e. moisture reliable cereals, moisture reliable enset,
humid lowlands, drought prone highlands, and pastoralist in the Table. Most smallholder
farms are located in the moisture reliable cereal-based highlands, which accounts for 59
percent of all farm area (i.e. 48 percent cultivated by medium-size farmers and 11 percent by
small farmers). Farm area in the drought-prone highlands is good for 27 percent of total area
cultivated (i.e. 20 percent medium-size farm area and 7 percent small farm area) (Table 2.2,
Figure 2.1).
4
Table 2.2. Ethiopia: Total area cultivated by farm size and agro-ecology
Farm size
(hectares)
Moisture
Reliable
Cereal
Moisture
Reliable
Enset
Humid
Lowland
Drought
prone Pastoralist Total
(thousand hectares)
0.0 - 0.25 111.7 133.2 6.5 76.9 6.8 335.1
0.25 - 0.52 364.3 298.7 17.1 271.2 22.1 973.4
0.52 - 0.90 884 355.7 31 474.3 39.4 1784.4
0.90 - 1.52 1739.5 330 47 824.8 70.5 3011.8
1.52 - 25.20 4153.2 272.4 94.4 1617.8 140.3 6278.1
Total 7252.7 1390 196 3265 279.1 12382.8
(percentage of national total)
0.0 - 0.25 0.9 1.1 0.1 0.6 0.1 2.7
0.25 - 0.52 2.9 2.4 0.1 2.2 0.2 7.9
0.52 - 0.90 7.1 2.9 0.3 3.8 0.3 14.4
0.90 - 1.52 14.0 2.7 0.4 6.7 0.6 24.3
1.52 - 25.20 33.5 2.2 0.8 13.1 1.1 50.7
Total 58.6 11.2 1.6 26.4 2.3 100.0
Note: Each farm size interval (quintile) contains 20 percent of Ethiopia’s small farms, approximately 2.57 million farms.
Source: Calculations from the Agriculture Sample Survey of 2007/08, Central Statistical Agency (CSA)
Figure 2.1. Shares of area cultivated by farm size and agro-ecology, 2007/08
Note: small = small farms (having a size less than 0.90 hectares; i.e. 60% of all farms), medium = medium-size farms (having a
size of 0.90 or more hectares, i.e. 40% of all farms)
Reliable access to water is an important condition to achieve good agricultural productivity.
However, in the moisture-reliable enset-based highlands (11 percent of total farm area, i.e. 5
percent medium-size and 6 percent small farms), population pressure has diminished farm
11%
6% 0%
7%
0%
48%
5%
1%
20%
2% Cereal-smal
Enset-small
Humid-small
Drought-small
Pasto
r
-small
Cereal-medium
Enset-medium
Humid-medium
Drought-medium
Pasto
r
-medium
5
size to such an extent that out-migration has become a major pathway out of poverty. The
farmers in the two other areas (humid lowlands and pastoralists) are relatively less important
as they count for only 3.9% of all smallholders in Ethiopia.
2.3. Crop area and production by farm size
Table 2.3 and 2.4 show the level of crop area and crop production by farm size for the year
2007/08 (CSA data). In this year, smallholder farmers (12.8 million farmers) cultivated
together 12 million hectares of land or 96.3 percent of the total area cultivated. A total of
461,000 hectares was cultivated by large commercial farms. Smallholder farms generated 95
percent of total production for the main crops (cereals, pulses, oilseeds, vegetables, root
crops, fruits and cash crops). In contrast, large farms contributed to only 5 percent of total
production of these main crops, and to only 2.6 percent of cereal production in particular.
However, large farms account for a much larger share of sugar cane, cotton and other
industrial crops (16.3 percent of total production). Coffee, fruit and vegetable production of
large farms accounted for 19.1 percent, 19.4 percent and 23.7 percent of total production
respectively. Even higher shares were reported for sesame and sugar cane: 42.6 percent
and 78.1 percent, respectively, of total production come from large farms. Cotton was only
produced on large farms.
6
Table 2.3. Crop area by season and size of farm, 2007/08
Small holder Large Total Total Small holder Large Total
Meher Belg Meher Belg
('000 has) ('000 has) ('000 has) ('000 has) (share) (share of crop) (share of crop) (share of crop) (share of crop)
Cereals 8,730 865 158 9,753 72.4% 89.5% 8.9% 1.6% 100.0%
Teff 2,565 69 5 2,639 19.6% 97.2% 2.6% 0.2% 100.0%
Barley 985 142 1 1,127 8.4% 87.4% 12.6% 0.1% 100.0%
Wheat 1,425 65 33 1,523 11.3% 93.6% 4.2% 2.2% 100.0%
Maize 1,767 512 54 2,334 17.3% 75.7% 22.0% 2.3% 100.0%
Sorghum 1,534 61 66 1,660 12.3% 92.4% 3.7% 3.9% 100.0%
Pulses 1,518 188 20 1,725 12.8% 88.0% 10.9% 1.2% 100.0%
Oilseeds 707 12 122 841 6.2% 84.1% 1.5% 14.5% 100.0%
Sesame 186 6 118 309 2.3% 60.1% 1.9% 38.0% 100.0%
Subtotal 10,955 1,065 300 12,319 91.5% 88.9% 8.6% 2.4% 100.0%
Vegetables 119 - 11 130 1.0% 91.7% 0.0% 8.3% 100.0%
Root crops 184 - 8 192 1.4% 95.9% 0.0% 4.1% 100.0%
Other temporary
crops - - 7 7 0.0% 0.0% 0.0% 100.0% 100.0%
Fruit crops 63 - 5 68 0.5% 92.2% 0.0% 7.8% 100.0%
Cash crops 596 - 59 655 4.9% 91.0% 0.0% 9.0% 100.0%
Coffee 407 - 54 461 3.4% 88.2% 0.0% 11.8% 100.0%
Sugar Cane 21 - 23 45 0.3% 47.8% 0.0% 52.2% 100.0%
Cotton - - 42 42 0.3% 0.0% 0.0% 100.0% 100.0%
Other
Permanent crops - - 5 5 0.0% 0.0% 0.0% 100.0% 100.0%
Total* 11,938 1,065 461 13,463 100.0% 88.7% 7.9% 3.4% 100.0%
Source: Calculated from CSA area data.
7
Table 2.4. Crop production by season and size of farm, 2007/08
Smallholder Large Total Smallholder Large Total
Meher Belg Meher Belg
('000 tons) ('000 tons) ('000 tons) ('000 tons) (% of Prod.) (% of Prod.) (% of Prod.) (% of Prod.)
Cereals 13,717 668 381 14,766 92.9% 4.5% 2.6% 100.0%
Teff 2,993 33 8 3,033 98.7% 1.1% 0.3% 100.0%
Barley 1,355 112 1 1,468 92.3% 7.6% 0.1% 100.0%
Wheat 2,314 67 66 2,448 94.6% 2.7% 2.7% 100.0%
Maize 3,750 412 191 4,353 86.1% 9.5% 4.4% 100.0%
Sorghum 2,659 26 115 2,800 95.0% 0.9% 4.1% 100.0%
Pulses 1,783 87 26 1,896 94.0% 4.6% 1.4% 100.0%
Oilseeds 617 0 142 760 81.2% 0.1% 18.7% 100.0%
Sesame 187 - 139 326 57.4% 0.0% 42.6% 100.0%
Subtotal 16,117 755 550 17,421 92.5% 4.3% 3.2% 100.0%
Vegetables 472 - 146 618 76.3% 0.0% 23.7% 100.0%
Root crops 1,531 - 154 1,685 90.9% 0.0% 9.1% 100.0%
Other temporary crops - - 99 99 0.0% 0.0% 100.0% 100.0%
Fruit crops 462 - 112 574 80.6% 0.0% 19.4% 100.0%
Cash crops 443 - 74 517 85.7% 0.0% 14.3% 100.0%
Coffee 273 - 64 338 80.9% 0.0% 19.1% 100.0%
Sugar Cane 782 - 2,782 3,564 21.9% 0.0% 78.1% 100.0%
Cotton - - 82 82 0.0% 0.0% 100.0% 100.0%
Source: Calculated from CSA data.
8
As yields are usually higher on large farms, their share in production is often higher than in
acreage. For example, sugar cane cultivated on large farms accounted for 52.2 percent of
total sugar cane acreage, though it accounted for 78.1 percent of total sugar cane
production. The yields are three times as high on large farms, i.e. 119 tons/ha, compared to
the smallholders, i.e. 37 ton/ha (Table 2.5). Other large differences between area and
production shares, driven by significant yield gaps, are seen for coffee (large farms: 11.8
percent of total coffee acreage, 19.1 percent of total coffee production) and maize (large
farms: 2.3 percent of total maize acreage, 4.4 percent of total maize production).
Table 2.5. Crop yields by season and size of farm, 2007/08
Smallholder Smallholder Large Yield Yield
Meher Belg Meher Total Meher
(tons/ha) (tons/ha) (tons/ha) (tons/ha) Large/Small
Cereals 1.57 0.77 2.41 1.51 1.53
Teff 1.17 0.47 1.66 1.15 1.43
Barley 1.38 0.79 1.87 1.30 1.36
Wheat 1.62 1.04 1.97 1.61 1.22
Maize 2.12 0.80 3.55 1.87 1.67
Sorghum 1.73 0.42 1.76 1.69 1.01
Pulses 1.17 0.46 1.29 1.10 1.10
Oilseeds 0.87 0.04 1.17 0.90 1.34
Sesame 1.00 -- 1.18 1.05 1.17
Subtotal 1.47 0.71 1.83 1.41 1.25
Vegetables 3.96 -- 13.49 4.76 3.40
Root crops 8.31 -- 19.66 8.77 2.37
Other temporary crops -- -- 15.14 15.14 --
Fruit crops 7.37 -- 20.90 8.43 2.84
Cash crops 0.74 -- 1.26 0.79 1.69
Coffee 0.67 -- 1.19 0.73 1.77
Sugar Cane 36.39 -- 118.57 79.29 3.26
Cotton -- -- 1.96 1.96 --
Source: Calculated from CSA data
2.4. Seasonal variation
In the main agricultural regions in Ethiopia there are two rainy seasons, the Meher and the
Belg, and consequently there are two crop seasons. Meher is the main crop season. It
encompasses crops harvested between Meskerem (September) and Yeaktit (February).
Crops harvested between Megabit (March) and Nehase (August) are considered part of the
Belg season crop. Table 2.3, 2.4 and 2.5 present data on crop area, production and yield by
season, for 2007/08 (CSA data). There are three important insights from these tables. First,
only smallholder farmers cultivate crops during the Belg season, as large farms concentrate
their production entirely on the more productive Meher season. Second, the Meher season is
overwhelmingly important. Area cultivated and crop production in the Meher season
9
accounted for 92.1 percent of total area cultivated and 96.9 percent of total crop production.
Third, crop yields were always smaller in the Belg season than in the Meher season.
Smallholder cereal production in the Meher season dominates cereal production in Ethiopia
and accounted for 93 percent of national cereal production in 2007/08. While 8.9 percent of
total cereal area was cultivated during Belg season, only 4.5 percent of national cereal
production was produced in the Belg season, a reflection of the significantly lower yields in
the Belg season. The most important contribution of the Belg season to total production is
found for the maize crop: 22.0 percent of total maize area was cultivated in the Belg season
and this resulted in 9.5 percent of total maize production.
3. Cereal production trends
3.1. Trends in total cereal production
Data on national cereal production levels and trends are controversial. Changes in
government and methodologies have coincided with distinct breaks in the data, making it
difficult to distinguish between actual changes and statistical artefacts. Moreover, beginning
in 1981/82, there have been two alternative data sources for each year, one from the Ministry
of Agriculture and Rural Development (or its predecessors) and one from the Central
Statistical Authority (CSA). We present the descriptive statistics of agricultural production and
areas based on both sources in Table 3.1.
Data from the Food and Agricultural Organization (FAO), generally derived from the Ministry
of Agriculture and Rural Development or its predecessors, indicate a steady but slow 1.9
percent average growth in cereal production in the 1960s, due almost equally to modest area
(1.1 percent per year) and yield (0.8 percent per year) increases (Table 3.1). Given a
population growth rate estimated at 2.3 percent per year in this period, it is estimated that per
capita production declined by an average of 0.4 percent per year. Due to the poor state of
infrastructure and weak statistical capacity in the country in the 1960s, the degree of
uncertainty in this data is rather high, however.
Cereal production showed high variability in the beginning of the 1970s. Cereal production
decreased from 5.17 million tons in 1972/73, to 4.37 and 4.35 million tons in 1973/74 and
1974/75, respectively, before falling even more dramatically to only 3.81 million tons in
1975/76, i.e. 31 percent below the level of three years earlier. Food aid and other net imports
of cereals increased more than ten-fold between 1972/73 and 1974/75, from 8 to 112
thousand tons, but they were nonetheless far too small to offset the decline in production. As
a result, per capita availability of food3 fell from 138 kg/person/year in 1972/73 to only 113
kg/person/year in 1973/74 and 1974/75, and then plummeted to only 96 kg/person/year in
1975/76 (see Figure 3.1).4
3 The figure for availability of food includes an adjustment for post-harvest production losses of about 5 percent, as well as feed,
seed and other non-food uses.
4 Data in the FAO Food Balance Sheets show almost no decline in food availability per capita in this period (from 116.7
kgs/person/year in 1972/73 to 113.3 kgs/person/year in 1975/76), due to very large changes in stocks. From 1961/62 through
1972/73, stocks rise each year with a cumulative build up of 4.46 million tons. Thus, per capita food availability for these
years is reduced accordingly. The FAO data then show a drawdown of stocks of 50,000 tons per year in 1973/74 and
10
The major cause of the reported production decline between 1972/73 and 1975/76 was a
steep 31 percent decline in area cultivated of cereals, a decline equal to the decline in
production. Two factors may have contributed to the change in cultivated area in that period:
the revolution of 1973 (i.e. the fall of the imperial regime of Hailie Selassie) and the
subsequent land reform, and regulation of cereal prices beginning in 1975 that may have
reduced incentives for production (or even led to major incentives to under-report
production). However, some of the decline in reported cultivated area may also be due to
differences in methodology and in the implementation of production surveys under the Derg
regime.
There were wide fluctuations in production and net availability in the second half of the 1970s
and the 1980s, but overall, cereal production stagnated in this period (Figure 3.1 and Table
3.1). The average growth rate of production from 1979/80 to 1989/90 was -0.3 percent
according to the FAO data; CSA data for 1981/82 to 1989/90 indicate a growth rate of 0.6
percent. In the 1990s, growth in cereal production accelerated to about 5 percent per year
(according to both FAO and CSA data). The rise was entirely due to increases in area
cultivated (by almost 6 percent per year), while yields continued to decline by 0.5 – 0.7
percent per year according.
Figure 3.1. Ethiopia: Per capita cereal consumption and imports, 1961/62 to 2008/09
0
20
40
60
80
100
120
140
160
180
200
1961/62
1963/64
1965/66
1967/68
1969/70
1971/72
1973/74
1975/76
1977/78
1979/80
1981/82
1982/83
1985/86
1987/88
1989/90
1991/92
1993/94
1995/96
1997/98
1999/00
2001/02
2003/04
2005/06
2007/08
(kgs/person/year)
NetFoodAvail(FAO) NetFoodAvail(FAOadj)
NetFoodAvail(CSA) NetImports
Source: FAO Food Balance Sheets.
1974/75, followed by a drawdown of 650,000 tons in 1975/76, thus raising per capita food availability in these years (See
Figure 3.1).
11
Table 3.1. Ethiopia: Cereal area, yield and production, decade averages and growth
rates
FAO CSA
Area Yield Production Area Yield Production
(mn has) (tons/ha) (mn tons) (mn has) (tons/ha) (mn tons)
1961/62-1969/70 6.23 0.73 4.53 -- -- --
1970/71-1979/80 5.25 0.90 4.63 -- -- --
1980/81-1989/90 4.89 1.15 5.63 4.30 1.14 4.89
1990/91-1999/00 5.87 1.18 6.88 5.60 1.20 6.67
2000/01-2008/09 8.24 1.30 10.68 7.72 1.41 10.94
Average Growth Rates (from logarithmic regressions)
1961/62-1969/70 1.1% 0.8% 1.9% -- -- --
1970/71-1979/80 -4.9% 3.7% -1.4% -- -- --
1980/81-1989/90 0.5% -0.8% -0.3% 2.4% -1.7% 0.6%
1990/91-1999/00 5.9% -0.7% 5.1% 5.8% -0.5% 5.2%
2000/01-2008/09 2.7% 3.6% 6.5% 3.1% 3.5% 7.0%
Source: Note: FAO data is for 2000/01 to 2007/08 (2000 to 2007). CSA 1980/81-1989/90 data is 1981/82 to 1989/90. CSA
levels and growth rates are based on interpolated data (constant logarithmic growth rates). FAO denotes 2007/08 as 2007.
Note: n.a. indicates not available. CSA data is small holder meher season only.
According to CSA data, growth in cereal production accelerated further to 7.0 percent per year from
1999/2000 to 2008/09. Average cereal production increased to 10.94 million ton per year during this
time period. Though growth in area cultivated slowed to 3.1 percent per year, yields
increased by 3.5 percent per year. Cereal production and yield growth was particularly rapid
from 2004/05 to 2008/09 (12.2 and 6.2 percent, respectively), while cereal acreage recorded
an annual growth rate of only 4.8 percent (Table 3.2). During the same time period, cereal
production on average involved 11 million holders. Cereal acreage and cereal output
averaged 8.2 million hectares and 12.1 million tonnes, respectively.
Table 3.2. Cereal production by crop, 2004/05-2007/08 (1997-2000 E.C.)
Crop
Average - 2004/2005 - 2007/08
Number of
holders
Production (quintals)
Area Cultivated
(hectares)
Yield (quintals per
hectare)
Level
Annual
growth
rate (%) Level
Annual
growth
rate (%) Level
Annual
growth
rate (%)
Grain 11,519,148 140,902,733 11.8 10,382,365 3.9
Cereals 11,156,837 120,629,724 12.2 8,230,211 4.8 14 6.2
Teff 5,462,782 24,079,480 15.9 2,337,850 6.7 10.2 7.7
Barley 3,842,462 13,264,217 0.7 1,024,390 -3.4 13 4.5
Wheat 4,118,164 22,933,077 2.1 1,439,098 0.6 15.9 1.5
Maize 7,287,931 33,142,865 18.9 1,595,238 9 20.6 7.8
Sorghum 4,253,534 22,161,808 18.3 1,429,886 7.4 15.4 8.9
Source: Author’s computation using CSA data (CSA (July 2006), CSA (July 2007), and CSA (June 2008)).
Note: Cereal yield is calculated as acreage-share weighted average of the yields of the five major cereals listed in the table –
they account for more than 95 percent of cereal acreage and cereal output.
12
3.2. Trends in the production of the major cereals
Since the start of the collection of national agricultural statistics in the 1960s, teff has always
accounted for the largest share of cereal area cultivated (Table 3.3). However, over the past
five decades the share of teff has declined gradually (a decrease by 5.8 percentage points
from the 1960s to the first decade of the 2000s), while the share of maize has increased by
7.8 percentage points. Compared to teff and maize, the share of other cereals stayed
relatively stable over time.
Table 3.3. Ethiopia: Cereal area cultivated, decade averages
Teff Wheat Maize Sorghum Barley Other Total
(million hectares)
1961/62-1969/70 2.11 0.97 0.80 1.09 0.96 0.30 6.23
1970/71-1979/80 1.67 0.78 0.83 0.87 0.84 0.27 5.25
1980/81-1989/90 1.23 0.52 0.84 0.71 0.86 0.15 4.30
1990/91-1999/00 1.76 0.75 1.12 0.95 0.73 0.29 5.60
2000/01-2008/09 2.17 1.27 1.59 1.35 0.96 0.38 7.72
(Shares of Total Cereal Area Cultivated)
1961/62-1969/70 33.9% 15.6% 12.8% 17.4% 15.4% 4.9% 100.0%
1970/71-1979/80 31.8% 14.8% 15.7% 16.6% 15.9% 5.1% 100.0%
1980/81-1989/90 28.7% 12.0% 19.5% 16.4% 19.9% 3.4% 100.0%
1990/91-1999/00 31.3% 13.4% 20.0% 17.0% 13.1% 5.2% 100.0%
2000/01-2008/09 28.1% 16.5% 20.6% 17.5% 12.5% 4.9% 100.0%
Source: 1961/62-1979/80 data are from FAO. 1980/81 – 2008/09 data are from CSA Agricultural Sample Surveys.
During the first decade of the 2000s, production of all the major cereals increased, with teff
(8.9 percent), sorghum (8.6 percent) and wheat (8.3 percent) having the fastest annual
growth rates. Growth in maize production, 6.8 percent per year in the 1980s and 5.5 percent
per year in the 1990s, slowed to 4.2 percent in the early 2000s. This reduced growth figure
was caused in part by a collapse in domestic maize prices inducing slow adoption, or even
dis-adoption, of hybrid maize technology.
Compared to the 1990s, wheat and sorghum area cultivated grew fastest (by 4.9 and 4.6
percent per year, respectively) during 2000/01–2008/09, while maize area cultivated
increased by only 1.6 percent per year. Yields of all five major cereals increased rapidly in
the first decade of the 2000s, with growth rates averaging from 2.9 and 3.0 percent per year
for maize and wheat, and 4.3 and 4.8 percent per year for sorghum and teff.
As total cereal production growth was particularly rapid from 2004/05 to 2008/09, it is worth
examining the growth rate for the five cereals separately in this period (Table 3.2). The speed
of growth was somewhat varied across crops. Average annual growth in output was fastest
in maize production (18.9 percent), closely followed by sorghum production (18.3 percent).
Teff production rose by 15.9 percent per year. The slowest output growth was recorded in
barley production (0.7 percent), due to a decline in barley acreage. It is interesting to note
that, for the main cereals, yield growth was faster than acreage expansion during the period,
13
so the increased production rates were more the result of increased yields than of increased
acreages. An exception to this was maize, a crop considered to have the highest potential for
yield increases. Over this four year period, yield increased by 7.8% while area grew by 9%.
4. Decomposition Analysis of Cereal Production
4.1. Methodology
Agro-ecology and market infrastructure, the key components of the development domains,
are important determinants of crop production/output and revenue. In this section, we
decompose changes in cereal output into changes in area and yield across various
development domains and across time periods. We also examine changes in gross crop
revenues by total output and price.
The quantity of output of crop i ( i
t
Q) is the product of yield ( i
t
y) and acreage allocated to its
production ( i
t
A
). Decomposition can thus take the following approximate form:
iiiii
dQ A dy y dA
The decomposition reveals the relative contribution of changes in acreage and changes in
yield to the overall change in the quantity of output. This is a policy-relevant issue to the
extent that acreage, and to a certain degree, yield, reflect government interventions in
agriculture and the wider economy, and are not simply determined by variations in weather
and severity of pest attacks.
A more informative decomposition involves crop revenues. Such decomposition can
highlight, in addition to the relative contributions of changes in acreage and yield as quantity
decomposition, those of changes in prices and the pattern of allocation of acreage. Changes
in prices in part reflect market development, while patterns of acreage allocation are partly
driven by differences in returns to the cultivation of alternative crops. Both are relevant to
policy decisions.
The total revenue from cereal cultivation (R) is given by the sum of revenues from each
cereal type i:
()
nn
ii i ii
ii
RpQ pAy
11
where i
p
= price of cereal i and the rest are as defined above. Defining total cereal acreage
as
n
i
i
A
A
1
and the share of each cereal in total acreage as i
A
iA
a, cereal revenue can
be computed as:
14
()
nn
ii i iii
ii
RpaAyApay
11
The expression shows that there are four potential sources of growth – changes in total
acreage, changes in the shares of crops in total acreage, changes in crop yields, and
changes in crop prices. Thus, approximately:5
The first term on the right-hand side of equation denotes the change in the gross crop
income due to changes in total cropped area; the second term gives the effect of changes in
real prices; the third term captures the effect of change in crop yields; and the fourth term
describes the change in gross crop income associated with changes in the area composition
of crops over time. If the fourth term is positive, this indicates a reallocation of cropland from
lower-value crops to higher-value crops, so this term represents the effect of crop
diversification on gross crop income. Dividing both sides of the last equation by the overall
change in gross crop income (dR) gives the proportional contribution of each component in
the growth.
4.2. Decomposition of changes in total cereal revenue
Tables 4.1 and 4.2 show the results of a decomposition of changes in cereal output and
cereal revenue across various development domains for the four main administrative regions
– Amhara, Oromiya, SNNPR, and Tigray. The data used in this analysis are derived from
CSA Agricultural Sample Survey data at the administrative zone level for the period 1996/97-
2007/08 (1989-2000 E.C.). Four development domains are considered: Low Market Access
(LMA) with Low Agricultural Potential (LAP), LMA with High Agricultural Potential (HAP),
High Market Access (HMA) with LAP, and HMA with HAP.
For cereal production, the broad story is very clear (Table 4.1). During the study period,
acreage expansion was the more important source of growth in output for four of the five
major cereals (the exception is teff) in almost all development domains. Out of the sixty crop-
domain-period specific pairs of yield and acreage contribution shares, in only twelve the
share of yield was higher. Moreover, no statistically significant correlation can be detected
between acreage share of a crop and the significance of yield changes as a source of growth
in that crop’s output. Moreover, the relative contributions of acreage and yield changes to
output growth were not statistically significantly different across development domains as
well as time periods, except for sorghum (see Taffesse 2009).
5 For a single crop, the expression reduces to:
iiiiiiiii
dR y p dA y A dp p A dy
A more detailed description of the decomposition approach and its application can be found in Taffesse (2010).
15
Table 4.1. Median contributions to changes in quantity of cereal output by crop and year, 1998/99 – 2007/08
Year
Barley Maize Sorghum Teff Wheat
Change
in crop
area (%)
Change
in crop
yield (%)
Change
in crop
area (%)
Change
in crop
yield (%)
Change
in crop
area (%)
Change
in crop
yield (%)
Change
in crop
area (%)
Change
in crop
yield (%)
Change
in crop
area (%)
Change
in crop
yield (%)
1998/99 - 2000/01 72.6 35.1 74.5 34.2 69.8 32.7 56.0 49.1 71.7 42.4
2001/02 - 2004/05 73.3 28.7 49.8 45.2 57.3 39.6 54.8 47.8 67.2 35.7
2005/06 - 2007/08 58.6 39.3 64.4 39.7 67.5 39.1 55.6 49.1 67.3 48.7
1998/99 59.3 49.2 78.6 36.8 51 53.2 61.1 48.6 77.6 30.5
1999/2000 95 8.1 74.8 25.7 72.5 19.2 64.5 39.2 78 39.9
2000/01 63.4 48 70 40 85.9 25.6 42.5 59.5 59.6 56.8
2001/02 57.9 37.1 62.6 31.1 67.4 26.9 68.4 25.3 71.1 33.1
2003/04 99.1 -0.3 60.7 29.6 55.6 36.7 56.2 38.8 76.8 21.9
2004/05 62.8 49.2 26.2 75 48.8 55.1 39.7 79.4 53.6 52.1
2005/06 32.2 57.1 44.6 67.4 69 48.9 37.4 60.7 37.9 60.1
2006/07 85.2 19.2 84.3 21.4 79.9 26.6 86.8 16.8 92.7 42.9
2007/08 58.4 41.5 64.3 30.3 53.7 41.9 42.5 69.7 71.3 43.2
Source: Calculated from CSA data, Taffesse (2009).
16
Similarly, the average picture for decomposition of cereal revenues across development
domains is relatively simple (Table 4.2). For all cereals, acreage expansion was the top
source of revenue change. This is to be expected since acreage increase generated the bulk
of output growth during the period. Increases in yield made the second largest contributor to
revenue growth in the case of maize, sorghum and wheat. In contrast, real price rises stood
second to acreage expansion as the origin of growth in barley and teff revenue (in fact, price
and acreage contributed equally to teff revenue growth).
Table 4.2. Median contributions to changes in cereal revenue by crop and
development domain, all periods, 1998/99 – 2007/08
Development
Domain Crop
Change
in crop
area
Change
in crop
yield
Change
in crop
price
Actual
Change
minus
Estimated
Change
LMA, LAP
Barley 54.6 14.7 20.5 10.2
Maize 47.2 14.1 24.9 13.9
Sorghum 30.6 29.9 26.7 12.8
Teff 51.8 25.2 15.7 7.3
Wheat 55.7 38.7 7.5 -1.9
LMA, HAP
Barley 38.4 13.1 37.6 10.9
Maize 51.7 35 17.1 -3.9
Sorghum 48 14.6 15.2 22.2
Teff 38.4 9.3 73.8 -21.5
Wheat 47.5 30.7 35.3 -13.5
HMA, LAP
Barley 54.6 21.3 28.5 -4.4
Maize 41.8 50.7 -3.9 11.5
Sorghum 42.4 33 28.6 -4
Teff 27.7 29.4 42.1 0.8
Wheat 50.2 32.7 23 -6
HMA, HAP
Barley 53.7 17.2 25.4 3.7
Maize 53.5 15.6 13.5 17.4
Sorghum 60.5 19.4 11.3 8.7
Teff 41.8 21 27.9 9.3
Wheat 41.5 26.8 17.2 14.4
Average
Barley 50.3 16.6 28 5.1
Maize 48.6 28.9 12.9 9.7
Sorghum 45.4 24.2 20.5 9.9
Teff 39.9 21.2 39.9 -1
Wheat 48.7 32.2 20.8 -1.8
Source: Authors’ computation using CSA data.
Note: HMA = ‘High Market Access’; LMA = ‘Low Market Access’; HAP = ‘High Agricultural Potential’; LAP = ‘Low
Agricultural Potential’.
This general picture holds across development domains and across periods. As in the case
of output change, it was not possible to detect statistically significant differences across
development domains in the pattern of contributions to the growth of each crop’s revenue
17
(with the exception of teff).6 In contrast, differences across periods are statistically significant
(with the exceptions of yield contibutions to the growth in barley revenue, sorghum revenue
and wheat revenue). A closer look at these time differences revealed the following. During
the first period (1999/2000-2001/02), acreage expansion was the dominant source of change
in cereal revenue, followed by yield (Table 4.3). Price increases became the top contributor
to revenue growth in the second period, with acreage change taking second place. Yield
improvements played a limited role during this period. The third period was characterised by
more mixed outcomes. Increases in acreage generated the largest contribution to revenue
growth in the case of barley, maize, sorghum, and teff, while yield change did so for wheat
revenue. Crop prices also made significant contributions to revenue growth in this third
period.
Table 4.3. Median contributions to changes in cereal revenue by crop and period
Crop
Revenue Source of Revenue Growth
Period
1998/99- 2001/02- 2005/06-
2000/01 2004/05 2007/08
Barley
Revenue
Change in crop area 75.89 31.21 43.08
Change in crop yield 20.99 6.39 24.61
Change in crop price 7.94 55.66 35.99
Maize
Revenue
Change in crop area 72.54 24.99 49.2
Change in crop yield 29.38 0.48 31.17
Change in crop price 6.37 53.09 13.23
Sorghum
Revenue
Change in crop area 69.65 28.22 40.09
Change in crop yield 25.06 10.49 34.39
Change in crop price 5.76 41.3 25.27
Teff
Revenue
Change in crop area 58.92 28.04 43.5
Change in crop yield 42.9 5.69 21.4
Change in crop price 14.02 47.74 37
Wheat
Revenue
Change in crop area 64.6 26.35 32.62
Change in crop yield 41.47 16.29 43.01
Change in crop price 6.13 53.29 25.79
Total
Cereal
Revenue
Change in crop total cereal area 60.62 27.98 18.59
Change in crop yield 19.58 -1.28 34.58
Change in acreage shares 3.27 0.08 -0.22
Change in crop price 15.31 64 44.62
Source: Authors’ computation using CSA data.
Note: The annual Agricultural Sample Survey for 2002/03 was not implemented. Thus 2002/03 is not included - i.e., the
period 2001/02-2004/05 includes 2001/02, 2003/04, and 2004/05.
Total cereal revenue is calculated as the sum of the value of output of the five cereals
covered by the study. As noted above, CPI-deflated real prices are used in computing the
value of crop output. Aggregation across crops leads to a fourth source of revenue growth,
namely, the share of each crop in total cereal acreage. In other words, change in a specific
crop’s acreage has two components – one due to change in total acreage and another due
to change in its share in total acreage.
6 Note that there are five significant differences (out of possible fifteen) with levels of significance falling between 5% and 10%.
These are: yield contributions in the case of sorghum, wheat, and teff; and area and price contributions in the case of teff.
18
The results of the decomposition exercise are reported in Table 4.3 (bottom four rows for
periods 1998/99 – 2000/01, 2001/02 – 2004/05, and 2005/06 – 2007/08) and Table 4.4.
Consistent with previous results, change in total cereal acreage was a primary source of
growth in total cereal revenue. That price changes were a competing source in this case is
an interesting variation. Change in allocation of cereal acreage was rather limited and thus
did contribute very little to revenue expansion. Its role is likely to be more prominent when a
more inclusive set of crops is considered (if pulses and oil seeds are added, for example).
Table 4.4. Median contributions to changes in cereal revenue by development domain
and period, 1998/99 – 2007/08
Development
Domain Period
Change
in total
area
under
cereals
Change
in
cereal
yields
Change
in the
allocation
of total
area
under
cereals
Change
in the
price of
cereals
Actual
Change
minus
Estimated
Change
HMA, HAP
1998/99-2000/01 58.98 34.39 2.3 22.44 -18.12
2001/02-2004/05 29.59 0.1 0.94 53.14 16.24
2005/06-2007/08 17.15 32.71 -0.39 45.68 4.85
HMA, LAP
1998/99-2000/01 61.12 36.45 0.58 -28.55 30.4
2001/02-2004/05 34.77 -22.94 -0.25 87.15 1.26
2005/06-2007/08 -0.81 20.64 -1.26 56.56 24.87
LMA, HAP
1998/99-2000/01 56.19 9.86 5.75 26.43 1.77
2001/02-2004/05 26.54 -12.64 -0.07 87.46 -1.3
2005/06-2007/08 18.67 34.39 0.14 74.31 -27.51
LMA, LAP
1998/99-2000/01 69.04 18.68 4.29 8.5 -0.51
2001/02-2004/05 25.96 7.77 -0.09 59.45 6.91
2005/06-2007/08 19.92 39.03 -0.17 36.95 4.27
Source: Authors’ computation using CSA data.
Note: The annual Agricultural Sample Survey for 2002/03 was not implemented. Thus 2002/03 is not included - i.e., the period
2001/02-2004/05 includes 2001/02, 2003/04, and 2004/05.
HMA: High Market Access, LMA: Low Market Access, HAP: High Agricultural Potential, LAP: Low Agricultural Potential
As before, a statistically significant difference in the pattern of contributions to revenue
growth could not be ascertained across development domains. The opposite is true across
time periods, however (Table 4.3 and 4.4). A clear dominance of acreage expansions is
found during the first period (1998/99-2000/01), while a considerable rise in the contribution
of price changes was found during 2001/02-2004/05. In a reversal of outcomes, changes in
yield were a positive and considerable, though second to price changes, source of revenue
growth in the last period (2005/06-2007/08).
19
5. Other crop agriculture
Although the production of cereals is by far the most important sector in Ethiopian
agriculture, it is important to also discuss the other crops, since area cultivated of other crops
is growing fast, even faster than the increase in cereal area. The other main crops discussed
here are: pulses, oilseeds, coffee and enset. Table 5.1 presents the area cultivated of these
crops in the periods 1994/95-2000/01 and 2003/04-2008/09, giving also the acreage growth
rates within each of these two periods.7
5.1. Pulses
In the periods 1994/95-2000/01 and 2003/04-2008/09 pulse acreage was 12 percent and
12.4 percent, respectively, of the total area cultivated. Annual production averaged 1.5
million ton; this represents 8.5 percent of total yearly production (in the period 2004/05-
2007/08, Table 2.1). The share of area cultivated of pulses is increasing; in the period
2003/04-2008/09 this was with 6.6 percent per year, which is a faster growth compared to
the yearly cereal area growth (4.6 percent). The main legumes are horse bean (Vicia faba
var. minor), field pea (Pisum arvense), haricot bean (Phaseolus vulgari) and chickpea (Cicer
arietinum). They form an important basis of non-meat national dishes and are a principal
protein source.
5.2. Oilseeds
The main oilseeds are neug (also known as noug or niger seed; Guizotia abyssinica),
linseed (also known as flax; Linum usitatissimum) and sesame (Sesamum indicum), with an
increasing importance of sesame over time. The cultivation of neug is found mostly in the
northern and central highlands at elevations between 1800 and 2500 meters. Linseed is
cultivated in the same areas as niger seed. Sesame grows at elevations from sea level to
about l500 meters. Oilseeds are the third crop according to acreage: 5.4 percent and 6.8
percent of the total area cultivated was occupied by oilseeds in the periods 1994/95-2000/01
and 2003/04-2008/09, respectively (Table 5.1). The area growth rate was 5.6 percent per
year in the first period, though declined to 4.3 percent per year in the second period. This
slower growth is mainly because of a negative yearly growth rate in neug and linseed area.
This is balanced by a fast growth in sesame area. Sesame has grown from essentially zero
in 1994/95 to 288 thousand hectares in 2008/09, with an impressive growth of 33.1 percent
per year in the first half of that period and a growth of 20.5 percent per year in 2003/04 to
2008/09.
7 Note that no data at the administrative zone level are available for either 2001/02 or 2002/03.
20
Table 5.1. Ethiopia: Area cultivated of all crops (smallholder meher season), 1994/95
to 2008/09
1994/95-2000/01 2003/04-2008/09
('000 ha's) (share) (growth rate) ('000 ha's) (share) (growth rate)
Cereals 6,545 82.6% 3.2% 8,115 73.5% 4.6%
Pulses 954 12.0% 4.7% 1,370 12.4% 6.6%
Horse Beans 336 4.2% 2.4% 470 4.2% 6.1%
Field Peas 159 2.0% 1.4% 227 2.1% -0.5%
Haricot Beans 122 1.5% 15.9% 219 2.0% 5.9%
Chickpeas 172 2.2% 4.3% 197 1.8% 8.9%
Other 165 2.1% 5.9% 257 2.3% 13.7%
Oilseeds 426 5.4% 5.6% 749 6.8% 4.3%
Neug 240 3.0% 6.4% 303 2.8% -0.8%
Linseed 115 1.5% -3.0% 186 1.7% -1.5%
Sesame 23 0.3% b33.1% 185 1.6% 20.5%
Other 48 0.6% 7.8% 75 0.7% 7.2%
Subtotal 7,926 100.0% 3.5% 10,235 92.7% 4.8%
Vegetables -- -- -- 112 1.0% 11.7%
Root crops -- -- -- 167 1.5% 0.5%
Fruit crops -- -- -- 49 0.4% 4.1%
Cash crops -- -- -- 485 4.4% 9.8%
Chat -- -- -- 136 1.2% 6.1%
Coffee -- -- -- 308 2.8% 12.3%
Hops -- -- -- 23 0.2% 3.7%
Sugar Cane -- -- -- 18 0.2% 2.3%
Totala 7,926 100.0% 100.0% 11,048 100.0% 5.1%
Source: CSA production data.
Note: a Data on vegetables, root crops, fruit crops and cash crops were not available for 1994/95 to 2000/01. Thus, the figure
for “Total” in 1994/95-2000/01 is not comparable to the “Total” for 2003/04 to 2008/09.
b Sesame area growth rate is 1995/96 - 2000/01.
In 2007/08, a total of 760 thousand ton of oilseeds was produced; this is three percent of
total annual production. Smallholder farms produced 81.3 percent of total oilseed production,
while large farms produced 18.7 percent of it. However, large farms produced 42.6 percent
of total sesame output. Sesame seed has the highest value per ton of Ethiopian oilseeds,
more than twice the value of linseed.8 According to market value oilseeds are much more
important than pulses.
5.3. Coffee
In 2003/04-2008/09 coffee was cultivated by three million farmers on a total of 308,000 ha,
which is only 2.8 percent of total cultivated area. However, the share of area cultivated for
coffee increased by 12.3 percent per year from 2003/04 to 2008/09. In 2008/09 337
thousand ton was produced, this is 1.3 percent of total production; 19 percent of total coffee
output was produced by large farms. Coffee is Ethiopia’s major export product, and Ethiopia
is the world’s fifth producer of coffee.
8 Ethiopia is the fifth world producer of linseed and the sixth of sesame seed; it is the third world exporter of sesame seed and
an important exporter of neug (niger seed).
21
5.4. Enset
Enset (Ensete ventricosum) is commonly known as “false banana” for its close resemblance
to the domesticated banana plant, but its fruit is not edible. Enset grows best at altitudes
above 1600 meters above sea level, not because it cannot withstand heat, but because it
needs adequate soil moisture. It can survive seasonal rainfall shortages, but succumbs to
prolonged droughts.9
Enset was cultivated on 279 thousand hectares in 2008/09, 2.5 percent of total cultivated
area. As many as 7 million people consume the carbohydrate-rich, but low-protein enset
products as a staple or co-staple food. For many households it forms an important food
security reserve against other crop failures. Besides its use as a staple food, enset is also
used for animal fodder, fibre production, construction materials and for its medicinal values.
5.5. Other crops
Only one percent of total area cultivated is used to grow vegetables, the equivalent of
112,000 hectares. However, the importance of vegetables is growing, as there is an 11.7
percent per year growth in acreage from 2003/04 to 2008/09 (Table 5.1). This increase in
growth rate is comparable to that of coffee (12.3 percent). Vegetables, together with sesame
and coffee, are the crops with the largest acreage increase in the recent years.
Chat is an important cash crop and its significance is increasing. Only 1.2 percent of total
area cultivated is used for chat production, however, its share in area cultivated grew with
6.1 percent per year in 2003/04-2008/09 (Table 5.1).
9 Each plant takes four to seven years to mature. The plant is cut before flowering and the pseudostem (stalk or base) and leaf
midribs are scraped to collect the pulpy white juice. The pulp is then fermented for 10-25 days in the soil, followed by another
20 days of sun-drying. Finally, enset-based food, in the form of a steam-baked flat-bread or a kind of porridge, can be
prepared.
22
6. Constraints and opportunities in crop agriculture
Much of the increase in crop production in the past decade has been due to increases in
area cultivated. To what extent the area cultivated can continue to expand remains an
important question. It seems that in the highland areas, expansion of cultivated area will
have to come almost exclusively from reduction in pasture land. In most instances, this land
is likely to be less fertile than existing crop land. Increased use of inter-cropping or double-
cropping may allow some expansion of area cultivated as well. Expansion of area cultivated
outside of the highland regions will require major investments in infrastructure and might
involve reductions in forest areas, with important negative environmental implications. As a
consequence, it seems that obtaining higher yield rates is the challenge of Ethiopia’s
agricultural system.
Numerous constraints to yield and productivity growth have been identified, including
relatively low levels of input use (fertiliser, pesticide, improved seeds), low levels of irrigation,
soil degradation and soil erosion, inadequate agricultural research and extension, and
constraints in market development.
The limited use of modern inputs is a major characteristic of crop production in Ethiopia and
it seems to be a major explanation for its current low productivity. Table 6.1 shows that in
2007/08 only about 40 percent of cereal acreage benefited from chemical fertilisers, with the
highest application in wheat areas. It is remarkable that the share of fertiliser-applied area in
cereal cultivation declined from 2001/02 to 2007/08, after an increase in 2001/02 compared
to 1997/98. The opposite is seen when the amount of fertiliser per hectare of fertiliser-
applied cereal area is considered. In that case, the levels used in 2001/02 were lower than in
1997/98, but an increase was noted in 2007/08 compared to 2001/02. In general, the
intensity of fertiliser use is relatively low when estimated as quantity of fertiliser per hectare
of total cereal acreage. However, it is broadly comparable to intensity in Asia when
measured as quantity of fertiliser per hectare of fertiliser-applied cereal area (Agwe et al.
2007).
Table 6.1. Fertilizer application by crop, private holdings; 1997/98, 2001/02, 2007/08
Crop
Fertilizer Applied area Fertilizer application Fertilizer application
(share in total area
cultivated - %)
(total quintals/
total hectares)
(quintals per hectare of
fertilizer applied area)
1997/98 2001/02 2007/08 1997/98 2001/02 2007/08 1997/98 2001/02 2007/08
Cereals 32.3 42.8 39 0.37 0.3 0.45 1.15 1 1.16
Teff 44.9 49.9 54.3 0.5 0.4 0.52 1.11 0.91 0.95
Barley 34.4 39.6 30.5 0.33 0.2 0.3 0.97 0.79 0.99
Wheat 57 56.7 62.1 0.75 0.56 0.85 1.32 1.12 1.36
Maize 18 45.7 32.8 0.25 0.28 0.54 1.39 1.33 1.63
Sorghum 2.9 16.9 3.1 0.04 0.01 0.03 1.26 0.54 1.05
Source: Authors’ computation using CSA data (CSA (September 1998), CSA (July 2003b), and CSA (August 2008)).
Though increasing, the use of other modern inputs is even more limited (Table 6.2). In
2007/08, improved seeds were applied over about 5 percent of cereal acreage. The highest
rate was in maize production (19.5 percent) with negligible rates in the production of other
23
cereals. Irrigation techniques are even less applied. Only one percent of cereal acreage was
irrigated in 2007/08. Pesticides were applied in 20.8 percent of total cereal acreage in
2007/08. Furthermore, the use of improved seeds, pesticides and irrigation is increasing only
slowly in the last decade. The constraints related to cereal production are similar to the ones
associated with crop production more broadly.
Table 6.2. Area under improved farm management practices by crop, private holdings,
1997/98, 2001/02, 2007/08
Share of crop area (%)
Crop
Improved seed applied
crop area
Pesticide applied crop
area Irrigated crop area
Extension
package
covered
crop area
1997/98 2001/02 2007/08 1997/98 2001/02 2007/08 1997/98 2001/02 2007/08 2007/08
Cereals 2.4 3.5 4.7 12 10.8 20.8 0.64 1.3 1.1 14.5
Teff 1.7 0.6 0.7 17.7 16.6 30.5 0.66 0.7 0.7 13.8
Barley 0.1 0.4 0.6 9.6 9.07 20.7 0.62 0.8 1.2 11
Wheat 5.6 2 2.9 31.3 28.11 43.6 0.32 0.4 0.5 21.9
Maize 5.2 12.5 19.5 1.3 1.93 2.9 1.1 3.2 2.2 21.3
Sorghum 0.2 0.4 0.1 3.1 1.69 5.4 0.39 1.1 1.2 1.4
Source: Authors’ computation using CSA data (CSA (September 1998), CSA (July 2003b), and CSA (August 2008)).
Several policy initiatives have been taken to stimulate productivity. In the nineties, the
Ethiopian government tried to improve Ethiopian agriculture through a range of measures. In
1993, the Sasakawa Global 2000 Program (SG 2000), an international non-governmental
organization for assisting small-scale farmers in sub-Saharan African countries to increase
staple food crop production, began work in Ethiopia in partnership with the government.10 In
1994/1995 the government introduced PADETES (Participatory Demonstration and Training
Extension System) with SG 2000 principles as a model.11
However, there are concerns that these state-led cereal intensification programmes are not
consistently generating the desired effects (Spielman 2008). For example, distribution of
improved maize seeds is a main focus, but adoption of improved seeds has generally been
disappointing. Shortfalls in supply, decreasing seed quality and delayed deliveries may
explain this. Similarly, there is evidence suggesting that many farmers have dis-adopted the
seed-fertiliser inputs over time due to poor extension service, cost, unavailability of preferred
varieties and other inputs from suppliers, a preference for local varieties, or other such
factors (Bonger et al. 2004; EEA/EEPRI 2006; Spielman 2008).
To illustrate the international position of Ethiopia and to indicate potential growth, Table 6.3
presents cereal yields of different countries in Eastern Africa for the period 2006-2008.
10 Sasakawa Global 2000 defends high-external-input technologies. The program provided credit, inputs (fertiliser and improved
maize seeds) and extension assistance to participants willing to establish half-hectare demonstration plots on their own land.
Data from the SG 2000 demonstration plots revealed that the use of improved seeds and fertiliser is strongly associated with
higher yields, but medium-input levels were as profitable or more profitable as high-input levels. Additionally, other factors
affecting yields were: soil type, frequency of ploughing, planting time, plant spacing and weeding (Howard et al. 2003).
However, the authors found no evidence of a successful expansion of the pilot programme. Two factors playing a plausible
role are: (1) scaling up takes the program into areas with less favourable production and/or market conditions and (2) scaling
up requires local organisations to take over from the special authorities.
11 PADETES reached to about 40 percent of the smallholder farms over a 10-year period. Initially, the program generated
positive impacts in Ethiopia.
24
Based on FAOSTAT data, it is shown that Ethiopia has similar cereal yields levels as
Uganda; Kenya and Malawi have higher cereal yields; and Tanzania, Rwanda and Sudan
have much lower yield levels. While Ethiopia achieves a higher cereal yield rate than the
average for Eastern Africa, it has however a lower yield level than the Least Developed
Countries average. Looking more into detail per crop (Table 6.4) we find that Ethiopia,
compared to the other countries in the region, has higher yields for maize and sorghum, but
smaller yields for wheat.
Table 6.3. Cereal yield by country and by year, 2006-2008
Country Cereal Yield (Kg/Ha)
Average as a
percentage of
Ethiopia’s average
yield (%)
2006 2007 2008 avg
Ethiopia 1651.9 1391.9 1421.7 1489 100
Kenya 1646.5 1773.3 1416.6 1612 108.3
Malawi 1444.6 2467 1598.6 1837 123.4
Rwanda 1117.7 1126.1 1126.1 1123 75.5
Sudan 644.7 729.4 567.1 647 43.5
Tanzania 1147.6 1238.4 1224 1203 80.8
Uganda 1522.9 1525.2 1534.4 1528 102.6
Eastern Africa 1393.9 1389.4 1302.1 1362 91.5
Least Developed Countries 1744.2 1780.3 1768.4 1764 118.5
World 3284.1 3381.9 3539.3 3402 228.5
Source: FAO data
Table 6.4. Yields (Kg/Ha) of maize, wheat and sorghum by country and by year, 2006-
2008
Country
Maize Wheat Sorghum
2006 2007 2008 2006 2007 2008 2006 2007 2008
Ethiopia 2640.4 1969.1 2136.7 1904 1505.5 1728.8 1575.5 1484.3 1510.2
Kenya 1719.7 1813.1 1392.4 2187.5 3093.9 2271.5 800.5 947.3 522
Malawi 1481.4 2654.7 1649.8 1207.1 2296.7 1613.2 768.7 859.2 831.4
Rwanda 799.5 818.1 818.1 850.9 869.5 869.5 1100.3 1098.2 1098.2
Sudan 1046.3 1909 2021.3 3831.9 2825.8 1945.7 667.1 766.3 584.5
Tanzania 1141 1180.3 1180.3 2750 2760 939.1 799.5 1000 1000
Uganda 1536 1495.2 1468.6 1800 1727.2 1727.2 1428.5 1452.2 1485.9
Eastern Africa 1423.5 1480.9 1518.7 1701.8 1820.1 1614.4 768.8 792.4 750.9
Least Developed Countries 1414.1 1461 1300.5 2005 1691.4 1747.6 1002.2 1077.3 1068.8
World 4752.8 4968.9 5109.4 2856.5 2857 3086.1 1327.7 1403.3 1459.1
Source: FAO data.
25
7. Summary and Conclusions
Ethiopia’s crop agriculture continues to be dominated by the country’s numerous small farms
that cultivate mainly cereals for both own-consumption and sales: smallholders account for
96 percent of total area cultivated. The five major cereals (teff, wheat, maize, sorghum and
barley) occupy almost three-quarters of total area cultivated, and represent almost 70
percent of total value added in recent years. Moreover, cereal acreage is still increasing,
though not as fast as area planted to other crops such as sesame, coffee, chat, vegetables
and pulses.
During the 1990s, most of the increase in cereal production came from increases in area.
However, in the 2000s, area and yield increases each accounted for about half of production
growth and we thus see an initial start of increasing intensification. With little suitable land
available for expansion of crop cultivation available, especially in the highlands, future cereal
production growth will need to come increasingly from yield improvements. Current improved
inputs use is relatively low, suggesting substantial scope for raising productivity through the
increasing adoption of improved seeds and chemical and organic fertilizer, i.e. at least in the
rainfall sufficient ecologies (and on irrigated farms). However, it seems that growth in
agricultural real incomes will also require more diversification and a shift to higher-value
crops, as to respond to changing consumption baskets driven by the increasing per capita
income growth in the country.
26
References
Agwe, J., M. Morris, and E. Fernandez. 2007. Africa’s Growing Fertilizer Crisis: What Role
for Fertilizer. ARD Note 21. World Bank.
Bonger, T., G. Ayele, and T. Kumsa. 2004. Agricultural Extension, Adoption and Diffusion in
Ethiopia. Ethiopian Development Research Institute, Research report no. 1. Addis
Ababa, Ethiopia.
CSA. January 2009. Large and Medium Scale Commercial Farms Sample Survey
2007/2008 (2000 E.C.). Results at Country and Regional Levels: Report on Area and
Production of Crops, and Farm Management Practices. Statistical Bulletin 443. Addis
Ababa: Central Statistical Agency.
CSA. October 2008. Report on Area and Production of Belg Season Crops for Private
Peasant Holdings. Ethiopian Agricultural Sample Survey (2007/08 (2000 E.C.)) –
Volume V. Statistical Bulletin 417. Addis Ababa: Central Statistical Agency. [various
years and numbers]
CSA. August 2008. Agricultural Sample Survey 2007/2008 (2000 E.C.): Volume III - Report
on Farm Management Practices (Private Peasant Holdings, Meher Season).
Statistical Bulletin 417. Addis Ababa: Central Statistical Agency.
CSA. June 2008. Agricultural Sample Survey 2007/2008 (2000 E.C.): Volume I - Report on
Area and Production Crops (Private Peasant Holdings, Meher Season). Statistical
Bulletin 417. Addis Ababa: Central Statistical Agency.
CSA. May 2007. Household Income, Consumption and Expenditure (HICE) Survey 2004/5:
Volume I - Analytical Report. Statistical Bulletin 394, Addis Ababa: Central Statistical
Agency.
EEA/EEPRI (Ethiopian Economic Association. Ethiopian Economic Policy Research
Institute). 2006. Evaluation of the Ethiopian Agricultural Extension with Particular
Emphasis on the Participatory Demonstration and Training Extension System
(PADETES). Addis Ababa, Ethiopia.
FAO (Food and Agriculture Organization of the United Nations). Food Balance Sheets
Database. http://faostat.fao.org/.
Taddesse, G. 2001. Land Degradation: A Challenge to Ethiopia. Environmental
Management 27 (6): 815–824.
Hamza, M.A., and W.K. Anderson. 2005. Soil compaction in cropping systems: A review of
the nature, causes and possible solutions. Review Article. Soil and Tillage Research
82 (2): 121–145.
27
Howard, J., E. Crawford, V. Kelly, M. Demeke, and J. J. Jeje. 2003. Prmoting high-input
maize technologies in Agrica: the Sasakawa-Global 2000 experience in Ethiopia and
Mozambique. Food Policy 28: 335–348.
McCann, J. C. 1995. People of the Plow: An Agricultural History of Ethiopia, 1800-1990.
Madison, Wisconsin: University of Wisconsin Press.
Spielman, D.J. 2008. Encouraging economic growth in Ethiopia: Perspectives on agricultural
input markets, agricultural extension and advisory services, and agricultural education
and training. Briefing note. Washington, D.C.: International Food Policy Research
Institute.
Taffesse, A. S. 2009. Cereal Production in Ethiopia: Recent Trends and Sources of Growth.
Unpublished manuscript, August 2009.
