Sustainable Agriculture Research; Vol. 10, No. 2; 2021 
ISSN 1927-050X   E-ISSN 1927-0518 
Published by Canadian Center of Science and Education 
Effects of Improved Cassava Varieties on Farmers’ Income in Northern 
Agro-ecological Zone, Uganda 
Graceline O. Akongo1, Godfrey A. Otim1, Laban F. Turyagyenda1, Anton Bua1, Alfred Komakech2 & S. Obong1 
1 National Agricultural Research Organization (NARO), P. O. Box 295, Entebbe, Uganda 
2 Project for the Restoration of Livelihoods in Northern Region (PRELNOR), Gulu, Uganda  
Correspondence: Graceline O. Akongo, Ngetta Zonal Agricultural Research and Development Institute, P.O. Box 
52, Lira, Uganda. Tel: 256-772-342-974. E-mail: gracelinako@gmail.com 
 
Received: December 22, 2020   Accepted: April 1, 2021   Online Published: April 10, 2021 
doi:10.5539/sar.v10n2p65          URL: https://doi.org/10.5539/sar.v10n2p65 
 
Abstract 
This paper examines the extent to which improved cassava varieties contribute to improvement in income of 
smallholder farmers in the Northern agro-ecological zone of Uganda. In order to achieve the objective, data was 
collected from PRELNOR supported farmers’ fields, other farmers’ fields and baseline cassava fields. 
Consequently, descriptive statistics, gross margin and stochastic frontier analysis were adopted during analysis. 
Results from the analysis revealed that higher yields per hectare were registered within PRELNOR supported 
farmers’ fields and yield from NAROCAS1 surpassed all the varieties (37.3 tons per hectare). Location specific 
results revealed that Gulu had better yields (34.5 tons per hectare) while Kitgum registered the lowest average 
yield (24.1 tons per hectare). Gross margin indicated that every Shilling invested in improved variety earned 
profit 1.3 to 1.8 times above the local variety and each shillings invested in PRELNOR supported fields 
generated 5.6 times above the baseline fields. The parameter estimate for profit function revealed that planting 
material, other production related costs, NAROCAS1, NASE14 and NASE19 were positively correlated with 
profit but labour and baseline field had negative correlations. Conversely, profit efficiency grew by 40% under 
improved varieties against local varieties. This study suggests that the difference in yields and profit between 
locations was caused by biophysical characteristic; disease tolerant varieties can tremendously improve 
profitability and income; meanwhile the profit gaps were partly attributed to inefficiency. This study 
recommends fast tracking adoption of pest and disease tolerant varieties and integrated research and 
development approach throughout the cassava value chain. 
Keywords: cassava, income, Northern Uganda, profit efficiency, yield 
1. Introduction 
Cassava is grown and consumed throughout the world as a cheap source of carbohydrates, food security and 
income crop. In Uganda, it is the major root crop and is grown and consumed throughout the country (Kilimo 
Trust, 2012; Buyinza & Kitinoja, 2018; NARO, 2018; UBOS, 2019). Accordingly, area planted with the crop 
increased from 401,000 hectares in 2000 to 794,000 during 2010 then to 881,040 by 2018 (UBOS, 2003, 2011, 
2019). This therefore makes Uganda the sixth and first largest producer of cassava in Africa and east Africa, 
respectively (Kilimo Trust, 2012). Consequently, the crop has graduated to constitute part of the 16 major food 
crops grown in the country according to the Uganda Census of Agriculture (UCA) 2008/09 (UBOS, 2010). 
According to the cassava vision Africa, the crop is expected to contribute to food security and incomes for value 
chain actors thus promoting rural development. Within Uganda, northern region is the second largest producer of 
the crop accounting for 34% after eastern region (UBOS, 2010). However, its production in the region has been 
constrained by the two decades of civil war, poor weather, lack of quality planting material, poor management 
practices and pests and diseases. Cassava mosaic disease (CMD) and cassava brown streak disease (CBSD) have 
been the most constraining diseases. A number of released varieties before 2015 including TME14, TME204 and 
NASE13 among others succumbed to CMD and CBSD (Okao-Okuja et al., 2017). At the national level, total 
production declined persistently from 4,966,000 tons during 2000 to 3,017,000 tons during 2010 then to 
2,819,327 tons as of 2018. Yield has also been on the decline from 12.4 tons per hectare in 2000 down to 3.8 
tons in 2010 and then 3.2 during 2018. Potential yields of cassava attainable under good management ranged 
between 40.5 and 50.6 tons per hectare (Buyinza & Kitinoja, 2018). In northern region (Acholi sub region) 
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farmers only get a tenth (5 tons per hectare) of the expected average (Akongo & Otim, 2017). Poor per unit 
performance of the crop has subsequently affected both food and income security of the farmers in the region.  
Consequently, PRELNOR through Ngetta Zonal Agricultural Research and Development Institute (Ngetta 
ZARDI) which is one of the National Agricultural Research Organisation (NARO) institutes, selected, adapted 
and promoted high yielding and disease resistant varieties and practices. Among the varieties adapted and 
promoted were NASE14, NASE19 and NAROCAS1. Although yields from these varieties were high, the biggest 
challenge beforehand was limited knowledge on the extent to which these varieties were translating into 
improvement in farmers’ income. It was against this background that this paper sought to examine the extent to 
which these varieties were contributing to farmers’ income while using Acholi subregion of the northern 
agro-ecological zone as a case. 
2. Methods 
2.1 Study Area 
Acholi subregion forms part of the northern agro-ecological zone (NAEZ) located in the northern region of 
Uganda (Figure 1). The NAEZ lies between Latitude 03°80' N and Longitude 33°00' E with elevations varying 
between 600 and 1,200 meters above sea level (JICA, 2012). The subregion is particularly bordered by South 
Sudan in the north, Lango subregion in the south, West-Nile and Lake Albert Crescent in the west and Karamoja 
subregion in the east. The subregion has got 8 districts including Gulu, Amuru, Nwoya, Omoro, Kitgum, Lamwo, 
Pader and Agago. The subregion has a total area of 28,278 km2 (11.7% of the total land area in Uganda) and a 
total population of 1,5 million people of whom women constitute 51.5% (UBOS, 2019). The study area was 
chosen because it had the lowest per unit yield (Akongo & Otim, 2017; UBOS, 2010). Secondly, it was where 
the high yielding and pest and disease resistant cassava varieties were widely adapted and promoted during the 
past three years under PRELNOR. 
The area is categorized by tropical dry climate with bimodal to unimodal rainfall patterns with long-term average 
of 1434 mm (Akongo et al., 2018; JICA, 2012). However, a noticeable reduction in amount, intensity and 
duration occurs in the north and eastern districts. 
 
Figure 1. Map of Acholi sub-region showing PRELNOR districts 
 
The temperature ranges between 17°C and 32°C and this explains high prevalence of cassava in the area since 
root production is maximized between 25 and 32°C (UNMA, 2017; Buyinza & Kitinoja, 2018; UBOS, 2019). 
The soil type is Ferralsols though some patches of Leptosols and Plinthosols are of common occurrence (Akongo 
et al., 2018). Leptosols is characterized by many coarse fragments (sandy-clay) which renders it less productive 
in terms of crop growth (IUSS Working Group WRB, 2015). Unlike the rest of other crops, cassava adapts to 
marginal soil conditions. In terms of economic activities, agriculture is the backbone of the regional economy 
and more than 80% of the population is engaged in subsistence farming for food and earn their income from sale 
of crops. 
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2.2 Data Collection 
This paper adopted exploratory designs and the research approach was quantitative. The study population 
consisted of fields planted with cassava. Data was collected from a total sample of 392 fields. A sample of 137 
constituted PRELNOR supported fields, 158 were other farmers’ fields (other farmers’ fields where those planted 
with cassava within proximity of PRELNOR area but not supported by PRELNOR) while 97 were baseline 
fields (these where fields from which data were collected during the PRELNOR baseline survey conducted in 
2017). Two sets of data were collected: The first data set were collected during baseline survey in 2017 while the 
second data set were collected in 2020. The production data included yield, cost of inputs and cassava sale prices. 
The cost and price data were based on the current market cost of cassava production per hectare and price of 
fresh root tubers per kilogram, respectively. Inkind costs were excluded and the actual costs together with the 
price of fresh root were later used to compute revenue and profit. This study operationally defines income in 
terms of profits (gain or loss) made from investment in cassava production by the farmers, and hence financial 
gains accruing to individual or household as a result of applying the improved technologies. 
2.3 Data Analysis 
Three forms of analysis were applied to achieve the study objective: descriptive statistics, gross margin and 
stochastic frontier analysis. Descriptive statistics was used to generate means, standard deviation, frequencies 
and percentages. Gross margin is the difference between the gross farm income (total revenue) and the total 
variable cost (Ezeano et al., 2017; Isonguyo & Omolehin, 2017; Itam et al., 2014, 2018). The analysis performed 
to estimate returns (profitability) was given as ;                                                (1) 
W  he re ;    Gross margin 
     Total Revenue (Price*Quantity) 
 Total variable cost (variable costs are costs which change as output changes). 
Profit efficiency: to earn profit, resources (costs are incurred) are used to generate some level of output and 
hence profitability is a measure of the relationship between profits earned and resources used to earn profits (It is 
influenced by the margins between per unit costs and returns). In essence, profitability is closely related to 
efficiency (profit efficiency). In order to examine this relationship, stochastic frontier analysis was performed 
(Akongo et al., 2016; Belotti et al., 2012; Hyuha et al., 2007). The model helps to account for inefficiency 
component separately from measurement error and other statistical noise in a survey data. Accordingly, a 
stochastic profit function was co𝑙n𝑛s𝜋tru cte𝑎d u+si𝑎ng Cob
0 0 +∑4b-D𝑎ou𝑝gl
𝑖=1 𝑖 𝑖 +as∑ fu4nctional form (equation2). 
𝑖=1𝑎𝑖𝑤𝑖 + 𝑣𝑖  𝑢𝑖                      (2) 
Where 
π = restricted normalized profit defined as gross revenue less variable costs divided by tuber price per kilogram 
(p) 
pi = Costs of variable inputs normalised by price of root tuber.  
Where,  
p1 = total cost per hectare, 
p2 = cost of planting material,  
p3 = cost of labour inputs,  
p4 = other costs,  
wi = dummies for cassava varieties and period.  
Where,  
w1 = Type of variety (1=NAROCAS1; 0=Otherwise) - priori assumption (positive relationship) 
w2 = Type of variety (1=NASE14; 0=Otherwise) - priori assumption (positive relationship) 
w3 = Type of variety (1=NASE19; 0=Otherwise) - priori assumption (positive relationship) 
w4 = Category (1=Baseline fields; 0=Otherwise) - priori assumption (negative relationship) 
Throughout the analysis, local varieties and baseline fields were used as the controls against improved varieties 
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and PRELNOR supported farmers’ fields, respectively 
3. Results and Discussion 
The result sections reports yields, gross margins, parameters of the profit function and efficiency scores. 
Throughout the sections, results are reported according to the field category (baseline fields, other farmers’ field 
and PRELNOR supported fields), locations (Gulu, Amuru, Kitgum and Agago districts) and varieties (Local, 
NAROCASI, NASE14 and NASE19). Standard units of measurement are used: cassava yields are provided in 
tons per hectare, cost of production and profits per hectare were provided in Ugandan Shilling (exchange rate for 
Uganda shillings against US Dollar was valued at Ugx 3,700/-) and prices of fresh root tubers are given in 
shillings per kilogram. 
3.1 Yield Performance 
Mean yields are provided by field category, location and varieties in tons per hectare (Table 1). For each field 
category, variations between the baseline fields, other farmers’ field and PRELNOR supported fields were 
observed. Cassava yielded highest (28 tons) in PRELNOR supported fields which was above the baseline 
average (6.1 tons) and other farmers’ field (11.1 tons), respectively. The PRELNOR supported fields were within 
the range of expected potential yield under good management practices which ranges between 25 and 45 tons per 
hectare (Okao-Okuja et al., 2017). Generally, significant differences among field categories were mainly 
attributed to good agronomic practices and quality planting materials promoted under PRELNOR. 
With respect to locations, yields varied significantly between the districts where higher yield averages were 
achieved in Gulu (34.5 tons) followed by Amuru (26.5 tons). However, Kitgum (24.1 tons) and Agago (24.3 tons) 
realised lower averages. The possible explanation for yield variations between locations is differences in 
biophysical characteristics (soil and climate). It is evidently clear that certain conditions within the locality of the 
eastern districts do not favour production compared to the western districts which attained higher averages.  
In regards to varieties, lower average was achieved under local variety (Bao variety) as expected (20.1 tons). On 
the contrary, higher yields per hectare were obtained under improved varieties with NAROCAS1 (37.3 tons) 
surpassing NASE14 (28.1 tons) and NASE19 (26.9 tons). Although there were yield variations between locations 
and varieties, still there were significant improvements above the baseline fields and average registered 
elsewhere in western region of the country for NASE14 (22 tons). Generally, all the improved varieties promoted 
by PRELNOR performed within the range of the expected yield potential under good management practices. 
Buyinza & Kitinoja (2018) reported national average yield of cassava in Uganda at 12.65 tons per hectare. 
However, yield potential attainable in the country under good management conditions and practices ranges 
between 25 and 45 tons per hectare depending on a variety (Okao-Okuja et al., 2017). Whereas in other countries 
like Nigeria, potential yield averages under local variety ranges between 20 and 30 tons per hectare, under 
improved varieties is 25 to 70 tons per hectare and under marginal conditions where other crops fail is between 8 
and 15 tons per hectare. 
Table 1. Yield (tons) per hectare 
 Obs Mean Std. Dev. Min Max 
Field category      
Baseline fields 97 6.1436  5.7636  0.4708  31.6384  
Other fields 158 11.1177  12.5118  4.1667  64.501  
PRELNOR supported fields 137 28.0111  13.5156  5  62.1469  
Location      
Agago 44 24.2926  13.1201  5  57.9096  
Kitgum 24 24.076  13.3497  5  48.4934  
Amuru 24 26.5214  8.5961  14.9434  45.0752  
Gulu 45 34.5402  14.0545  9.8587  62.1469  
Variety      
Local 35 20.8409  9.7232  5  62.1469  
NASE14 36 28.1033  9.7268  14.9434  57.9096  
NASE19 35 26.874  14.686  5  57.9096  
NAROCAS1 31 37.2832  14.6906  5  57.9096  
 
 
 
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3.2 Income Analysis 
3.2.1 Change in Profit 
Profits are computed on per hectare basis and the results are provided in Uganda shillings while investment 
effects are provided against the baseline and local variety (Table 2). The baseline fields registered lower per unit 
profit of 2,519,209/- shillings. Other farmers’ field obtained 5,454,677/- shillings while PRELNOR supported 
fields generated 14,200,000/- shillings. Comparatively, investment effect from PRELNOR supported fields was 
5.6 times above the baseline fields. By implication, profit could improve by 5.6 times above the baseline fields 
for every 1 shilling invested. Likewise for every 1 shilling invested in other farmers’ fields, the return to 
investment was 3.1 times above the baseline fields. In fact, returns to investment (profit) within PRELNOR 
supported fields also surpassed 4,861,850/- shillings per hectare obtained elsewhere (AgriTT, n.d.). This could be 
explained by exposure and knowledge on good agronomic practices obtained by the farmers through trainings 
and information exchange under PRELNOR. Investment effects from other farmers’ fields were 2.2 times the 
baseline fields and this could have been a result of spillover effects from PRELNOR. 
Table 2. Revenue, profit and investment effect per hectare 
 Revenue Profit (shilling) per hectare Investment effects 
  Mean Std. Dev. Min Max 
Field category       
Baseline fields 3,262,267  2,519,209  3,075,843  150,000  16,300,000   
Other fields 5,903,475  5,454,677  6,283,513  1,389,500  32,500,000  2.17 
PRELNOR  14,900,000  14,200,000  7,134,750  1,970,055  32,500,000  5.64 
supported fields 
Variety       
Local 11,100,000  10,600,000  5,161,140  2,170,055  32,500,000   
NASE14 14,900,000  14,200,000  5,159,230  7,250,000  30,000,000  1.34 
NASE19 14,300,000  13,600,000  7,783,921  1,970,055  30,000,000  1.28 
NAROCAS1 19,800,000  19,100,000  7,769,297  1,970,055  30,000,000  1.80 
 
The improved varieties performed better than the local varieties with NAROCAS1 surpassing all the other 
varieties. NAROCAS1 generated profit worth 19,100,000/- shillings, NASE14 had 14,200,000/- shillings and 
NASE19 was the least among improved varieties with 13,600,000/- shillings. In terms of the investment effects, 
every shillings investment in NAROCAS1 variety would translate into income improvement worth 1.8 times 
above the local variety. Similarly NASE14 and NASE19 were 1.34 and 1.28 times that of local variety, 
respectively. Generally, every 1 shilling invested in improved variety increase farmers’ income by 1.3 to 1.8 
times (investment effects) above the local varieties. This is a confirmation that having access to improved 
varieties is a strategy towards improving farm household income and poverty reduction. Similar results have 
been reported elsewhere. In Nigeria, Akerele et al. (2019) reported benefit/cost ratio of ₦1.99k which suggested 
that every ₦1k invested in cassava production could realize 99k as a profit. Isonguyo & Omolehin (2017) 
observed similar result where an average rate of return of CMD resistant variety was higher at 2.49 against 1.67 
for non-CMD resistant variety. Itam et al. (2014) found cassava production profitable with a gross margin of 
₦9,520.66 per hectare. Likewise a study by Omotayo & Oladejo (2016) revealed that cassava is profitable 
according to the gross margin analysis but its net return was being affected negatively by cost of labuor and 
cassava planting material. Meanwhile (Ndonda et al., 2015) found that local varieties of cassava performed 
poorly and less profitable under intercropping system in DRC. These results were confirmed by the finding in 
this study that improved varieties are more profitable than non-improved varieties. 
3.2.2 Profit Function 
The results obtained through gross margin analysis confirmed that cassava production was profitable and indeed 
it contributes to improvement in farmers’ income. However, additional analysis was conducted to ascertain 
whether resources are being utilized efficiently (cost minimization) given the current level of profit (Akongo et 
al., 2016; Belotti et al., 2012; Hyuha et al., 2007). Consequently, stochastic profit function was estimated and the 
results of the parameter estimates are presented in Table 3. All the estimated parameters to explain the current 
level of profit were statistically significant except total cost of production and cost of labour used in production. 
Joint test for the variables was statistically different from zero (chi2
 (8) = 463.02; Prob > chi2 = 0.000). The result 
confirmed the priori expectation for all the variables in terms of the sign of the coefficient. Return to scale from 
investing in direct variable costs was on the decrease (RTS of 0.6) implying that the current level of profit is not 
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economically viable. Interestingly, the RTS could be enhanced to 1.3 when improved varieties are used and 
therefore economically viable. 
The estimated coefficients for the normalized profit function assume competitive market price in the cassava 
industry. The coefficient of variable cost of planting material was positive and significant at 1% level and by 
implication profit could increase with a unit increase in cost at the current level of production. In Nigeria, Itam et 
al. (2018) reported range similar to this study (22%) for cost of cuttings to total costs of production. However, in 
a related study the same authors observed contrary result where planting material had an inverse relationship 
with output (Itam et al., 2014). Ezeano et al. (2017) reported cost of cuttings at 37% of the total input cost in 
Nigeria. Other costs of production had a strong positive bearing on profit implying that a unit increase in other 
costs would translate in improvement in profit by approximately 43%. According to the authors, it was 
economical for farmers to increase their scale of production to match the current cost level. 
Table 3. Maximum likelihood estimates of the parameters 
    Number of obs = 392 
    Wald chi2(8) = 463.02 
Log likelihood -476.2627  Prob > chi2  = 0 
lnProfit Coef. Std. Err. z P>z [95% C.I] 
lnTotal Cost -0.0863 0.0960 -0.9 0.369 -0.2745 0.1020 
lnplanting material 0.2660 0.0989 2.69 0.007 0.0720 0.4599 
lnLabour cost -0.0136 0.0834 -0.16 0.87 -0.1771 0.1498 
lnOther costs 0.4264 0.0724 5.89 0 0.2845 0.5682 
NAROCAS1 0.5650 0.1390 4.06 0 0.2924 0.8375 
NASE14 0.3776 0.1488 2.54 0.011 0.0859 0.6693 
NASE19 0.4263 0.1504 2.83 0.005 0.1315 0.7211 
Baseline -0.6950 0.1132 -6.14 0 -0.9168 -0.4732 
_cons 6.9034 0.2816 24.52 0 6.3515 7.4552 
/lnsig2v -2.7625 0.3081 -8.97 0 -3.3664 -2.1586 
/lnsig2u 0.7015 0.0942 7.45 0 0.5169 0.8861 
sigma_v 0.2513 0.0387    0.1858 0.3398 
sigma_u 1.4201 0.0669    1.2949 1.5575 
sigma2 2.0799 0.1824    1.7224 2.4374 
lambda 5.6520 0.0906    5.4744 5.8295 
 
Using improved varieties confirmed priori assumption that it would enhance profit. NAROCAS1 had the highest 
positive response to profit (1% level of significance) and similarly planting NASE19 and NASE14 significantly 
improves profit implying that planting the varieties results in an increment in profit. Results from this study are 
in agreement with studies by Ndonda et al. (2015) who observed that the choice of cassava variety determines 
profitability of a cropping system. Ndonda et al. (2015) further found low efficiency associated with local 
cassava variety and concluded that improved varieties that are more productive and increase the net income and 
thus provide an economic benefit. Again this confirms (Itam et al., 2018) that improved cassava varieties are 
more profitable. As expected, lower profits generated from the baseline fields did not come as a surprise. 
Generally, there was a significant reduction in profit from the baseline fields. This relationship is best explained 
by the fact that farmers were growing low yielding and disease susceptible varieties and were less equipped with 
knowledge in good management practices before the project was introduced (Akongo & Otim, 2017). 
However, there were no significant results for total costs and labour costs to warrant further discussion. 
Nevertheless, the inverse relationship depicted meant profit level decreases with costs. Although the cost of 
labour was not statistically significant, the result indicated negative effect on profit and hence farmers’ income. 
Elsewhere, labour has been found to be a constraining input factor in cassava production (AgriTT, n.d.). Besides 
its cost implication, failure to have timely access can compromise quick and timely operations to catch up with 
rains. In Itam et al. (2018), cassava production in Nigeria was reported profitable but labour costs was found to 
constrain profit.  
3.2.3 Efficiency Gain and Loss 
The variance of inefficiency effect (σ²υ) was large suggesting that 97% (gamma) of variation in profit were due 
to inefficiency. Consequently, further investigation was conducted to identify inefficiency gaps and source of 
profit gains and lose (Figure 2). The result revealed that there was a huge inefficiency gap between the actual and 
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the best profit frontier. Comparison of inefficiency performance between the baseline, PRELNOR supported and 
other fields also revealed some degree of variations.  
 
Figure 2. Efficiency gain/loss by field category and variety (%age) 
 
On average the baseline fields attained mean efficiency of 26.7% which translated into an inefficiency gap of 
73.3% from the best frontier. Meanwhile other farmers’ field registered mean efficiency of 48.4% representing 
81.3% gain above the baseline. Whereas PRELNOR supported fields registered an average of 57.2% and in 
comparison to the baseline fields, there was an improvement (efficiency gain) of 114.2%. These results imply 
that profit efficiency will improve as farmers gain access to programmes directed towards improving cassava 
value chain. 
Conversely, efficiency performance in terms of varieties revealed poor performance in local variety (38.4%) as 
expected. On the other hand, all the improved varieties performed slightly above average frontier. NASE14 was 
more efficient at 53.7% followed by NASE19 (50.8%) and NAROCAS1 (50.5%). According to the growth 
comparison, efficiency improved by 31.5 to 39.8% above the local variety. This did not come as a surprise since 
improved varieties are bred to enhance yields, profit and subsequently income level by addressing challenges 
such as pest and disease and poor adaptability to bad weather among others which affects yields. Isonguyo & 
Omolehin (2017) also found planting material of improved varieties (resistant CMD) more efficient (1.0) than 
non-improved varieties (1.15) among Nigerian farmers. Relatedly, Akerele et al. (2019) reported mean technical 
of 58.6% and concluded that there was room for improvement by 41.4% and that cassava production in the study 
area is very lucrative. Eze & Nwibo (2014) observed that cassava production was profitable but farmers were 
inefficient because they were underutilizing resources. Planting material and labour were underutilized with 
efficiency index of 3.1 and 6.3, respectively implying that income can only be improved by using resources 
efficiently. 
4. Conclusion and Recommendation 
4.1 Conclusions 
This paper concludes that the use of improved varieties increases farmers income by 1.2 to 1.7 times above the 
local varieties. The study also revealed that lack of information on good agronomic practices and labour 
constraints affect profitability from cassava growing. 
4.2 Recommendation 
This study recommends further research into biophysical constraints causing yield and profit gaps and the 
possible solution. The study also recommends increase in investment in promotion of pest and disease tolerant 
improved varieties by enhancing access to low cost planting materials of improved varieties. There is need to 
turn the current rate of return into economically viable enterprise through integrated approach throughout the 
value chain by integrating high-yielding and pest and disease resistant varieties with value addition and 
marketing. There is need to encourage farmers to upscale production in order to enjoy economies of scale since it 
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is economically viable. 
Acknowledgement 
This study was funded by the Government of Uganda with a grant from ASAP (Adaptation for smallholder 
Agricultural Program) and a loan from IFAD through the Project for the Restoration of Livelihood in Northern 
Region (PRELNOR). We are grateful to farmers in Kitgum, Lamwo, Pader, Agago Amuru and Gulu from whom 
we collected the data. 
Reference 
AgriTT. (n.d.). Building Uganda’s cassava production base. 
Ajetomobi, J., Abiodun, A., & Hassan, R. (2011). Impacts of Climate Change on Rice Agriculture in Nigeria. 
Tropical and Subtropical Agroecosystems, 14(2), 613-622. 
Akerele, E. O. (2019). Productivity and Technical Efficiency of Cassava Production in Ogun State, Nigeria.  
Akongo, G. O., Gombya-Ssembajjwe, W., Buyinza, M., & Bua, A. (2016). Effects of Climate Variability on 
Technical Efficiency of Rice in Acholi and Lango Sub-regions, Uganda. Journal of Economics and 
Sustainable Development, 7(11). Retrieved from www.iiste.org 
Akongo, G. O., Gombya-Ssembajjwe, W., Buyinza, M., & Namaalwa, J. J. (2018). Characterisation of Rice 
Production Systems in Northern Agro-Ecological Zone, Uganda. Journal of Agricultural Science, 10(1), 
272. https://doi.org/10.5539/jas.v10n1p272 
Akongo, O. G., & Otim, A. G. (2017). Baseline survey report for Project for the Restoration of Livelihoods in 
Northern Region (PRELNOR). Ngetta Zonal Agricultural and Development Institute. National Agricultural 
Research Organisation. 
Belotti, F., Daidone, S., Ilardi, G., & Atella, V. (2012b). Stochastic frontier analysis using Stata. Stata Journal, 
13(14), 718-758. https://doi.org/10.2139/ssrn.2145803 
Buyinza, T., & Kitinoja, L. (2018). Commodity Systems Assessment of Cassava in Uganda. 
Coelli, T. J., Rao, D. S. P., O’Donnell, C. J., & Battese, G. E. (2005). An Introduction to Efficiency and 
Productivity Analysis (2nd ed.). 
Eze, A. V., & Nwibo, S. U. (2014). Economic and technical efficiency of cassava production in Ika North East 
Local Government Area of Delta State, Nigeria. Journal of Development and Agricultural Economics, 6(10), 
429-436. https://doi.org/10.5897/jdae2013.0541 
Ezeano, C. I., Okeke, C. C., Obiekwe, N. J., & Onwusika, A. I. (2017). Adoption and profitability of TMS 
cassava variety Inenugu South Local Government Area Of Enugu State, Nigeria. Indo-Asian Journal of 
Multidisciplinary Research (IAJMR), 3(3), 1125-1134. https://doi.org/10.22192/iajmr.2017.3.3.3 
Hyuha, T. S., Bashaasha, B., Nkonya, E., & Kraybill, D. (2007). Analysis of Profit Inefficiency in Rice 
Production in Eastern and Northern Uganda. African Crop Science Journal, 15(4). 
Isonguyo, R. G., & Omolehin, R. A. (2017). Comparative Economic Analysis of Cassava Mosaic 
Disease-Resistant Varieties and Non-Resistant Varieties Production in Akwa Ibom State of Nigeria. 
International Journal of Environment, Agriculture and Biotechnology, 2(5), 2605-2621.  
https://doi.org/10.22161/ijeab/2.5.43 
Itam, K. O., Ajah, E. A., & Agbachom, E. E. (2014). Analysis of Determinants of Cassava Production and 
Profitability in Akpabuyo Local Government Area of Cross River State, Nigeria. International Business 
Research, 7(12). https://doi.org/10.5539/ibr.v7n12p128 
Itam, K. O., Ajah, E. A., & Udoeyop, M. J. (2018). Comparative cost and return analysis of cassava production 
by adopters and non-adopters of improved cassava varieties among farmers in Ibesikpo Asutan LGA, Akwa 
Ibom State, Nigeria. Global Journal of Agricultural Sciences, 17(1), 33.  
https://doi.org/10.4314/gjass.v17i1.4 
JICA. (2012). The Project for Rural Road Network Development in Acholi Sub-region in Northern Uganda Final 
Report Vol.2: Main Report. Japanese International Cooperation Agency (JICA). 
Kilimo Trust. (2012). Development of Inclusive Markets in Agriculture and Trade (DIMAT): A Value Chain 
Analysis of the Cassava Sub-sector in Uganda. Undp. Retrieved from  
http://www.undp.org/content/dam/uganda/docs/UNDPUg_PovRed_ValueChainAnalysisReportHoney2013
Report.pdf 
72 
 
http://sar.ccsenet.org Sustainable Agriculture Research Vol. 10, No. 2; 2021 
Kumbhakar, S. C., & Lovell, C. A. K. (2000). Stochastic Frontier Analysis. Cambridge University Press. 
https://doi.org/10.1017/cbo9781139174411 
NARO. (2018). The NARO Strategic Plan 201819 - 202728, National Agriculture Research organization, 
Entebbe, Uganda. 
Ndonda, A., Mahungu, N., Frangoie, A., & Moango, A. (2015). Enhancing yield and profitability of cassava in 
the savannah and forest zones of Democratic Republic of Congo through intercropping with groundnut. 
Journal of Applied Biosciences, 89(1), 8320. https://doi.org/10.4314/jab.v89i1.6 
Okao-Okuja, G., Hamba, S., Omara, J., Nuwamanya, E., Kawuki, R., Alicai, T., & Hnya, E. K. R. (2017). 
Cassava applied research for food and income security in Northern Uganda. Cassava baseline survey 
report. 
Omotayo, A. O., & Oladejo, A. J. (2016). Profitability of Cassava-based Production Systems. Journal of Human 
Ecology, 56(1-2), 196-203. https://doi.org/10.1080/09709274.2016.11907056 
UBOS. (2003). Statistical abstract 2003. Uganda National Bureau of Statistics (UBOS). Retrieved from 
http://www.ubos.org 
UBOS. (2010). Uganda Census of Agriculture 2008/2009 Volume 4: Crop Area and Production Report. Uganda 
Bureau of Statistics. Retrieved from http://www.ubos.org/ 
UBOS. (2011). Statistical abstract 2011. Uganda Bureau of Statistics (UBOS). Retrieved from 
http://www.ubos.org/ 
UBOS. (2019). Statistical abstract final 2019. Uganda National Bureau of Statistics (UBOS). Retrieved from 
http://www.ubos.org/ 
UNMA. (2017). UNMA. (2017). Monthly mean rainfall and temperature for the last ten years collected from 
weather stations in Lira, Gulu and Kitgu. Uganda National Meteorology Authority (UNMA). 
 
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