Your search found 17 records
1 Siderius, W. 1991. The use of remote sensing for irrigation management with emphasis on IIMI research concerning salinity, waterlogging and cropping patterns. Unpublished mission report prepared for IIMI Pakistan. iv, 97p.
(Location: IWMI-HQ Call no: IIMI 621.3678 G730 SID Record No: H020029)
2 Yamaguchi, Y.; Harada, Y.; Otsubo, Y.; Amano, T.; Imazato, A.; Rikimaru, A. 1998. A new monitoring system for land and water resources management in arid area. In ICID, The Tenth Afro-Asian Regional Conference Proceedings: Water and land resources development and management for sustainable use, Denpasar, Bali, Indonesia, 19-24 July 1998. Volume II - B. Jakarta, Indonesia: Indonesian National Committee on Irrigation and Drainage (INACID) pp.B33:1-11.
(Location: IWMI-HQ Call no: ICID 631.7 G570 ICI Record No: H022963)
(Location: IWMI HQ Call no: IIMI 631.7.3 G730 STA Record No: H024724)
(3.81MB)
The final report of this project documents the lessons learned by researchers, social organizers, agency personnel and farmers. The project has demonstrated the willingness and ability of farmers and agency personnel to manage the land and water resources of the area jointly. The view of the researchers is that the small dams offer an excellent opportunity for the promotion of reforms in the irrigation sector.
4 Bodla, M. A.; Tariq, M. 1999. Interpretive analysis of canal seepage investigations for impact assessment of water conservation measures. In ICID, 17th Congress on Irrigation and Drainage, Granada, Spain, 1999: Water for Agriculture in the Next Millennium - Transactions, Vol.1A, Q.48: Irrigation under conditions of water scarcity; Q.48.1: Management of irrigation systems and strategies to optimize the use of irrigation water; 48.2: Techniques to promote water saving in irrigation. New Delhi, India: ICID. pp.301-318.
(Location: IWMI-HQ Call no: ICID 631.7 G000 ICI Record No: H025079)
(Location: IWMI-HQ Call no: PER, IWMI 631.7.1 G730 SAR Record No: H027451)
6 Sarwar, A.; Feddes, R. A. 2000. Evaluating drainage design parameters for the Fourth Drainage Project, Pakistan by using SWAP model: Part II - modeling results. Irrigation and Drainage Systems, 14(4):281-299.
(Location: IWMI-HQ Call no: PER, IWMI 631.7.1 G730 SAR Record No: H027452)
(Location: IWMI-HQ Call no: PER Record No: H028134)
(Location: IWMI-HQ Call no: P 7425 Record No: H037625)
(Location: IWMI-HQ Call no: P 7426 Record No: H037626)
10 Pradhan, P. 1996. Distributary level water users associations in pilot projects for farmer-managed irrigated agriculture, Punjab and Sindh Provinces, Pakistan. Consultancy report. Lahore, Pakistan: International Irrigation Management Institute (IIMI). Pakistan National Program. iii, 34p. (IIMI Pakistan Report C-5)
(Location: IWMI HQ Call no: IIMI 631.7.3 G730 PRA Record No: H009186)
11 Gill, M. A.; Mushtaq, K. 1998. Case study on Agriculture Department of Punjab Province. Lahore, Pakistan: International Irrigation Management Institute (IIMI). Pakistan National Program. vii, 126p. (IWMI Pakistan Report C-010 / IIMI Pakistan Report C-010) [doi: https://doi.org/10.3910/2009.497]
(Location: IWMI-HQ Call no: IIMI 631.7.3 G730 GIL Record No: H023178)
12 Skogerboe, G. V.; Bandaragoda, D. J. 1998. Towards environmentally sustainable agriculture in the Indus Basin Irrigation System. Final report. Lahore, Pakistan: International Irrigation Management Institute (IIMI). Pakistan National Programme. ix, 154p. (IWMI Pakistan Report R-077 / IIMI Pakistan Report R-077) [doi: https://doi.org/10.3910/2009.515]
(Location: IWMI-HQ Call no: IIMI 631.7.5 G730 SKO Record No: H024892)
13 Waheed-uz-Zaman. 1998. Impacts of farmer participation for water resources management in the Punjab Province, Pakistan: an analysis of process documentation for the Hakra 4-R Distributary. Lahore, Pakistan: International Irrigation Management Institute (IIMI). Pakistan National Program. viii, 39p. (IWMI Pakistan Report R-076 / IIMI Pakistan Report R-076) [doi: https://doi.org/10.3910/2009.532]
(Location: IWMI HQ Call no: IIMI 631.7.3 G730 WAH Record No: H025423)
(Location: IWMI HQ Call no: IWMI 631.7.4 G730 ULH Record No: H041394)
The smallholder irrigators of Pakistan have been under squeeze due to rising energy costs, as they depend heavily on pump and tractor owners for irrigation water and agricultural operations. The recent trends of perpetual increase in the energy prices in general, and diesel prices in particular, have resulted into soaring operational costs of agricultural machinery, causing the pumps and tractor rentals to rise because of monopoly of pump owners in the informal village markets. This paper aims at bringing forth the impacts of successive diesel price increase on irrigation economy of smallholders, and their coping strategies to absorb the energy shocks and sustain their livelihoods. Based on a synthesis of qualitative assessment from 9 village level case studies carried out in NWFP, Punjab and Sindh provinces of Pakistan, where diesel and electric pumps are essential for sustaining irrigated agriculture, the paper confirms that the recent hike in diesel prices have proven to be the proverbial last straw on camel’s back for the livelihoods of small farmers and tenants. While some landless tenants had quitted agriculture as a profession due in part to soaring diesel prices, the major coping strategies of the survivors were [a] switching the power source; [b] high input – high profit strategy; c) water conservation strategy; and d) agriculture exodus strategy. The paper also suggests areas for policy intervention and further research.
15 Ahmad, Mobin-ud-Din; Turral, Hugh; Nazeer, Aamir. 2009. Diagnosing irrigation performance and water productivity through satellite remote sensing and secondary data in a large irrigation system of Pakistan. Agricultural Water Management, 96:551-564.
(Location: IWMI HQ Call no: e-copy only Record No: H041854)
(1.74 MB)
(Location: IWMI HQ Call no: PER Record No: H042570)
(0.25 MB)
In 2006 a comprehensive sampling program was undertaken in two pre-selected peri-urban villages in Faisalabad, Pakistan to evaluate the soil and agronomic impacts of long-term (25–30 years) untreated wastewater re-use on wheat grain and straw yields and attributes of wheat straw fodder quality. Soil SAR, ESP, RSC and ECe were 63%, 37%, 31%, and 50% higher under wastewater (WW) as compared with canal water (CW) irrigated plots. Further, 2.7 and 6.65 fold increases in soil NO3- + NO2 - - N and Olsen-P were observed in WW as compared with CW irrigated plots. However, no significant differences in grain yield, wheat straw biomass, or fodder quality attributes were observed between WW and CW irrigated plots. In addition, for both CW and WW irrigated plots wheat straw, Cd and Pb concentrations were orders of magnitude below the EC Maximum permissible levels for Pb and Cd in feed materials and thus pose no threat to the fodderlivestock food chain. Further, elevated soil N associated with WW irrigated plots has a significant (p<0.01) positive influence on fodder quality by increasing the N content. Factorial ANOVA with covariance indicates that effective management of the elevated soil ECe in WW irrigated plots would increase grain yield and wheat straw biomass by 853 kg ha-1 (19.5%) and 819 kg ha-1 (18.6%) respectively as compared with CW irrigated plots. In Faisalabad, if managed appropriately to address emerging salinity issues the contribution of wastewater irrigation to the achievement of MDGs 1 and 7 could be significant if adverse impacts remain as marginal as found in this study.
(Location: IWMI HQ Call no: PER Record No: H046131)
(0.43 MB)
The fixed-turn or warabandi system of irrigation management is aimed at providing equitable rationing of Pakistan’s limited water resources. This paper assesses the equity in practice of the warabandi system using the Gini and Theil indices. Defining equity as the delivery of an equal depth of water over the irrigated area for a crop season, distribution is relatively equitable at the distributary level. There is a need for improved indices that represent inequity and the difference between canal capacity and operational flows. This is particularly important for canals in the low- and lowest-priority subsets of the warabandi schedule.
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