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Irrg scheduling & Methods.ppt

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Proper irrigation scheduling determines when and how much to irrigate crops. It is important for efficient water use and maximizing yields. Methods for determining when to irrigate include soil moisture indicators like tensiometers, plant indicators like wilting, and meteorological data. The amount of irrigation applied should bring the soil moisture in the effective root zone to field capacity, accounting for expected rainfall and crop water needs.

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IRRIGATION SHEDULING AND METHODS Dr Shiv Prakash Singh
ABSTRACT  Scheduling of irrigation to crops is essential for efficient utilization of available water, saving of input and enhancing yield.  It is prime process decides two important questions in irrigation, ‘when to irrigate?’, ‘how much to irrigate?’.  Soil indicators such as gravimetric method, feel and appearance method, tensiometer method, electrical resistance method and water budget technique; plant indicators like appearance and growth, leaf water potential and stomatal resistance techniques; meteorological indicators approach decides when to irrigate?.  The quantity of irrigation water to be applied (how much to irrigate?) at each irrigation depends upon the amount of available moisture in the soil (at effective root depth).
INTRODUCTION  Scheduling of irrigation is a process to decide ‘when to irrigate’ and ‘how much to irrigate’ to the crops.  Proper scheduling is essential for efficient use of irrigation water, inputs such as seeds, fertilizers, labour etc.  Appropriate scheduling of irrigation not only saves water, but also, saves energy besides, higher crop yield.  Farmers are generally irrigating their crops on either time interval basis (say weekly interval, ten days interval) or based on the appearance of the crops (based on wilting symptoms).  There are several soil, plant and atmospheric (meteorological) indicators in addition to combination approach, critical stage approach etc. to decide when to irrigate the crop.  Similarly, based on the moisture content in the effective root zone quantity of irrigation water (how much to irrigate?) to crops is decided.
LEARNING OBJECTIVES  To study the importance of scheduling of irrigation to crops.  To learn the detailed methods of scheduling of irrigation along with their merits and limitations.
ADVANTAGE OF IRRIGATION SCHEDULING
FARMERS FOLLOW TODAY Most of the farmers follow irrigation practices which are resulting in either under-irrigation or over- irrigation of crops, resulting in low production per unit of water (water use efficiency).
SITUATIONS FARMERS FREQUENTLY FACE  Where adequate water is available, farmer aims is to produce maximum yield per unit of land and unit of water.  Here, he has to provide optimum irrigation schedules, with time-sequence for number of irrigations and quantity of each irrigation, for ensuring optimum crop yield with high water-use efficiency.  Where a limited quantity of water is available, he aims to produce maximum yield per unit of water.  In this case, information is to be provided for rationalizing the limited water distribution over the available land, applying water at moisture sensitive stage of crop growth and withholding irrigation at other stages.
Factors in Determination of Irrigation Scheduling  The scheduling tool must consider information about the crop, soil, climate, irrigation system, water deliveries and management objectives.  An irrigation scheduling tool needs only be accurate enough to determine how much water to apply and when.  A good rule of thumb to follow when developing an irrigation scheduling tool is to keep it simple and easy to understand.
WHEN TO IRRIGATE ?  Crops vary with their soil moisture requirement for maximum yields and quality of produce.  Most plants are efficient in absorbing water from soil, if the soil moisture level is nearing at field capacity (-0.33 bar).  As the soil moisture level drops from field capacity due to evapotranspiration and other losses, soil moisture tension naturally increase and eventually crops can’t extract needed moisture from soil for their optimum growth.  Crops start to wilt and growth is first retarded and then completely stops.  When the moisture level is restored again by addition of irrigation water or rain, some crops regain their growth and show little or no permanent damage.  Other crops, however, are permanently damaged.
WHEN TO IRRIGATE  These crops are generally drought tolerant. Ex. Sorghum, pearl millet, finger millet, cotton.  For certain crops, providing irrigation at 25% depletion of available moisture enhance yield levels. Ex. Maize, wheat. Crops should not experience moisture stress in the period between two irrigations, which naturally happens under field condition especially under light textured (sandy, sandy loamy) soils.  Irrigation has to be given when there is adequate moisture in the soil to meet transpiration demand of the crop and evaporation need of atmosphere.  By knowing the amount of moisture available in the root zone of the crop and the evapotranspiration demands of the crop and atmosphere, it is easy to determine when irrigation is needed.  There are several approaches to decide ‘when to irrigate’ based on soil, plant and atmospheric parameters, combination of soil and atmospheric parameters and critical crop stage approaches.
IRRIGATION SCHEDULING CRITERIA
SOIL INDICATORS  These methods involve in determining moisture content of the soil and finding the deficit level in available moisture.  Based on pre-determined minimum water content, irrigation is given to bring the soil to field capacity.  The soil water content is determined either by direct measurement or inference from measurements of other soil parameters such as soil water potential or electrical conductivity.
GRAVIMETRIC METHOD  It is the direct method of measuring the moisture content of soil.  Samples taken from the field, weighted, dried at 105°C for about 24 hours till constant weight is obtained and again weighed after drying.  The difference in weight between the wet (WS1) and oven dry (WS2) samples gives the moisture content (Pw) in percentage. PW (%)=  The method is simple and reliable, but, time consuming. WS1-WS2 WS2
FEELAND APPEARANCE METHOD  With experience, farmer can judge soil water content by the feel and also appearance of the soil.  Soil samples are taken with a probe or soil auger from each quarter of the root zone depth, formed into a ball, tossed into air and caught in one hand.  Available moisture percentage is estimated for different textures of soils.  Considerable experience and judgment are necessary to estimate available soil moisture content in the sample within reasonable accuracy.
JUDGING THE AMOUNTOF AVAILABLE MOISTURE IN SOIL
JUDGING THE AMOUNTOF AVAILABLE MOISTURE IN SOIL Available moisture range Coarse Texture (Loamy Sand) Moderately coarse texture (Sandy Loam) Med. Texture (Loamy and silt loamy) Fine texture (Clay loam and silty clay loam) Field capacity (100%) On squeezing, no free water appears on soil, but wet outline is left on hand Similar Symptoms 75-100% Tends to stick together slightly, sometimes forms a very weak ball under pressure Forms weak ball, breaks easily, don’t slick Forms a ball, very pliable, slicks readily Easily ribbons out between fingers, has slick feeling 50-75% Appears to be dry don’t form a ball with pressure Tends to form a ball under pressure but seldom holds together Forms a ball somewhat plastic, some-times slick slightly with pressure Forms a ball, ribbons out between thumb and fore- finger 25-50 % As above, but ball is formed by squeezing very firmly Appears to be dry, don’t form a ball unless squeezed very firmly Some what crumbly but holds together with pressure Somewhat pliable, forms a ball under pressure 0-25 % Dry, loose, single grained flows through fingers Dry, loose, flows through fingers Powdery dry, sometimes slightly crusted but easily broken down into powdery conditions. Hard, baked, cracked, sometimes has loose crumbs on surface.
TENSIOMETER METHOD   Irrigation can be scheduled based on soil moisture tension.  Tensiometers are installed at specified depth in the root zone.  When the soil moisture tension reaches to a specified values (0.5, 0.75 or 1.0 bars etc.) irrigation is scheduled.  Tensiometers are generally used to schedule of irrigation in wheat / orchards.  This method however, fails to provide the quantity of water to be irrigated.
WATER BUDGET TECHNIQUE  It is computed by posting everyday ET, effective precipitation, soil water content etc.  This method is cumbersome and lot of data is required.  Determining the balance of moisture in the soil. Also, Electrical resistance methods like Gypsum, nylon, nylon and fibre, fibre glass blocks are generally used to measure a tension of different levels
APPEARANCE AND GROWTH  Deliberate visual indicators to asses the water need in plant are leaf and shoot wilting, leaf colour, drooping of leaves, rolling of leaves etc.  But, appearance and growth are not often effective parameters for deciding irrigation scheduling, as plants exhibit visible symptoms of deficiency long after they experience moisture stress.  When partial or full stomatal closure occurs due to reduction of transpiration (because of reduced availability of water to the plant), there is a rise in leaf temperature.  A hand-held infrared thermometer measures the difference between plant canopy temperature (Tc) and air temperature (Ta) and displays Tc-Ta values.  This Tc-Ta value is much useful for scheduling of irrigation. Positive values in Tc-Ta values are an indication of more temperature in the canopy than atmosphere (stress in plant canopy) and irrigation is to be given
METROLOGICAL INDICATORS  When supply of soil moisture is adequate for the plant, evapotranspiration is primarily controlled by the evaporative demand of the air atmosphere.  Meteorological concepts and approaches have been used as indicators to determine ‘when to irrigate?’.  Irrigation can be conveniently scheduled to a crop, if allowable water depletion in the root zone and evapotranspiration of the crop for short periods during the crop period is known.  At the end of each such period, the crop sown after the soil is brought to field capacity would require irrigation with the depth of water sufficient to meet the total cumulative evapotranspiration less effective rainfall during the period since previous irrigation.
IW/CPE APPROACH In this approach, a known quantity of irrigation water (IW) is applied when cumulative pan evaporation (CPE) reaches a predetermined level. The amount of water given in each irrigation ranges from 4 to 6 cm, the most common being 5 cm of irrigation. Scheduling irrigation at an IW/CPE ratio of 1.0 with 5 cm of irrigation water is applied when the CPE reaches 5 cm. Generally, irrigation is scheduled at 0.75 to 0.8 ratio with 5 cm of irrigation water. In IW/CPE ratio approach, irrigation can also be scheduled at fixed level of CPE by varying amount of irrigation water.  However, the equipment to measure CPE and IW are not easily available with the farmers.
ROUGH METHODS FOR FARMERS  Simple methods are suggested to the farmers to find out when to start irrigation and how much water to apply.  They use only the feel and appearance method described earlier as a rough guide to know when to irrigate and the probe is used to determine when to stop irrigation.
SOIL CUM MINI-PLOT TECHNIQUE  In this method, 1x1x1 m size of pit is dug in the middle of the field.  About 5% of sand (by volume) is added to the pit, mixed well with soil and the pit is filled up in natural order.  Crops are grown normally in all areas including pit area.  The plants in the pit show wilting symptoms earlier than the other areas.  Irrigation is scheduled as soon as wilting symptoms appear on the plants in the pit.
SOWING HIGH SEED RATE  In an elevated area, one square metre plot is selected and crop is grown with four times thicker than the normal seed rate.  Because of high plant density, plants show wilting symptoms earlier than in the rest of the crop area indicating the need of scheduling of irrigation.
CRITICAL STAGE APPROACH  In each crop, there are certain growth stages at which moisture stress leads to irrevocable yield losses.  These stages are called as critical period or moisture sensitive period.  Hence, irrigation must be given to these stages to avoid yield losses
Moisture Sensitive Stages of Important Crops Rice, pearl millet, finger millet Panicle initiation, flowering Wheat Crown root initiation, jointing, milking Sorghum Seedling, flowering Maize Silking, tasselling Groundnut Rapid flowering, pegging, early pod formation Red gram, Pea, Moong, Urd Flowering, pod formation Sugarcane Formative stage Sunflower Two weeks before and after flowering Soybean Blooming, seed formation Cotton Flowering, boll development Chilli Flowering Potato Tuber formation to tuber maturity Onion Bulb formation to maturity Tomato From commencement of fruit setting Cabbage Head formation to firming stage of head
How Much to Irrigate ?  The quantity of irrigation water to be applied to the soil at each irrigation depends upon the amount of available moisture in the soil (specifically at effective root depth i.e. moisture extraction depth of the roots), at the time of starting irrigation (or the level of available moisture depletion from field capacity) at which irrigation is proposed.  The effective rainfall expected in the period between this irrigation and the next one and the additional quantity of irrigation water required if salts are to be leached beyond root zone and the application losses.  The basic principle is mainly to give irrigation to bring the soil (at effective root zone depth of crops) to field capacity.  More often, allowance is given for expected effective precipitation to be stored in the soil. (Contd)…
How Much (Depth) to Irrigate ?  Bout 70 % root mass is found in the upper half of the max. root depth.  About 70 % of the water used by top 50 % root zone  Normally, 01 cm water irrigated to 4-5 cm soil depth in loam soil, but in sandy soil it may be more than 5 cm.  In case 60 cm root depth, effective root zone will be 30 cm and irrigation depth will be 30/5 means 6 cm.
Factors Affecting Crop Water Need  Climatic factors eg. temperature, humidity, wind velocity and sun shine.  Type of soil eg. Soil texture, soil structure, soil density, water holding capacity , soil reaction, biological properties, organic content in soil etc.  Plant features eg. Vegetative growth, number of stomata, leaf area, depth of root.  Agriculture activities. weed control and inter-culture operations
IRRIGATION METHODS
Improvement in Water Use Efficiency  Water Management at field Levelling of field: Less time in irrigation, uniform water distribution, water saving, equal moisture environment, proper seed germination and growth etc Irrigation scheduling Improvement in conveyance efficiency Improved irrigation method e.g. bed planting Micro irrigation Water holding in field : bund making Mulching
Improvement in Water Use Efficiency  Selection of suitable crop varieties  Timely sowing/panting  Conjunctive use of surface and ground water  Renovation of ponds in rural areas  Agriculture diversification  Artificial water recharge  Mass awareness generation
Summary  Scheduling of irrigation is a process decides ‘when to irrigate’ and ‘how much to irrigate’ to the crops.  Most plants are efficient in absorbing water from soil, if the soil moisture level is nearing at field capacity (-0.33 bar).  Soil indicators, plant indicators, meteorological indicators, combination approach (of soil and meteorological), rough methods for farmers and critical stage approach are some of the means to scheduling irrigation.  Soil indicators involve in determining moisture content of the soil and finding the deficit level. Contd.-----
Summary  Gravimetric method, feel and appearance method, tensiometer method, electrical resistance method and water budget technique are used as soil indicators.  Plant parameters have to be related to soil water content to determine the irrigation scheduling.  Appearance and growth, leaf water potential and stomatal resistance techniques are used as plant indicators.  Meteorological indicators such as evapotranspiration of the crop are important to identify the irrigation need and IW/CPE approach is mainly followed here. Contd.-----
Summary  Simple methods such as can evoporimetry method, soil cum mini-plot technique and sowing high seed rate are used by farmers to decide irrigation scheduling.  Critical stage of crop for irrigation is identified to crops and irrigation is given during the stage to avoid yield losses is called critical stage approach.  The quantity of irrigation water to be applied (how much to irrigate) to the soil at each irrigation depends upon the amount of available moisture in the soil (at effective root depth).
Summary  Different methods of irrigation are followed by farmers to irrigate field.  Generally, flooding of field is most common method used by farmers, specially in canal area, which is the most unwise method.  Farmers should select the irrigation method, which are water saving without compromising the crop yield.  Micro irrigation is most effective method for irrigating the crops, which save water with improved yield and quality of produce.  Major objective should be to improve the crop water productivity.
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Irrg scheduling & Methods.ppt

  • 2. ABSTRACT  Scheduling of irrigation to crops is essential for efficient utilization of available water, saving of input and enhancing yield.  It is prime process decides two important questions in irrigation, ‘when to irrigate?’, ‘how much to irrigate?’.  Soil indicators such as gravimetric method, feel and appearance method, tensiometer method, electrical resistance method and water budget technique; plant indicators like appearance and growth, leaf water potential and stomatal resistance techniques; meteorological indicators approach decides when to irrigate?.  The quantity of irrigation water to be applied (how much to irrigate?) at each irrigation depends upon the amount of available moisture in the soil (at effective root depth).
  • 3. INTRODUCTION  Scheduling of irrigation is a process to decide ‘when to irrigate’ and ‘how much to irrigate’ to the crops.  Proper scheduling is essential for efficient use of irrigation water, inputs such as seeds, fertilizers, labour etc.  Appropriate scheduling of irrigation not only saves water, but also, saves energy besides, higher crop yield.  Farmers are generally irrigating their crops on either time interval basis (say weekly interval, ten days interval) or based on the appearance of the crops (based on wilting symptoms).  There are several soil, plant and atmospheric (meteorological) indicators in addition to combination approach, critical stage approach etc. to decide when to irrigate the crop.  Similarly, based on the moisture content in the effective root zone quantity of irrigation water (how much to irrigate?) to crops is decided.
  • 4. LEARNING OBJECTIVES  To study the importance of scheduling of irrigation to crops.  To learn the detailed methods of scheduling of irrigation along with their merits and limitations.
  • 6. FARMERS FOLLOW TODAY Most of the farmers follow irrigation practices which are resulting in either under-irrigation or over- irrigation of crops, resulting in low production per unit of water (water use efficiency).
  • 7. SITUATIONS FARMERS FREQUENTLY FACE  Where adequate water is available, farmer aims is to produce maximum yield per unit of land and unit of water.  Here, he has to provide optimum irrigation schedules, with time-sequence for number of irrigations and quantity of each irrigation, for ensuring optimum crop yield with high water-use efficiency.  Where a limited quantity of water is available, he aims to produce maximum yield per unit of water.  In this case, information is to be provided for rationalizing the limited water distribution over the available land, applying water at moisture sensitive stage of crop growth and withholding irrigation at other stages.
  • 8. Factors in Determination of Irrigation Scheduling  The scheduling tool must consider information about the crop, soil, climate, irrigation system, water deliveries and management objectives.  An irrigation scheduling tool needs only be accurate enough to determine how much water to apply and when.  A good rule of thumb to follow when developing an irrigation scheduling tool is to keep it simple and easy to understand.
  • 9. WHEN TO IRRIGATE ?  Crops vary with their soil moisture requirement for maximum yields and quality of produce.  Most plants are efficient in absorbing water from soil, if the soil moisture level is nearing at field capacity (-0.33 bar).  As the soil moisture level drops from field capacity due to evapotranspiration and other losses, soil moisture tension naturally increase and eventually crops can’t extract needed moisture from soil for their optimum growth.  Crops start to wilt and growth is first retarded and then completely stops.  When the moisture level is restored again by addition of irrigation water or rain, some crops regain their growth and show little or no permanent damage.  Other crops, however, are permanently damaged.
  • 10. WHEN TO IRRIGATE  These crops are generally drought tolerant. Ex. Sorghum, pearl millet, finger millet, cotton.  For certain crops, providing irrigation at 25% depletion of available moisture enhance yield levels. Ex. Maize, wheat. Crops should not experience moisture stress in the period between two irrigations, which naturally happens under field condition especially under light textured (sandy, sandy loamy) soils.  Irrigation has to be given when there is adequate moisture in the soil to meet transpiration demand of the crop and evaporation need of atmosphere.  By knowing the amount of moisture available in the root zone of the crop and the evapotranspiration demands of the crop and atmosphere, it is easy to determine when irrigation is needed.  There are several approaches to decide ‘when to irrigate’ based on soil, plant and atmospheric parameters, combination of soil and atmospheric parameters and critical crop stage approaches.
  • 12. SOIL INDICATORS  These methods involve in determining moisture content of the soil and finding the deficit level in available moisture.  Based on pre-determined minimum water content, irrigation is given to bring the soil to field capacity.  The soil water content is determined either by direct measurement or inference from measurements of other soil parameters such as soil water potential or electrical conductivity.
  • 13. GRAVIMETRIC METHOD  It is the direct method of measuring the moisture content of soil.  Samples taken from the field, weighted, dried at 105°C for about 24 hours till constant weight is obtained and again weighed after drying.  The difference in weight between the wet (WS1) and oven dry (WS2) samples gives the moisture content (Pw) in percentage. PW (%)=  The method is simple and reliable, but, time consuming. WS1-WS2 WS2
  • 14. FEELAND APPEARANCE METHOD  With experience, farmer can judge soil water content by the feel and also appearance of the soil.  Soil samples are taken with a probe or soil auger from each quarter of the root zone depth, formed into a ball, tossed into air and caught in one hand.  Available moisture percentage is estimated for different textures of soils.  Considerable experience and judgment are necessary to estimate available soil moisture content in the sample within reasonable accuracy.
  • 15. JUDGING THE AMOUNTOF AVAILABLE MOISTURE IN SOIL
  • 16. JUDGING THE AMOUNTOF AVAILABLE MOISTURE IN SOIL Available moisture range Coarse Texture (Loamy Sand) Moderately coarse texture (Sandy Loam) Med. Texture (Loamy and silt loamy) Fine texture (Clay loam and silty clay loam) Field capacity (100%) On squeezing, no free water appears on soil, but wet outline is left on hand Similar Symptoms 75-100% Tends to stick together slightly, sometimes forms a very weak ball under pressure Forms weak ball, breaks easily, don’t slick Forms a ball, very pliable, slicks readily Easily ribbons out between fingers, has slick feeling 50-75% Appears to be dry don’t form a ball with pressure Tends to form a ball under pressure but seldom holds together Forms a ball somewhat plastic, some-times slick slightly with pressure Forms a ball, ribbons out between thumb and fore- finger 25-50 % As above, but ball is formed by squeezing very firmly Appears to be dry, don’t form a ball unless squeezed very firmly Some what crumbly but holds together with pressure Somewhat pliable, forms a ball under pressure 0-25 % Dry, loose, single grained flows through fingers Dry, loose, flows through fingers Powdery dry, sometimes slightly crusted but easily broken down into powdery conditions. Hard, baked, cracked, sometimes has loose crumbs on surface.
  • 17. TENSIOMETER METHOD   Irrigation can be scheduled based on soil moisture tension.  Tensiometers are installed at specified depth in the root zone.  When the soil moisture tension reaches to a specified values (0.5, 0.75 or 1.0 bars etc.) irrigation is scheduled.  Tensiometers are generally used to schedule of irrigation in wheat / orchards.  This method however, fails to provide the quantity of water to be irrigated.
  • 18. WATER BUDGET TECHNIQUE  It is computed by posting everyday ET, effective precipitation, soil water content etc.  This method is cumbersome and lot of data is required.  Determining the balance of moisture in the soil. Also, Electrical resistance methods like Gypsum, nylon, nylon and fibre, fibre glass blocks are generally used to measure a tension of different levels
  • 19. APPEARANCE AND GROWTH  Deliberate visual indicators to asses the water need in plant are leaf and shoot wilting, leaf colour, drooping of leaves, rolling of leaves etc.  But, appearance and growth are not often effective parameters for deciding irrigation scheduling, as plants exhibit visible symptoms of deficiency long after they experience moisture stress.  When partial or full stomatal closure occurs due to reduction of transpiration (because of reduced availability of water to the plant), there is a rise in leaf temperature.  A hand-held infrared thermometer measures the difference between plant canopy temperature (Tc) and air temperature (Ta) and displays Tc-Ta values.  This Tc-Ta value is much useful for scheduling of irrigation. Positive values in Tc-Ta values are an indication of more temperature in the canopy than atmosphere (stress in plant canopy) and irrigation is to be given
  • 20. METROLOGICAL INDICATORS  When supply of soil moisture is adequate for the plant, evapotranspiration is primarily controlled by the evaporative demand of the air atmosphere.  Meteorological concepts and approaches have been used as indicators to determine ‘when to irrigate?’.  Irrigation can be conveniently scheduled to a crop, if allowable water depletion in the root zone and evapotranspiration of the crop for short periods during the crop period is known.  At the end of each such period, the crop sown after the soil is brought to field capacity would require irrigation with the depth of water sufficient to meet the total cumulative evapotranspiration less effective rainfall during the period since previous irrigation.
  • 21. IW/CPE APPROACH In this approach, a known quantity of irrigation water (IW) is applied when cumulative pan evaporation (CPE) reaches a predetermined level. The amount of water given in each irrigation ranges from 4 to 6 cm, the most common being 5 cm of irrigation. Scheduling irrigation at an IW/CPE ratio of 1.0 with 5 cm of irrigation water is applied when the CPE reaches 5 cm. Generally, irrigation is scheduled at 0.75 to 0.8 ratio with 5 cm of irrigation water. In IW/CPE ratio approach, irrigation can also be scheduled at fixed level of CPE by varying amount of irrigation water.  However, the equipment to measure CPE and IW are not easily available with the farmers.
  • 22. ROUGH METHODS FOR FARMERS  Simple methods are suggested to the farmers to find out when to start irrigation and how much water to apply.  They use only the feel and appearance method described earlier as a rough guide to know when to irrigate and the probe is used to determine when to stop irrigation.
  • 23. SOIL CUM MINI-PLOT TECHNIQUE  In this method, 1x1x1 m size of pit is dug in the middle of the field.  About 5% of sand (by volume) is added to the pit, mixed well with soil and the pit is filled up in natural order.  Crops are grown normally in all areas including pit area.  The plants in the pit show wilting symptoms earlier than the other areas.  Irrigation is scheduled as soon as wilting symptoms appear on the plants in the pit.
  • 24. SOWING HIGH SEED RATE  In an elevated area, one square metre plot is selected and crop is grown with four times thicker than the normal seed rate.  Because of high plant density, plants show wilting symptoms earlier than in the rest of the crop area indicating the need of scheduling of irrigation.
  • 25. CRITICAL STAGE APPROACH  In each crop, there are certain growth stages at which moisture stress leads to irrevocable yield losses.  These stages are called as critical period or moisture sensitive period.  Hence, irrigation must be given to these stages to avoid yield losses
  • 26. Moisture Sensitive Stages of Important Crops Rice, pearl millet, finger millet Panicle initiation, flowering Wheat Crown root initiation, jointing, milking Sorghum Seedling, flowering Maize Silking, tasselling Groundnut Rapid flowering, pegging, early pod formation Red gram, Pea, Moong, Urd Flowering, pod formation Sugarcane Formative stage Sunflower Two weeks before and after flowering Soybean Blooming, seed formation Cotton Flowering, boll development Chilli Flowering Potato Tuber formation to tuber maturity Onion Bulb formation to maturity Tomato From commencement of fruit setting Cabbage Head formation to firming stage of head
  • 27. How Much to Irrigate ?  The quantity of irrigation water to be applied to the soil at each irrigation depends upon the amount of available moisture in the soil (specifically at effective root depth i.e. moisture extraction depth of the roots), at the time of starting irrigation (or the level of available moisture depletion from field capacity) at which irrigation is proposed.  The effective rainfall expected in the period between this irrigation and the next one and the additional quantity of irrigation water required if salts are to be leached beyond root zone and the application losses.  The basic principle is mainly to give irrigation to bring the soil (at effective root zone depth of crops) to field capacity.  More often, allowance is given for expected effective precipitation to be stored in the soil. (Contd)…
  • 28. How Much (Depth) to Irrigate ?  Bout 70 % root mass is found in the upper half of the max. root depth.  About 70 % of the water used by top 50 % root zone  Normally, 01 cm water irrigated to 4-5 cm soil depth in loam soil, but in sandy soil it may be more than 5 cm.  In case 60 cm root depth, effective root zone will be 30 cm and irrigation depth will be 30/5 means 6 cm.
  • 29. Factors Affecting Crop Water Need  Climatic factors eg. temperature, humidity, wind velocity and sun shine.  Type of soil eg. Soil texture, soil structure, soil density, water holding capacity , soil reaction, biological properties, organic content in soil etc.  Plant features eg. Vegetative growth, number of stomata, leaf area, depth of root.  Agriculture activities. weed control and inter-culture operations
  • 31. Improvement in Water Use Efficiency  Water Management at field Levelling of field: Less time in irrigation, uniform water distribution, water saving, equal moisture environment, proper seed germination and growth etc Irrigation scheduling Improvement in conveyance efficiency Improved irrigation method e.g. bed planting Micro irrigation Water holding in field : bund making Mulching
  • 32. Improvement in Water Use Efficiency  Selection of suitable crop varieties  Timely sowing/panting  Conjunctive use of surface and ground water  Renovation of ponds in rural areas  Agriculture diversification  Artificial water recharge  Mass awareness generation
  • 33. Summary  Scheduling of irrigation is a process decides ‘when to irrigate’ and ‘how much to irrigate’ to the crops.  Most plants are efficient in absorbing water from soil, if the soil moisture level is nearing at field capacity (-0.33 bar).  Soil indicators, plant indicators, meteorological indicators, combination approach (of soil and meteorological), rough methods for farmers and critical stage approach are some of the means to scheduling irrigation.  Soil indicators involve in determining moisture content of the soil and finding the deficit level. Contd.-----
  • 34. Summary  Gravimetric method, feel and appearance method, tensiometer method, electrical resistance method and water budget technique are used as soil indicators.  Plant parameters have to be related to soil water content to determine the irrigation scheduling.  Appearance and growth, leaf water potential and stomatal resistance techniques are used as plant indicators.  Meteorological indicators such as evapotranspiration of the crop are important to identify the irrigation need and IW/CPE approach is mainly followed here. Contd.-----
  • 35. Summary  Simple methods such as can evoporimetry method, soil cum mini-plot technique and sowing high seed rate are used by farmers to decide irrigation scheduling.  Critical stage of crop for irrigation is identified to crops and irrigation is given during the stage to avoid yield losses is called critical stage approach.  The quantity of irrigation water to be applied (how much to irrigate) to the soil at each irrigation depends upon the amount of available moisture in the soil (at effective root depth).
  • 36. Summary  Different methods of irrigation are followed by farmers to irrigate field.  Generally, flooding of field is most common method used by farmers, specially in canal area, which is the most unwise method.  Farmers should select the irrigation method, which are water saving without compromising the crop yield.  Micro irrigation is most effective method for irrigating the crops, which save water with improved yield and quality of produce.  Major objective should be to improve the crop water productivity.