Preface As a result of concerted multi-agency efforts focussing on R&D and technology with effective policy and institutional mechanism, India could harvest a record production of foodgrains of about 250 million tonnes during 2011-12. However, low production/ productivity and almost stagnant production of pulses remained a matter of concern for the researchers and planners of the country. Backed up with higher support prices and technological backstopping by developmental agencies, pulses production could also be achieved to a record levels of 18.24 million tonnes in 2010-11 and 17.28 million tonnes in 2011-12. In spite of the record production, the country still imported 3.5 million tons of pulses (2010-11) costing about Rs.7,000 crores in foreign exchange, being the biggest importer with close to 20 percent share of the world. Whenever availability of pulses fell short of domestic demand, there has been a spurt in prices causing widespread concerns among the planners and policy makers because pulses are considered a major source of proteins and play an important role in improving food and nutritional security particularly for the poor and small and marginal farmers in India. To alleviate protein-energy malnutrition in the country, a minimum of 50 gm of pulses per capita per day is required in addition to other sources of proteins such as cereals, milk, meat, egg, etc. To make up this shortfall, about 27 million tonnes of pulses are required by 2015 and 32 million tons by 2030. To meet this target, the overall pulses production must increase at the rate of around 4 percent per annum. Though the latest data shows that pulses productivity has reached a record level of approximately 700 kg/ ha, the present productivity growth is still not sufficient enough to meet the diversified pulses demand of the rising population. This seems a herculean task in the light of the past trends in pulses production. India's dependence on global market to meet the domestic demand for pulses would increase in future. Completely relying on imports would not be a good strategy for a country with a large vegetarian population. Therefore, a well thought strategy is urgently needed to meet future demand of pulses and avoid crises situations. The key elements of such a strategy should aim at providing technological backstopping for managing biotic and abiotic stresses and achieving a breakthrough in pulse productivity on sustainable basis alongwith remunerative price support for the farmers. It must be remembered that pulses are going to play crucial role not only for nutritional security but also for improving human-livestock- soil health and also for saving water resource. Experiences from farming system research reveal that opting for specific cropping pattern for different regions and adopting improved agronomic practices provide us with substantial scope for incorporating pulses in the prevailing farming systems, and realising the target of pulses production is not difficult if location-specific strategies are implemented effectively. The content of the present book addresses all the relevant issues by dovetailing the region-specific strategy and options for solving pulses crises in the country. It is expected that the book would serve to sensitise the planners and policy makers as well as the local agricultural development officials to explore and implement region-specific strategy for enhancing pulses production by incorporating these in the prevailing farming systems by harnessing the available technological potential. Moreover, various technological options and strategies presented in this book would also be useful for all the stakeholders to realise the target of pulses production in near future.

India has witnessed a phenomenal increase in foodgrains production since Independence and from a food deficit state producing about 51 million tons in 195051 it become food surplus country with a record harvest of more than 250 million tons in 201112. This particular year also saw a remarkable record production of pulses at about 18.1 million tons. However, to meet the increasing demand of the continuously rising population about 23 million tons of pulses have to be imported every year costing the country about Rs.3000 crores in foreign exchange. Despite the changes in the dietary habits in which the large middle class has moved away from traditional cereals towards high value dairy, meat, fruits and vegetable products, pulses in India are still considered an important source of proteins, particularly for the poor. Pulses are not only an excellent source of protein (2040%), carbohydrates (5060%) and minerals (24%) but also provide calories almost equal to that of cereals energy to the tune of 300 to 540 Kcal/ 100g (Ofuya and Akhidue, 2005). Thus, pulses play an important role in achieving food and nutritional security for small and marginal farmers. However, the per capita availability of pulses has been declining over the time – it has declined from 60.7 gm/ day in 1951 to about 32 gm/day in 2010 – mainly due to stagnant production (except in recent years), rising demand for consumption and other uses. Pulses not only are used for consumption, but also play an even greater role in maintaining and enhancing soil fertility through nitrogen (N2) fixation. Though the estimates of Nfixed by pulses depends on crop species, soil type, agroclimatic zone and crop management practices, it was reported that early, medium and long duration pigeonpea varieties fix 7, 55 and 69 kg/ ha1, respectively, in Vertisols of Patancheru (Kumar Rao and Dart, 1987). Pulses N2 are grown not only as sole crops but also as intercrops and the biological nitrogen fixation (BNF) of pulses substantially benefits the associated or succeeding crops in terms of nitrogen contribution (1668 kg/ N2 ha1 for succeeding cereals). Thus on a conservative estimate, the BNF (@46 kg/N2 ha1) by pulses, excluding the intercrop area, alone amounts to 1.06 million tons annually.

India is the largest producer of pulses in the world with 24% share in the global production. During 201011, the total production was 18.09 million tonnes from an area of 25.6 million hectare (Table 1). The important pulse crops grown in India are chickpea (48%), pigeonpea (15%), mungbean (7%), urdbean (7%), lentil (5%) and fieldpea (5%). The major pulse producing states are Madhya Pradesh, Maharashtra, Rajasthan, Uttar Pradesh, Karnataka and Andhra Pradesh, which together account for about 80% of the total production. The pulses production does not keep pace with the domestic requirement and consequently, the nation has to import 23 million tonnes and the per capita availability of pulses has declined progressively from 41.6 g in 1990 to 37 g in 2008 (Indian Council of Medical Research recommends 65 gm/day/capita). Thus, increasing production from the current level poses a serious challenge for the nation. Even with the best of efforts, pulses production and productivity has more or less remained stagnant. Due to the low productivitylow input nature, pulses are grown as residual/alternative crops on marginal lands after taking care of food/income needs from high productivityhigh input crops like rice and wheat by most farmers. Also, they grow as rainfed crops with little or no modern yield enhancing inputs. The low priority accorded to pulse crops may be related to their relatively low status in the cropping system. As a crop of secondary importance, in many of these systems, pulse crops do not attract much of the farmer’s crop management attention. In deficient soils, the application of micronutrients has also been found to be remunerative, yet the farmers hardly use these inputs. Seeds of newly developed varieties are not available to the farmers in the required quantities. As a result the seed replacement rate is hardly about 2 to 5%. In addition to this, these crops are adversely affected by a number of biotic and abiotic stresses, which are responsible for reduced yield. Lack of onfarm storage facilities and the vulnerability of pulses to store grain pests also results in considerable losses. Stray cattle and blue bulls are responsible for a lot of damage to the pulse crops especially during offseason, thus affecting adversely the cultivation of crops like mungbean, urdbean, pigeonpea, fieldpea and lentil in Bihar, Uttar Pradesh, Madhya Pradesh, Rajasthan and Haryana also resulting in instability and low yields.

Pulse production in NE states in still too low as compared to whole India. However, there is very good potentialfor enhancing pulse producity in the region and contribute to food grain production of the country. In view of these constraints, prospects for increasing pulse production from this region have been visualized. Pulse production scenario Despite immense importance of pulses in humanand animal nutrition, the share of north-easternregion inthe total pulse areofIndiaistoolow (0.76%)andthisregion contributesonly176.44 thousandtons(0.99%) in the all Indiapulse production (Table 1). WithinNE Region, mostof the pulsearea isoccupied by Assam and 47% of total N.E. Region’s pulse production is contributed by this state alone. After Assam, Nagaland and Tripura are major pulse growing states with 33.5 and 14.5 thousand hectares of area and 36.46and 24.20thousandtons ofproduction, respectively. In Meghalaya, pulseswere grownon4 thousandhaarea and4.2 thousand tonnesof pulses wereharvested in 2010-11. Thefactthat theaverage pulse productivity of NE region (883.0kg/ha)is much higher thanthatof whole India (689kg/ha) offers opportunityfor increasingarea and production of pulses in the region.

Indian agriculture is characterized by small farm holdings. The average farm size was only 1.21 hectares during 2005-10 and it would be 0.68 ha by 2030. Around 85% of farmers have land holdings smaller than 2 ha and they cultivate nearly 60% of the available land. The contribution of agriculture sector to the total (GDP) has decline from 38% in 1980 to 29% in 2000 and 15% in 2010-11. The per capita availability of land was 0.15 ha in 1999-2000, which will reduce to 0.11 ha by 2020. As per estimates, India would require about 345 million tones of food grains for feeding about 1.5 billion populations by the year 2020. Approximately 90% of total farm holdings are categorized as small and marginal. There is hardly any scope of horizontal area expansion. The situation is, further, aggravated due to globalization of market and trade relaxations, which call for competitiveness and efficient agricultural production system to face never challenges on the ecological, climatic, equity, social justice and employment front. In areas, endowed with adequate irrigation resources, short duration pulses, oilseeds and other high value crops will find their definite niche as sequential or intercrops, rather than replacing the major cereal crops having higher yield potential combined with high stability. Hence, an increased cropping intensity will contribute substantially to additional demands of food and cash crops.

The relevance and need for an eco-friendly alternative farming system arose from the ill effects of the chemical farming practicesadopted worldwide during the second half of the last century. The methods of farming evolved and adopted by our forefathers for centuries were less injurious to the environment. People began to think of various alternative farmingsystemsbased on the protection of environment which in turn would increase the welfare of the humankind in various ways like clean and healthy foods, an ecology which is conducive to the survival of all the living and non-living things, low use of the non-renewable energy sources, etc. Many systems of farming evolved as an outcome of the efforts of many experts and laymen. However, organic farming is considered to be the best amongall of them because of its scientific approach and wider acceptance all over the world. Organic farming means farming in the spirit of organic relationship. In nature, organic relationship is a pervasive phenomenon. Everythingis connectedwith everything else. Hence, organic farmingis not mere non-chemicalism in agriculture. Since, organic farmingmeans placingfarmingonintegral relationship, wehave to know therelationship between soil-water and plant; betweensoilandsoil microbes andwasteproducts;between the plant and animal kingdom of which the apex animal is the human being; between agriculture and forestry; between soil, water and atmosphere etc.It is the totality of the relationship that is the bedrock of organic farming. However, the understanding of this totality of relationship is not sufficient for success in organic farming. Understanding the local specificity in respect of each of these aspects of these multiple relationship is also important (Pal, 2006).

Among thirty major cropping systems in the country, which contribute significantly to the national food basket, the majority are cereal-based. In fact, continuous cropping of cereal-based systems during last three decades has resulted in second generation problems and the sustainability of these systems is under threat. The major challenge is to produce more from each unit of land on the one hand and to sustain soil health on the other. The depletion of soil fertility by the intensive cereal-cereal production systems is considered to be a major cause of the yield decline. For example, a rice-wheat cropping system (RWCS) yielding 7 t/ha of paddy and 4 t/ha of wheat removes 315 kg nitrogen (N)/ ha, 28 kg phosphorus (P)/ ha and 333 kg potassium (K)/ ha, and significant amounts of micro-nutrients (Hegde and Dwivedi, 1992). These off-takes often exceed fertiliser input in many Indian states. Refinement of nutrient management strategies would help maintain the crop productivity and soil fertility, but other rotational strategies could also help especially in situations where greater fertiliser use may be uneconomic or environmentally unacceptable. Legume crops fix atmospheric N and enrich soil fertility, and could help to sustain the long-term productivity of cereal-based cropping systems. Depending on the soil and ecological stresses, a cropping system can be diversified using legumes under different mode. Results from the All-India Coordinated Project on Integrated Farming Systems (AICRP-IFS) of Indian Council of Agricultural Research show consistently better productivity with inclusion of legumes in cropping systems. The benefits of legumes in rotation are not solely due to biological nitrogen fixation but also because it increased nutrient availability, improved soil structure, reduced disease incidence and increased mycorhyizal colonization (Wani et al., 1995). Inclusion of pulses as intercrops in sequential as well as intercropping systems would not only make the country self reliant but also help in improving the soil health. Series of experiments are being conducted under (AICRP-IFS) and elsewhere in the country to identify need based cropping systems for different agro-climatic zones of India. The pre-dominent cropping systems involving legumes as a strategy for nutrient management through different approaches are being discussed here for ready reference of researchers, planners and extension workers.

Tillage management and seedbed preparation is crucial for crop establishment, growth and ultimately, yield. Typically, the aims of cultivation are to incorporate crop residue, bury weeds and loosen soil to allow appropriate soil–seed contact, easy flow of nutrients, air and water and unimpeded root penetration and crop growth (Hermawan and Bomke, 1997; Bengough et al., 2006). The use of tillage to prepare seedbeds and the subsequent benefits are well documented. However, the amount of tillage and best practice in terms of optimumsoil physical properties specifically for the establishment period has received less attention in comparison. The influence of a seedbed can vary greatly in terms of soil aggregation and subsequent porosity. This soil arrangement, therefore, has direct impacts on soil temperature, water content, oxygen availability and strength, all of which have the potential to affect the performance of the seedbed and its ability to provide an adequate environment for crop establishment. In a review, Braunack and Dexter (1989) stated as summary of previous works conducted on soil aggregation that aggregates will exhibit differing physical and chemical properties depending on the size of the aggregates, thus influencing the suitability of a seedbed for germination, emergence and root development, by influencing factors such as intra- and inter-aggregate aeration. Schjønning and Rasmussen (2000) found that cultivation methods can have large impacts on surface soil layers, altering both strength and pore dynamics (air and water filled), which can restrict plant growth. The relationship between soil physical properties and the plant root systems are vitally important in this process since they directly affect seedbed quality (Awadhwal and Thierstein, 1985; Aubertot et al., 1999; Dexter, 2004).

Integrated nutrient management is considered to be the key for achieving higher yield of crops and cropping systems. In general, the productivity of pulse crops has remained low mainly for two reasons: cultivation on agriculturally marginal soils and little if any crop inputs. Among production inputs, fertilizer plays a key role in pulses too like other crops for enhancing productivity levels. Most of the pulses fix atmospheric N, which is the predominant mechanism to meet their N requirement. It can enrich soil fertility by fixing nitrogen. It has been estimated that chickpea can fix (convert atmospheric nitrogen to organic nitrogen which would be available for subsequent crops)up to 140 kg nitrogen per hectare in a growing season, although measured values are usually in the range of about 20-60 kg nitrogen per hectare (Reddy 2004). It has been well established that long duration pigeonpea in northern India can fix nitrogen in the order of 200 kg/ha when grown over a 40 week period. Pigeonpea can also have substantial residual effects on subsequent crops. For example, medium-duration pigeonpea grown at the International Crop Research Institute for Semi-Arid Tropics (ICRISAT) (Asia Centre) could benefit a subsequent maize crop to an extent equivalent to 40 kg nitrogen per hectare. However, this capability is jeopardized through insufficient supply of other plant nutrients. General recommendations for phosphorus (P) fertilization are made in most states. However, K application is generally neglected, resulting in imbalanced nutrient supply and lower crop yields. Under intensive cropping systems, large amounts of K are removed, leading to serious depletion of soil K reserves. Pulses such as chickpea and pigeonpea remove about 60 and 52 kg K2O/t of grain, respectively. Information compiled from various sources on integrated nutrient management in pulse/pulse based cropping systems in different agroecological regions of the country suggest that there is a wide scope for practicing integrated plant nutrient (IPN) practices in pulses and pulse based cropping systems. Practicing of INM not only economize inorganic fertilizer use but also helps in balanced fertilization and improving soil health and productivity through complimentaryeffects of fixed N by pulses and applied phosphorus and potassium.

Pulses in India are considered a residual crop and grown under rainfed conditions in marginal/ less fertile lands. About 90 percent of total pulse production comes from 97 million ha of rainfed areas in our country. Presently, Madhya Pradesh, Maharashtra, Uttar Pradesh and Rajasthan contribute 85% of the total area and production of pulses in the country. Pulse crops usually face soil water deficits sometime during their growth cycles. Thus, drought stress is a common phenomenon and ranks high among all abiotic stresseslimiting yields of pulses (Ali and Mishra, 2000). Hence, there is an urgent need to increase the pulse productivity to increase the income of farmers and reduce malnutrition. Productivityof pulsesin rainfed agriculture has remainedlowand unstable owing to climate and soil related constraints (Swindale, 1982). Soil moisture is the foremost factor that determines the productivity of rainfed pulses where rainfall is the only source of water. To maintain required soil moisture in rainfed lands, every action must be focused to conserveas much quantity of rainfall in the soil as possible (Rao, 1997). Unfortunately, farmers following rainfed agriculture in our country are not practicing any sort of moisture management techniques though wehaveahandful of techniques suitable for rainfed conditions.

Symbolic to its nomenclature, ’PULSE’ (P = people, U = umbrella, L = livestock, S = soil and E = energy) is a superb group of agricultural crops extending an energy umbrella to people (as a major source of dietary protein), livestock (as a green nutritious fodder and feed) and soil (as a builder and restorer of soil fertility through biological N2 fixation). On account of these qualities, pulses have occupied a unique position in the Indian farming system. Crop diversification with greater inclusion of legumes is essential to alleviate declining factor productivity, input use efficiency and increasing cost of cultivation for realizing sustainable use of natural resources. Pulses are increasingly becoming a component of the intensive cropping systems as intercrop, substitute crop or catch crop. In upland situations, pulses play an important role as intercrops and ensure more income and efficient use of resources. While analyzing the reasons of low productivity of pulses in various parts of the country, it is observed that non availability of high yielding disease resistant varieties, cultivation on marginal and sub-marginal lands under deficit moisture and fertility and poor pest management are the major constraints in realizing optimum yield potential.

In the past, focus on implementing plant protection measures was given to cereals, largely because of their central role in food security, however, recent shortages in legumes has warranted an all out attention on edible pulses. For more than four decades, the concept of integrated pest management (IPM) - which combines a range of controls, including conserving natural predators, using pest resistant crop varieties, intercropping and rotation, with judicious use of pesticides -has struggled to gain ground against conventional agricultural ideology and practices. But it is now increasingly challenging the methods of high-input agriculture and policies arising with implementation of General Agreement forTrade andTariffs (GATT) & World Trade Organization (WTO) that cannot be ignored. In fact, a major factor responsible for sustaining soil productivity in this country has been the highly diversified nature of the cropping patterns which either include a pulse crop or a legume crop as one of the components. India is the largest producer of pulses in the world with 25% share in the global production. While chickpea is the topper among pulses occupying 39% of pulse area, pigeon pea is next with 21% area. The major pulse producing states are Maharashtra (20%), Madhya Pradesh (17%), Rajasthan (11%), Uttar Pradesh (11%) andAndhra Pradesh (11%) together accountingfor 70% of thetotal production of 14.76 m.t from an area of 23.63 m ha (www.agricoop.nic.in, 2007-08). In general, the pulse production is not keeping pace with the domestic requirements, hence, the country has to import 1.5-2.8 m.t per year, which is a matter of concern. Keeping this in view, the 1PM programme covers the two important pulse crops viz., chickpea and pigeon pea, across different cropping systems which will take care of changing scenario emerging out of climatic changes as well as cropping patterns. The present strategy, which is based on a holistic approach and changing ecosystem, will help in increasing production through reduction in pest infestation that would eventually reduce the need for the import of these two vital commodities.

Pulses are the major source of lysine richprotein, which is supplementaryto cereal based proteins (metheonine).Leguminous speciesproducing edible seeds occupy prominent place in Indian dietary habits. They are, even today, a primary sourceof protein forthe majority of population in the country. Avariety of pulse crops such as peas, lentils, urad, tur, moong, yellow peas, chickenpea,pigeonpea andbeans aregrown underdifferent agro-climatic conditions, and India is recognized globally as a major player contributing toabout25 percentoftheworld’sproduction.Thepresent demand forpulsesin the countryis estimated to be about 15 milliontonnes, while the productionhovers around 12 to 14 million tones. The post harvest losses in the legumes take place at farm as well as in storage as reported by DMI (2002) are detailed in Table 1, 2 and 3.

Pulse legumes are considered to be the best choice for intensification of predominant cereal-based systems. The studies conducted in different agro-climatic zones under AICRP on cropping systems have revealed that the productivity of existing cropping-systems can be enhanced by the inclusion of legumes during summer or as catch crop, or in intercropping systems (Gangwar et al., 2009). Further, these food legumes also serve as a feed crop in many farming systems and fetch higher prices compared to cereals and are increasingly being grown to supplement farmers’ incomes (Gouda et al., 1999). Although pulse legumes have many desirable characteristics in terms of increasing system’s productivity, raising nutritional standards and environmental benefits, in most countries of the world they are considered secondary crops. Globally, the harvested area under pulse crops is about one-tenth of the harvested area under all cereal crops. In view of the important and diverse role played by pulses in the farming systems and in the diets of the poor population, this chapter presents the global trade scenario in pulses followed by pulses production and trade opportunities in India. An attempt is also made to highlight the major concerns and to meet the future challenges in production and trade of pulses in India.

Of the total global pigeonpea production, over 90 percent of this is grown in India. The major pigeonpea growing states are Karnataka, Andhra Pradesh, Tamil Nadu, Maharashtra, Bihar, and Uttar Pradesh, contributing to 88.2% of the total pigeonpea basket and the same holds goodover the years. Over the decades, whatever little increase in production level was observed i.e. from 1.75 mt (19701975) to 2.75 mt (20052009), it is neither uniform nor steady. It is mainly through the expansion of area from 2.52 mha to a level of 3.58 mha ( 20052009 ) without significant change in productivity which ( 1970 1975) has remained almost stagnant around 700 kg/ha (Table 1) and is a matter of real concern (Srivastava, 1993).The gross geographical shifting of area ( 467 th. ha) took place mainly from traditional areas (Uttar Pradesh and Bihar) to new and less productive areas (Maharashtra, Karnataka, Gujarat, Andhra Pradesh, Orissa) with a netgainof area 837 th. ha in Central zoneandSouthzone includingexpandedadditional area (Table 23).

Mungbean (Vigna radiata L Wilczek) is considered to be originated from Vigna sublobata. It is also known as green gram, an important short duration grain legume with wide adaptability, low input requirements, and the ability to improve soil fertility by fixing atmospheric nitrogen. Mungbean is well suited to a large number of cropping system and constitutes an important source of cereal based diets. Mungbean is used for different purpose. The major portion is utilized in making dal, curries, soup, sweets and snacks. The food values of mungbean lie in its high and easily digestible protein. Mungbean is grown throughout Asia, Australia, West Indies, South and North America, Tropical and subtropical Africa. However, India alone accounts for 65% of the world acreage and 54% of the world production. It is widely cultivated in India in different seasons; however, the maximum area is under kharif cultivation. Extremely plastic morphology, phenology and short maturity duration (60 days) makes the crop ideal as a catch crop, inter crop or relay cropping. It is grown as sole relay crop in rice fallows during rabi season in A.P., Tamilnadu, Karnataka and Orissa and sole catch crop during spring/summer season in Uttar Pradesh, Bihar, West Bengal, Jharkhand, Punjab, Haryana & Rajasthan (Table 1).

Chickpea, Cicer arietinum L, is the second most important pulse crop in the world. In India, it occupies prime position in terms of area, production and economic value and as an important constituent vegetarian diet. Chickpea is traditionally grown in many parts of the world covering Asia, Africa, Europe and North and South America. But the bulk of it is produced and consumed in South Asia and increasingly in Middle East as well as in some Mediterranean countries. Recently, chickpea cultivation started in Australia, Canada and USA mainly for export to south Asia. The cultivated species, Cicer arietinum L. (2n=16 and n=8), is characterized by possessing two distinct types-small and brown seeded known as desi type, and bold and white seeded known as kabuli type. The former is mostly cultivated in Indian sub-continent. Chickpea (Cicer arietinum L.) is also known by several common names viz., Bengal gram, Gram, Chhola, Hommes and Garbenzobean. Chickpea provides 2-3 times more protein than many cereals, constituting a major component of the agrarian diet of the Indian sub-continent. Chickpea grains provide about 18-24% protein, 4-10% fat, 52-70.9% carbohydrate, 10-23% fibre, minerals and vitamins. Among essential amino acids lysine, methionine, threonine, valine, isolucine and leucine are major components of seed protein. It also contains considerable amount of vitamins such as B1 and B2, ascorbic acid (vitamin C) and niacin also. Chickpea, therefore, plays an important role in human nutrition.

Lentil is one of the most nutritious cool season food legume and ranks next only to chickpea. It is grown throughout the northern and central India for grains, which are used as dal (wholeor dehulled) andin various otherculinarypreparations. Lentil contains about 25% protein, 0.7% fat, 2.1% mineral, 0.7% fibre and 59% carbohydrate. It is a rich source of phosphorus and carotene. It is generally grown as rainfed crop during rabi season after rice, maize, pearl millet orkharif fallow. It is also grown as intercrop with barley, linseed, mustard and autumn planted sugarcane. In North-eastern parts of the country, lentil is also cultivated as paira crop with rice in which seeds of lentil are broadcast in the standing crop of rice 7-10 days before its harvest. It is grown on a wide range of soils from light loamysand to heavy clay soil in northern parts and moderately deep black soils in central India.

Fieldpea is animportantrabi pulse crop which is highly productive and is grown for food, feed as a vegetable. There are two types of peas grown in India viz., vegetable type in which grains arevery sweet when green and become wrinkled ondrying, and grain type where grains are generally white and round. Green seeds of the grain type are not so sweet as in thecase ofvegetable type. The dry grains areconsumed in various forms such as chat, chhola, dal, vegetable and flour. Green seeds are used as fresh, frozen or canned vegetables. The cultivation of grain type is confined to northern and central parts of the country. It is high protein (20%) crop with all the essential aminoacids important for normal activity of living organisms. The fractional composition is also favourable the most easily assimilated water soluble protein from mature pea seeds varies from 36 to 87% and in green matter from 65 to 82%. Pea contains 4 mgpro-vitamin A, 300 mgvitamin C, 3 mgB1, 1.5 mgB2and 1.2 mgpantothenic acid per 1000 g fresh seed weight. Also, it contains 1.1% fat, 2.2% minerals, 4.5% fibre and 56.5% carbohydrate. It is rich in phosphorus. Green pea and the immature pods of pea are typified by a high level of active lipotropic antisclerotic substances-choline and inositol.Choline deficiency may lead to the development and growth of malignant tumors.

Grasspea (Lathyrus sativus L.), also called chickling pea, is an important crop of economic significance in India, Bangladesh, Pakistan, Nepal and Ethiopia. It is also cultivated in China, many countries of Europe, the Middle East and northern Africa. It is a food, feed and fodder crop belonging to the family Leguminacaae and the tribe vicieae (Smartt, 1990). Grasspea is very tolerant to drought conditions and has been grown successfully in areas with an average annual precipitation of 380 to 650 mm. Despite its tolerance to drought, grasspea is not affected by excessive rainfall and can be grown on land subject to flooding (Sinha, 1977). It has a very hardy and penetrating root system and, therefore, can be grown on a wide range of soil type, including very poor soil and heavy clays. This hardiness together with its ability to fix atmospheric nitrogen makes the crop ideally to grow under adverse conditions (Campbell et al. 1994). In India, Bangladesh, Nepal and Pakistan, it is often broadcast into a standing rice crop one to two weeks before the rice is ready for harvest where it flourishes on the residual soil moisture after the rice has been harvested. Despite all the advantages compared to other crops, relatively little efforts have been made to improve this very hardy pulse crop. The main reason has been the knowledge that excessive consumption of grasspea can lead to a neurological disorder, called Lathyrism in man and domestic animals (Jackson and Yunus, 1984). It appears when Lathyrys sativus forms the main component of the diet contributing to at least 30% of the caloric intake for a period of 3 to 4 months (Campbell et al. 1994).

Guar [Cyamopsis tetragonoloba (L.) Taub.], internationally known as guar, is extremely drought hardy, deep rooted, summer annual legume of great economic and adaptive significance. Virtues of guar effectively match with low and erratic rainfall pattern and high ambient temperature habitats of arid regions. The crop may thrive very well in rainfall range of 250-450 mm with 3-4 spells, temperature range of 25-40°C, RH values of 50-65%, longer days with 8-9 hr sunshine, particularly at maturity. Guar is ideally suited to light to medium textured soils, with no water logging conditions. The crop tolerates less inputs and restricted after care, matching with the arid farmers’ livelihood conditions. It is grown for grain, vegetable, fodder, cattle feed and green manure purposes, mainly in rainfed habitats of Rajasthan, Haryana, Gujarat and to some extent in Punjab and Madhya Pradesh. This crop has recently been introduced in non-traditional regions of Annantpur, Kadappa and Chittoor dry region of Andhra Pradesh. Only duringcurrent summer season of 2012, guar has been successfully cultivated with 4-5 irrigations in parts of Chattirgarh and Vidarbha and in non traditional summer seasons of Rajasthan. The cultivation in non-traditional regions and seasons have increased possibility of two crops in rainy and summer seasons. Even though, guar is cultivated on marginal lands, with marginal inputs in these regions, yet it has occupied the status of international, export oriented cash crop. The same has been due to presence of natural polysaccharide galactomannan gum content in seed endosperm. The gum content has wide industrial uses. Almost 80-85% guar gum produced in India is exported and rest is used for inland commercial demands. Of late, increasing demands of guar gum for USA alone to the tune of 5.0 lakh tonnes annually has led to sky rocketing prices resulting in economic benefit of Rs. 1.0 lakh to 1.5 lakh/ha in 90-100 days only. Hence, guar is rated as a source for providing livelihood security to arid farmers in practical reference. Relevant information on guar have been provided in this chapter.

Among the pulses, rajmash is one of the high potential pulse crops with a yielding potential of 18 to 20 q per ha. Rajmash or French bean (Phaseolus vulgaris L.) is a short duration non–traditional grain legume and one of the precious and highly relished pulse crops of North India. Rajmash is known by various names viz., French bean, rajma, haricot bean, field bean, kidney bean, snap bean, pole bean etc. It is an important winter vegetable grown both for tender pods and dry seeds, which form a rich source of crude protein (21.25%), fat (1.7%) and carbohydrates (70%). Besides, it contains 0.16 mg iron, 1.76 mg calcium and 3.43 mg zinc per 100 g of edible part (Jasvinder Kaur and Mehta, 1994). The fresh pods and green leaves are used as vegetable. The antimetabolites of dry beans needs removal by cooking and soaking in water.

The Arid Legume includes clusterbean (Cyamopsis tetragonoloba (L.) Taub.); moth bean (Vigna aconotifolia (Jacq) Marechal; cowpea (Vigna unguiculata (L.) Walp) and horse gram (Macrotylom uniflorum (L.) Verdc). In India, these are grown extensively as rainfed crops in Rajasthan, Orissa, Maharashtra, Karnataka, Gujarat, Haryana, M.P. and to a limited extent in other states covering a total area of 51-80 lakh hectares (Table1). Most of the production comes from harsh environments where both biotic and abiotic constraints prevail limiting the production. Arid Legumes as a group of pulses are extremely important in the common vegetarian diet of the people in the area of its cultivation. They also offer a new dimension as they have become foreign exchange earners through export opportunities. For example, clusterbean (guar) contains 30-35 per cent guar gum and India is a world leader in the export of this commodity and earns more than Rs.1100 crores annually (Mathur and Henry, 2009). Similarly, moth bean is gaining great industrial importance because of Bikaneri Bhujia industry which is heavily based on this crop (Singh and Henry, 1985). Cowpea is very important in Dahi bada industry and making curry preparation while horsegram is a minor pulse and is utilized by the poorest of the poor in its growing areas as well used for kidney stone treatment (Henry et.al., 2006; Vishwanatha et. al., 2006). Clusterbean and moth bean together account for 3.5 million hectare areas in the great Indian Thar Desert and play a very important role in the economy of the desert farmers. Similarly, cowpea and horse gram are grown mostly in marginal and sub-marginal lands under rainfed situations with no inputs applied by the farmers. These two pulses are grown in various areas in the country and easily adapted to various conditions.