Preface Horticulture plays an important part in today’s agriculture and there are new avenues that are being achieved by horticulture. The subject has transformed from only being about vegetables, fruits, flowers and postharvest technology and has moved towards disease, breeding, pathology, physiology, greenhouse technologies and other areas which were never heard for. The book series: Hi-Tech Horticulture has been worked out keeping the above mentioned issues in mind with contribution by eminent professors and scientists. The volumes are on: 1. Crop Improvement Nursery and Rootstock Management 2. Organic Farming and Sustainable Development Techniques 3. Improved Production Techniques 4. Plant Protection and Stress Management 5. Value Addition and Post-Harvest Techniques 6. Advance Techniques

Precision farming is one of the most scientific and modern approach to sustainable agriculture. It involves management of within field variation and helps farmers to grow crops more efficiently. Precision farming is concerned with the management of variability in the dimensions of both space and time. Variability of resources is a key factor of precision farming.   Precision farming is the application of technologies and principle to manage spatial and temporal variability associated with all aspects of horticultural production for improving crop performance and environment quality. Precision farming calls for an efficient management of resources through location specific hi-tech inventions to produce cost-effective and eco-friendly consumer- acceptable quality products (Mondal and Tewari, 2007).

Precision Farming Precision farming is a concept of proper crop management based on the observation, technology, measurement and response during inter and intra field variability in crops. It is also known as satellite farming or site specific crop management (SSCM).It is an application of right things, in right place, in the right way and at the right time. It has three main requirements viz. first identify various field location, second capture, interpret and analyzed the data in a proper scale & frequency and third, adjust the input with farming practices for efficient economic yields. There are 17 Precision Farming Development Centers (PFDC) located in different agro-climatic zones of India. It is mostly exist in SAUS, ICAR Institute and IIT Kharagpur. 

Introduction Tuberose (Polianthes tuberosa) occupies an important position among commercial ornamental bulbous crops, because of its highly fragrant flowers which can be used in various ways and is essentially a florists flower. The white tubular flowers emit the most popular odour and hence are cultivated on a large scale in some parts of the world for the extraction of its highly valued natural flower oil. The lingering delightful fragrance and excellent keeping quality are the predominant characteristics of this crop. It is popularly known as Rajanigandha, derives its generic name from the greek word Polios, which means white or shinning and anthos meaning a semi perennial bulbous plant. It is commercially cultivated for cut flowers and loose flowers trade and also for extraction of its highly valued natural flower oil. The serene beauty of the flower spikes, bright white flowers, sweetness of blooms and delicacy of fragrance of this ornamental crop, transform the entire area into a nectarine and joyous one. Fresh flowers and value added products of tuberose are exported from India to USA, Germany, United Kingdom, Italy, The Netherland, Japan, United Arab Emirates and Saudi Arabia.

Introduction In India, Fruits and vegetables comprises nearly 90% of the total horticulture production. India is now the second largest producer of fruits and vegetables in the world and leader in several horticultural crops, namely mango, banana, papaya, cashewnut, arecanut, potato, and okra (National Horticulture Board, 2015). The total area occupied by horticultural crops in India was 23.69  million ha and total production was 283 million tonnes in 2015-16 (Source: Ministry of Agriculture and Farmers’ Welfare). Different horticultural crops like fruits, vegetables, spices, medicinal plants and plantation crops comprises a large chunk of the total crop sales value of the country and also secures nutritional security of the persons of the country. For systematic and efficient management of existing crops and to bring more area of the country under the cultivation of horticultural crops to increase overall horticultural production in term of time and area, a database must be created for decision making and planning. 

Abstract Fruit, Vegetable, Flowers, Medicinal and Aromatic crops are as horticultural crops play significant role in improving the productivity of land, generating employment, enhancing exports, improving economic conditions of the farmers and entrepreneurs and providing food and nutritional security to the people. For better management of the existing crops and to bring more area under horticulture crops, updated and accurate database is necessary for systematic planning and decision making. Remote sensing (RS) is an advanced tool that aids in gathering and updating information to develop scientific management plans. Many types of sensors namely microwave radiometers, laser meters, magnetic sensors and cameras collect electromagnetic information to derive accurate, large-scale information about the Earth’s surface and atmosphere. Because these data and images are digital, they can easily be quantified and manipulated using computers. RS can be used in efforts to reduce the risk and minimize damage. The same data can be analyzed in different ways for different applications. A number of studies were aiming at identification of crop, area estimation, disease and pest identification, etc. using satellite data in horticulture. The potential use of RS techniques in Horticulture is briefly reviewed in order to exploit the available techniques for efficient crop management.

Introduction There has been a slow evolution of information technologies in fruit crop production as innovators combined their prior field experience with an attitude of learning by doing while looking for practical applications for farm management. As a suite of technologies became available for use in agriculture production, a new management strategy that combined information with decision making became known as Precision farming. Precision farming is the emerging technology which involves maintaining of crop inputs on site specific basis with reducing waste, increasing the profits and maintaining the quality of environment. The main tools involved in this are Geographical Information System (GIS), Variable Rate Technology (VRT), Global Positioning System (GPS), Yield Monitoring and Remote Sensing.

Abstract Horticulture crops play significant role in improving the productivity of land, generating employment, enhancing exports, improving economic conditions of the farmers and entrepreneurs and providing food and nutritional security to the people. For better management of the existing crops and to bring more area under horticulture crops, updated and accurate database is necessary for systematic planning and decision making. Remote sensing (RS) is an advanced tool that aids in gathering and updating information to develop scientific management plans. Many types of sensors namely microwave radiometers, laser meters, magnetic sensors and cameras collect electromagnetic information to derive accurate, large-scale information about the Earth’s surface and atmosphere. Because these data and images are digital, they can easily be quantified and manipulated using computers. RS can be used in efforts to reduce the risk and minimize damage. The same data can be analyzed in different ways for different applications. A number of studies were aiming at identification of crop, area estimation, disease and pest identification, etc. using satellite data in horticulture. The potential use of RS techniques in Horticulture is briefly reviewed in orde

Abstract The term “Horticulture” is a part of agriculture system which is concerned with the raising of so called garden crops. At present, fruits, vegetables, flowers etc., are grown not only within the backyards, but also in large areas in open fields on a commercial scale where better visualization can be viewed with GIS. It emerged by calculating the present context which allows us to produce a complex view about the land’s characteristics. Most of the GIS in use today have not been designed to support multimedia data and therefore have very limited capability due to the large data volumes, very rich semantics and very different modelling and processing requirements. Use of Remote Sensing (RS) and GIS in natural resource and environmental monitoring has been advocated strongly in present years. The present review gives an idea about the basic concepts of GIS, its components and applications in the agricultural sector particularly horticulture. GIS has been extensively and successfully exploited in various areas using various software’s which are available in current market.

Introduction Sensors are the key components for enabling any IoT(Internet of Things) application. The concept of IoT came as early as 1990 but the practical implementations of the IoT technology is actually becoming possible as the cost of the devices that are needed to create any IoT application have reduced. Sensors are one of the major hardware components needed to form IoT systems and decrease in its price has given a forward leap in developing IoT applications. Sensors have to be uniquely identifiable devices with a unique device ip address so that they can be easily identifiable over a large network. These have to be active in nature which means that they should be able to collect real time data. These can either work on their own (autonomous in nature) or can be made to work by the user depending on their needs (user controlled).

Abstract The development of nano technology creates an excellent opportunity to address complex technical  issues of food supply chain. Failure to embrace nano technology will deny the horticultural sector an opportunity to capitalize on improved product visibility, food safety, quality and security and associated economic benefits. Agricultural and food supply chain management is complex due to the diverse characteristics of agricultural products. There are numerous types of horticultural crops and products, many of which are perishable. In addition, the degree of standardization of some kinds of fruit products and their management is still low. In this regard, the potential application of nano technology to the horticulture is reviewed. Investigation confirms that incremental applicationof nano technology in the horticulture,

Abstract The term nano technology, buzzword of present day science owes its origin from the Greek word ‘nano’ literally meaning dwarf. It is expressed in terms of dimension one nanometer equals to one billionth of a meter (1nm=10-9m), work on the principle of particle movement, smallest particle accelerate fast in the system. The nano technology deals with manufacturing, study and manipulation of matter at nano-scale (or atomic scale) in the size range of  1-100 nm, called as nanoparticles (Rajan, 2004). Nano technology is one of the most fascinating and rapidly possessing potential to revolutionize in science and technology of medicine and agriculture. In plant pathology, nano technology has potential scope to detection, diagnosis and management of plant diseases. Micromechanical cantilever arrays for selective immobilization and fast quantitative detection of vital fungal spores (Nugaeva et al., 2005). Micro-fabricated chambers designed to mimic some of the features of xylem vessels and discovered that Xylella fastidiosa migrates via type IV pilus-mediated twitching motility (Meg et al., 2005). Antifungal properties of chitosan, chitosan-saponin and Cu-chitosan nanoparticle reveal against phytopatogenic fungi namely Alternaria alternate, Macrophomina phaseolina and Rhizoctonia solani (Sharan et al. 2013). 

Introduction In the present, India is food secure due to our self-sufficiency in foodgrains, but still,we have to achieve the goal of nutritional security. The horticulture sector is the one which alsoescapes the weather shocks and has the potential to help in poverty alleviation, nutritional security. Again, it has ample scope for farmers to increase their income and helpful in sustaining a large number of agro-based industries which generate a large number of employment opportunities besides helping to achieve the national goal of 4.0 per cent agricultural growth. India with more than 28.2 million tonnes of fruits and 66 million tonnes of vegetables, is the second largest producer of fruits and vegetables in the world, next only to Brazil and China.Onshares, the world fruit production is 11% and vegetables 7%.

Introduction Hi Tech horticulture is synonymous to cultivation of commercial horticultural crops using advanced scientific technology to make more profit. India is acclaimed globally for production of high value horticultural crops but there productivity is less as compared to many countries. One of the main reasons for low productivity is poor water and nutrient management. The Task Force on Agricultural Development constituted by the National Institution for Transforming India (NITI) Aayog, Government of India in March 2015 has suggested to increase productivity, progress is required along three dimensions: (i) Quality and judicious use of inputs such as water, seeds, fertilizer and pesticides; (ii) judicious and safe exploitation of modern technology; and (iii) shift into high value commodities such as fruits, vegetables, flowers, etc. (Anonymous, 2015).  Hi tech horticulture meeting the entire requirement as suggested by the task force.

Water is the most critical component of life system. Irrigation plays vital role in rising and stabilizing yield and maintaining quality of fruit crops grown in tropical or sub-tropical climate. Micro irrigation is one of the modern and advanced methods of irrigation which is becoming popular in areas having problems like water scarcity and poor quality of water. Since the competition for water between agricultural and non-agricultural sector is increasing day by day, the efficient management of water resources is very essential to meet the water requirement. It is anticipated to reduce water use for agriculture by 70% in the coming decade, where the present day share is 80%. Demand for water is increasing in non-agricultural sectors like industry, energy, domestic use etc. Hence, policy makers and researchers consider water as the main obstacle for growing enough food crops in the coming years. In India where population is increasing at alarming rate, the area under irrigation should go up from 60 million hectares to 114 million hectares by the year 2050. In this context, micro irrigation plays a major role under limiter water agro ecosystem.

Water is most essential thing to sustain life for plants, human and animals. In fact, land and water are the two important natural resources, which play an important role in horticulture production. Irrigation is the lifeline for any crop production. As Pomegranate is mostly grown under water scarce regions of India, so utilization of available water more effective and efficient irrigation system is need along micro-irrigation system offers the way of using water in a most judicious fashion for irrigation purpose. It is based on the elementary concept on irrigating root zone rather than entire land surface which results in higher water use efficiency and improved crop yield. This technique is now being used to mitigate water scare situation in the pomegranate growing regions of the country in enormous way.

Introduction In the environment of dwindling water resources and contention of the other sectors, the share of water allocated to irrigation is likely to be decreased by 10 to 15 per cent in the next two decades. One of the ways of improving water scarcity is by enhancing its use efficiency or productivity. Water use efficiency (WUE) is a broad concept that can be defined in many ways. For farmers or farm irrigators, WUE is the yield of harvested crop produce achieved from the available water to the crop from irrigation, rainfall and soil water storage. Improving WUE in pomegranate will be required an increasing in pomegranate water productivity (i.e. an increasing marketable yield per unit of water used by plants and reduction in water losses from the root zone (Chopde and Gorantiwar, 1998; Chopde et al., 2001; Intrigoli et al., 2011). For comprehensive improvement of WUE, it is necessary to raise the following ratios to their maximum: stored soil water content/water received through rainfall and irrigation, transpiration/water consumption, biomass yield/transpiration, water consumption/soil water storage and economic benefit/biomass yield (Frederick, 1993).