Adgaba Nuru, Alghamdi Ahmed, Sammoud Rachid, Shenkute Awraris, Tadesse Yilma, Ansari Mahammad J, Sharma Deepak, Hepburn Colleen
Engineer Bagshan Chair for Bee Research, Department of Plant Protection, College of Food and Agricultural Science, King Saud University, P O Box: 1460, Riyadh 11451, Saudi Arabia.
College of Computer and Information Sciences, King Saud University, Saudi Arabia.
Saudi J Biol Sci. 2017 Jul;24(5):1038-1044. doi: 10.1016/j.sjbs.2017.01.009. Epub 2017 Jan 24.
In arid zones, the shortage of bee forage is critical and usually compels beekeepers to move their colonies in search of better forages. Identifying and mapping the spatiotemporal distribution of the bee forages over given area is important for better management of bee colonies. In this study honey bee plants in the target areas were inventoried following, ground inventory work supported with GIS applications. The study was conducted on 85 large plots of 50 × 50 m each. At each plot, data on species name, height, base diameter, crown height, crown diameter has been taken for each plant with their respective geographical positions. The data were stored, and processed using Trimble GPS supported with ArcGIS10 software program. The data were used to estimate the relative frequency, density, abundance and species diversity, species important value index and apicultural value of the species. In addition, Remotely Sensed Satellite Image of the area was obtained and processed using Hopfield Artificial Neural Network techniques. During the study, 182 species from 49 plant families were identified as bee forages of the target area. From the total number of species; shrubs, herbs and trees were accounting for 61%, 27.67%, and 11.53% respectively. Of which , , , , , and were the major nectar source plants of the area in their degree of importance. The average vegetation cover values of the study areas were low (<30%) with low Shannon's species diversity indices (H') of 0.5-1.52 for different sites. Based on the eco-climatological factors and the variations in their flowering period, these major bee forage species were found to form eight distinct spatiotemporal categories which allow beekeepers to migrate their colonies to exploit the resources at different seasons and place. The Remote Sensed Satellite Image analysis confirmed the spatial distribution of the bee forage resources as determined by the ground inventory work. An integrated approach, combining the ground inventory work with GIS and satellite image processing techniques could be an important tool for characterizing and mapping the available bee forage resources leading to their efficient and sustainable utilization.
在干旱地区,蜜蜂饲料短缺问题严重,这通常迫使养蜂人迁移蜂群以寻找更好的饲料。识别并绘制给定区域内蜜蜂饲料的时空分布,对于更好地管理蜂群至关重要。在本研究中,在地理信息系统(GIS)应用的支持下,通过实地清查工作,对目标区域内的蜜蜂植物进行了编目。该研究在85个50×50米的大样地中进行。在每个样地,记录了每种植物的物种名称、高度、基部直径、树冠高度、树冠直径以及它们各自的地理位置。这些数据使用天宝(Trimble)全球定位系统(GPS)并借助ArcGIS10软件程序进行存储和处理。这些数据用于估计物种的相对频率、密度、丰度、物种多样性、物种重要值指数和养蜂价值。此外,获取了该区域的遥感卫星图像,并使用霍普菲尔德(Hopfield)人工神经网络技术进行处理。在研究过程中,确定了来自49个植物科的182种植物为目标区域的蜜蜂饲料。在这些物种总数中,灌木、草本植物和树木分别占61%、27.67%和11.53%。其中,[此处原文缺失具体植物名称]是该区域按重要程度排序的主要蜜源植物。研究区域的平均植被覆盖值较低(<30%),不同地点的香农物种多样性指数(H')在0.5 - 1.52之间也较低。基于生态气候因素及其花期变化,发现这些主要的蜜蜂饲料物种形成了八个不同的时空类别,这使得养蜂人能够迁移蜂群,以便在不同季节和地点利用资源。遥感卫星图像分析证实了实地清查工作所确定的蜜蜂饲料资源的空间分布。将实地清查工作与GIS和卫星图像处理技术相结合的综合方法,可能是表征和绘制可用蜜蜂饲料资源从而实现其高效和可持续利用的重要工具。
