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引用次数: 16
摘要
介绍了两种自动步进频率数据采集和快速计算天线参数的方法。这些参数包括天线因子、固有增益、实现增益、天线输入阻抗、电压驻波比和站点衰减。文中着重讨论了天线阻抗对天线测量的意义和精度的影响。目前,美国国家标准与技术研究所(National Institute of Standards and Technology)使用一种标准的开路半波接收偶极子来测量电场强度,用于校准频率为25至1000 MHz的天线系数。该方法与使用120 dB动态范围的精确自动网络分析仪测量发射天线和接收天线之间插入损耗的三天线方法进行了比较。使用具有30*60米地面屏幕的现场场地,作为良好的反射器。因此,计算和补偿了地面反射的影响。新的插入损耗技术允许更快的测量,具有更高的重复性和降低校准不确定性,特别是在频率高于75 MHz的情况下
Calibration of antenna factor at a ground screen field site using an automatic network analyzer
Two approaches are described that permit automatic stepped-frequency data acquisition and rapid calculation of several antenna parameters. These parameters include antenna factor, intrinsic gain, realized gain, antenna input impedance, voltage standing wave ratio and site attenuation. The effects of antenna impedance on the meaning and accuracy of antenna measurements are emphasized throughout. The technique now used at the National Institute of Standards and Technology for calibrating the antenna factor at frequencies from 25 to 1000 MHz uses a standard open-circuit half-wave receiving dipole to measure the electric field strength. This approach is compared with a three-antenna method that uses an accurate automatic network analyzer with 120 dB dynamic range to measure insertion loss between the transmitting and receiving antennas. A field site having a 30*60 m ground screen, which acts as a good reflector, is used. Thus, the effects of ground reflection are calculated and compensated for. The new insertion loss technique permits faster measurements with greater repeatability and reduction in calibration uncertainty, especially at frequencies above 75 MHz.<>
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