Scale factor considerations for SDF technique

Proceedings of the 2nd Pan African International Conference on Science, Computing and Telecommunications (PACT 2014) Pub Date : 2014-07-14 DOI:10.1109/SCAT.2014.7055121

Thanh T. Nguyen, J. Devlin, D. Elton, E. Custovic, B. Bienvenu

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引用次数: 2

Abstract

The Tasman International Geospace Environment Radars (TIGER) form part of an international network of similar HF radars called Super Dual Auroral Radar Network (SuperDARN) which explore the impact of solar disturbances on Earth. These radars utilise an Auto Correlation Function (ACF) to measure the changing phase of the ACF between lag times to determine the Doppler frequency and the target velocity.With the development of TIGER-3, an all digital radar platform, a novel method of determining target velocities has been proposed. In the proposed methoThe Tasman International Geospace Environment Radars (TIGER) form part of an international network of similar HF radars called Super Dual Auroral Radar Network (SuperDARN) which explore the impact of solar disturbances on Earth. These radars utilise an Auto Correlation Function (ACF) to measure the changing phase of the ACF between lag times to determine the Doppler frequency and the target velocity.With the development of TIGER-3, an all digital radar platform, a novel method of determining target velocities has been proposed. In the proposed method, a comparison of the transmit and receive signal magnitude spectrums is performed to determine the Spectrum Difference Function (SDF). The gradient of SDF in the vicinity of the carrier frequency is calculated, from this value the Doppler Frequency Shift fd can be deduced. The result is then multiplied by a precalculated Scale Factor which is necessary to compensate for the systematic error due to the method. This paper will address all the factors which have influence on the value of Scale Factor, therefore minimize the error associated with the process of calculating Scale Factor.d, a comparison of the transmit and receive signal magnitude spectrums is performed to determine the Spectrum Difference Function (SDF). The gradient of SDF in the vicinity of the carrier frequency is calculated, from this value the Doppler Frequency Shift fd can be deduced. The result is then multiplied by a precalculated Scale Factor which is necessary to compensate for the systematic error due to the method. This paper will address all the factors which have influence on the value of Scale Factor, therefore minimize the error associated with the process of calculating Scale Factor.

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SDF技术的尺度因子考虑

塔斯曼国际地球空间环境雷达(TIGER)是一个名为超级双极光雷达网(superdam)的类似高频雷达国际网络的一部分，该网络探索太阳扰动对地球的影响。这些雷达利用自相关函数(ACF)来测量ACF在滞后时间之间的相位变化，以确定多普勒频率和目标速度。随着全数字雷达平台TIGER-3的发展，提出了一种确定目标速度的新方法。在提出的方法中，塔斯曼国际地球空间环境雷达(TIGER)是一个类似的高频雷达国际网络的一部分，该网络被称为超级双极光雷达网络(superdam)，用于探索太阳扰动对地球的影响。这些雷达利用自相关函数(ACF)来测量ACF在滞后时间之间的相位变化，以确定多普勒频率和目标速度。随着全数字雷达平台TIGER-3的发展，提出了一种确定目标速度的新方法。在该方法中，通过比较发射和接收信号的幅值频谱来确定频谱差函数(SDF)。计算载波频率附近SDF的梯度，由此可以推导出多普勒频移fd。然后将结果乘以预先计算的比例因子，该比例因子是补偿该方法引起的系统误差所必需的。本文将解决所有影响尺度因子值的因素，从而最大限度地减少与计算尺度因子过程中的误差。d，对发射和接收信号的幅度频谱进行比较，以确定频谱差函数(SDF)。计算载波频率附近SDF的梯度，由此可以推导出多普勒频移fd。然后将结果乘以预先计算的比例因子，该比例因子是补偿该方法引起的系统误差所必需的。本文将解决所有影响尺度因子值的因素，从而最大限度地减少与计算尺度因子过程中的误差。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 2nd Pan African International Conference on Science, Computing and Telecommunications (PACT 2014)

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