基于浮标平台的反舰导弹过靶实况观测系统研究

根据弹靶遭遇实况观测领域存在的问题,提出了一种基于便携式小型浮标平台的过靶实况观测系统,设计了系统总体方案,阐述了系统工作模式,分析了系统观测能力,并对其关键技术进行了论证研究。     

带移动负载海上浮筒系统运动响应特性初步研究

将某类海上自动作业系统简化为带移动负载的浮筒系统,其中负载简化为外径为180mm、约50kg重的柱型体,浮筒为外径533mm的圆筒;初步设计了浮筒系统的主参数。在此基础上,采用频域数值模拟计算,获得了浮筒自由状态下的固有周期和运动响应传递函数(RAO);再采用时域模拟方法,预报了3级海况下(JONSWAP谱)浮筒系统整体的运动响应特性,给出了运动响应幅值、最小干舷高度等特性参数,可为相关装备设计提供技术参考和借鉴。     

An Integer Precise Point Positioning technique for sea surface observations using a GPS buoy

GPS data dedicated to sea surface observation are usually processed using differential techniques. Unfortunately, the precision of resulting kinematic positions is baseline-length dependent. So, high precision sea surface observations using differential GPS techniques are limited to coasts, lakes, and rivers. Recent improvements in GPS satellite products (orbits, clocks, and phase biases) make phase ambiguity fixing at the zero difference level achievable and opens up the observation of the sea surface without geographical constraints. This paper recalls the concept of the Integer Precise Point Positioning technique and discusses the precision of GPS buoy positioning. A sequential version of the GINS software has been implemented to achieve single epoch GPS positioning. We used 1 Hz data from a two week GPS campaign conducted in the Kerguelen Islands. A GPS buoy has been moored close to a radar gauge and 90 m away from a permanent GPS station. This infrastructure offers the opportunity to compare both kinematic Integer Precise Point Positioning and classical differential GPS positioning techniques to in situ radar gauge data. We found that Precise Point Positioning results are not significantly biased with respect to radar gauge data and that horizontal time series are consistent with differential processing at the sub-centimetre precision level. Nevertheless, standard deviations of height time series with respect to radar gauge data are typically [4–5] cm. The dominant driver for noise at this level is attributed to errors in tropospheric estimates which propagate into position solutions.     

Argos海洋浮标多普勒定位原理与方法

通过对海洋浮标进行定位,Argos系统在海洋科学方面得到较为广泛的应用。但Argos系统卫星过顶弧段甚短,加之信号发射周期较长,测量资料甚为稀疏,给海洋浮标的定位造成很不利的影响,容易出现矩阵奇异情况,造成定位失败。文章给出了有效的基于多普勒测量的用于数据收集发射平台的定位算法,并利用参考椭球面约束定位目标,从而改进定位算法,计算结果显示如果能有效的使用约束条件,可以使：①原先定位失败的情形成功解算;②原先定位成功的情形定位精度得到改进。文章还给出了针对海洋目标信标运动以及卫星星历误差等因素对定位结果造成的误差影响的统计分析。