红外技术
紅外技術
홍외기술
INFRARED TECHNOLOGY
2014年
7期
521-526
,共6页
苏德伦%廖守亿%张金生%王仕成
囌德倫%廖守億%張金生%王仕成
소덕륜%료수억%장금생%왕사성
电阻阵列%红外景象投射器%红外成像%半实物仿真
電阻陣列%紅外景象投射器%紅外成像%半實物倣真
전조진렬%홍외경상투사기%홍외성상%반실물방진
resistor array%IR scene projector%infrared image%hardware-in-the-loop simulation
电阻阵列是一种出射式红外场景投射器,为了改善投射图像质量,提高半实物仿真可信度,需要对电阻阵列的非均匀性进行实时校正。对电阻阵列结构和原理的分析表明非均匀性表现为一种固定模式的空间噪声。对辐射像元响应特性的研究发现电阻阵列的输入输出呈现非线性特性,非均匀性的本质是辐射像元间响应特性的差异。基于先验信息对辐射像元驱动数据进行补偿,对电阻阵列的非均匀性进行校正。对辐射像元的非线性进行预处理,降低校正对先验测试数据的要求。采用分段线性插值实现在线校正算法,提高校正算法的实时性。数值仿真结果表明:该方法可将电阻阵列的非均匀性降低到1%以下,在128×128和256×256像元规模下均可保证200 Hz的处理速度。基本满足红外成像半实物仿真对图像质量和帧频的要求。
電阻陣列是一種齣射式紅外場景投射器,為瞭改善投射圖像質量,提高半實物倣真可信度,需要對電阻陣列的非均勻性進行實時校正。對電阻陣列結構和原理的分析錶明非均勻性錶現為一種固定模式的空間譟聲。對輻射像元響應特性的研究髮現電阻陣列的輸入輸齣呈現非線性特性,非均勻性的本質是輻射像元間響應特性的差異。基于先驗信息對輻射像元驅動數據進行補償,對電阻陣列的非均勻性進行校正。對輻射像元的非線性進行預處理,降低校正對先驗測試數據的要求。採用分段線性插值實現在線校正算法,提高校正算法的實時性。數值倣真結果錶明:該方法可將電阻陣列的非均勻性降低到1%以下,在128×128和256×256像元規模下均可保證200 Hz的處理速度。基本滿足紅外成像半實物倣真對圖像質量和幀頻的要求。
전조진렬시일충출사식홍외장경투사기,위료개선투사도상질량,제고반실물방진가신도,수요대전조진렬적비균균성진행실시교정。대전조진렬결구화원리적분석표명비균균성표현위일충고정모식적공간조성。대복사상원향응특성적연구발현전조진렬적수입수출정현비선성특성,비균균성적본질시복사상원간향응특성적차이。기우선험신식대복사상원구동수거진행보상,대전조진렬적비균균성진행교정。대복사상원적비선성진행예처리,강저교정대선험측시수거적요구。채용분단선성삽치실현재선교정산법,제고교정산법적실시성。수치방진결과표명:해방법가장전조진렬적비균균성강저도1%이하,재128×128화256×256상원규모하균가보증200 Hz적처리속도。기본만족홍외성상반실물방진대도상질량화정빈적요구。
Resistor array is a kind of emissive IR scene projector. In order to improve the quality of projected image and enhance the credibility of simulation, the non-uniformity of the resistor array need to be corrected. The structure and mechanism analysis of resistor array indicates that the non-uniformity represents a fix pattern spatial noise. Research of radiant pixels response presents a nonlinear characteristic of resistor array. The essence of non-uniformity is the difference between radiant pixels’ response. The non-uniformity was corrected by adjusting the inputs of each radiant pixel according to test data acquired previously. The nonlinearity was preprocessed to decrease the demand of test data for non-uniformity correction. Piecewise linear interpolation was applied to realize on-line non-uniformity correction algorithm and improve the real-time quality of the algorithm. Numeric simulation results indicate that the algorithm can reduce the non-uniformity to 1% below and satisfy the frame rate up to 200Hz in 128×128 and 256×256 pixels format. The non-uniformity correction method presented can meet the demand of infrared image hardware-in-the-loop simulation for image quality and frame rate.
