1) undersampling
欠采样
1.
Uniform undersampling technique of bandpass signal and its engineering application in software digital IF receiver;
带通欠采样技术及在数字中频软件接收机中的工程应用
2.
Project of Convex Set Method for Reconstructing A Super-resolution Image from Multiframe Undersampling Images;
一种多幅欠采样图像的凸集投影超分辨率重建方法
3.
Application of bandpass undersampling principle in software radio;
带通欠采样定理在软件无线电中的应用
2) sub-sampling
欠采样
1.
Time-delay estimation for sub-sampling sinusoidal signals;
欠采样条件下的正弦信号时差估计
2.
In order to break through the limitation of Electronic analog-to-digital converter in speed and time-delay precision,a wideband digital frequency measurement method based on optical sub-sampling is proposed.
为了突破高速电模数转换器采样速率和时延控制精度对测频带宽的限制,文中提出了一种采用光脉冲欠采样的超宽带、高分辨率数字测频方法。
3.
In the algorithm for estimation of frequency of ultra-wideband LFM signal based on multi-channel and sub-sampling,even tiny error of the remainder can lead to huge error of the frequency.
针对基于多速率欠采样的超宽带LFM信号瞬时频率估计方法中,余数的很小测量误差将导致很大的测频误差问题,提出一种基于欠采样的超宽带LFM信号参数估计算法。
3) sub-Nyquist sampling
欠采样
1.
Using Different Frequencies Method to Solve Bandpass sub-nyquist sampling;
欠采样信号多采样频率处理方法
2.
In view of the present sub-Nyquist sampling frequency estimation method,in order to overcome the existing problems such as complex arithmetic and difficult to engineer realizing,the paper puts forward a three-sample rates switching frequency estimation method based in virtual instruments.
为了克服现有的欠采样频率估计方法存在的算法复杂、工程实现困难等问题,本文提出了一种基于虚拟仪器的三采样率切换的频率估计方法。
3.
Based on an auxiliary time-delay channel and ESPRIT approach,a new algorithm for wide band frequency estimation with sub-Nyquist sampling was proposed.
基于时延和旋转不变子空间技术 (ESPRIT) ,本文提出了一种新的欠采样宽频带信号频率的高分辨估计方法 。
4) under-sampling
欠采样
1.
According to the characteristics of the wayside frequency-shift signal spectrum,and based on a great number of computer emulators and real-time experiments and on non-complete periods sampling,the feasibility of applying the under-sampling technology to the real-time FFT analytical method of tramroad FSK signal is validated.
针对轨道移频信号的频谱特点,采用欠采样技术对轨道移频信号进行非整周期的采样,经过计算机仿真实验,验证了基于非整周期采样方法对轨道移频信号进行实时傅里叶变换(FFT)分析检测的可行性,证明采样方法满足检测指标的要求。
2.
Based on the theoretic modeling and analysis of the IF GPS signals,an accurate software simulator of IF GPS signals is implemented in Matlab/Simulink,the effects of noise,under-sampling and receiver clock error are also simulated.
在对中频GPS信号理论建模与分析的基础上,采用Matlab/Simulink构建了一种精确的数字中频GPS信号软件模拟器,考虑了噪声、欠采样以及接收机时钟误差等的影响。
3.
The theoretical analysis has proved that in the condition of under-sampling, because the paired echoes will be appeared, the system’s multi-object resolution will be affected.
理论分析证明:在欠采样情况下,脉冲压缩后会出现成对回波,因而系统的多目标分辨能力受到影响;由于信号带宽的损失,脉压输出回波信号的主瓣展宽,距离分辨力下降;另外,主瓣幅度或相位还会受到调制。
5) subsampling
欠采样
1.
An algorithm for estimation of wideband LFM signal parameters based on subsampling;
基于欠采样的宽带线性调频信号参数估计
2.
A receiver architecture is presented that utilizes the subsampling concept to down-convert the IF signal to a lower IF before been digitized.
提出了一个欠采样中频收发器的体系结构,它在中频数字化以前先通过欠采样将中频频率变到一个较低的频率。
3.
Firstly,the paper briefly presented the imaging system’s aliasing effect as a result of subsampling and the theory of reducing aliasing effect by increasing sampling frequency.
文章简要地阐述了成像系统由于欠采样所带来的混叠效应,以及微扫描成像技术提高采样频率以减小混叠效应的原理,分析了微扫描工作模式和成像过程,然后介绍了几种典型光学微扫描器的实现方式。
6) aliasing noise
欠采样噪声
1.
The small scale artifacts generated by aliasing noise existing everywhere in an image,bring difficulties to some applications,such as target identification.
欠采样噪声产生分布于整个画面的小尺寸附加像 ,给目标识别等应用带来困难 。
2.
Minifying digital images used downsampling introduces aliasing noise.
在降采样过程中不可避免地会引入欠采样噪声。
3.
Assuming several sets of system design parameters we analyze aliasing noise that exists in sampled-imaging system widely, blurring effects of optical imaging system and the tradeoff between them by the way of computer simulation.
模拟系统设计参数,计算机仿真分析了采样成像系统中普遍存在的欠采样噪声、光学成像系统的模糊效应以及二者之间的涨落、平衡,做出了基于互信息量的系统评价仿真曲线,提出了光学成像系统与图像捕捉系统的匹配条件和优化设计方法。
补充资料:被动式大气采样器
分子式:
CAS号:
性质:无需动力,通过气体扩散采集气体污染物的一种采样装置。该采样品是根据气体扩散原理和选择吸收的特点设计而成的。其结构由三部分构成(见图示)。A:上盖。上面放置浸渍采样膜。B:圆环。为气体扩散通道;C:带孔下盖。放不锈钢网和聚四氟乙烯微孔滤膜。整个采样器可放入筒状套匣,作为贮备容器。适用于各种场所的空气监测之用;尤其在无动力供给的边远、山岭地区更为适用。采样周期可长达1~2个月。所得污染物为在采样时间区段内空气中的平均浓度。
CAS号:
性质:无需动力,通过气体扩散采集气体污染物的一种采样装置。该采样品是根据气体扩散原理和选择吸收的特点设计而成的。其结构由三部分构成(见图示)。A:上盖。上面放置浸渍采样膜。B:圆环。为气体扩散通道;C:带孔下盖。放不锈钢网和聚四氟乙烯微孔滤膜。整个采样器可放入筒状套匣,作为贮备容器。适用于各种场所的空气监测之用;尤其在无动力供给的边远、山岭地区更为适用。采样周期可长达1~2个月。所得污染物为在采样时间区段内空气中的平均浓度。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条