1) differential phase shift
差分相位编码
1.
An auto-compensating and efficient differential phase shift quantum key distribution system;
自动补偿高效的差分相位编码QKD系统
2.
A highly stable differential phase shift key distribution QKD system;
高稳定的差分相位编码量子密钥分发系统
2) 2DPSK
差分编码移相键
1.
The simulation design of the overall structure and the sub-modules of a 2DPSK communication system are finished according to the principle of binary difference code phase-shift keying(2DPSK) by using MATLAB.
以旋转导向钻井工具的井下短程通讯为研究背景,根据二进制差分编码移相键控(2DPSK)工作原理,利用MATLAB软件实现了2DPSK通讯系统的总体结构及其子模块的仿真设计。
3) differential phase shift keying(DPSK)
差分移相编码
4) differential relational coding
差分相关编码
5) phase encoding
相位编码
1.
A new method for prestack depth migration of areal shot records with phase encoding;
一种新的相位编码面炮记录叠前深度偏移方法
2.
A new OCDM technology of QPSK coherent phase encoding in time domain;
QPSK时域相干相位编码的OCDM新技术
3.
In this paper, an encoding method is proposed for improving the resolution of rotary encoder-phase encoding method.
本论文对输出信号为正弦信号的增量式编码器提出一种细分方法—相位编码细分方法,从原理上进行了深入的分析,井设计了硬件电路。
6) phase coding
相位编码
1.
In order to further improve the precision and efficiency of prestack depth algorithm, the paper introduced a relief surface-based prestack depth migration algorithm of synthetic shot records, in which the basic idea is to use phase coding method to produce synthetic shot records, realizing prestack depth migration of mu.
为了进一步提高叠前深度算法的精度和效率,本文介绍一种基于起伏地表的合成炮叠前深度偏移方法,其基本思路是采用相位编码方法产生合成炮,实现多炮叠前深度偏移,提高了计算效率;用波动方程波场延拓取代浅地表的高程静校正,提高了偏移成像精度。
2.
Phase coding patterns of MPSK (multiple phase shift keying) are recogniged based on the phase mutation values which are determined by computing the error energy of adjacent code elements in MPSK.
通过计算多相编码信号(MPSK)相邻码元间的误差能量的方法来确定相位突变值,从而达到对MPSK信号相位编码规律的识别。
3.
A new quantum key distribution scheme is proposed to realize both phase coding and time coding based on two unbalanced Mach-Zehnder interferometers.
提出了一种在双马赫-曾德尔干涉仪量子保密通信系统上同时实现时间编码和相位编码的混合量子密钥分发方案。
补充资料:相位编码
相位编码
磁共振成像术语。磁共振成像中,为确定所选层面内自旋的位置,90°射频脉冲后间隔一段时间,在与层面选择梯度垂直的方向再施加一个梯度磁场(相位编码梯度),使沿该梯度方向自旋的相对相位发生变化。磁场越强,自旋进动频率越快,因此较强磁场中自旋偏转的角度比较弱磁场中自旋偏转的角度要大。经层面选择后,相位编码和梯度编码可共同确定层面中自旋的位置。
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