UC知道英语翻译B段
来源:百度知道 编辑:UC知道 时间:2024/06/04 16:51:44
B. Kreless Channel and Link Model
We consider a discrete time channel with stationary,
ergodic, slowly time-varying gain and additive
white Gaussian noise (AWGN) n , ( k ) , where the subscript
a refers to the ith link and k refers to the kth time instant.
In this paper, our analysis will be based on static channel
gains. This is justified by the assumption of very slow fading
where the channel coherence time (the time over which the
channel remains roughly constant) is long enough so that the
control system converges to steady-state within a coherence
time interval. We assume that the channel power gain g;(k)
is independent of the channel input and the transmission
power Pi does not change as the channel gain varies.
Different link layer design choices (coding, modulation,
etc.) lead to different performance for the data transfer. We
assume a simple class of communication link designs as
shown in Figure 3.
We consider a discrete time channel with stationary,
ergodic, slowly time-varying gain and additive
white Gaussian noise (AWGN) n , ( k ) , where the subscript
a refers to the ith link and k refers to the kth time instant.
In this paper, our analysis will be based on static channel
gains. This is justified by the assumption of very slow fading
where the channel coherence time (the time over which the
channel remains roughly constant) is long enough so that the
control system converges to steady-state within a coherence
time interval. We assume that the channel power gain g;(k)
is independent of the channel input and the transmission
power Pi does not change as the channel gain varies.
Different link layer design choices (coding, modulation,
etc.) lead to different performance for the data transfer. We
assume a simple class of communication link designs as
shown in Figure 3.
乙kreless通道和连接模型
我们认为,离散时间与频道文具,
遍历,时间慢慢地变增益和添加剂
高斯白噪声( awgn )氮, ( k )款,凡标
a指该提取环节和K是指以第k时间瞬间。
在本文中,我们的分析将基于静态频道
收益。这是合理的假设很慢衰落
地方频道相干时间(时间超过其中
频道仍然大体不变) ,是足够长,使该
控制系统收敛到稳定状态在一个连贯性
时间间隔。我们假定了信道功率增益G ; (十一)
是独立的通道输入及传输
电力丕并不能改变作为通道增益各不相同。
不同的链路层设计选择(编码,调制,
等) ,导致不同的表现为数据传输。我们
假设一个简单的类通信链路的设计
如图3所示。这个数字表明,无线连接
一个传感器向控制器中。我们承担同样的连接模型
为无线链路,包括三通,从控制器
该驱动器与输入的丁( k )和输出
铀( k )款。在发射机,数据是第一次量化,并
转换成二进制码流通过一个统一的量化
[ 2 ] [ 5 ] 。该位流,然后通过渠道
编码器采用线性分组码纠错
和错误检测。我们假定BPSK调制在
发射机。在接收端,我们假设匹配滤波
随后进行了最大似然检测器。概率
成功传输的PS为每包可以很容易
计算鉴于连接设计,无线频道增益和
传输功率。我们假定时间是开槽,我们允许
转播,如果有额外的时间槽。可选
信息反馈渠道,从接收到发射机可能
存在的。这样的一个反馈渠道,接收器发送一个
" ack " ,以变送器基于一个成功的传播。
如果发射机接收ack ,它擦亮了,其传输
缓冲区并没有传递到一个新的包抵达。我们
承担传输缓冲区,只有有能力的一个数据
包。因此,一包,将他discardedz如果它没有被
成功地传输到去年底,该样本时期。
从控制系统的角度来看,有关
参数,从无线链路数据速率,时间延迟
和概率丢包'