联系我们

与泰克代表实时聊天。 工作时间:上午 9:00 - 下午 5:00(太平洋标准时间)。

电话

致电我们

工作时间:上午9:00-下午5:00(太平洋标准时间)

下载

下载手册、产品技术资料、软件等:

下载类型
型号或关键字

反馈

How do I build a crosstalk model with IConnect?

问题:

How do I build a crosstalk model with IConnect?

答案:

The victim's near end noise (NEXT) is dominated by the even and odd impedance difference, and the victim's far end noise (FEXT) is directly proportional to the odd and even time delay difference. Therefore, when the crosstalk model is considered, it is important to obtain a good correlation between even and odd time delays and impedances. The best suitable models for this condition are distributed four-line coupled and symmetric coupled lossy line models.

To model the crosstalk, the differential fully coupled model, similar to the one shown in Figure 1, is built first, and then we change the probing setup to measure the crosstalk values (Figure 2). The IConnect partitioning in the distributed four-line coupled model should take into account the time delay difference; otherwise the FEXT model will underestimate the induced voltage. When the desired correlation between the even and odd impedances and time delays is obtained, the differential model could be could easily be converted to a single-ended one by replacing the PWL source on the “victim” with the source probe set to zero volts. IConnect simulation of this setup will produce four waveforms where the reflected waveform of the probe port will give NEXT value, and the waveform transmitted from the same port will give FEXT.
figure 1

Figure 1. Fully coupled differential model topology.
figure 2

Figure 2. Crosstalk model. An ideal probe to measure the crosstalk replaced one of the PWL sources.


此常见问题适用于:

无产品系列

产品:

常见问题 ID 56526

查看所有常见问题 »