A 4-channel 10.3Gb/s transceiver with adaptive phase equalizer for 4-to-41dB loss PCB channel

摘要

In multi-Gb/s wireline communications, equalizers are used to compensate for channel-induced signal distortion in order to stretch the maximum distance of transmission. Both amplitude and phase can be distorted in a channel. Amplitude distortion is a frequency-dependent attenuation due to skin effect and dielectric loss, causing inter-symbol-interference (ISI). A transmitter (TX) discrete-time pre-emphasis (PE) filter, a receiver (RX) continuous-time Linear Equalizer (LE), and an RX Decision-Feedback Equalizer (DFE) are generally used to cancel ISI. At 10Gb/s or higher data rate, equalizers for up to 33 to 39dB Nyquist loss and up to 20 to 25dB adapted loss range were reported [1–3]. On the other hand, how to compensate phase distortion is not clearly understood in practical circuit design. Theoretically, if a channel has minimum-phase-likecharacteristics, phase distortion is automatically co-equalized with amplitude distortion by a minimum-phase equalizer [4]. While this is the case for high-speed cables [5], it is not for PCB traces, because a non-minimum-phase equalizer, e.g., a PE with a pre-cursor tap, produces lower BER over a high-loss PCB channel than a minimum-phase equalizer, e.g., a PE without a pre-cursor tap. Thus the IEEE 10Gb Ethernet standard for backplanes adopted 3-tap PE with a precursor tap [6]. However, adaptive phase equalization in hardware has not been reported in the literature.