Link training for a full-duplex ethernet link

The invention claimed is: 1. A communication system, comprising: a first physical-layer (PHY) transceiver, comprising (i) a first transmitter and (ii) a first receiver comprising a first equalizer; and a second PHY transceiver, comprising (i) a second transmitter and (ii) a second receiver comprising a second equalizer, wherein the first PHY transceiver and the second PHY transceiver are configured to communicate with one another over a full-duplex link, including training the first equalizer on a second training signal transmitted from the second PHY transceiver, and concurrently training the second equalizer on a first training signal transmitted from the first PHY transceiver, the first PHY transceiver configured to initiate training of the first equalizer while the first training signal is being transmitted and while the second training signal is being received. 2. The communication system according to claim 1 , wherein the first PHY transceiver further comprises a first echo canceler, and the second PHY transceiver further comprises a second echo canceler; and wherein the first PHY transceiver and the second PHY transceiver are configured to train the first echo canceler and the second echo canceler concurrently, using the first and second training signals. 3. The communication system according to claim 1 , wherein the first PHY transceiver further comprises a first crosstalk canceler, and the second PHY transceiver further comprises a second crosstalk canceler; and wherein the first PHY transceiver and the second PHY transceiver are configured to train the first crosstalk canceler and the second crosstalk canceler concurrently, using the first and second training signals. 4. The communication system according to claim 1 , wherein the first PHY transceiver is configured to transmit the first training signal using a same modulation subsequently used for transmitting data to the second PHY transceiver. 5. The communication system according to claim 1 , wherein the first PHY transceiver is configured to transmit the first training signal in accordance with a first clock signal; and wherein the second PHY transceiver is configured to transmit the second training signal in accordance with a second clock signal that is independent of the first clock signal. 6. The communication system according to claim 5 , wherein the first PHY transceiver further comprises: a clock recovery circuit, configured to recover the second clock signal from the second training signal received from the second PHY transceiver; a resampling circuit configured to resample the first training signal produced in the first transmitter, in accordance with the recovered second clock signal; and a first echo canceler, configured to cancel, using the resampled first training signal, an echo of the first training signal in the received second training signal. 7. The communication system according to claim 1 , wherein the first PHY transceiver is configured to transmit the first training signal using four-level Pulse-Amplitude Modulation (4-PAM). 8. A physical-layer (PHY) transceiver, comprising: an interface, configured to connect to a full-duplex link for communicating with a peer PHY transceiver; a transmitter, configured to transmit a first training signal to the peer PHY transceiver; a receiver comprising an equalizer, the receiver configured to receive a second training signal from the peer PHY transceiver; and a controller, configured to initiate training of the equalizer while the first training signal is being transmitted and while the second training signal is being received. 9. A communication method, comprising: transmitting a first training signal from a first physical-layer (PHY) transceiver to a second PHY transceiver over a full-duplex link; transmitting a second training signal from the second PHY transceiver to the first PHY transceiver over the full-duplex link; and training a first equalizer in the first PHY transceiver using the second training signal transmitted from the second PHY transceiver, and concurrently training a second equalizer in the second PHY transceiver using the first training signal transmitted from the first PHY transceiver, including, in the first PHY transceiver, initiating training of the first equalizer while the first training signal is being transmitted and while the second training signal is being received. 10. The communication method according to claim 9 , further comprising training a first echo canceler in the first PHY transceiver, and concurrently training a second echo canceler in the second PHY transceiver, using the first and second training signals. 11. The communication method according to claim 9 , further comprising training a first crosstalk canceler in the first PHY transceiver, and concurrently training a second crosstalk canceler in the second PHY transceiver, using the first and second training signals. 12. The communication method according to claim 9 , wherein transmitting the first training signal comprises modulating the first training signal using a same modulation subsequently used for transmitting data from the first PHY transceiver to the second PHY transceiver. 13. The communication method according to claim 9 , wherein transmitting the first training signal is performed in accordance with a first clock signal; and wherein transmitting the second training signal is performed in accordance with a second clock signal that is independent of the first clock signal. 14. The communication method according to claim 13 , further comprising, in the first PHY transceiver: recovering the second clock signal from the second training signal received from the second PHY transceiver; resampling the first training signal, produced in the first PHY transceiver, in accordance with the recovered second clock signal; and canceling, using the resampled first training signal, an echo of the first training signal in the received second training signal. 15. The communication method according to claim 9 , wherein transmitting the first training signal comprises modulating the first training signal using four-level Pulse-Amplitude Modulation (4-PAM). 16. A communication method, comprising: using a physical layer (PHY) transceiver, communicating with a peer PHY transceiver over a full-duplex link, including transmitting a first training signal to the peer PHY transceiver and receiving a second training signal from the peer PHY transceiver; and initiating training of an equalizer of the PHY transceiver while the first training signal is being transmitted and while the second training signal is being received.