Active 1:N breakout cable

What is claimed is: 1. An active 1:N breakout cable that comprises: a unary end connector connected by electrical conductors to each of N split end connectors, N being an integer greater than 1, the unary end connector being adapted to fit into a network interface port of a primary host device to provide output PAM4 electrical signals that convey a multi-lane outbound data stream to the primary host device and to accept input PAM4 electrical signals that convey multi-lane inbound data stream from the primary host device, and each of the split end connectors being adapted to fit into a network interface port of a secondary host device to provide output NRZ electrical signals that convey a split portion of the inbound data stream to that secondary host device and to accept input NRZ electrical signals that convey a split portion of the outbound data stream from that secondary host device, each of the split end connectors including a transceiver that performs clock and data recovery on the input NRZ electrical signals to extract and re-modulate the split portion of the outbound data stream as one or more of converging transit signals that transport the split portions of the inbound data stream via the electrical conductors to the unary end connector, wherein the transceiver performs clock and data recovery on diverging transit signals to extract and re-modulate the split portion of the inbound data stream as said output NRZ electrical signals. 2. The active 1:N breakout cable of claim 1 , wherein the unary end connector includes a transceiver that performs clock and data recovery on the input PAM4 electrical signals to extract and re-modulate the inbound data stream as diverging transit signals that transport the split portions of the inbound data stream via the electrical conductors to the split end connectors, and wherein the transceiver performs clock and data recovery on converging transit signals to extract and re-modulate the outbound data stream as said output PAM4 electrical signals. 3. The active 1:N breakout cable of claim 2 , wherein the diverging transit signals and the converging transit signals are NRZ electrical signals. 4. The active 1:N breakout cable of claim 3 , wherein the transceiver in the unary end connector further performs forward error correction when extracting the outbound data stream. 5. The active 1:N breakout cable of claim 3 , wherein the transceiver in each split end connector further performs forward error correction when extracting the split portion of the inbound data stream. 6. The active 1:N breakout cable of claim 1 , wherein the diverging transit signals and the converging transit signals are PAM4 electrical signals. 7. The active 1:N breakout cable of claim 6 , wherein the unary end connector includes a transceiver that performs clock and data recovery on the input PAM4 electrical signals to extract and re-modulate the inbound data stream as the diverging transit signals that transport the split portions of the inbound data stream via the electrical conductors to the split end connectors, and wherein the transceiver in the unary end connector performs clock and data recovery on the converging transit signals to extract and re-modulate the outbound data stream as said output PAM4 electrical signals. 8. The active 1:N breakout cable of claim 7 , wherein the transceiver in the unary end connector further performs forward error correction when extracting the outbound data stream. 9. An active 1:N breakout cable that comprises: a unary end connector connected by electrical conductors to each of N split end connectors, N being an integer greater than 1, the unary end connector being adapted to fit into a network interface port of a primary host device to provide output PAM4 electrical signals that convey a multi-lane outbound data stream to the primary host device and to accept input PAM4 electrical signals that convey multi-lane inbound data stream from the primary host device, and each of the split end connectors being adapted to fit into a network interface port of a secondary host device to provide output NRZ electrical signals that convey a split portion of the inbound data stream to that secondary host device and to accept input NRZ electrical signals that convey a split portion of the outbound data stream from that secondary host device, wherein the unary end connector includes a transceiver that performs clock and data recovery on the input PAM4 electrical signals to extract and re-modulate the inbound data stream as diverging transit signals that transport the split portions of the inbound data stream via the electrical conductors to the split end connectors, and wherein the transceiver performs clock and data recovery on converging transit signals to extract and re-modulate the outbound data stream as said output PAM4 electrical signals, wherein the diverging transit signals and the converging transit signals are NRZ electrical signals, wherein each of the split end connectors includes a redriver circuit that provides the output NRZ electrical signals by amplifying the diverging transit signals that it receives, and wherein the redriver circuit provides at least one of the converging transit signals by amplifying the input NRZ electrical signals that it receives. 10. A cable manufacturing method that comprises: packaging a transceiver into a unary end connector that is adapted to mate with a network interface port of a primary host device, the transceiver being configured to provide output PAM4 electrical signals that convey a multi-lane outbound data stream to the primary host device and to accept input PAM4 electrical signals that convey multi-lane inbound data stream from the primary host device; connecting each of N split end connectors to the unary end connector with electrical conductors, where N is an integer greater than one, and where each of the split end connectors is adapted to mate with a network interface port of a secondary host device to provide output NRZ electrical signals that convey a split portion of the inbound data stream to that secondary host device and to accept input NRZ electrical signals that convey a split portion of the outbound data stream from that secondary host device, the transceiver in the unary end connector being configured to perform clock and data recovery on the input PAM4 electrical signals to extract and re-modulate the inbound data stream as diverging transit signals that transport the split portions of the inbound data stream via the electrical conductors to the split end connectors, and further configured to perform clock and data recovery on converging transit signals to extract and re-modulate the outbound data stream as said output PAM4 electrical signals; and packaging a transceiver in each of the split end connectors, the transceiver in each split end connector being configured to perform clock and data recovery on the diverging transit signals that it receives to extract and re-modulate the split portion of the inbound data stream, and being further configured to perform clock and data recovery on the input NRZ electrical signals to extract and re-modulate the split portion of the outbound data stream, wherein the diverging transit signals and the converging transit signals are PAM4 electrical signals. 11. A cable manufacturing method that comprises: packaging a transceiver into a unary end connector that is adapted to mate with a network interface port of a primary host device, the transceiver being configured to provide output PAM4 electrical signals that convey a multi-lane outbound data stream to the primary host device and to accept input PAM4 electrical signals that convey multi-lane inbound data stream f