Capacitive hybrid with PGA for full duplex transceivers

What is claimed is: 1. A hybrid network for use in a full duplex communication system, wherein the hybrid network comprises: a first circuit coupled between an output of a communication channel and a node between a transmitter and the communication channel; a second circuit comprising a first resistor having a first resistance coupled between a first output of the transmitter and the node; a third circuit coupled between the node and an input of an amplifier; a fourth circuit comprising a second resistor having a second resistance coupled between the input of the amplifier and a second output of the transmitter, wherein the hybrid network is configured to use a second transmit signal from the second output of the transmitter to cancel a first transmit signal from the first output of the transmitter based at least on the first resistance and the second resistance; and a fifth circuit coupled between an output of the amplifier and the input of the amplifier, wherein the output of the amplifier is coupled to an input of a receiver. 2. The hybrid network of claim 1 , wherein the hybrid network is configured to: provide, to the receiver, a receive signal provided by the output of the communication channel. 3. The hybrid network of claim 1 , wherein the fifth circuit includes a first capacitor. 4. The hybrid network of claim 1 , wherein: the third circuit includes a first capacitor having a first capacitance; and the fourth circuit includes a second capacitor having a second capacitance. 5. The hybrid network of claim 4 , wherein the hybrid network is configured to use the second transmit signal from the second output of the transmitter to cancel the first transmit signal from the first output of the transmitter based further on a ratio of the first capacitance and the second capacitance. 6. The hybrid network of claim 5 , wherein: the second circuit includes the first resistor having the first resistance and coupled to the first capacitor; and the fourth circuit includes the second resistor having the second resistance and coupled to the second capacitor. 7. The hybrid network of claim 6 , wherein the hybrid network is configured to use the second transmit signal from the second output of the transmitter to cancel the first transmit signal from the first output of the transmitter based on a second ratio of the first resistance and the second resistance. 8. The hybrid network of claim 6 , wherein the fourth circuit includes a tunable capacitor coupled at one end between the second capacitor and the second resistor and coupled at a second end to a ground. 9. The hybrid network of claim 6 , wherein the first circuit includes a third resistor having a third resistance equal to the first resistance, and coupled to the first capacitor. 10. The hybrid network of claim 6 , further comprising: a sixth circuit coupled between a second node and a second input of the amplifier; and a seventh circuit coupled between the second input of the amplifier and the first output of the transmitter, wherein the sixth circuit includes a third capacitor, and the fourth circuit includes a fourth capacitor. 11. The hybrid network of claim 1 , wherein the fifth circuit includes a third resistor. 12. The hybrid network of claim 1 , wherein: the third circuit includes a third resistor having a third resistance. 13. The hybrid network of claim 12 , wherein the hybrid network is configured to use the second transmit signal from the second output of the transmitter to cancel the first transmit signal from the first output of the transmitter based further on a ratio of the third resistance and the second resistance. 14. A hybrid network for use in a full duplex communication system, wherein the hybrid network comprises: a first circuit comprising a first resistor having a first resistance coupled between a first output of a transmitter and a node of the transmitter and a communication channel; a second circuit coupled between the node and an input of an amplifier, wherein the second circuit includes a first capacitor; a third circuit comprising a second resistor having a second resistance coupled between the input of the amplifier and a second output of the transmitter, wherein the third circuit includes a second capacitor, wherein the hybrid network is configured to use a second transmit signal from the second output of the transmitter to cancel a first transmit signal from the first output of the transmitter based at least on the first resistance and the second resistance; and a fourth circuit coupled between an output of the amplifier and the input of the amplifier, wherein the output of the amplifier is also coupled to a receiver. 15. The hybrid network of claim 14 , wherein the hybrid network is configured to: provide, to the receiver, a receive signal provided by the communication channel. 16. The hybrid network of claim 14 , wherein the fourth circuit includes a third capacitor. 17. The hybrid network of claim 14 , wherein: the first capacitor has a first capacitance; and the second capacitor has a second capacitance, wherein the hybrid network is configured to use the second transmit signal from the second output of the transmitter to cancel the first transmit signal from the first output of the transmitter further based on a ratio of the first capacitance and the second capacitance. 18. The hybrid network of claim 17 , wherein: the first circuit includes the first resistor coupled to the first capacitor; and the third circuit includes the second resistor and coupled to the second capacitor. 19. The hybrid network of claim 18 , wherein the hybrid network is configured to use the second transmit signal from the second output of the transmitter to cancel the first transmit signal from the first output of the transmitter based on a second ratio of the first resistance and the second resistance. 20. The hybrid network of claim 18 , wherein the third circuit includes a tunable capacitor coupled at one end between the second capacitor and the second resistor and coupled at a second end to ground. 21. A device, comprising: a first resistor coupled between an output of a communication channel and a node between a transmitter and the communication channel; a second resistor having a first resistance coupled between a first output of the transmitter and the node; a first capacitor coupled between the node and an input of an amplifier; a second capacitor and a third resistor having a second resistance coupled between the input of the amplifier and a second output of the transmitter, wherein the device is configured to use a second transmit signal from the second output of the transmitter to cancel a first transmit signal from the first output of the transmitter based at least on the first resistance and the second resistance; and a third capacitor coupled between an output of the amplifier and the input of the amplifier, wherein the output of the amplifier is coupled to an input of a receiver. 22. The device of claim 21 , wherein: the first capacitor has a first capacitance; and the second capacitor has a second capacitance, wherein the device is configured to use a second transmit signal from the second output of the transmitter to cancel a first transmit signal from the first output of the transmitter based further on a ratio of the first capacitance and the second capacitance. 23. The device of claim 21 , comprising: the third resistor coupled betwee