Adaptive techniques for full duplex communications

What is claimed: 1. A method for residually-tuned self-interference cancellation comprising: converting a digital transmit signal of a communication system into a Radio Frequency (RF) transmit signal; wherein the RF transmit signal is an analog signal having a first center frequency; wherein the first center frequency is a radio frequency; sampling the RF transmit signal; transmitting, at a transmit antenna of the communication system, the RF transmit signal; receiving, at a receive antenna of the communication system, an RF receive signal of the communication system; wherein the RF receive signal is an analog signal having a second center frequency; wherein the second center frequency is identical to the first center frequency; transforming, in an RF domain and without performing frequency downconversion, the sampled RF transmit signal into an RF self-interference cancellation signal; wherein transforming the sampled RF transmit signal comprises: attenuating, according to an attenuation setting of an adapter, the sampled RF transmit signal; delaying, according to a delay setting of the adapter, the sampled RF transmit signal; and inverting the sampled RF transmit signal; combining, over a wired cancellation path, in order to remove a first portion of self-interference from the RF receive signal, the RF self-interference cancellation signal with the RF receive signal, resulting in a reduced-interference RF receive signal; sampling the reduced-interference RF receive signal; and modifying, using the adapter and according to a gradient descent algorithm, both of the attenuation setting and the delay setting in order to reduce a measured magnitude of the sampled reduced-interference RF receive signal. 2. The method of claim 1 , wherein modifying, using the adapter and according to the gradient descent algorithm, both of the attenuation setting and the delay setting further comprises: identifying false positives occurring due to noisy minima and adapting the gradient descent algorithm to ignore the false positives. 3. The method of claim 1 , further comprising: sampling the digital transmit signal; converting the reduced-interference RF receive signal into a reduced-interference digital receive signal; transforming, in a digital domain, the sampled digital transmit signal into a digital self-interference cancellation signal; and combining, in order to remove a second portion of self-interference from the reduced-interference digital receive signal, the digital self-interference cancellation signal with the reduced-interference digital receive signal, resulting in a further-reduced-interference digital receive signal. 4. The method of claim 3 , wherein transforming the sampled digital transmit signal comprises transforming the sampled digital transmit signal using a finite impulse response filter; wherein the finite impulse response filter is configured using a channel estimate. 5. The method of claim 4 , further comprising iteratively calculating the channel estimate to reduce residual error. 6. The method of claim 5 , further comprising sampling the further-reduced-interference digital receive signal; and modifying, using the adapter and according to a least squares algorithm, the channel estimate in order to reduce a measured magnitude of the sampled further-reduced-interference digital receive signal. 7. A method for self-interference cancellation comprising: sampling a Radio Frequency (RF) transmit signal; wherein the RF transmit signal is an analog signal having a first center frequency; wherein the first center frequency is a radio frequency; transmitting, at a transmit antenna of a communication system, the RF transmit signal; receiving, at a receive antenna of the communication system, an RF receive signal of the communication system; wherein the RF receive signal is an analog signal having a second center frequency; transforming, in an RF domain and without performing frequency downconversion, the sampled RF transmit signal into an RF self-interference cancellation signal; wherein transforming the sampled RF transmit signal comprises: attenuating, according to an attenuation setting of an adapter, the sampled RF transmit signal; delaying, according to a delay setting of the adapter, the sampled RF transmit signal; and inverting the sampled RF transmit signal; combining, over a wired cancellation path, in order to remove a first portion of self-interference from the RF receive signal, the RF self-interference cancellation signal with the RF receive signal, resulting in a reduced-interference RF receive signal; sampling the reduced-interference RF receive signal; and modifying, using the adapter, both of the attenuation setting and the delay setting in order to reduce a measured magnitude of the sampled reduced-interference RF receive signal. 8. The method of claim 7 , wherein the transmit antenna is also the receive antenna. 9. The method of claim 7 , further comprising: sampling a digital transmit signal of the communication system; converting the digital transmit signal into the RF transmit signal; converting the reduced-interference RF receive signal into a reduced-interference digital receive signal; transforming, in a digital domain, the sampled digital transmit signal into a digital self-interference cancellation signal using a digital finite impulse response filter; and combining, in order to remove a second portion of self-interference from the reduced-interference digital receive signal, the digital self-interference cancellation signal with the reduced-interference digital receive signal, resulting in a further-reduced-interference digital receive signal. 10. The method of claim 9 , further comprising sampling the further-reduced-interference digital receive signal; and iteratively modifying, using the adapter, a configuration of the digital finite impulse response filter in order to reduce a measured magnitude of the sampled further-reduced-interference digital receive signal. 11. The method of claim 7 , further comprising: after sampling the RF transmit signal, converting the sampled RF transmit signal into an RF-sourced digital transmit signal; transforming, in a digital domain, the RF-sourced digital transmit signal into a digital self-interference cancellation signal using a digital finite impulse response filter; converting the reduced-interference RF receive signal into a reduced-interference digital receive signal; and combining, in order to remove a second portion of self-interference from the reduced-interference digital receive signal, the digital self-interference cancellation signal with the reduced-interference digital receive signal, resulting in a further-reduced-interference digital receive signal. 12. The method of claim 11 , further comprising sampling the further-reduced-interference digital receive signal; and iteratively modifying, using the adapter, a configuration of the digital finite impulse response filter in order to reduce a measured magnitude of the further-reduced-interference digital receive signal. 13. A system for self-interference cancellation comprising: a transmitter, coupled to a transmit antenna, that transmits a Radio Frequency (RF) transmit signal having a first center frequency; wherein the first center frequency is a radio frequency; a signal splitter, communicatively coupled to the RF transmit signal, that samples the RF transmit signal to create a sampled RF transmit signal; a receiver, coupled to a receive antenna, that receives an RF receive signal having a second center frequency; wherein the second center frequency is a radio frequency; an R