Beam forming for first adjacent cancellation

What is claimed is: 1. A communications device for improving reception of transmissions with first-adjacent co-channel interference signals corresponding to digitally-modulated side-bands of in-band on-channel (IBOC) broadcasted signals, the device comprising: a radio frequency (RF) signal-reception circuit including two RF-signal paths driven in response to signals received via at least two respective antennas and including respectively-associated front-end circuits including analog-to-digital converter and signal-processing circuitry configured to respond to signals carried in the respective RF-signal paths by providing pre-processed RF output signals; a beam-forming circuit driven in response to the signals received at the at least two respective antennas and configured and arranged in parallel with the two RF-signal paths of the RF signal-reception circuit to facilitate first-adjacent interference cancellation (FAC) by: providing a beam forming for first adjacent cancellation (BFFAC) signal as a function of the first-adjacent co-channel interference signals; using a statistically-based analysis to weight or assess a likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant; and providing a beam-forming output signal in which weighting for noise-cancellation is provided for in response to the statistically-based analysis; and an interference-cancelling circuit configured and arranged to reduce the first-adjacent co-channel interference signals by combining the beam-forming output signal with the pre-processed RF output signals by using the statistically-based analysis of the BFFAC signal to compensate for the first-adjacent co-channel interference. 2. The communications device of claim 1 , wherein the beam-forming circuit is configured and arranged to apply a log-likelihood ratio analysis to weight or assess the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant. 3. The communications device of claim 1 , wherein the beam-forming circuit is configured and arranged to compare the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant to a pre-stored threshold level of first-adjacent co-channel interference. 4. The communications device of claim 1 , wherein the beam-forming circuit is configured and arranged to compare the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant to a pre-stored threshold level of first-adjacent co-channel interference as part of a maximum ratio combining (MRC) process, and the interference cancelling circuit is configured and arranged to apply the MRC process responsive to a determination that the likelihood of the BFFAC signal indicating that the first-adjacent co-channel interference signals are less than the pre-stored threshold level of first-adjacent co-channel interference. 5. The communications device of claim 1 , wherein the beam-forming circuit is configured and arranged to compare the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant to a pre-stored threshold level of first-adjacent co-channel interference, and the interference cancelling circuit is configured and arranged to apply a weighting process to the BFFAC signal based on the comparison. 6. The communications device of claim 1 , wherein the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant is represented by bit metrics, and wherein the interference-cancelling circuit is configured and arranged to reduce the first-adjacent co-channel interference signals by performing a weighted-addition of the bit metrics. 7. The communications device of claim 1 , wherein the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant is represented by sub-carrier metrics, and wherein the interference-cancelling circuit is configured and arranged to reduce the first-adjacent co-channel interference signals by performing a weighted-addition of the sub-carrier metrics. 8. A method for improving reception of transmissions with first-adjacent co-channel interference signals corresponding to digitally-modulated side-bands of in-band on-channel (IBOC) broadcasted signals, the method comprising: generating at least two radio frequency (RF)-signal paths in response to signals received via at least two respective antennas; providing pre-processed RF output signals for each of the at least two RF-signal paths using respectively-associated front-end circuits including analog-to-digital converter and signal-processing circuitry; in response to the signals received at the at least two respective antennas, facilitating first-adjacent interference cancellation (FAC) by: providing a beam forming for first adjacent cancellation (BFFAC) signal as a function of the first-adjacent co-channel interference signals; using a statistically-based analysis to weigh or assess a likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant; and providing a beam-forming output signal in which weighting for noise-cancellation is provided for in response to the statistically-based analysis; and reducing the first-adjacent co-channel interference signals by combining the beam-forming output signal with the pre-processed RF output signals using the statistically-based analysis of the BFFAC signal to compensate for the first-adjacent co-channel interference. 9. The method of claim 8 , including combining the pre-processed RF output signals and the BFFAC signal responsive to application of the statistically-based analysis to each of the pre-processed RF output signals and the BFFAC signal, and applying a maximum ratio combining (MRC) process to the combined signals. 10. The method of claim 8 , including combining the pre-processed RF output signals and the BFFAC signal, applying a maximum ratio combining (MRC) process to the combined signal, and applying the statistically-based analysis to the combined signal responsive to application of the MRC process. 11. The method of claim 10 , wherein the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant is represented by bit metrics, and applying the MRC process to the combined signal includes performing a weighted-addition of the bit metrics. 12. The method of claim 8 , wherein the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant is represented by sub-carrier metrics, as part of an maximum ratio combining (MRC) process, and wherein the MRC process is applied in a manner proportional to the sub-carrier metrics. 13. The method of claim 8 , wherein providing pre-processed RF output signals includes applying a fast Fourier transform (FFT) process to each of the RF-signal paths, the method including applying the FFT process to the BFFAC signal prior to application of the MRC process. 14. The method of claim 8 , including: comparing the likelihood of the BFFAC signal indicating the first-adjacent co-channel interference signals are significant to a pre-stored threshold level of first-adjacent co-channel interference; and applying a maximum ratio combining (MRC) process responsive to a determination that the likelihood of the BFFAC signal indicating that the first-adjacent co-channel interference signals are less than the pre-stored threshold level of first-adjacent co-channel interference. 15