Far-field R-wave detection to control atrial pace timing in a dual-chamber leadless pacemaker

The invention claimed is: 1. An implantable leadless pacemaker device, comprising: a housing; at least one attachment member on the housing for attaching the pacemaker device to an inner wall of a heart; only two electrodes, spaced far enough apart from one another to be able to detect P-waves generated by a chamber of the heart in which the pacemaker device is implanted and far-field R-waves in an adjacent chamber of the heart; a first sensing channel in the housing, configured to sense P-waves detected via the only two electrodes and having a first band-pass filter with a frequency range with a low end of approximately 10 Hz to approximately 40 Hz and a high end of greater than approximately 30 Hz and a low sensitivity threshold of about 1 mV; a second sensing channel in the housing, configured to sense far-field R-waves and P-waves detected via the only two electrodes and having a second band-pass filter with a frequency range with a low end of approximately 0.5 Hz to approximately 20 Hz and a high end of greater than approximately 20 Hz and a high sensitivity threshold of about 0.15 mV; and a processor configured to distinguish between P-waves and far-field R-waves based on a comparison between data from the first and second sensing channels and to generate a timing signal for timing atrial pacing therapy delivered by the pacemaker. 2. The device of claim 1 , wherein the two electrodes are spaced at least 17 millimeters apart. 3. The device of claim 1 , further comprising an analog-to-digital converter configured to convert analog signals detected by the electrodes into digital signals for processing by the sensing channels. 4. The device of claim 1 , wherein the sensing channels are located within the processor. 5. An intracardiac pacemaker system, comprising: an implantable, leadless, ventricular pacemaker device; and an implantable, leadless, atrial pacemaker device, comprising: a housing; at least one attachment member on the housing for attaching the pacemaker device to an inner wall of a heart; only two electrodes, spaced far enough apart from one another to be able to detect P-waves generated by an atrium of the heart in which the pacemaker device is implanted and far-field R-waves in an adjacent ventricle of the heart; a first sensing channel in the housing, configured to sense P-waves detected via the only two electrodes and having a first band-pass filter with a frequency range with a low end of approximately 10 Hz to approximately 40 Hz and a high end of greater than approximately 30 Hz and a low sensitivity threshold of about 1 mV; a second sensing channel in the housing, configured to sense far-field R-waves and P-waves detected via the only two electrodes and having a second band-pass filter with a frequency range with a low end of approximately 0.5 Hz to approximately 20 Hz and a high end of greater than approximately 20 Hz and a high sensitivity threshold of about 0.15 mV; and a processor configured to distinguish between P-waves and far-field R-waves based on a comparison between timing markers from the sensing channels and to generate a timing signal for timing atrial pacing therapy delivered by the pacemaker. 6. The system of claim 5 , wherein the two electrodes are spaced at least 17 millimeters apart. 7. The system of claim 5 , further comprising an analog-to-digital converter configured to convert analog signals detected by the electrodes into digital signals for processing by the sensing channels. 8. The system of claim 5 , wherein the sensing channels are located within the processor. 9. An implantable leadless pacemaker device, comprising: a housing; at least one attachment member on the housing for attaching the pacemaker device to an inner wall of a heart; only two electrodes, spaced far enough apart from one another to be able to detect P-waves generated by a chamber of the heart in which the pacemaker device is implanted and far-field R-waves in an adjacent chamber of the heart; and a processor configured to process data sensed by the two electrodes and convert to digital data to distinguish between P-waves and far-field R-waves, wherein the processor comprises: a first sensing channel, configured to sense P-waves detected via the only two electrodes and having a first band-pass filter with a frequency range with a low end of approximately 10 Hz to approximately 40 Hz and a high end of greater than approximately 30 Hz and a low sensitivity threshold of about 1 mV; and a second sensing channel, configured to sense far-field R-waves and P-waves detected via the only two electrodes and having a second band-pass filter with a frequency range with a low end of approximately 0.5 Hz to approximately 20 Hz and a high end of greater than approximately 20 Hz and a high sensitivity threshold of about 0.15 mV, and wherein the processor is configured to distinguish between P-waves and far-field R-waves based on a comparison between digital data from the first and second sensing channels. 10. The device of claim 1 , wherein the processor is configured to distinguish between P-waves and far-field R-waves based on a comparison between timing markers from the first and second sensing channels. 11. The device of claim 10 , wherein the processor is configured to determine a sensed waveform corresponds to a P-wave on condition that a timing marker from the first sending channel is matched to a timing marker from the second sensing channel within a particular temporal interval. 12. The device of claim 10 , wherein the processor is configured to determine a sensed waveform corresponds to a R-wave on condition that a timing marker from the second sensing channel is unmatched to a timing marker from the first sensing channel.