Abstract: Methods and devices for identification of intrinsic ventricular activity occurring within a ventricular signal. Ventricular signal morphology is analyzed to determine if the signal contains intrinsic ventricular activity while delivering pacing pulses separated by nearly constant time intervals. Furthermore, an extension of a pacing interval is specified based on whether or not the signal contains autonomous intrinsic ventricular activity. In this manner, the pacing interval is only extended when it is likely for autonomous intrinsic ventricular activity to occur.

Abstract: Waveform analysis is used to identify and distinguish components of a sensed input signal, such as P-wave and Far Field R-wave signal components present in a sensed cardiac signal, even when the components are so closely spaced in time that the overlap to create a distorted input signal. A set of composite waveforms are generated by superimposing waveform templates of the signal components with different time delays or degree of overlap. Form parameters for each composite waveform are derived and mapped in a multidimensional map, from which form parameter boundaries are derived. Waveform data is collected from an input signal during a sensed event time window, and form parameters for the input signal waveform are derived. An output identifying the signal component of interest (e.g., a P-wave) and its location within the sensed event time window is produced based upon the set of form parameters of the input signal waveform and the form parameter boundaries.

Abstract: Waveform analysis is used to identify and distinguish components of a sensed input signal, such as P-wave and Far Field R-wave signal components present in a sensed cardiac signal, even when the components are so closely spaced in time that the overlap to create a distorted input signal. A set of composite waveforms are generated by superimposing waveform templates of the signal components with different time delays or degree of overlap. Form parameters for each composite waveform are derived and mapped in a multidimensional map, from which form parameter boundaries are derived. Waveform data is collected from an input signal during a sensed event time window, and form parameters for the input signal waveform are derived. An output identifying the signal component of interest (e.g., a P-wave) and its location within the sensed event time window is produced based upon the set of form parameters of the input signal waveform and the form parameter boundaries.

Abstract: An implantable medical device uses a sampling scheme to obtain digital representation from analog signals. The analog signals represent intracardiac activity. Generally, a detector detects the amplitude of the analog signals and generates first and second difference signals. The first difference signal is generated after detection of significant changes in the analog signal amplitude. The second difference signal is generated upon confirmation of the absence of significant changes in the analog signal amplitude over a predetermined period of time. A frequency selection is implemented to select the sampling frequency based on the first and second difference signal.

Abstract: In general, the invention is directed to techniques for determining capture status of a heart chamber that receives a pulse from an implantable pulse generator (IPG). Digital signal processing (DSP) can be used to improve the reliability of capture detection by transforming the sensed response signal into a set of morphological characteristics. Analysis of selected morphological characteristics serves to distinguish signals indicative of capture from signals indicative of loss of capture.

Abstract: In general, the invention is directed to identification of intrinsic ventricular activity occurring within a ventricular signal. In particular, the invention involves the analysis of ventricular signal morphology to determine if the signal contains intrinsic ventricular activity while delivering pacing pulses separated by nearly constant time intervals. Furthermore, the invention specifies an extension of a pacing interval based on whether or not the signal contains intrinsic ventricular activity. In this manner, the pacing interval is only extended when it is likely for intrinsic ventricular activity to occur.