Monitoring a property of the cardiovascular system of a subject

The invention claimed is: 1. A device for monitoring a cardiovascular property of a subject, wherein the device comprises: a primary pressure wave sensor positioned and arranged to detect pressure waves in an extracorporeal fluid circuit in fluid communication with the cardiovascular system of the subject, the extracorporeal fluid circuit including a venous line and an arterial line; and an input configured to obtain measurement data from the primary pressure wave sensor, wherein the device further comprises a signal processor configured to: generate a time-dependent monitoring signal based on the measurement data, such that the monitoring signal comprises a sequence of heart pulses, wherein each heart pulse represents a pressure wave originating from a heart beat in the subject; determine beat classification data for each heart pulse in the monitoring signal, the beat classification data including information sufficient to distinguish between heart pulses originating from normal heart beats and heart pulses originating from ectopic heart beats; form a classification of at least one heart pulse of the sequence of heart pulses using the beat classification data, the classification based on (i) the at least one heart pulse represented as a cluster of shape features, and (ii) distances of the at least one heart pulse cluster of shape features from a plurality of clusters of shaped features of other heart pulses, wherein each cluster is in an N-dimensional space, and wherein N represents a number of shape features for each heart pulse; calculate, based at least partly on the classification of the at least one heart pulse, a parameter value indicative of the cardiovascular property; and at least one of (i) cause the calculated parameter value to be displayed, or (ii) generate an alarm based on the calculated parameter value. 2. The device of claim 1 , wherein the beat classification data includes information sufficient to distinguish between different types of ectopic heart beats. 3. The device of claim 1 , wherein the signal processor is configured to determine the beat classification data based on at least one of primary timing data, which represents an occurrence time of each heart pulse in the monitoring signal, and shape data, which represents a shape of each heart pulse in the monitoring signal. 4. The device of claim 3 , wherein the signal processor is configured to determine the beat classification data by processing the monitoring signal to extract at least one shape feature which is representative of temporal shape of each heart pulse. 5. The device of claim 3 , wherein the signal processor is configured to determine the beat classification data based on a combination of a plurality of different shape features extracted from each heart pulse. 6. The device of claim 3 , wherein the signal processor is configured to determine the beat classification data by extracting at least part of a temporal profile of each heart pulse, and matching said at least part of the temporal profile against a set of templates. 7. The device of claim 3 , wherein the signal processor is configured to determine the beat classification data by obtaining, based on the primary timing data, time differences between heart pulses in the monitoring signal, and evaluating each time difference against a time interval criterion. 8. The device of claim 1 , wherein the signal processor is configured to calculate the parameter value by generating secondary timing data based on the beat classification data, the secondary timing data representing occurrence times of the at least one heart pulse for use in calculating the parameter value. 9. The device of claim 8 , wherein the signal processor is configured to, if the classification identifies heart pulses originating from ectopic heart beats and if a selection criterion is met, generate the secondary timing data by estimating a corrected time point for each heart pulse that is classified as originating from an ectopic heart beat. 10. The device of claim 9 , wherein the selection criterion indicates that the parameter value is at least one of heart rate and heart rate variability. 11. The device of claim 8 , wherein the signal processor is configured to process the secondary timing data for calculation of the parameter value as a measure of at least one of heart rate variability and heart rate. 12. The device of claim 8 , wherein the signal processor is configured to, if the classification identifies heart pulses originating from ectopic heart beats, process the beat classification data and the secondary timing data, for calculation of the parameter value as a measure of heart rate turbulence. 13. The device of claim 8 , wherein the signal processor is configured to, if the classification identifies heart pulses, originating from ectopic heart beats, select, based on the beat classification data, a subset of the heart pulses in the monitoring signal and to generate the parameter value as a measure of an average temporal shape of the selected subset. 14. The device of claim 13 , wherein the signal processor is configured to generate the average temporal shape by aligning and combining, based on the secondary timing data, the subset of the heart pulses. 15. The device of claim 1 , wherein the signal processor is configured to, if the classification identifies heart pulses originating from ectopic heart beats, process the beat classification data for calculation of the parameter value as a count of ectopic heart beats. 16. The device of claim 1 , wherein the measurement data comprises the sequence of heart pulses and at least one interference pulse, wherein the signal processor is configured to generate the monitoring signal by processing the measurement data to essentially eliminate said at least one interference pulse. 17. The device of claim 16 , wherein the signal processor is configured to obtain a pulse profile (u(n)) which is a predicted temporal signal profile of the interference pulse, and to filter the measurement data in the time domain, using the pulse profile (u(n)), to essentially eliminate the interference pulse while retaining the sequence of heart pulses. 18. The device of claim 1 , wherein the signal processor implements a first process for generating the monitoring signal, and a second process for obtaining primary timing data, and a third process for calculating the parameter value, wherein the signal processor is further configured to evaluate a magnitude of each heart pulse in the monitoring signal, or in a reference signal obtained from a reference sensor. 19. The device of claim 1 , wherein the measurement data comprises the sequence of heart pulses and at least one interference pulse, which originates from at least one pumping device in the extracorporeal fluid circuit, wherein the signal processor is further configured to calculate a rate of heart pulses in the monitoring signal, or in a reference signal obtained from a reference sensor, and to cause a pumping frequency of said at least one pumping device to be controlled in relation to the rate of heart pulses. 20. The device of claim 19 , wherein the pumping frequency is controlled to shift a rate of interference pulses away from the rate of heart pulses. 21. The device of claim 19 , wherein the pumping frequency is controlled to synchronize a rate of interference pulses with the rate of heart pulses, while applying a given phase difference between the at least one interference pulse and the sequence of heart pulses.