Abstract:
The invention relates to an electrocardiogram arrangement having a plurality of lead channels, in which at least two lead channels are assigned an evaluation unit ( 1, 2 , . . . ) which evaluates the ECG quality, classifies the results and locates the QRS complexes. For the QRS complex location, a central logic unit ( 14 ) selects that lead channel which has the highest ECG quality as the dominant lead channel. When special events occur in the dominant lead channel, other lead channels are accessed as appropriate.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to an electrocardiogram (ECG) arrangement having m (m≧2) lead channels for locating QRS complexes in an electrocardiogram and having a central logic unit. 
     As is known, in ECG examinations, it is becoming evermore frequent to use electrocardiogram arrangements having a plurality of lead channels which are usually fitted to the arms and legs (limb lead) and to the chest (chest lead). In the main, electrocardiogram arrangements which have twelve lead channels are available. There are, however, also electrocardiogram arrangements in which more or fewer than twelve lead channels are employed. 
     By way of example, for measuring heart rate or for analyzing arrhythmia, the redundancy involved with having multiple lead channels provides advantages when this redundancy is used to reduce or eliminate the effect of noise or artifacts in the result obtained using the electrocardiogram arrangement. 
     Previous electrocardiogram arrangements have exploited the multiple lead-channel redundancy and have collated the individual lead-channel signals by taking their first mathematical derivative. The individual mathematical derivatives are squared and then summed over all the lead channels. The square root of the result obtained in this way is then taken. The signal obtained in this way has the advantage that, compared with the individual original signals, the ratio of the useful signal component to the noise signal component is improved, which in the final analysis means that the QRS complexes can be located better. 
     Instead of squaring and taking the square root, sometimes only the magnitude of the signals given by the first mathematical derivative is calculated, this being followed by summing the magnitudes obtained for the individual lead channels. 
     In any event, with both electrocardiogram arrangements, the final result is a one-channel signal which is subjected to evaluation in relation to the QRS complexes. 
     The conventional electrocardiogram arrangements constructed in this way give reliable results if the level of noise is approximately the same in all the lead channels. However, if some of the lead channels have substantially stronger interference than other lead channels, which is often the case, for example, when recording a stress test electrocardiogram, it is expedient to exclude the signals from the very noisy lead channels from any subsequent processing. 
     SUMMARY OF THE INVENTION 
     To that end, there are already electrocardiogram arrangements which, although they are constructed in the manner indicated above, they only use signals from lead channels which are empirically found to have relatively few artifacts and are approximately orthogonal to one another. This is because the orthogonality of the lead-channel signals ensures that the normal QRS complexes or ventricular extrasystoles are well represented in at least one of the signals. The disadvantage with a procedure of this type is, however, that because of the requirement of evaluating mutually orthogonal signals, lead-channel signals which have stronger interference than other signals also have to be used aid, in the final analysis, an electrocardiogram arrangement constructed in this way only gives good results under certain circumstances. 
     It is known that, in a stress test electrocardiogram, most interference occurs in the heavy load phase. However, the heavy load phase is actually one of the most important phases of a stress test. For example, it is during this phase that the doctor decides, amongst other things, whether or not the examination should be stopped. 
     In order to decide whether or not the heavy load phase should be stopped, amongst other things the heart rate, the ST segment of the electrocardiogram and arrhythmia results are employed. 
     It is therefore very important to be able to calculate correctly the data relevant to this decision actually in the heavy load phase, in spite of the greater incidence of interference. One prerequisite for such correct calculation of the data is, however, accurate location of the QRS complexes. 
     The object of the present invention is therefore to provide an electrocardiogram arrangement which allows accurate location of QRS complexes even during heavy load phases. 
     This object is achieved according to the invention, with an electrocardiogram arrangement of the type mentioned at the start, in the following way: 
     n (n≦m) independent evaluation units are provided in the plurality of lead channels, each lead channel being respectively assigned at most one evaluation unit which locates the QRS complexes, classifies the events and assesses the ECG quality, 
     a comparator, in the central logic unit connected to the individual evaluation units, which compares with one another the ECG qualities obtained by the ECG quality assessments in the individual lead channels and identifies the lead channel obtaining the highest ECG quality as the dominant lead channel, and 
     a test unit, in the central logic unit, which tests the results of the event classification of the dominant lead channel and, when special events occur in the dominant lead channel, accesses other lead channels in order to correct the results of the QRS complex location and the event classification of the dominant lead channel on that basis. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic view of a processor embodying the invention. 
    
    
     DETAILED DESCRIPTION 
     In this regard, the electrocardiogram arrangement according to the invention firstly uses the fact that, during a heavy load phase, the signals of virtually all the lead channels are noisy. It is indeed often the case that only the signals from one or two lead channels are useable, while the signals from all the other lead channels vitiate the results since the interference in them is too strong. 
     In the electrocardiogram arrangement according to the invention, the QRS complexes in the various lead channels are evaluated and located separately. This means that, in contrast to the prior art, the individual ECG curves from the various lead channels are not combined to form one signal. Instead, quality assessments are made in each individual lead channel and, in order to do this, quality features are calculated separately. The instance of the QRS complexes located in this way, and their event classification, are taken from the lead channel with the highest ECG quality, referred to as the dominant lead channel, and are for example used to calculate the heart rate. 
     In the event of special results in the electrocardiogram of the dominant lead channel, for example a pause, a superventricular extrasystole or a fusion beat, the QRS complex features from other lead channels are accessed. If, for example, a pause occurs in the dominant lead channel, then the corresponding features are taker from a different lead channel, if a QRS complex, for example a ventricular extrasystole, has been located at this point. 
     Examples of the features for determining the ECG quality include: 
     the amplitude of the QRS complexes, 
     a noise level value for high-frequency interference, for example caused by muscle tremors, 
     a noise level value for medium-frequency interference, for example caused by motion of the electrodes relative to the patient&#39;s body, and 
     the electrode condition, for example electrodes having fallen off. 
     The following features, in particular, are thus essential to the electrocardiogram arrangement according to the invention for reliable location of QRS complexes in an electrocardiogram: 
     Two or more independent evaluation units, which are equivalent to one another, are used for location and event classification of QRS complexes and for ECG quality evaluation in each individual lead channel. 
     On the basis of the ECG quality of the individual lead channels, a central logic unit takes the results of the QRS location and the event classification from the “best” lead channel. 
     The central logic unit tests the event classification of the “best” lead channel for events, for example pauses, superventricular extrasystoles or fusion beats, accesses the results from the other lead channels and, on the basis of their results, corrects the results of the event classification and the QRS location of the “best”, or dominant, lead channel. 
     The specific selection of the lead channels having the signals with the least interference, which is carried out in this way, improves the QRS complex location in comparison with conventional arrangements. Consequently, the quality of the algorithms based on this, such as heart rate calculation, and even beat averaging for ST measurement, is also improved. 
     The invention will be explained in more detail below with the aid of the drawing, the single figure of which schematically represents a block diagram of the electrocardiogram arrangement according to the invention. 
     In the electrocardiogram arrangement according to the invention, ECG lead channels  1 ,  2 , . . . , m are fed to evaluation units  10   1 ,  10   2 , . . . ,  10   m , although each ECG lead channel need not necessarily have such an evaluation unit  10   1 ,  10   2 , . . . ,  10   m . However, no more than one evaluation unit is provided in each ECG lead channel, so that the number of evaluation units  10   1 ,  10   2 , . . . ,  10   m  corresponds at most to the number of ECG lead channels. QRS complex location, event classification and ECG quality assessment are carried out in each of the ECG evaluation units, this being done in a conventional way. The results of this QRS complex location, this event classification and this ECG quality assessment are all fed to a central logic unit  14 , this being indicated by arrows  11 ,  12  and  13 , respectively, which in particular has a comparator  15  and a test unit  16 . The comparator  15  compares with one another the ECG qualities obtained using the individual evaluation units  10   1 ,  10   2 , . . . ,  10   m  for the lead channels, and identifies the lead channel obtaining the highest ECG quality. The QRS complex location (see arrow  11 ) of the lead channel which has the highest ECG quality is then selected by the comparator  15  for it to be processed further. The test unit  16  tests the event classification of the dominant lead channel and, when special events occur, for example pauses, superventricular extrasystoles and fusion beats, accesses other lead channels and, on the basis of this access, corrects the event classification and the result of the QRS complex location of the dominant lead channel. 
     Said further processing may, for example, involve calculating the heart rate. Other processing operations are, however, also possible. 
     Finally, the QRS location results and the event classification results (see arrow  17 ) are output by the central logic unit  14 .