WO2024052089A1 - Method and device for determining cardiogram signals of one or more people - Google Patents

Abstract

The invention relates to a method for determining magnetocardiogram signals of one or more people, wherein measurement signals of at least one person are determined contactlessly by at least one sensor device integrated into a surface, e.g. a mattress, wherein the measurement signals are transferred to an evaluation unit, wherein the sensor device is a magnetic field sensor device, and wherein the measurement signals are magnetocardiogram signals and wherein the magnetic field sensor device has a plurality of magnetic field sensors arranged in the form of a sensor array in or on the surface. According to the invention, by evaluating the sensor signals of the individual magnetic field sensors of the sensor array, sensor groups (so-called cells) of, in particular spatially adjacent, magnetic field sensors are formed, wherein a sensor group is associated with a signal source, i.e. in particular a person's heart. Via a separate examination and further processing of the signals of a respective sensor group, different signal sources can be differentiated in this way and thereby also other people that are simultaneously present on the surface during the measurement.

Description

title

Method and device for determining cardiogram signals from one or more people

The present invention relates to a method and a device for determining magnetic cardiogram signals of one or more people, wherein cardiogram signals of one or more people lying on the same support are determined in a non-contact manner by a sensor device integrated into a support.

The present invention further relates to a device for a support, in particular a mattress, comprising a sensor device.

State of the art

In the area of patient monitoring, in particular the monitoring of cardiac function, it is known to monitor a person over a longer period of time using suitable sensors and to record their vital functions in order to be able to detect any impairment of the person's health at an early stage and, if necessary, to be able to initiate countermeasures.

Medical emergency detection, such as a heart attack, is currently only possible through direct derivation of heart muscle signals. This is usually done via electrodes with direct skin contact and is therefore unsuitable for comfortable integration into a surface on which a person can sit or lie comfortably for a longer period of time.

From US 8,706,204 B2 a system for monitoring the heart rate of a passenger is known. The system includes a variety of different types of heart rate sensors mounted on a seat cushion or a Seat backrest are arranged. The heart rate sensors are designed as electrocardiogram sensors.

From DE 102021209759.6 a sensor device is known which is integrated into a vehicle seat and comprises magnetic field sensors in a gradiometer arrangement, whereby measurement signals of a person sitting on the vehicle seat are determined in a non-contact manner and cardiogram signals are determined from the measurement signals. Vital functions of the person can be determined from the cardiogram signals, it being further provided that the sensor device is a magnetic field sensor device and that the cardiogram signals are magnetic cardiogram signals (MCG).

Such M KG systems as well as pulse monitoring systems based on other technologies are designed to monitor only a single person or to record their heart signal. Especially when arranging such a sensor device in a mattress, it can happen that the mattress is used by several people at the same time or, for example, that there is a pet on the mattress in addition to the person.

Disclosure of the invention

The present invention is based on the object of providing a method for determining a person's cardiogram signals by means of a sensor device integrated into a support, for example a mattress, which enables precise measurements, even if several people are present on the support.

To solve the problem on which the invention is based, a method for determining magnetic cardiogram signals from one or more people is proposed, with measurement signals from at least one person being determined in a non-contact manner by at least one sensor device integrated into a support, for example a mattress, the measurement signals being transmitted to an evaluation unit , wherein the sensor device is a magnetic field sensor device, and wherein the measurement signals Magnetic cardiogram signals are and wherein the magnetic field sensor device has a plurality of magnetic field sensors, which are arranged as a sensor array in or on the support. According to the invention, it is provided that sensor groups (so-called cells) of, in particular spatially adjacent, magnetic field sensors are formed by evaluating the sensor signals of the individual magnetic field sensors of the sensor array, with a sensor group being assigned to a signal source, i.e. in particular the heart of a person. By separately viewing and further processing the signals from a respective sensor group, different signal sources can be distinguished and thus also different people who are present on the support at the same time during the measurement.

For example, those spatially adjacent magnetic field sensors through which a heart signal is maximally measured can be assigned to a specific sensor group. These are typically the magnetic field sensors that are closest to the person's heart. In this way, the individual signal sources (hearts) can be localized and the individual magnetic cardiogram signals can be derived.

By using a sensor array, the invention thus makes it possible to separate their different heart signals when several people are present so that separate monitoring of the respective cardiac activity of all relevant people can be ensured.

The assignment of the magnetic cardiogram signals to different signal sources, in particular different people, can preferably be done by means of a signal analysis, for example the distance of the detecting magnetic field sensor from the sensor plane and/or characteristic patterns such as amplitude, frequency, etc. of the magnetic cardiogram signals can be taken into account. Artificial intelligence methods can be used particularly advantageously here.

Preferably, a pattern of the magnetic cardiogram signal that is characteristic of a specific person is previously recorded once during a calibration operation. For example, when the edition is put into operation, the A specific person is placed on the support once for a specific period of time to record the pattern and magnetic cardiogram signals are recorded. In this way, a characteristic pattern of the magnetic cardiogram signal can be determined and stored, which can be assigned to a person in the future.

Such pattern recognition can also differentiate between interference signals (e.g. from pets lying on the bed).

From the magnetic cardiogram signals, the evaluation unit can draw conclusions about the fitness and health status of the people on the support. In particular, the evaluation of the magnetic cardiogram signals makes it possible to detect medically relevant cardiac emergencies at an early stage.

Vector information of the magnetic cardiogram signal, in particular one or more components of a magnetic field vector, is preferably determined by means of the magnetic field sensor device. By using vector magnetometry, it is advantageous to record the direction of the signal sources to one another and thus the precise localization (3D image). With a scalar measurement (in which the direction of the measured magnetic field is not taken into account), two hearts at the same distance from a magnetic field sensor in different directions cannot be distinguished. This distinction is made possible by using a sensor array through which the spatial components of the magnetic field vector can be determined.

It is preferably provided that the magnetic field sensor device is a gradiometer with at least two magnetic field sensors arranged at positions spaced apart from one another, the at least two magnetic field sensors measuring a magnetic field at the spaced positions and generating the measurement signal, the magnetic cardiogram signal more preferably as a difference signal of the measurement signals of the at least two Magnetic field sensors are determined. For example, certain magnetic field sensors on the edge (preferably three, one in each spatial direction) can be used as a reference for all magnetic field sensors. Alternatively, it is also possible for each magnetic field sensor to have a specific different one Magnetic field sensor is assigned as a partner to form a gradiometer, so that a sensor array of individual gradiometers results. By using a number of vector magnetometer units in a geometric arrangement and gradiometer interconnection, these magnetometer units have a different orientation to the magnetic field of the heart. The position and strength of the magnetic field exciter (heart) can be determined by the gradiometer connection, ie essentially vector arithmetic of what is measured. Since the much stronger background field is essentially the same in both magnetometer units (same strength and orientation), it can be eliminated. This eliminates the need for magnetic shielding, making magnetic field measurement possible in everyday environments. Another advantage over classic gradiometer arrangements with one-dimensional magnetometers is the compact design this enables, as no distant reference magnetometer is required. The invention is particularly suitable for unshielded measurement of weak magnetic fields.

Technical details of gradiometer solutions that can also be used within the scope of the present invention are disclosed in DE 102022201690.4 and should be included here.

The magnetic fields generated by the heart muscle usually have a strength in the range of 100 pT. These magnetic field strengths are well below typical magnetic field strengths in the environment. The earth's magnetic field strength is approx. 50 pT. By designing the magnetic field sensor device as a gradiometer with two magnetic field sensors arranged at positions spaced apart from one another, these interference fields can be eliminated from the environment. For this purpose, the magnetic field is measured simultaneously with two or more magnetic field sensors. The interference fields from the environment, which have the same field strength at the two positions of the magnetic field sensors, can be eliminated by forming the difference between the measurement signals from the at least two magnetic field sensors. In the difference signal, only the magnetic field generated by the heart remains in the form of the magnetic cardiogram signal, since the magnetic field generated by the heart has a high gradient between the two positions of the magnetic field sensors. The difference signal can be generated directly by the magnetic field sensor device. However, it is also possible for the difference signal to be generated in the evaluation unit, in which case the measurement signals from the magnetic field sensors are transmitted to the evaluation unit.

Such a gradiometer structure makes it possible, in particular, to dispense with complex magnetic shielding during the implementation of the method.

It is preferably provided that the magnetic field sensors are nitrogen defect sensors, with each nitrogen defect sensor preferably comprising a diamond, optical filters and photodetectors, and more preferably a microwave resonator and / or a light source, in particular a laser.

However, the microwave resonator and/or the light source can also be arranged away from the magnetic field sensor device or from the magnetic field sensors.

In principle, it is possible to use TMR, GMR or Hall sensors, SQUID sensors or vapor cell magnetometers to measure the magnetic fields for determining the magnetic cardiogram signals. However, such sensors generally do not have a sufficiently high sensitivity.

Although highly sensitive, superconducting SQUID sensors have sufficient accuracy, they require active cooling with liquid nitrogen or helium and are therefore less suitable for use in a person's bed. Although vapor cell magnetometers have the required sensitivity, they only have a limited dynamic range.

It is therefore preferred that the magnetic field sensors are nitrogen defect sensors. Nitrogen vacancy sensors are based on measuring a fluorescence spectrum of nitrogen centers in a diamond. The spectrum of a diamond with nitrogen vacancies shows fluorescence in the red wavelength range when optically excited. You shine In addition to the optical excitation of microwave radiation, there is a drop in fluorescence at 2.88 GHz, since in this case the electrons move from the m _s = 0 level of the 3A state to the m _s = +/-1 level of the 3E state be lifted and from there recombine non-radiatively or by emitting IR light. In an external magnetic field, the m _s levels split, the so-called Zeeman splitting, and when the fluorescence is plotted against the frequency of the microwave excitation, two dips appear in the fluorescence spectrum, the frequency spacing of which is proportional to the magnetic field strength. The magnetic field sensitivity is defined by the minimally resolvable frequency shift and can reach up to 1 pT. Since the nitrogen vacancy center in single-crystalline diamond has four options for arranging itself in the crystal lattice, in the presence of a directed magnetic field, the nitrogen vacancy centers present in the crystal react to the external magnetic field with different strengths depending on their location in the crystal. As a result, in the maximum case, four associated pairs of fluorescence minima can appear in the spectrum, from whose shape and position relative to each other the amount and direction of the magnetic field can be clearly determined.

The structure and functionality of a nitrogen vacancy sensor are also known to those skilled in the art.

With further advantage it can be provided that the magnetic cardiogram signals of a sensor group are filtered by the evaluation unit with a high pass and/or low pass, and/or that the evaluation unit detects a bias drift of the magnetic field sensors, in particular by averaging the magnetic cardiogram signals over a period of time which is greater than the heart rate is determined.

Filtering using a low pass eliminates noise components with frequencies well above the heart rate. The bias drift can also be subtracted from the high-pass and/or low-pass filtered signal, so that a clean magnetic cardiogram signal is present. Furthermore, it is preferably provided that the evaluation unit uses the magnetic cardiogram signals to determine Vita Iparameter, preferably a heart rate, and/or a heart rate variability, and/or a duration and/or amplitude of ECG-equivalent signal changes, preferably P wave, QRS complex, T wave and corresponding combinations

Preferably, the evaluation unit can determine a vital function and/or the assessment of a vital function of a person using the magnetic cardiogram signals of a specific sensor group. In this way, monitoring of the person's vital function can be ensured, especially if the person is on the support for a longer period of time, such as overnight.

It is preferably provided that further measures are taken on the basis of an assessment of the vital parameters, the further measures including, for example, making an emergency call and/or transmitting the vital functions to medical staff.

The assessment can be provided with a confidence value that reflects the statistical certainty of the classification result or assessment.

According to a further aspect of the invention, a device is proposed which is set up to determine cardiogram signals of one or more people using the method according to the invention. The device comprises a support for people, at least one sensor device integrated into the support, which is designed to determine measurement signals of at least one person in a non-contact manner, the sensor device being a magnetic field sensor device, and the cardiogram signals being magnetic cardiogram signals. The magnetic field sensor device has a plurality of magnetic field sensors, which are arranged as a sensor array in or on the support. The device further comprises an evaluation unit which is designed to generate sensor groups of, in particular spatially adjacent, magnetic field sensors from the magnetic cardiogram signals obtained from the individual magnetic field sensors of the sensor to determine, wherein a sensor group is assigned to a signal source, in particular the heart of a person.

The support for people is designed, for example, as a mattress. Alternatively, the support can be designed as a topper, i.e. a topper, or a lower, i.e. an underlay for a commercially available mattress. Alternatively, the cushion can be designed as a blanket or a pillow or as a piece of clothing.

In a possible embodiment of the invention, several supports with a device according to the invention can be present, for example two mattresses in one bed. In order to reliably ensure that if several people are lying in the bed, cardiogram signals are assigned to the correct person, the sensor arrays of each individual support can be interconnected so that the evaluation unit takes into account all available magnetic field sensors when forming the sensor groups and thus the localization and signal separation can be guaranteed over the entire support surface.

In a preferred embodiment of the invention, the device has one or more additional sensor units, which are designed, for example, as temperature sensors and/or pressure sensors and/or microphones. These additional sensor units can provide additional information about where a person is located on the support through the measurement signals they generate. If nitrogen vacancy sensors are used as magnetic field sensors, the intrinsic temperature sensitivity of such magnetic field sensors can alternatively or additionally be used to determine where and how many people are based on the temperature distribution on the area that spans the sensor array formed by the magnetic field sensors the surface. Breathing sounds can also be recorded using one or more additional microphones and this information can be taken into account during the evaluation and the assignment and localization of the signal sources can be improved.

Short description of the characters Embodiments of the invention will be described in detail with reference to the accompanying figures.

Figure 1 shows a flowchart of a method according to the invention according to an exemplary embodiment of the invention.

Figure 2 shows an example of a bed with a mattress designed according to a possible embodiment of the invention.

Figure 3 shows examples of arrangements of magnetic field sensors as a sensor array for use in a method according to the invention or a device according to the invention.

Preferred embodiments of the invention

In the following description of the exemplary embodiments of the invention, the same elements are referred to with the same reference numerals, with a repeated description of these elements being omitted if necessary. The figures represent the subject matter of the invention only schematically.

Fig. 1 shows the sequence of a method 100 for determining magnetic cardiogram signals of one or more people. In the first step 110, measurement signals of at least one person are determined in a non-contact manner by a sensor device integrated in a support, in particular in a mattress, the sensor device being a magnetic field sensor device , which has a plurality of magnetic field sensors, which are arranged as a sensor array in or on the support and where the measurement signals are magnetic cardiogram signals. In step 120, the measurement signals are transmitted to an evaluation unit. In step 130, sensor groups of spatially adjacent magnetic field sensors are determined by evaluating the magnetic cardiogram signals of the individual magnetic field sensors of the sensor array by the evaluation unit. In step 140, they are previously assigned to specific sensor groups with a signal source, in particular the heart of a person. In step 150, a separate evaluation is now carried out person-specific magnetic cardiogram signals from each sensor group. In step 160, the person-specific magnetic cardiogram signals are subjected to pattern recognition and thus assigned to specific people.

Fig. 2 shows two examples of the arrangement of a device designed according to the invention in a mattress.

A bed 10 is shown in FIG. 2a). The bed has a mattress 12 to support people. Integrated into the mattress 12 are two magnetic field sensor devices 3, each of which has a plurality of magnetic field sensors. In this example, two magnetic field sensor devices 3 are arranged along the longitudinal axis of the mattress in such a way that a person 1 who sleeps on the mattress comes to rest with his heart in the area of at least one of the magnetic field sensor devices 3. Furthermore, the magnetic field sensor devices 3 are arranged near the surface or on the surface of the mattress 12 in order to ensure the smallest possible distance from the heart of the person 1.

The arrangement according to Fig. 2b) essentially corresponds to the arrangement from Fig. 2a) with the difference that an additional magnetic field sensor device 3 'is arranged at a deeper point on the mattress (approximately the underside of the mattress 12. This arrangement offers the additional advantage Detect interference fields better and take them into account when measuring the magnetic cardiogram signals.

3 shows examples of possible arrangements of the individual magnetic field sensors 4 of a magnetic field sensor device 3. Fig. 3 a) shows a linear sensor array of a total of ten magnetic field sensors 4, which are arranged in a row, for example transversely to the longitudinal axis of the mattress 12 of Fig. 2. In the example shown, there are two people and a pet on the mattress , in which the magnetic field sensor device 3 is arranged. The first person's heart 6a is approximately between the magnetic field sensors 4a and 4b, the second person's heart 6b is approximately at the position of the magnetic field sensor 4d, the pet's heart 6c is approximately between the magnetic field sensors 4f and 4g. By evaluating the magnetic cardiogram signals from the individual magnetic field sensors 4 of the sensor array through an evaluation unit (not shown), three sensor groups 5a, 5b and 5c can now be determined. For this purpose, those magnetic field sensors 4 arranged adjacent to one another are combined into a sensor group, which deliver a measurement signal above a certain threshold value. In the present example according to FIG. 3 a), the magnetic field sensors 4a and 4b are determined to belong to a first sensor group 5a, with the sensor group 5a being assigned to the heart 6a of the first person as a signal source. The magnetic field sensors 4c, 4d and 4e are determined to belong to a second sensor group 5b, with the sensor group 5b being assigned to the heart 6b of the second person as a signal source. The magnetic field sensors 4f and 4g are determined to belong to a third sensor group 5c, with the sensor group 5c being assigned to the heart 6c of the pet as a signal source. The distinction as to whether the signal source is the heart of a person or a pet can be derived, for example, by means of pattern recognition from the magnetic cardiogram signals of the respective sensor group 5a, 5b, 5c. For example, a dog typically has a much faster heart rate than a human.

Fig. 3 b) shows a magnetic field sensor device 3 comprising a two-dimensional sensor array with five rows of ten magnetic field sensors 4, which are arranged alternately offset from one another, for example along the support surface of the mattress 12 of Fig. 2. Such a two-dimensional arrangement offers an improved Accuracy of localizing a signal source. In the example shown, there are again two people and a pet on the mattress in which the magnetic field sensor device 3 is arranged. By evaluating the magnetic cardiogram signals from the individual magnetic field sensors 4 of the sensor array by an evaluation unit (not shown), three sensor groups 5d, 5e and 5f can in turn be determined. For this purpose, those magnetic field sensors 4 arranged adjacent to one another are combined to form a sensor group, which deliver a measurement signal above a certain threshold value. In the present example according to FIG. 3 b), a first sensor group 5d is determined, which is assigned to the heart 6d of the first person as a signal source. A second sensor group 5e is determined, which is assigned to the heart 6e of the second person as a signal source. One Third sensor group 5f is determined, which is assigned to the heart 6f of the pet as a signal source.

In a linear sensor array as in Fig. 3a), two to three magnetic field sensors 4 contribute to a sensor group. In a two-dimensional

In the triangular arrangement shown in FIG. 3 b), the sensor array consists of between three and five magnetic field sensors 4 that contribute to a sensor group. In other arrangements, a sensor group always has to take into account the magnetic field sensors connected to the signal source, i.e. in particular to the heart, which deliver an even more significant measurement signal, in particular a measurement signal that is above the measurement noise and is stronger than the measurement signal from a more distant signal source.

Claims

Expectations

1. Method (100) for determining magnetic cardiogram signals of one or more people (1), wherein measurement signals of at least one person are determined contactlessly by at least one sensor device integrated in a support, in particular in a mattress (12), the measurement signals being sent to an evaluation unit are transmitted, the sensor device being a magnetic field sensor device (3), the measurement signals being magnetic cardiogram signals and the magnetic field sensor device (3) having a plurality of magnetic field sensors (4) which are arranged as a sensor array in or on the support, characterized in that that by evaluating the magnetic cardiogram signals of the individual magnetic field sensors (4) of the sensor array by the evaluation unit, sensor groups (5) of in particular spatially adjacent magnetic field sensors (4) are determined, with a sensor group (5) of a signal source, in particular the heart (6). Person (1) is assigned.

2. Method (100) according to claim 1, characterized in that the magnetic field sensor device (14) is a gradiometer with at least two magnetic field sensors (4) arranged at positions spaced apart from one another, the at least two magnetic field sensors (4) measuring a magnetic field at the positions spaced apart from one another and generate the measurement signals, wherein a magnetic cardiogram signal is preferably determined as a difference signal of the measurement signals of the at least two magnetic field sensors (4).

3. Method (100) according to claim 1 or 2, characterized in that the sensor array has a plurality of magnetic field sensors (4) which are linear are arranged or are arranged in the form of a gate or in a circle. Method (100) according to one of the preceding claims, characterized in that vector information of the magnetic cardiogram signal is determined by means of the magnetic field sensor device (3), in particular one or more components of a magnetic field vector. Method (100) according to one of the preceding claims, characterized in that the magnetic field sensors (4) are nitrogen defect sensors, each nitrogen defect sensor preferably comprising a diamond, optical filters and photodetectors, and more preferably a microwave resonator and/or a light source, in particular a laser. Method (100) according to one of the preceding claims, characterized in that the magnetic cardiogram signals of the individual magnetic field sensors (4) are filtered by the evaluation unit with a high pass and/or low pass, and/or that the evaluation unit detects a bias drift of the magnetic field sensors, in particular an averaging of the magnetic cardiogram signals from the individual magnetic field sensors (4) is determined over a period of time that is greater than the heart rate. Method (100) according to one of the preceding claims, characterized in that the evaluation unit (19) uses the magnetic cardiogram signals of a specific sensor group (5) to determine vital parameters, preferably a heart rate, and/or a

Heart rate variability, and/or a duration and/or amplitude of E KG equivalent signal changes, preferably P wave, QRS complex, T wave and corresponding combinations, are determined, which are assigned to a specific person (1), in particular based on the signal source become. Method (100) according to one of the preceding claims, characterized in that the magnetic cardiogram signals are one Sensor group (5) and/or vital parameters derived therefrom are compared with a profile database in order to identify a specific person (1) as a signal source, the profile database having previously been created or updated by at least one calibration measurement. Method (100) according to one of the preceding claims, characterized in that the assignment of a sensor group (5) to a specific signal source, in particular the heart (6) of a specific person, takes place by means of pattern recognition of the magnetic cardiogram signals, which is based in particular on artificial intelligence and / or machine learning based. Device, set up for determining magnetic cardiogram signals of one or more people, according to a method (100) according to one of claims 1 to 9, comprising at least one sensor device integrated into a support, which is designed to determine measurement signals of at least one person (1) in a non-contact manner , wherein the sensor device is a magnetic field sensor device (3), and the measurement signals are magnetic cardiogram signals, wherein the magnetic field sensor device (3) has a plurality of magnetic field sensors (4), which are arranged as a sensor array in or on the support, further comprising an evaluation unit, which is designed to determine sensor groups (5) of, in particular, spatially adjacent magnetic field sensors (4) by evaluating the magnetic cardiogram signals of the individual magnetic field sensors (4), wherein a sensor group (5) is assigned to a signal source, in particular the heart (6) of a person is. Device according to claim 10, characterized in that the magnetic field sensor device (3) is arranged in a mattress (12). Device according to one of claims 10 or 11, characterized in that the device has at least one additional Has sensor unit, which is designed in particular as a pressure sensor and / or temperature sensor and / or as a microphone.