WO2008131468A1

WO2008131468A1 - System for the mobile detection and processing of vital signs of humans and/or animals

Info

Publication number: WO2008131468A1
Application number: PCT/AT2008/000147
Authority: WO
Inventors: Martin Neubauer
Original assignee: Martin Neubauer
Priority date: 2007-04-26
Filing date: 2008-04-23
Publication date: 2008-11-06
Also published as: AT10035U1

Abstract

The invention relates to a measuring and processing system (1) for the mobile detection of vital signs (V) of humans and/or animals, comprising a pulse meter having at least two pulse detection units (2A, 2B) for detecting pulses and one processor (8) for determining the pulse frequency from output signals (P1, P2) representative of the pulse frequency of the pulse detection unit. Each pulse detection unit (2A, 2B) has one optoelectronic transmitter (3A, 3B) for radiating light beams onto an appropriate, radiation-reflecting body part that is moving with the pulse frequency, and one optoelectronic receiver (4A, 4B) for receiving light beams emitted by the transmitter and reflected by the body part. The pulse detection units (2A, 2B) are disposed at a distance from each other. The processor (8) evaluates the output signals (P1, P2) of the pulse detection units independently of each other and uses the most distinct output signal, or evaluates the amplitude, as pulse signal.

Description

System for mobile recording and processing of vital signs to humans and / or

animals

The invention relates to a measuring and processing system for mobile detection and processing of vital signs on humans and / or animals, wherein the recorded vital signs include the pulse rate, the skin conductance, the skin temperature, the muscle tension, etc.

There are so-called "heart rate monitors" known, these are watches worn on the wrist, on whose display you can read your own pulse rate.Also, these watches usually also provide a normal time measurement function (time, stopwatch) and other useful functions (eg alarm function) These watches are primarily used in sports where they allow for pulse-controlled training, but the two types of heart rate monitors that are currently available on the market and are very useful wristwatches have the following disadvantages:

a) In the pulse rate continuously displaying pulse watches a chest belt is required, which has a pulse sensor and a transmitter that wirelessly transmits the signals generated by the pulse sensor to a, built in the wrist-worn clock receiver to display the pulse rate on the clock display , The chest belt is often felt during exercise as disturbing.

b) In the other type of heart rate monitors, although no chest belt is required, however, a continuous display of the pulse rate is not possible here. In order to obtain an indication of the pulse rate, the person wearing the heart rate monitor on a wrist must place fingers of the other hand on certain contacts of the heart rate monitor for a short time, which usually necessitates the interruption of a sports activity or is at least very cumbersome and therefore annoying ,

Both known types of heart rate monitors measure according to the ECG principle, the electrical potential changes of the heart muscle, which occur in the heart action per heartbeat.

From US 5,807,267 a heart rate monitor is known, which corresponds in shape to that of the above-mentioned worn on the wrist watches. However, the signal recording to determine the heart rate does not follow the ECG principle, but by a Detection unit for the registration of the pulses, which consists in principle of 3 elements: a) a light emitting diode, b) a photodiode and c) an electronic circuit for evaluating the output signals of the photodiode. The light-emitting diode and the photodiode are attached to the inside of the bracelet of the heart rate monitor at a certain location close to each other. By way of reflection of the light pulse emitted by the light-emitting diode, the pulse wave is detected and its frequency is measured by the electronic circuit and displayed on a display of the heart rate monitor.

Although this pulse meter has proven itself in principle, so it has a disadvantage in that the reliability of the measurements is very much dependent on a specific arrangement and orientation of the bracelet of the heart rate monitor. Slight displacements of the bracelet can already lead to the detection unit coming to rest at a point on the arm where no or at least no reliable pulse measurement is possible.

There is therefore still a need for a measuring system for the mobile recording of vital signs on humans and / or animals, which is designed so that it can be used by anyone and everywhere without the help of professionals. In particular, such a measurement system should be capable of treating diseases and disorders, increasing concentration, inducing relaxation, etc., using techniques known from medicine and biofeedback.

The present invention solves this problem by providing a measuring system for the mobile acquisition of vital signs to humans according to the characterizing features dc3 claim 1; advantageous embodiments of the invention are set forth in the subclaims.

The measuring and processing system according to the invention makes it possible for the user in a simple manner without auxiliary means known from the prior art, e.g. Contact gel to measure and process the vital signs, either presented on the measuring and processing system or wirelessly transmitted to a computer or mobile phone and displayed there, or transmitted further, or processed using biofeedback methods in exercise programs or games can.

The measuring and processing system according to the invention for the mobile acquisition of vital signs on humans and / or animals comprises a heart rate monitor which has at least two Pulse detection units for the detection of heartbeats and a processor for determining the pulse rate and optionally the heart rate variability from representative of the pulse rate output signals of the pulse detection units. Each pulse detection unit comprises an opto-electronic transmitter for emitting light rays to a suitable radiation-reflecting body location moving at the pulse rate by the pulse beat, and an optoelectronic receiver for receiving the light rays emitted by the transmitter and reflected from the body location. The pulse detection units are arranged next to each other at a distance from one another, and the processor independently evaluates the output signals of the pulse detection units, selecting the most pronounced output signal, eg evaluated according to the amplitude, and using it as a pulse signal. With this configuration, it is possible to reliably perform pulse measurements even without accurate positioning of the pulse detection units.

In a further embodiment of the invention, at least one conductivity sensor communicating with the processor is provided. Similarly, at least one temperature sensor communicating with the processor is also provided. Through these sensors, the recorded vital signs are supplemented by the electrical conductivity of the skin or the skin temperature. The measured electrical conductivity of the skin and the skin temperature are used in a further embodiment of the invention for a plausibility check of the measured values of the pulse beat, in that the processor is provided with comparison means for comparing the recorded vital signs with predefined value ranges, wherein the recorded vital signs outside the predefined value ranges, the processor gives a message.

In a particularly preferred embodiment of the measuring system according to the invention, the pulse detection units and optionally the conductivity sensor and / or the temperature sensor are arranged on a support which can be brought into easy contact with the body location at which the measurements are to be performed. According to the invention, the carrier is formed for example as a bracelet or cuff, or has a support surface for placing a body part. The support surface may be, for example, the surface of a ball on which the user hangs up a hand for measurement.

In a further embodiment, the measuring and processing system according to the invention has an acceleration sensor communicating with the processor for detecting movements of a body part, while on this body part a Measurement to record vital signs is performed. If a predefined acceleration threshold value in the X, Y or Z direction is exceeded, the processor excludes the acquired measured values from the processing for a predefined period of time, as a result of which any erroneous measurements caused by the movement are not included in the result. It is further provided that the processor terminates the vital-value detection during a renewed exceeding of the acceleration threshold value during the predefined period of time in order reliably to preclude erroneous measurements.

In a preferred embodiment, the measuring system according to the invention comprises a radio signal transmitter or radio signal transceiver, via which the processor sends the recorded vital signs and, if necessary, messages to a mobile telephone or a computer or a data transmission network, where they are displayed or further processed.

In a further embodiment of the invention, the processor calculates the heart rate variability from the detected pulse frequency and sends a warning signal when it falls below a defined threshold value of the heart rate variability, preferably together with historical measurement data. The warning signal and / or the historical measurement data are preferably transmitted to an emergency center 14, as too low a heart rate variability may be an indication of impending heart attack.

The invention will now be explained in more detail on the basis of a non-limiting exemplary embodiment with reference to the single drawing, which represents a diagrammatic block diagram of the measuring system according to the invention.

The measuring and processing system 1 according to the invention for the mobile detection and processing of vital signs on humans and / or animals comprises a heart rate monitor which has a plurality of, but at least two pulse detection units 2A, 2B for the detection of heartbeats, which are representative of the pulse rate Output signals Pl, P2 deliver. Each pulse detection unit 2A,... R has an optoelectronic transmitter 3A, 3B, eg a light emitting diode, for emitting light beams to a suitable radiation-reflecting body point, the reflectance of which moves with the pulse frequency, and an optoelectronic receiver 4A, 4B, eg Photodiode or a phototransistor, for receiving the radiated from the transmitter 3A, 3B and reflected from the body site light rays. The pulse detection units 2A, 2B are arranged side by side in a suitable pattern spaced apart from each other. The output signals P 1, P 2 of the pulse detection units 2 A, 2 B are fed to a processor 8 which determines the pulse rate therefrom by the processor 8 evaluating the output signals P 1, P 2 independently of each other and determining the most pronounced output signal, eg according to the Amplitude, selects and uses as a pulse signal.

Furthermore, at least one conductivity sensor 5 for detecting conductivity signals S of the electrical conductivity of the skin and at least one temperature sensor 6 for detecting temperature signals T of the skin temperature of the user are connected to the processor 8.

A three-dimensionally acting acceleration sensor 7 transmits acceleration signals A to the processor 8, with which movements of the body part on which the measurements are taken during the detection of the vital signs are detected. Exceed the acceleration signals A a predetermined

Acceleration threshold value, the processor 8 does not consider measured vital values during processing for a predefined period of time. If further exceedances of the acceleration threshold value occur within the predefined time period, the processor 8 aborts the vital-value detection.

The pulse detection units 2A, 2B, the conductivity sensor 5, the temperature sensor 6 and the acceleration sensor 7 and optionally the processor 8 are arranged on a support 10, which is e.g. is formed as a bracelet or cuff or has a support surface for placing a body part and, for. is designed as a spherical surface.

In order to detect incorrect measurements or manipulations, the processor 8 has comparison means 8A which compare the recorded vital signs (pulse frequency, skin conductance, skin temperature) with predefined value ranges. If the detected vital signs are outside the predefined value ranges, the processor 8 issues a message. This message is as well as the rest also generally the vital signs determined via a radio signal transmitter 9 or radio signal transceiver to a receiving device 1 1, which has a radio signal receiver 12, transmitted for further processing or visual representation. The receiving device 11 is, for example, a mobile telephone, a computer or a data transmission network 13, to which authorized data processing devices can access. In the processor and in the receiving device 11, the received vital signs V are further processed, for example, by means of programs which, by means of graphic processing of the vital signs, etc., help to treat illnesses and disorders with the aid of methods known from medicine and biofeedback, to increase concentration, to induce relaxation. to train etc.

With the aid of the measuring and processing system 1 according to the invention, the heart rate variability critical for high-risk patients can also be monitored. This is calculated by the processor 8 from the detected pulse rate. When falling below a defined threshold value of the heart rate variability, the processor sends a warning signal W, preferably together with historical measurement data H of the vital signs V, in particular the historical pulse data, via the radio signal transmitter 9 and the receiving device 1 1 to an emergency call center.

By the term "vital signs" are meant the physical condition of a human or animal describing measured values, such as the pulse rate, the skin conductance, the skin temperature, the muscle tension, etc.

Claims

Claims:

1. measuring and processing system (1) for mobile detection and processing of vital signs (V) to humans and / or animals, with a heart rate monitor, characterized by at least two pulse detection units (2A, 2B) for the detection of heartbeats and a processor (8) for determining the pulse rate from pulse rate representative output signals (P1, P2) of the pulse detection units, each pulse detection unit (2A, 2B) comprising an optoelectronic transmitter (3A, 3B) for radiating light beams to a suitable radiation reflecting one Body site moving at the pulse rate and having an opto-electronic receiver (4A, 4B) for receiving the light beams emitted by the transmitter and reflected from the body site, the pulse detection units (2A, 2B) being spaced apart from each other and the processor ( 8) evaluate the output signals (P1, P2) of the pulse detection units independently and the strongest distinct output, e.g. evaluated according to the amplitude, selects and uses as a pulse signal.

2. Measuring and processing system according to claim 1, characterized by at least one communicating with the processor conductivity sensor (5) for detecting the electrical conductivity (S) of the skin.

3. Measuring and processing system according to claim 1 or 2, characterized by at least one communicating with the processor temperature sensor (6) for detecting the skin temperature (T).

¹ I. measuring and processing system according to any one of the preceding claims, characterized by a communicating with the processor acceleration sensor (7) for detecting movements (A) of a body part, while on this body part, a measurement for detecting vital signs is performed.

5. measuring and processing system according to claim 4, characterized in that the processor (8) when a predetermined acceleration threshold value detected measured values for a predefined period of time does not include in the processing, and preferably at a renewed exceeding the acceleration threshold within the predefined period of time, the Vital value acquisition terminates.

6. measuring and processing system according to any one of the preceding claims, characterized in that the processor (8) comparison means (8A) for comparing the detected Vital signs having predefined value ranges, wherein, if the recorded vital signs are outside the predefined value ranges, the processor gives a message.

7. Measuring and processing system according to one of the preceding claims, characterized by a radio signal transmitter (9) or radio signal transceiver, via which the processor (8) the recorded vital signs (V) and optionally messages (W) to a receiving device (1 1), as a mobile phone or a computer, or a data transmission network (13) sends.

8. measuring and processing system according to any one of the preceding claims, characterized in that the pulse detection units (2A, 2B) and optionally the conductivity sensor (5) and / or the temperature sensor (6) and optionally the processor (8) on a support (10) are arranged.

9. measuring and processing system according to claim 8, characterized in that the carrier (10) is designed as a bracelet or cuff.

10. measuring and processing system according to claim 8, characterized in that the carrier (10) has a support surface for placing a body part.

1 1. Measuring and processing system according to one of the preceding claims, characterized in that the processor (8) from the detected Piäsfrequenz calculates the heart rate variability and falls below a defined threshold of heart rate variability a warning signal (W), preferably together with historical measurement data (H ) sends