EP0849716A2 - Method and device for monitoringendangered persons by means of automatic alerting - Google Patents

Abstract

The monitoring system uses detection of vital parameters, body movements and the location of the monitored person for automatic initiation of an alarm call, for requesting assistance. The measured parameters are converted into corresponding electrical signals (115) fed to a signal processor (4), which is coupled to a communication device (2) for communication with the monitored person and which provides data for an input/output device (8), coupled to external sensors (3.1) and external components (9).

Description

The invention relates to methods and devices for detection and processing of vital parameters, body movements and body position of monitored, endangered persons in emergency and Risk situations, in the event of accidents and the like, as well for automatic alarming.

Telephone emergency call systems [TeleAlarm from Telectronic, Carouge (CH)] with the following mode of operation are known: Endangered persons carry a small device with an alarm button and a built-in radio transmitter on them. The associated receiver is located in a nearby, specially equipped telephone device. After the alarm has been triggered manually, help is automatically requested via the telephone network.
A crucial disadvantage of these systems is that the alarm must be triggered by the accident or endangered person. Affected persons are often unable to do so due to injuries, fainting, panic or mental confusion. Monitoring by recording and evaluating vital parameters and body movements, as well as a location system for quickly finding the person are not available.

Personal protection systems [DiriCALL from Nira, Brüttisellen (CH); telePROTECT from Ascom, Dübendorf (CH)] with the following functionality: Vulnerable people carry a small device with an alarm button and a built-in radio transmitter. An alarm is triggered in the following situations:
The person presses an alarm button or the device remains in a rest position [DiriCALL] for a long time or is in a horizontal position [telePROTECT]. Alarms are transmitted to a central alarm point via radio. There it is possible to display the location from where the alarm was triggered on a screen.
A crucial disadvantage of these systems is that they require a home control center and therefore only have a limited range of action within a building and its immediate surroundings. In addition, the above-mentioned criteria for monitoring automatic alarms in emergency situations in daily, permanent use are insufficient. Monitoring by recording and evaluating vital parameters and body movements is not available.

PS-WO 93/16638 describes a method and a device in which a monitoring device worn on the wrist contains sensors for detecting physical parameters such as activity and temperature and / or electrical conductivity of a person's skin. An alarm is triggered either automatically upon detection of abnormal parameter states or by pressing a button and sent to one or more receivers via radio transmitters, which set a local alarm or forward the data via existing systems to a central alarm point.
A disadvantage of this system is that the sensors described above and their arrangement cannot be used to make a reliable statement regarding the condition of a person being monitored and whether he is in an emergency situation and help must be requested. Using the activity sensor on the wrist, for example, no statement can be made regarding the total body movements and position, such as when the person being monitored falls. The ability to monitor breathing, heart activity and blood pressure with the sensors used is also not available. In addition, there is no facility for locating the monitored person, which means that it is not possible to find the monitored person quickly in an emergency situation.

PS-WO 94/10902 describes a method and a device which monitors physiological parameters such as breathing and / or cardiac activity by means of ECG information. When irregularities are detected, an alarm is transmitted via radio to a local help center and can be forwarded from there, for example, to a pager.
A disadvantage of this system is that its use is only intended for hospitals and homes and requires an appropriate infrastructure with a central office. Furthermore, only physiological parameters such as breathing and heart activity and not body movements and posture are monitored, which means that the fall, one of the most common emergency situations and accident events, is not recognized. A manual alarm trigger is also not possible. In addition, there is no facility for locating the monitored person, which means that it is not possible to find the monitored person quickly in an emergency situation.

PS-DE-A1-3830655 describes a method and a device for a personal protection device with automatic and manual emergency alarm. A series of sensors permanently installed in the living room, which are suitable for detecting movements in the room, switching on the lighting, loading furniture and certain noises, signal the utterance of life, the lack of which during the day and night triggers the emergency call.
The disadvantage of this system is that all sensors are permanently installed in the room to be monitored and connected to a central unit via cable. This requires a complex installation and only one room can be monitored. It is not possible to assess the condition of the monitored person based on the signals from a motion detector. Monitoring and recording of vital parameters is not available. In addition, the monitored person has to give signs of life over and over again in certain periods of time. Furthermore, the possibility of triggering an alarm by means of noise or knocking is very susceptible to errors.

The object of the present invention is methods and devices indicate with which various vital parameters and the Location recorded centrally and decentrally with sensors and one Alarm information can be processed. This includes information about Movement, fall and location and will trigger an automatic alarm fed.

Fig. 1

Erste schematische Darstellung des Verfahrens

Fig. 2

Zweite detailliertere, schematische Darstellung des Verfahrens

Fig. 3

Schematische Darstellung eines ersten Ausführungsbeispiels

Fig. 4

Schematische Darstellung eines zweiten Ausführungsbeispiels als Sturzdetektor mit lokaler Ortung

According to the invention, this object is achieved with methods according to the wording of claims 1-14 and devices according to the wording of claims 15-20. Show it:

Fig. 1

First schematic representation of the process

Fig. 2

Second more detailed, schematic representation of the process

Fig. 3

Schematic representation of a first embodiment

Fig. 4

Schematic representation of a second embodiment as a fall detector with localization

1 shows a schematic representation of a method for a portable personal surveillance system, vital signs and Body movements recorded by persons to be monitored, evaluated, records and in emergency and risk situations and at Accident events automatically trigger an alarm.

A central unit (1), which the person to be monitored carries, includes means for detection (3), means for signal processing (4), means for communication (2) and an input / output unit (8th). First electrical signals (115) lead from the detection means (3) to the signal processing means (4). Second electrical signals (114) connect the means for signal processing (4) with the means for communication (2). Data (116) connect the means for signal processing (4) the input / output unit (8). The input / output unit (8) is bidirectional with the external components (9) via data (118) connected. The input / output unit (8) is with the external Sensors (3.1) connected via third signals (117).

The functions are described in a first general form to go into more detail later.

Attach and measure:

The means for detection (3) are sensors, such as Acceleration sensors and the like, which body movements and vital parameters can capture. In the simplest case there is only one Sensor, e.g. an acceleration sensor in front; in general but it is a variety of different sensors.

If the means for detection (3) are in the central unit (1) , these are referred to as so-called 'central recording'; if the means of detection (3) are external sensors (3.1), these are referred to as 'decentralized registration' designated. Both in the central and in the decentralized The sensors on the person to be monitored are recorded appropriate. For example, sensors (3) are part of the Central unit (1), with this e.g. attached to a shoulder strap, or the external sensors (3.1) e.g. on the wrist with attached to a bracelet or implanted.

Convert measurands:

The measured variables are converted into the first electrical signals (115) in the sensors (3) and are available as outputs of the sensors (3).
In the external sensors (3.1), the measured variables are converted to the third signals (117) and are available as outputs of the sensors (3.1).

Feed (I):

This includes all signals that are fed to the signal processing (4) as inputs. These are: the first electrical signals (115), the fourth electrical signals (102) and the third signals (117).
The signals (115) and (117) are supplied via a wire connection. The signals (117) are only supplied in exceptional cases via a wire connection; generally it is wireless, for which the external sensors (3.1) are equipped with a radio interface and are referred to as 'intelligent sensors'. This wireless connection leads to the output unit (8), which in turn is also equipped with a radio interface via which the sensor signals for signal processing (4) are carried as data (116).

Connect :

The means for signal processing (4) are bidirectionally connected to the means for communication (2) via the second electrical signals (114). Control signals, in particular alarm signals, are fed to the signal processing via the means for communication (2); on the other hand, status signals which have been processed in the signal processing are optically made known to the means for communication (2), for example a display, of the monitored person. This can also be done acoustically.
This results in a dialogue system with a possibility of dialogue between the person to be monitored and an expert system, which will be described later.

Process data (116) :

In the signal processing (4), the supplied signals 115 and 117 worked up with various methods, which will be described in detail later.

Feed (II) :

Outputs of the signal processing (4) are the data (116) be guided bidirectionally to the input / output unit (8). Essentially, the data (118) is in the input / output unit (8) performed on different interfaces.

Keep data (118) ready:

In the input / output unit (8), the data (118) become ready for further use: be it via interfaces to be available to the external components (9). On the one hand, this enables data access via an external Computer, otherwise the transmission of data (118), or Parts of it, to an alarm unit and / or to a local one Location system, as will be described in more detail later.

When an emergency situation or an emerging one is identified Endangerment of the monitored person, the state of danger checked for plausibility and, if necessary, the device set in an alarm status. You can choose between different Different stages of alarm depending on the degree of danger and emergency situation will. The monitored person can also be active in decision making be included. If the assessment of the recorded sizes suggests an emergency situation, this but actually not, the monitored person can clear the alarm status for a predetermined time to prevent a false alarm. Found during this predetermined No acknowledgment on the part of the monitored person instead, an alarm of an alarm unit is triggered via an interface forwarded, resp. fed into a public network or transmitted to a central office. Of course, the monitored one Person also through their own work through the means of communication (2) trigger the alarm. With the alarm, the triggering cause and optionally the location of the monitored Person submitted. This has the advantage of providing help accordingly the cause can occur and the monitored person immediately Is found.

2 shows a second, more detailed, schematic illustration of the method.
The central unit (1), the means for detection (3), the means for communication (2), the input / output unit (8) and the external sensors (3.1) correspond to FIG. 1.
The means for signal processing (4) are divided here into a signal conditioning (4.10), a processor (4.20) with an expert system (4.21) and a signal evaluation (4.22) and an information memory (4.30).
The input / output unit (8) is divided into a radio interface (8.1) and a serial interface (8.2).
The external components here are a local positioning system (9.1), an alarm unit (9.2) and a computer (9.3).
First electrical signals (115) lead from the means for detection (3) to signal conditioning (4.10), the output signal (105) of which is fed to the signal evaluation (4.22).
Second electrical signals (114) connect the expert system (4.21) with the means for communication (2).
The external sensors (3.1) are connected to the radio interface (8.1) via third signals (117), which are transmitted wirelessly.
The data (116) of FIG. 1 are here divided into three different data lines; connect it:
The radio interface (8.1) via data line (107) the signal evaluation (4.22), the radio interface (8.1) via data line (103) the expert system (4.21) and the serial interface (8.2) via data line (113) the expert system (4.21).
The data (118) of FIG. 1 are here divided into three different data lines; connect it:
The radio interface (8.1) via data line (111) the local location system (9.1) and the alarm unit (9.2) and the serial interface (8.2) via data line (112) the external computer (9.3).
Fourth electrical signals (102) from the external location system (4.40) and data (108) from the signal evaluation (4.22) are also fed to the expert system (4.21).
Furthermore, the information store (4.30) connects the expert system (4.21) via data (109).

The functions of signal processing, the input / output unit and the external components are detailed below described.

The signals from the internal sensors (3) are processed via signal conditioning (4.10) so that they can be processed in the processor (4.20). The signals from the external sensors (3.1) are already processed decentrally and transmitted via radio to the radio interface (8.1) of the central unit (1), and there directly to the processor (4.20) or via the data line (107) of the signal evaluation (4.22) fed. In the signal evaluation (4.22), the sensor data (115, 105; 117, 107) are processed using various methods such as statistics, threshold value detectors, digital filtering, fast Fourier transformation and correlation functions. The data (108) processed in this way are fed to an expert system (4.21) based on fuzzy logic, which assesses the condition of the person being monitored using links between the data from different sensors (3, 3.1). Depending on the sensor data (115, 105; 117, 107) that has arrived, the evaluation algorithms include the subsequent measurement values in the evaluation in order to be able to better assess the event. If, for example, a fall of the monitored person is determined, the expert system waits for the coming measured values and determines whether the monitored person gets up again or not. In addition, the monitored person can be actively involved in the decision-making function by querying the monitored person about their condition in unclear situations. Not only current sensor data but also previous sensor data (previous history) are included in the assessment in order to determine trends that could endanger the monitored person. If trends are identified that could endanger the person being monitored, such as rapid breathing and a lack of physical activity, early warnings are given to the person to be monitored so that they can take appropriate countermeasures. A further assessment of the sensor data is made by comparing the current patterns that result from the recorded sensor data and with different patterns that are already stored in the information memory (4.30) and are typical for certain situations. such as for the fall behavior.
The method has adaptive properties in that the expert system (4.21) is equipped with a neural network that learns from the behavior of the person being monitored and adapts the expert system accordingly or optimizes it itself. With a computer (9.3) and appropriate software, the expert knowledge can also be adapted from outside via a serial interface (8.2) to the person being monitored. In order to improve the assessment of the condition of the monitored person, their whereabouts can also be consulted. For example, different assessment criteria apply to the bedroom than to the basement. A system (9.1), which is available on the market and with which communication can take place via a radio interface (8.1), is used for local location of the monitored person in buildings and their immediate surroundings. A positioning system (4.40) based on the 'Global Positioning System' or the like is used for global positioning outside of buildings. The data continuously stored in the information memory (4.30) can be read via a serial interface (8.2) with a computer (9.3) and appropriate software and used for diagnosis, therapy, training and prevention.

Fig. 3 shows a schematic representation of a first embodiment to the procedure described. The central unit points a separation into a registration unit (1.1) and an evaluation unit (1.2). The means of communication (2), the means for detection (3), the external sensors (3.1) with third electrical signals (117), signal processing (4) and external components (9) correspond to those described in FIG. 1. The means of communication (2) are here via second ones electrical signals (120) with an interface (8.3) bidirectional connected. The external components (9) are about data (123) bidirectionally connected to an interface (8.4), which in turn uses signal processing (4) via data (122) connected is.

The measurement variables are recorded via the sensors (3) with the first electrical signals (115) in the same way as in the previously described method.
The sensors or external sensors (3.1) for detecting body movements, body position, breathing, cardiac activity and blood pressure and the like are provided as means for recording measured variables (3). Some of the sensors (3) are located in the central unit (1), which the monitored person carries on them, such as sensors for detecting body movements and body position, and / or are partially attached to the body of the monitored person, such as sensors to record breathing, heart activity and blood pressure.
A wireless connection for the continuous transmission of the measurement data (117) to the central unit (1), or the acquisition unit (1.1), is provided for the measurement quantities detected by the external sensors (3.1).

However, the data (115, 117) are not evaluated in the registration unit (1.1) which the monitored person carries on them, but via an intelligent interface (8.3) via an integrated radio transmitter from the registration unit (1.1) to an evaluation unit (1.2) with a radio receiver located in an intelligent interface (8.4), transmitted as data (121). The evaluation unit (1.2) is located in the vicinity, for example in the living areas in old people's homes, and can be connected to the mains for power supply. The means for signal processing, which are provided for processing the data (122), are arranged in the evaluation unit (1.2).
The means for communication (2) are designed as operating and display elements. Means for triggering the alarm are available for operating the device, which can be intervened by the monitored person's own active action, such as resetting the alarm status. The various device stages can be displayed optically and / or acoustically. This results in the device being able to communicate.
The intelligent interface (8.3) has the task of processing the sensor signals so that they can be transmitted to the intelligent interface (8.4) by radio using the asynchronous start / stop bit method with an error detection code. The data (121) are transmitted with frequency modulation, since the susceptibility to interference is smaller than with amplitude modulation. In the evaluation unit (1.2), the data (121) is decoded again in the intelligent interface (8.4), checked for errors, and the data is requested again if the transmission is faulty. If no error-free transmission is possible, the monitored person will be informed. If there is no perfect transmission within a certain time, an alarm is automatically triggered. If the transmission is error-free, the data (122) are fed to the signal processing (4) for evaluation, where they are evaluated as in the previously described method.

Fig. 4 shows a schematic representation of a second Embodiment as a fall detector with localization. By recording body movements and body position with Acceleration sensors and their evaluation are falling monitored person is recognized and, if necessary, automatically triggered an alarm.

• Mittel zur Erfassung der Messgrössen, die als drei orthogonal angeordnete Beschleunigungssensoren ausgebildet sind,
• Mittel zur Signalverarbeitung, wie eine Signalkonditionierung (4.10), ein Prozessor (4.20) mit einem Expertensystem (4.21) und einer Signalauswertung (4.22) und ein Informationsspeicher (4.30),
• Mittel zur Kommunikation, wie eine Bedien- und Anzeigeeinheit (2)
• Ein-/Ausgabeeinheit, bestehend aus einer Funkschnittstelle (8.1) und einer seriellen Schnittstelle (8.2),
• externe Komponenten, wie ein lokales Ortungssystem (9.1), eine Alarmeinheit (9.2) und ein externer Computer (9.3), und
• die Signale (114), (105), die Datenleitungen (107), (103), (113), (111), (112) und die Daten (108), (109), wie in Fig. 2 bereits vorbeschrieben.

The following are provided in the central unit (1), which the person to be monitored carries:

• Means for detecting the measured variables, which are designed as three orthogonally arranged acceleration sensors,
• Means for signal processing, such as a signal conditioning (4.10), a processor (4.20) with an expert system (4.21) and a signal evaluation (4.22) and an information memory (4.30),
• Communication means, such as an operating and display unit (2)
• Input / output unit, consisting of a radio interface (8.1) and a serial interface (8.2),
• external components, such as a local positioning system (9.1), an alarm unit (9.2) and an external computer (9.3), and
• the signals (114), (105), the data lines (107), (103), (113), (111), (112) and the data (108), (109), as already described in FIG. 2.

A multiplex method is used to operate the acceleration sensors provided to reduce electricity consumption. For the Power supply is a common battery powered unit provided, which is not described in detail. The sensor signals (115) are led to signal conditioning (4.10) where they are amplified, filtered and converted into digital signals (105) for the subsequent processing in the processor (4.20) or in the signal evaluation (4.22) contained therein can be converted.

The acceleration sensors (3) also detect static accelerations, such as gravitational acceleration, making it possible to use the g-vector to make a reliable statement about the body position of the person being monitored. The signals (105) are preprocessed in the signal evaluation (4.22) in two different ways. Low-pass filters separate the signals from parts of high frequencies, so that only the quasi-static parts are allowed to pass through and statements about the body position can be made. Bandpasses suppress the constant component of the signals in order to make statements about the dynamics of the signal and thus about body movements. These data are then processed in the signal evaluation (4.22) using various methods such as statistics and digital filtering and compared in an expert system (4.21) based on fuzzy logic with typical movement patterns that occur in the event of a fall. If fall-like patterns are recognized, the expert system checks whether the situation has changed at this moment, whether the monitored person then behaves motionless, a new change in the body position occurs and where the monitored person is located. If all signs indicate a fall, the device is automatically set to the alarm status. The monitored person can then delete the alarm status by his own action for a predetermined time if this has been set in error. Otherwise an alarm with the location of the person being monitored is fed into a public network via the radio interface (8.1) via alarm unit (9.2) or forwarded to a house control center. Of course, the monitored person can also trigger an alarm himself at any time through his own actions. The data line (111) carries the alarm information, which is present as an alarm profile, ie not only the alarm yes / no information is available, but a qualified validation of the alarm status. For example, the alarm status contains a diagnostic part that can be used to determine the cause of the alarm and to take appropriate measures. The alarm status can also include the location.
For the local location of the monitored person in buildings, an interface (8.1) to an existing location system (9.1) is installed.
The measurement data are stored in an information memory (4.30) as a 'memory with memory' so that they can later be used with a computer (9.3) and appropriate software via a serial interface (8.2) for further use such as research into causes and prevention.

The present invention proves to be particularly advantageous in that the person to be monitored permanently carries the device on him, vital parameters are permanently recorded without the device restricting the person being monitored in any way or having a stigmatizing effect and, as a result, no complex, expensive and fixed, on-site installations being necessary are,
that the alarm is triggered automatically when an emergency situation is detected by the expert system, such as in the event of a fall, and an alarm status is checked for plausibility in various ways before it is forwarded in order to avoid false alarms,
that the location of the monitored person can also be taken into account when evaluating the sensor signals and, in the event of an alarm, the location of the monitored person with the cause of the alarm is transmitted to the alerting point so that the monitored person can be found as quickly as possible and efficient help can be provided, and
that the device for the respective application, such as for diabetic people, can be configured in a modular manner in the means for recording the measured variables; the hardware part remains essentially the same, while the software (expert knowledge) can be easily adapted.

It is essential to the invention that, in addition to the sensor signals for the vital parameters, the location of the person being monitored is also taken into account for the evaluation,
that different sensor signals are linked for decision making,
that for the decision-making process, a combination of various vital parameters detected by sensors, such as breathing and / or cardiac activity with body activity and location, takes place in a fuzzy expert system,
that the signal evaluation takes place with the inclusion of intelligent algorithms, which allow reliable decision-making, especially in the event of falls, when using precise sensors,
that the decision is made by comparing the current patterns recorded by the sensors with stored experience patterns (movement and energy patterns) that are typical of certain dangerous situations,
that the monitored person's expert knowledge can be adapted externally via a computer or with an internal, self-learning neural network, and
that trends that can lead to a hazard are recognized and the monitored person is warned.

• Betagte Personen, die infolge von Stürzen auf einen automatischen Notruf angewiesen sind,
• Berufsleute, die in ihrer Arbeitsumgebung einer permanenten Gefahr ausgesetzt sind, ohne dass jemand bei einem Unfall etwas bemerken würde,
• Rekonvaleszente, die nach einer Operation vorzeitig aus dem Spital entlassen werden, aber noch einer Überwachung bedürfen,
• Sportler, die zur Unterstützung und Kontrolle des Trainings eine Aufzeichnung bestimmter Vitalparameter benötigen.

The present invention finds applications wherever permanent monitoring, recording and evaluation of important vital parameters and body movements is desirable or necessary and where alarms are to be triggered automatically in emergency situations and the location of the monitored person is to be transmitted. These are:

• Elderly people who rely on an automatic emergency call as a result of falls,
• Professionals who are in constant danger in their working environment without anyone noticing in an accident,
• Convalescents who are discharged from the hospital prematurely after an operation but still require monitoring,
• Athletes who need a record of certain vital signs to support and control their training.

Claims (20)

Procedure for the acquisition and processing of vital parameters, Body movements and body position of the monitored people at risk in emergency and risk situations, in the event of an accident and the like, as well as for automatic alarms, characterized in that on a person to be monitored Means for detection (3) are attached, via which Measured variables recorded and in first electrical signals (115) that the signals (115) are averaged Signal processing (4) are supplied, the latter with Communication means (2) to the person to be monitored second electrical signals (114) are connected, that by means of signal processing (4) data (116) be processed, which are fed to an input / output unit (8) are and on this as data (118) for transmission to ready for further use. A method according to claim 1, characterized in that the Measured variables are recorded centrally and, if necessary, decentrally. A method according to claim 1 or 2, characterized in that that the signals (115) via the input / output unit (8) Signal processing means (4) are supplied. Method according to one of claims 1-3, characterized in that that the signals (115) via an interface (8.3) wireless to an interface (8.4) and from this the means the signal processing (4) are supplied. Method according to one of claims 1-4, characterized in that that feeding the signals (117) to the input / output unit (8) wired or wireless he follows. Method according to one of claims 1-5, characterized in that that the processing of the data (116) by means of a Expert system (4.21) and signal evaluation (4.22) in one Processor (4.20), and by means of signal conditioning (4.10), an information store (4.30) and a neural, self-learning Network. Method according to one of claims 1-6, characterized in that that the transmission of the data (118) via a Interface (8.2) to an external computer (9.3) and via an interface (8.1) to an alarm unit (9.2) and possibly to a local positioning system (9.1) takes place. Method according to one of claims 1-7, characterized in that that in the expert system (4.21) decision making using fuzzy logic using the stored individual Data of the monitored person is made. Method according to one of claims 1-8, characterized in that in the expert system (4.21) decision making using fuzzy logic using the location. Method according to one of claims 1-9, characterized in that that in the expert system (4.21) in addition to the current Measurement data, respectively. Signals (115), and past measurement data of the last minutes also saved individual data of the monitored Person used to determine trends and early warnings the latter to the person to be monitored will give up. Method according to one of claims 1-10, characterized in that that typical data patterns in the information store (4.30) saved and for comparison with the recorded data patterns used and used for decision making will. Method according to one of claims 1-11, characterized in that that the transmission of the data (118) is delayed, to ensure the security of the assessment, including other signals (115) to increase. Method according to one of claims 1-12, characterized in that that the person being monitored is actively involved in decision making is involved and that about the means for Communication (2) a dialogue is conducted. Method according to one of claims 1-13, characterized in that that in addition to the signals (115) fourth electrical Signals (102) from an external positioning system (4.40) the means the signal processing (4) are supplied. Device for performing the method according to one of the Claims 1-14, characterized in that means for detection (3) of measured quantities and their conversion into first electrical ones Signals (115) that means of communication (2) with second electrical signals (114) that means for signal processing (4) with data (116) and external components (9) are provided and that an input / output unit (8) with means for transmission is provided. Apparatus according to claim 15, characterized in that the means for recording (3) internal sensors and possibly external ones Include sensors. Device according to claim 15 or 16, characterized in that that as internal sensors, acceleration sensors with three orthogonal axes, or three orthogonally arranged acceleration sensors are provided. Device according to one of claims 15 - 17, characterized in that that as a means of communication (2) operating and Display elements and means for control by voice are provided are that as a means for signal processing (4) Signal conditioning (4.10), one processor (4.20) with one Signal evaluation (4.22) and an expert system (4.21), and a Information storage (4.30) are provided, and that as external Components (9) an alarm unit (9.2), an external computer (9.3) and possibly a local positioning system (9.1) are provided. Device according to one of claims 15 - 18, characterized in that that as an input / output unit (8) a serial Interface (8.2), which is the transmission to the external Computer (9.3) enables, and a radio interface (8.1), which the transmission to the alarm unit (9.2) and possibly to local positioning system (9.1) enables, and are provided. Device according to one of claims 15-19, characterized in that that the data (111) as alarm information with the Cause of the alarm and, if necessary, also with the indication of the location are.

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