CH712710A2 - Multi-level dead man's alarm system and procedure. - Google Patents

Abstract

The invention relates to a system (1), a back-end server (1), a mobile device (3) and a method for the automatic monitoring of the physical and / or environmental conditions of one of several operators. Thanks to a multi-stage, staggered escalation of communication - first with the person in charge, then with a control point (4) and finally with an emergency service - a timely triggering of an alarm signal (5) can be secured, whereby the occurrence of false positive warning messages (sensitivity / specificity) can be reduced in frequency.

Description

description

Technical field of the invention The invention relates to a system or a method for monitoring people and for reporting so-called dead man or similar failure events. In particular, but not exclusively, it relates to the monitoring of several individual operational personnel who are located in several operational locations that are at a distance from one another, wherein the safety of the operational personnel can be monitored by a common control point.

PRIOR ART [0002] Alarm systems are known in which the vital signs are monitored by operational personnel. For example, an employee who works in a dangerous environment is equipped with a signaling device which triggers an alarm signal in the event of deviations from the normal vital signs or environmental conditions of the employee.

It is also known that in such an alarm event, a so-called dead man's message is automatically transmitted to a remote central station. An emergency medical service is then switched on, who immediately goes to the person at risk to get them out of danger or to provide first aid.

Since no alarm system can be absolutely reliable and error-free, known systems always tend to act on the safe side. In borderline or doubtful cases, the alarm should rather be triggered, whereby a false-positive alarm signal may be issued than no message. In such known systems it can therefore happen that an alarm signal is triggered accidentally or too easily. After repeated occurrences of such false alarms, a certain skepticism can spread among the surveillance and emergency services, which in the long term can have a significantly negative impact on the reliability of the system and on the safety of the employees.

There is therefore a need for a monitoring system or method in which all extraordinary messages are addressed, but in which the occurrence of such false positive alarm signals is reduced in frequency.

Brief Description of the Invention To at least some of the above. To eliminate disadvantages in the prior art, the invention provides a backend server according to claim 1, a mobile device according to claim 2 and a method according to claim 8. Thanks to the multi-stage, staggered process of monitoring in the event of deviations in the physical or environmental conditions of the monitored person, all extraordinary circumstances can be dealt with. Messages that may not justify triggering the alarm signal can be subjected to two preliminary dead man request stages in advance.

Thanks to the inherent intelligence and the multi-level alarm trigger, the system is much more reliable and less susceptible to false reports than known alarm systems, since the specificity and sensitivity in the detection of real incidents are optimized.

[0008] The invention will be described with reference to the accompanying drawings, in which:

1 shows a simplified schematic illustration of an exemplary system with an inventive backend server and mobile device.

FIG. 2 shows a simplified schematic illustration of an exemplary structure of the back-end server shown in FIG. 1.

3 shows a flow diagram of a first example of a monitoring method according to the invention.

4 shows a second example of a monitoring method according to the invention as a flow diagram.

5 shows as a flowchart an example of an initialization sequence of a monitoring method or back-end server according to the invention.

The accompanying drawings are only intended to be illustrative examples which serve to better understand the invention. They do not represent a restriction of the claimed invention. In the drawings, the same reference numbers are used for identical or functionally similar elements. However, the use of different drawings does not mean that the features indicated are different.

Detailed Description of the Invention In the following detailed description, embodiments of the invention are described.

[0011] The term “deployment person” means any person who is in a position where they do not have immediate access to emergency or emergency services. Examples can include construction or maintenance workers in a power plant

CH 712 710 A2 or excavation pit, mountain hikers, aircraft personnel, bus drivers or divers. An operator can typically be one of many who are in different locations. The automated monitoring of such a scattered number of people, where each individual has different internal (physical) and external (environment) conditions, is complex.

1 shows a monitoring system 1 which has a back-end server 2. The backend server 2 is connected (10-15) to a portable mobile device 3 such as a smartwatch, as well as with the communication device 4, a control point and an alarm trigger 5. The communication between the backend server 2 and the remote devices 3 and 4 can e.g. via wireless connections such as WLAN, Bluetooth®, cellular network, etc.

From a mobile device 3, sensor or measurement data, which represent the vital signs and / or the environmental status of the person wearing it, are transmitted continuously or in batches to the back-end server 2. The measurement data can also include location information such as Include GPS coordinates of the mobile device. Regardless of whether or not they recognize an incident, the measurement data are still transmitted to the back-end server 2, where they are stored and evaluated. If the server 2 detects a deviation or an extraordinary state (first target range) from the received data, the server can send a first request signal 11 to the mobile device 3. The request signal 11 can e.g. include a push message on a smartwatch, a smartphone in the form of an SMS, an email or an automatic phone call. It can be a message to the sensor on the person whose sensor the deviating measurement comes from. Upon receipt of the first request signal 11, e.g. automatically or with the intervention of the person wearing the smartwatch, a first response signal 12 is sent to the back-end server. The response signal 12 can e.g. include an entry on the smartwatch or smartphone. Communication 10, 11, 12 between mobile device 3 (also called frontend) and backend server 2 is preferably carried out over the Internet in encrypted form. The front and back end 2 can be connected using wireless technology such as WLAN and / or a mobile phone network (GSM). The response signal 12 is then evaluated in the back-end server. If the server 2 can recognize from the response signal 12 that the said deviation or the extraordinary condition is again in a normal range (target range) or that the deviation does not justify further intervention steps, then no further special steps take place; the backend server 2 returns to a normal monitoring mode. On the other hand, if the back-end server 2 does not receive a satisfactory response signal, it goes into a first alarm level mode, in which it sends a second request signal 13 to the control point 4. The control point 4 can e.g. be the regular PC or a smartphone or a smartwatch of the person who is responsible for the safety of a large number of people. The second request signal 13 can e.g. include a push message, SMS, email, or automatic phone call. Upon receipt of the second request signal 13, further steps are taken, e.g. by the named responsible person in order to determine the condition of the corresponding operator. For example, attempts are made to contact the operator, e.g. by phone or in person to conduct an independent investigation of their condition.

If everything is in order, or everything could be put back in order, the second all-clear signal 14, from the control point 4, or the first all-clear signal 12 from the mobile device 3, can be sent to the back-end server 2. The backend server 2 waits for one of the two all-clear signals 12 or 14 and automatically switches back to the normal mode as soon as it receives one of the two signals.

If an event has occurred (e.g. a fall or a medical incident), no all-clear signal 12 or 14 is transmitted to the back-end server 2 in response to the request signals 11 and 13. If the back-end server 2 does not receive such a response (e.g. within a specified period of time), it 15 automatically triggers the alarm 5. The alarm trigger 5 can establish an automated connection to an emergency service or trigger a predefined measure on site.

Measurement data can e.g. can be obtained from sensors of the mobile device 3. Alternatively, or in addition, data from separate remote sensors (so-called beacons) can be received in the vicinity on the mobile device, e.g. via Bluetooth®, infrared, WLAN, etc. The measurement data can be continuously transmitted to the backend server 2 10, where it can be temporarily stored. The stored measurement data can be used to automatically recognize historical patterns and trends in the data. The occurrence of certain patterns or trends that lie outside a target range can also be used as the basis for an inquiry or alarm signal. The stored data can contain personal medical data. For data protection reasons, they can preferably, e.g. at the end of a working shift without incident. However, if there is a medical emergency, the stored data can be transferred to the emergency service if necessary.

2, the structure of a back-end server 2 according to the invention is explained in more detail by way of example. In this example, the back-end server has a first communication unit 6 _Ί for communication with the mobile device 3, a second communication unit 6 ₂ for communication with the control point 4 and a third communication unit 6 ₃ for triggering 15 of the alarm 5. A control unit 8 takes over certain tasks of the back-end server, such as the evaluation of the measurement data received by the mobile device 3. Memory 7 serves to store the received measurement data in order to evaluate them according to predetermined algorithms and knowledge rules (knowledge database).

Fig. 3 shows in a first embodiment the automated sequence 100 of a method according to the invention, which e.g. can be implemented in the back-end server 2 as a software algorithm. In a first step 110

CH 712 710 A2, measured values are received and evaluated by the mobile device (e.g. smartwatch). If the measured values are in the target range (»normal»), this step is repeated each time new measured values are received. As soon as one of the measured values, or a constellation of several received measured values, falls outside the target range, the second step 130 is initiated in that a first request signal, also called a warning message, is sent to the mobile device. A waiting all-clear signal is then waited for. The alarm status and / or the reason for this is preferably shown on the display of the mobile device. In this way, or e.g. The operator is made aware of the changed alarm status by an acoustic alarm tone on the mobile device. The all-clear signal can e.g. triggered by the operator himself, for example by means of a corresponding input or a graphic interaction with the user interface of the mobile device, an SMS, e-mail or by means of a telephone call to a central office.

After receiving the first all-clear signal, e.g. the backend server resets to its normal position 110 within a predetermined waiting time. If the all-clear signal does not come during the waiting time, the system changes to a second alarm state 150 in which the back-end server sends a second request signal to the control point. Measures are taken at the control point, e.g. automatically (for example, by a general or local alarm signal from an internal company alarm) or manually (an employee tries to contact the operator or tries to contact them) to establish communication with the operator. If the employee or the control body succeeds in establishing a connection to the operator, the reason for the measured value lying outside the target range or for the missing first all-clear signal is determined. If a plausible reason is ascertained, or if the condition of the operator could be brought back into the target area, a second all-clear signal is sent to the backend server. The second all-clear signal can e.g. on the mobile device or from the control point. As with the first all-clear signal, the second all-clear signal may e.g. triggered by the operator himself, for example by means of a corresponding input or a graphic interaction with the user interface of the mobile device, an SMS, e-mail or by means of a telephone call to a central office. The mobile device can e.g. can be programmed with an app that always runs in the foreground mode, whereby the operator can continuously obtain information about the current status of the measured values and / or the alarm status, whereby he or she can trigger and / or cancel the warning messages to the backend server manually can.

After receiving the second all-clear signal, e.g. the back-end server returns to its normal position 110 within a predetermined second waiting time. If the all-clear signal does not come during the waiting time, the system goes into a third alarm state 170 in which the backend server reports an urgent emergency status, and e.g. calls an emergency service and / or triggers a general alarm.

FIG. 4 shows a further variant of a method 101 according to the invention. In this example, the second and / or third alarm level 150, 170 can be reached directly if the measured values indicate a serious state 112 or a critical state 111 of the operator suggest. If the measured values justify it, the first and / or the second all-clear signal cycle is dispensed with, so that the appropriate alarm status can be triggered directly.

5 shows an initialization or calibration phase 102 of the system 1, which can be carried out, for example, at the beginning of a working shift in order to adapt the evaluation of the measurement data of several individual operators. After the usual system checks, measurement data (body movement or orientation, blood pressure, heart rate, CO ₂ in the blood, blood O ₂ measurement, blood sugar measurement, urea measurement, ambient CO ₂ measurement, ambient CO measurement, etc.) are, for example, trial for each of the Operators measured and saved. These are compared with independent control parameters to determine a plausible, individual measurement data pattern for the operator. Such a control parameter could be, for example, that the operator is in a state of rest at the time of the measurement, that he wears the smartwatch loosely on his right wrist, or that he works standing. The measurement data and control parameters can then be used, for example in the back-end server, to calculate the first and second target range. In this way, the target ranges of the measurement data are adjusted to the current physical and environmental conditions of the operator on that day.

The control point 4 can be e.g. Browser-based interface are provided, which provides the supervising employee with a visual overview of the current and / or historical status of several employees. The interface can also be configured in such a way that certain measured values or constellations of measured values, which indicate a possible, developing incident situation, are displayed graphically, even though the corresponding measured values are actually still in the normal range.

The system is preferably configured so that sensors or sensor types can be connected modularly. If e.g. If the mobile device is connected to a new external sensor, such as a smoke detector, a corresponding set of knowledge rules that define the expected behavior or evasive behavior of the detector can be loaded into the backend server at the same time.

Thus, the modular system can also be used when the monitored persons are very different and are in very different environments. Unless otherwise stated, the features mentioned here can be combined in any way to form further embodiments of the invention form.

CH 712 710 A2

Claims (10)

Claims 1. Backend server (2) for the automatic monitoring of a state of at least one deployment person, by communication (10, 11, 12) with a mobile device (3) portable by the deployment person and (13, 14) a communication device of a monitoring control point, characterized in that - The backend server (2) has a first communication unit (61), which is configured in such a way that measured values of the physical and / or environmental condition of the operating person can be received (10) from the mobile device (3); - The back-end server (2) is configured in such a way that an extraordinary physical and / or environmental condition of the _operator can be determined from the measured values received by the first communication unit (6 _Ί ) and, _after determining the extraordinary physical and / or environmental condition, a first Dead man request signal (11) can be automatically transmitted to the mobile device, and if no all-clear signal (12) is received by the mobile device (3) in response to the first dead man request signal (1), a second dead man request signal (13) is automatically applied the communication device (4) can be transmitted to the monitoring control point and, if a second all-clear signal (12, 14) in response to the second dead man request signal is neither received by the mobile device (3) nor by the communication device (4) of the control point, an alarm signal (15) can be triggered. 2. A mobile device (3) which can be carried by an emergency worker for communication with a backend server (2) according to claim 1, the mobile device (3) characterized by: - a second communication unit for communication with the first communication unit (6,) of the backend server (2); - At least one sensor for determining measured values of a physical and / or environmental condition of the operator; - an operator interface for communication with the operator; and - a control unit; wherein the control unit, the second communication unit and the at least one sensor are configured such that the measured values can be determined and transmitted to the back-end server (2); wherein the control unit and the communication unit are configured such that a first dead man request signal (11) can be received by the first communication unit (61) and that, after receiving the first request signal (11), a first all-clear signal (12) to the first Communication unit (61) can be transmitted. 3. Mobile device according to claim 2, which has an operator interface for communication with the operator, wherein the all-clear signal (12) can be triggered by manual actuation of the operator interface. 4. Mobile device according to claim 2 or 3, wherein the mobile device (3) is a smart watch. 5. System (1) for monitoring the state of at least one deployment person, the system (1) a backend server (2) according to claim 1, at least one mobile device (3) portable by at least the deployment person according to one of claims 2 to 4 and a communication device (4) has a control part. 6. The system (1) according to claim 5, which has at least one remote sensor for detecting said measured values of a physical and / or environmental condition of the operator, wherein the measured values of the at least one remote sensor can be transmitted to the mobile device (3) via a wireless communication connection. 7. System (1) according to one of claims 5 or 6, wherein the measured values of the physical and / or environmental conditions include one or more of body movement, body orientation, blood pressure measurement, blood 02 measurement, blood sugar measurement, urea measurement, blood CO ₂ measurement, Heart rate, respiratory rate, ambient CO ₂ measurement, ambient CO measurement include. 8. A method (100) for automatically monitoring the physical and / or environmental conditions of at least one operator, characterized by: - A first step (110), in which measured values of the physical and / or environmental condition of the deployment person are transmitted from a mobile device (3) worn by the deployment person to a back-end server (2), with measurement values being outside a predetermined first target range are searched for; - a second step (130) in which, if a first condition is met, a first dead man request signal (11) is automatically transmitted to the mobile device (3), the first condition determining (120) at least one of the measured values, that lies outside a predetermined first target range, includes; - a third step (150), in which, if a second condition is met, a second dead man request signal (13) is automatically transmitted to a communication device (4) of a monitoring control point (3), the second condition receiving ( 140) the first all-clear signal (12) in response to the first dead man request signal; a fourth step (170) in which, if a third condition is met, an alarm signal (15) is triggered, the third condition receiving (160) the second all-clear signal (12, 14) in response to the second dead man Inquiry signal (13) comprises. 9. The method (101) according to claim 8, wherein: CH 712 710 A2 - The said evaluation of the measured values includes a search for measured values that lie outside a predetermined second target range, the second target range being wider than the first target range, and wherein the second condition involves determining (112) at least one of the measured values that is outside the second target range, includes; and or - The said evaluation of the measured values includes a search for measured values that lie outside a predetermined third target range, the third target range being wider than the second target range, and the third condition being the determination (111) of at least one of the measured values that is outside the third target range is included. 10. The method (101) according to claim 9, which has a calibration step (106), in which calibration step: the physical and / or the environmental condition of the operator are checked by means of control parameters, which control parameters include status values which are obtained in a different way than the mentioned measurement values; the first, the second and / or the third target range are determined at least in part on the basis of the status data of the control parameters. CH 712 710 A2