ES2711642A1 - SYSTEM DEFIBRILLATORS AND STATE CONTROL PROCESS OF EACH OF THEM THROUGH A COMMUNICATING DEVICE COUPLED INSIDE (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Defibrillator system that is based on a communicating device, whose purpose is to attach itself to a defibrillator, in order to detect the state of the set of them at all times and communicate with a central system. Each defibrillator emits a signal by Bluetooth BT 2.1 in different circumstances signaling internal information. The communicator captures this BT signal, decodes it, interprets it and forwards the important data through GPRS (mobile network 2G) to a database. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

System of defibrillators and process of control of the state of each of them through a communicating device coupled inside.

Field of industrial application

A communicator device has been developed, the purpose of which is to be coupled to a defibrillator, in order to detect the state of the set at all times and communicate with a central system capable of managing the set of all connected devices.

State of the prior art

There are countless patents on defibrillators, called Automated External Defibrillator or AED, with the ability to communicate with each other or with a control center, although almost all refer to controlling the operation of the defibrillator itself, to instruct how to use it, to control its functions or movements, to give emergency warnings, or to send medical data about the performance on a patient. Only one, the PCT WO2010140809, of Korean origin is thought to prevent the theft of the AED device, based on a vibration sensor that triggers an alarm in case of theft. The US patent US2014087762, deals with a device to locate a defibrillator at all times, but its operation is very complicated, based on sending 2 "digital signatures" at different times, comparing them to situate the situation of the AED and the PCT patent. WO030131177 of USA origin, defines a radio-based system to locate the situation of the defibrillator, but does not explain how it explains that the AED communicates with a server to inquire its status (on, off or charging), battery level or Parameters of its configuration, but does not give details of how the process is carried out The patent more similar to ours we believe is the WO2005058417, also of American origin, which claims a defibrillator / monitor system which has a module capable of communicating without cables with a base, but the main object of it is to control the AED discharges.

Explanation of the invention

It is a system constituted by a communicating device coupled to a defibrillator and the control process associated with the set, in order to know the state of the system at all times. This system communicates with a central system, provided with a database, from which all connected communicating systems are controlled.

The defibrillator system emits a Bluetooth BT 2.1 signal in different circumstances signaling internal information. The communicator captures this BT signal, decodes it, interprets it and forwards the important data through GPRS (mobile network 2G) to a database.

The communicator has an accelerometer and a GPS sensor. When it detects a movement, that is to say that someone has taken it from its resting position, through the accelerometer, the first thing it does is to listen to the bluetooth during a certain period of time. The communicator understands the use of the defibrillator and only sends a message of use to also alert medical teams.

In the event that after this time no one is using the defibrillator (no message is received by BT), the communicator is put into theft mode by activating the GPS and GPRS for triangulation and positioning, or other systems such as LoRA could also be used. , etc, sending this information by GPRS to the server. The system continues in this mode until the battery runs out or is intercepted and shut off.

There is a specific routine to start this anti theft mode! As normal operation because the communicator is inserted into the defibrillator during manufacturing, it is connected to a battery and left on-the-self until it is purchased, at which time it is transported to the end customer and performing a certain routine of movements, detected by the accelerometer, the communicator starts to function normally.

Brief description of the drawings

Figure 1 is a schematic of the components of the global system. Figure 2 shows the ways in which the different components of the system communicate with each other.

Detailed exposition of a realization mode

The phases during the control process are:

- Pairing

- Storage (Stocking)

- Activation (Activating)

- Normal operation (Functioning)

First steps:

Figure 1 shows the components of the Defibrillator-Communicator system, which highlights 2 other physical components, an antenna A and a DB SERVER database.

Once the battery is connected for the first time to the COMM Communicator, it will start scanning nearby devices (it will perform 14 scans of 10 seconds each). At this time, the user of the defibrillator or AED, should open the cover at the same time to make it visible.

The way in which the communicator will identify the AED will be with the search of devices with a name of 9 digits. This means that, if apart from the AED there are also other devices with 9 digits in the name, the last one that is being detected will be the one chosen and its name will be stored in memory.

Once the AED is selected, the COMM communicator will attempt to pair with it (there will be 4 pairing attempts). For this purpose, the keys required for matching will be exchanged.

When the pairing has been carried out, a message is sent to the database, DB SERVER, giving the information about the state of the pairing (completed or not).

If the pairing has not been completed or no device has been detected while scanning, the communicator will enter "sleep" mode until the battery is removed.If the pairing has been successfully completed the device will enter sleep mode ", But a routine of three movements will suffice to awaken him. The reason for this routine is to save as much battery as possible in the months in which the unit is stored in the warehouse until it is sent to the customer.

These three specific movements must be done in 1 minute. If the three movements are not carried out in this period of time the system will return to the "sleep" mode and the routine of the three movements will be restarted. The movements will be detected by an accelerometer, ACCELER, so, for the first movement, the The COMM communicator needs to be placed in a certain position and remain there for at least 10 seconds.This will trigger an interruption to the system and the second movement will be configured.In the same way, the communicator must now be placed in another position and remain there for at least 10 seconds. The third movement follows the same rule, if one of the movements does not last at least 10 seconds, then the time of 1 minute will pass and the routine will restart.

If all three movements are performed correctly, a message will be sent to the DB SERVER database indicating that they have been made correctly.

After this, the COMM communicator will synchronize with the AED. This is why the user must open the AED cover to make it visible. Then the communicator will begin to scan the AED (with which it was previously paired and stored in memory) and once detected, try to connect and read the AED clock. In case it is not detected (there will be 4 scans of 10 seconds each), is not able to connect (3 attempts per scan), or does not get the value of the AED clock, a message will be sent to the database , confirming that the communication was not possible and then entering "sleep" mode, waiting for the routine of the 3 movements to be repeated.

If the AED is scanned and also the communicator manages to connect to it, several messages will be exchanged. First, the communicator sets the AED in "engineering" mode, for which a specific command has to be sent It is important to mention that the AED will only recognize known commands, if an erroneous command is sent, the AED will ignore it and will not respond.

Once in "engineering" mode, the command to recover the RTC, the AED clock in figure 1 will be sent and the COMM communicator will decode the response, set the clock with the same time as the AED and set an alarm every so often.

After the clocks are synchronized, the communicator will send a message to the database stating that the synchronization has occurred correctly and then it will go back into "sleep" mode.

Main Functionality:

The "sleep" mode after synchronization (main "sleep" mode) is the state where the communicator will spend most of its time. The alarm set is one of the only two reasons why the communicator woke up.

When the alarm is activated, the communicator will start scanning the AED. The reason for this is that the AED should be visible at the same time to allow the communicator to receive certain information.

Once the device is scanned, the connection will be made and the command will be sent to retrieve an internal test made by the AED. This test contains important information about the state of the AED. Once the information is decoded, it is sent to the database indicating that the internal test was successfully read.

In the event that the internal test is not read (the AED is not scanned, it is not connected or it is not possible to receive the information after the command) a message will be sent to the database indicating that it is not possible to perform the internal test .

Now the communicator will go back into sleep mode until the next day at the same time, since every day you need to read the internal test.

The other reason why the communicator may wake up is due to movement. The accelerometer, ACCEL, of the system is measuring the state of the unit all the time, so when a movement is made outside the "known state" an alarm is sent.

The "known state" is set right after entering "sleep" mode. At that moment the accelerometer will fix its current position as the known position.

When the alarm is activated, the accelerometer will check during the next 3 minutes if the movement continues. The threshold by which movement is considered can be adjusted as desired. If during that 3 minute window the device remains motionless for 1 minute, the communicator will take the last measurement of the accelerometer and set it as the new "known state." However, if movement is detected during those 3 minutes, the communicator Look for a good GPS signal for 6 minutes.

If during those 6 minutes there is a GPS signal, 5 messages with 5 good GPS measurements will be sent to the database. If the messages are sent before 6 minutes, the communicator will leave the counter because you already have what you were looking for.

If the GPS is not read, a message will be sent to the database indicating that the GPS was not read correctly but that movement was detected.

After the message, the accelerometer will set its current position as "known position" and will return to "sleep" mode again.

In Figure 2 it can be seen that the defibrillator emits a signal by Bluetooth 2.1 (BT) in different circumstances signaling internal information. The communicator captures this BT 2.1 signal, decodes it, interprets it and forwards the important data through GPRS (mobile network 2G) to a database. The operation of the system guarantees that for at least 3 years, energy management allows this type of communication.

Claims (4)

1. Defibrillator system in each of them includes a communicator and communicate with a server that includes a database, characterized because to. Each defibrillator has an internal digital clock b. Each communicator includes a GPS and an accelerator c. The communication between the defibrillator and the communicator is done via Bluetooth d. The communicator captures the defibrillator signal, interprets it and forwards the important data through GPRS to the server, to be stored in the database 2. Process of controlling the status of the defibrillators connected to a system by means of a communicating device coupled to each of them, characterized by the phases through which the defibrillator passes during the control process ^o Pairing ^o Normal operation (Functioning) And in intermediate situations, ^o Storage (Stocking) ^o Activation (Activating) 3. Process of monitoring the state of the defibrillators connected to a system by means of a communicating device coupled to each of them, according to claim 2, characterized in that in the phase of Pairing • Once the defibrillator is selected, the communicator will attempt to pair with the defibrillator through 4 pairing attempts, exchanging the keys required to pair. • When the pairing has been done, a message is sent to the server database, giving the information about the status of the pairing (completed or not) • If the pairing has not been completed or no device has been detected while scanning, the communicator will enter "sleep" mode until the battery is removed, if the pairing has been successfully completed, the device will enter the mode " sleep ", but a three-movement routine will suffice to wake him up: • If the three movements are not performed in 1 minute the system will return to "sleep" mode and the routine of the three movements will be restarted. • The communicator needs to be placed in a certain position and remain at least 10 seconds. • Then the communicator must be placed in another position and remain there for at least 10 seconds. • The third movement follows the same rule. If one of the movements does not last at least 10 seconds, then the 1 minute time will pass and the routine will restart. • In case it is not detected (there will be 4 scans of 10 seconds 5 each), it will not be able to connect (3 attempts per scan) or it will not get the value of the AED clock, it will send a message to the base of data, confirming that the communication was not possible and then entering "sleep" mode, waiting for the routine of the 3 movements to be repeated. • If the defibrillator is scanned and also the communicator manages to connect to it, the communicator sets the AED in "engineering" mode. • Once in "engineering" mode, the command will be sent to recover the RTC, the AED clock and the communicator will decode the response, set the clock with the same time as the AED and set an alarm every so often. • After the clocks are synchronized, the communicator will send a message to the database stating that the synchronization has occurred correctly and then it will go back into "sleep" mode. 4. Process of monitoring the state of the defibrillators connected to a system by means of a communicating device coupled to each of them, according to claim 2, characterized in that in the normal operating phase, • When the alarm is activated, the communicator will start scanning the AED • Once the device is scanned, the connection will be made and the command will be sent to retrieve an internal test made by the AED, whose content consists of important information about the state of the AED • If the internal test is not read (the AED is not scanned, it is not connected or it is not possible to receive the information after the command) a message will be sent to the database stating that it is not possible to perform the internal test. • Now the communicator will go back into sleep mode until the next day at the same time, since each day you need to read the internal test. • The other reason why the communicator may wake up is due to movement. The accelerometer of the system is measuring all the time the state of the unit, so when a movement is made outside the "known state" an alarm is sent. • When the alarm is activated, the accelerometer will check during the next 3 minutes if the movement continues • If during that 3-minute window the device remains motionless for 1 minute, the communicator will take the last measurement of the accelerometer and set it as the new "known state." However, if movement is detected during those 3 minutes, the communicator will look for a good GPS signal for 6 minutes. • If during those 6 minutes there is a GPS signal, 5 messages with 5 good GPS measurements will be sent to the database. If the messages are sent before 6 minutes, the communicator will leave the counter because you will have what you were looking for If the GPS is not read, a message will be sent to the database indicating that the GPS was not read correctly but that movement was detected. After the message, the accelerometer will set its current position as "known position" and will return to "sleep" mode again. In case that after this time nobody is using the defibrillator (no message is received by BT), the communicator is put in theft mode activating GPS and GPRS for triangulation and positioning and send this information by GPRS to the server (server) . There is a specific routine to initiate this anti-theft mode as well as normal operation because the communicator is inserted into the defibrillator during fabrication, connected to a battery and left on-the-self until it is purchased, at which time it is transported to the final client and by performing a certain routine of movements, detected by the accelerometer, the communicator begins to function normally.