CZ308380B6 - Method of activating emergency communication between active NFC devices and the emergency communication system - Google Patents

Abstract

Method of activating emergency communication on an emergency communication system between active NFC devices if power is lost to the NFC target (2) by placing the NFC target (2) within range of the NFC initiator antenna (1), then activating the component on the NFC initiator (1) (10) to increase the power of the modulated communication signal, the NFC initiator (1) significantly increases the power of the modulated communication signal transmitted from the antenna (11) by adjusting the reference voltage or current of the sinusoidal antenna generator (11) to activate the NFC tag (20) ), then the NFC tag (20) of the NFC target (2) is activated by receiving a modulated communication signal transmitted from the antenna (11) of the NFC initiator (1) and then the NFC initiator (1) reads the information from the NFC tag (20) of the NFC target (2).

Description

Method of activating emergency communication between active NFC devices and emergency communication system

Field of technology

The invention is in the field of radio frequency communication and identification (RFID) based on short distance radio contact (NFC) technology.

Prior art

NFC technology is currently a commonly used and generally accepted technical solution in a number of technical applications, it is often used to implement access systems for objects such as building or vehicle entrances or access systems for using things such as short-term electric scooter rental or also at payment terminals.

The technology uses the principle of an electromagnetic field, which is emitted by one side and influenced by the other side, whereby this information is transmitted. The second option is the transmission of information by emitting the electromagnetic field from both sides.

The original variant of the technology uses simple passive RFID chips without its own energy source, where the energy needed for the response is obtained by inducing the electromagnetic field of the reader. These passive RFID chips are simple to design and manufacture, but they can be used for the single application for which they are intended. With the extension of NFC technology to active devices with their own power supply, such as mobile phones and smart watches, it is possible to have multiple access applications connected to one device.

NFC devices that communicate with each other can be divided into passive ones, which do not need their own energy source, and active, which use their own energy source for a given function.

The devices are also divided into a communication initiator and a communication target that responds to the initialization of communication from the initiator. The initiator constantly maintains the magnetic field and responds to changes caused in it, the target of communication responds based on the discovery of the magnetic field of the initiator. In access systems, the role of the initiator is on the side of the element with greater possibilities for obtaining electrical energy, ie buildings, equipment or machines. A device with its own user passkey has the role of target.

The access key, or the data representing the access key, the NFC tag, is unique for passive devices at the moment, while active devices can actively change it. The NFC tag usually needs to be secured against modification, so it can be stored on the SIM card, in an encrypted built-in chip in the phone (eSE) or it can be emulated within the operating system of the phone or an extension application (OS).

Therefore, the active device must have a physically implemented connection of the NFC antenna with the given components (SIM, eSE, OS) and also implemented a system for determining which NFC tag to use, because only one NFC tag can be active at a time.

In the case of a passive device, the magnetic field is the only source of energy for the NFC chip and allows its active function, ie communication with the initiator side. For active devices in the corner of the target, the source of energy from the magnetic field is supplemented by energy from the battery itself. The technical implementation of NFC into active devices, such as mobile phones and smartphones, is usually much more complex than that of passive NFC devices, as it is associated with the possibility of implementing multiple NFC tags, as mentioned above.

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A more complex implementation may mean that the energy required for the NFC tag function is higher than can normally be obtained by induction through the initiator's magnetic field, and the remaining energy must be replenished from the device's own battery.

In the case of a low battery condition, it is usually not possible to use the access solution in the current conditions. Some manufacturers of active NFC devices use a software solution to maintain the functionality of the NFC connection, where when the battery is low, such a device goes into standby mode outside the operating system, with the remaining battery voltage being used only to maintain NFC functions.

Another approach to a partial solution to such a technical problem may be the integration of wireless charging of the power supply of the target NFC device in the initiator of the NFC communication. Such systems are known, for example, from US 2015087228 A1 and US 2014035521 A1, which combine simultaneously wireless charging of the power supply of the target NFC device and NFC communication with the target NFC device. However, these systems have the disadvantage of not being able to provide immediate NFC communication when the battery of the target NFC device is discharged below a critical level or is completely missing, eg due to a fault. Furthermore, there is a risk of damage to the NFC chip of the target NFC device by too high a voltage or current produced by the charging antenna of the NFC initiator, which can be prevented by the chip protection method described for example in WO 2018048111 A1.

The object of the invention is therefore to ensure the functionality of NFC communication even in cases where the battery of the target NFC device is discharged below a critical limit or completely missing, e.g. due to a fault, even in a situation where the target NFC device does not have wireless charging, as the invention focuses on immediate commissioning of the NFC tag as such, but not to restore the function of the entire target NFC device.

The essence of the invention

The subject of the application is a method of activating emergency communication between active NFC devices and an emergency communication system of the NFC target and the NFC initiator. The invention overcomes the identified shortcoming of the prior art and ensures communication between two active NFC devices even in the event that the NFC target of the device loses power from its own battery.

The essence of the invention lies in the fact that the NFC initiator is equipped with a component for increasing the power of the modulated communication signal so that there is a short-term significant increase in voltage or current of the signal generator, or a combination of increasing both quantities, even above the level defined by relevant standards to wirelessly induce an NFC tag of an NFC target without activating the entire NFC target.

The level of modulated communication signal power increase may be predefined depending on the desired type of NFC target and NFC initiator antenna, or the NFC initiator may be set to increase the modulated communication signal power to the highest achievable NFC antenna power to ensure as many NFC tags can be activated types of NFC targets separately.

Frequent use of such a system can be, albeit to a limited extent, energy uneconomical. Due to the fact that the energy intensity of NFC tag activation depends on the degree of its complexity, it seems advantageous to gradually increase the NFC initiator antenna voltage until the power of the modulated communication signal reaches sufficient intensity to activate the NFC tag of the NFC target at a given time without self-supply or to keep the NFC tag active. As soon as the given NFC tag is activated, the further increase in power is stopped and the information from the NFC tag is read by the NFC initiator. Once the information is retrieved, the performance enhancement component is modulated

-2 GB 308380 B6 communication signal is deactivated and the NFC initiator antenna power returns to normal operating value. However, such a solution is structurally more complex in comparison with the variant of a simple step increase in the power of the modulated communication signal.

Depending on the specific intended application, it is therefore possible to implement a variant with a significant step increase in the power of the modulated communication signal or with a gradual significant increase.

The component for increasing the power of the modulated communication signal can be activated depending on the on-site implementation method, manually by the user, for example by pressing a button, or remotely, for example via a telephone support center.

Activation of the component does not increase the power of the modulated communication signal transmitted from the antenna by adjusting the current or voltage on the circuit directly in front of the antenna, as this would cause undesired interference with the modulation and damage the modulated signal. It is therefore necessary to adjust the current or voltage on the sine signal generator and leave the actual modulation of the signal unmodified.

The component for increasing the power of the modulated communication signal regulates the transmission power of the antenna and can be implemented in several variants, by adjusting the reference voltage or current of the sine generator, for example:

1) in the form of a capacitor, which is gradually charged during the normal operation of the NFC initiator, when it is connected at the moment of activation by the user, and thus increases the power of the modulated communication signal;

2) in the form of a voltage divider or a resistive divider;

3) in the form of digitally controlled output from the microprocessor of the NFC initiator;

4) a combination of the above-mentioned variants to ensure an energetically optimal design, in particular in relation to the degree of necessary increase in the power of the modulated communication signal.

Explanation of drawings

Figure 1 schematically shows an emergency communication system according to an exemplary embodiment of the invention.

Example of an embodiment of the invention

The example describes how to activate emergency communication using the emergency communication system, comprising the following steps:

- NFC target 2 in the form of mobile phones turned off due to low battery;

- the NFC user places the target 2 within range of the antenna of the NFC initiator 1 in the form of an entry terminal into the building;

- the user activates the component 10 to increase the power of the modulated communication signal via the user interface 12 in the form of an emergency communication button on the NFC initiator 1;

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- the component 10 is activated on the NFC initiator 1 to increase the power of the modulated communication signal transmitted from the antenna 11 in the form of a digitally controlled output from the microprocessor;

- the NFC initiator 1 starts to increase the power of the modulated communication signal transmitted from the antenna 11;

- the NFC tag 20 of the NFC target 2 is activated by receiving a modulated communication signal transmitted from the antenna 11 of the NFC initiator 1;

- the connection of NFC tag 20 of NFC target 2 and NFC initiator 1 is established;

- communication of NFC tag 20 of NFC target 2 and NFC initiator 1 is terminated;

- the component 10 is deactivated on the NFC initiator 1 to increase the power of the modulated communication signal;

- The NFC initiator 1 terminates the increase in power of the modulated communication signal transmitted from the antenna 11.

Industrial applicability

The invention is industrially applicable to NFC devices in which it is desirable to be able to connect to another active NFC device, for example in the form of a mobile telephone, in particular in building, vehicle or ship access systems.

Claims (6)

PATENT CLAIMS A method of activating emergency communication between active NFC devices in the event of a loss of power to the NFC target (2), characterized in that it comprises the following steps: - the NFC target (2) is placed within range of the NFC initiator antenna (1), - a component (10) is activated on the NFC initiator (1) to increase the power of the modulated communication signal, - the NFC initiator (1) significantly increases the power of the modulated communication signal transmitted from the antenna (11) for activating the NFC tag (20) of the NFC target (2), - the NFC tag (20) of the NFC target (2) is activated by receiving a modulated communication signal transmitted from the antenna (11) of the NFC initiator (1), - The NFC initiator (1) retrieves information from the NFC tag (20) of the NFC target (2). Method according to claim 1, characterized in that the component (10) for increasing the power of the modulated communication signal is activated manually by the user via the user interface (12). Emergency communication system of an NFC initiator (1) and an NFC target (2) for carrying out the method according to claim 1 or 2, characterized in that it comprises an NFC initiator (1) which is an active NFC device provided with a performance enhancing component (10) modulated communication - 4 CZ 308380 B6 signal transmitted from the antenna (11) by adjusting the reference voltage or current of the sine generator, and a wirelessly connected NFC tag (20) of the NFC target (2), the NFC target (2) being an active NFC device provided with at least one NFC tag (20). The system according to claim 3, characterized in that the NFC target (2) is a mobile phone. System according to claim 3 or 4, characterized in that the component (10) for increasing the power of the modulated communication signal is connected to a user interface (12) for manual activation by the user. O System according to claim 5, characterized in that the user interface (12) is a button or a touch screen.